Next Article in Journal / Special Issue
Safety Bubbles: A Review of the Proposed Functions of Froth Nesting among Anuran Amphibians
Previous Article in Journal / Special Issue
Acquisition of Adaptive Traits via Interspecific Association: Ecological Consequences and Applications
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

The Subnival Vegetation of Moquegua, South Peru: Chasmophytes, Grasslands and Cushion Communities

1
Environmental Sciences, Plant Ecology and Nature Conservation Group, Wageningen University, Droevendaalsesteeg 3a, 6708 PB Wageningen, The Netherlands
2
Escuela Profesional de Ingeniería Ambiental, Universidad Nacional de Moquegua, Pacocha, Ciudad Jardín s/n, Mariscal Nieto, Moquegua, Peru
3
Naturalis Biodiversity Centre, Darwinweg 2, 2333 CR Leiden, The Netherlands
4
Institute for Biodiversity and Ecosystem Dynamics (IBED), University of Amsterdam, P.O. Box 94248, Science Park 904, 1098 XH Amsterdam, The Netherlands
*
Author to whom correspondence should be addressed.
Submission received: 19 December 2020 / Revised: 31 December 2020 / Accepted: 12 January 2021 / Published: 20 January 2021
(This article belongs to the Special Issue Feature Papers of Ecologies 2021)

Abstract

:
The present work is a phytosociological synthesis and syntaxonomic overview of the vegetation of the highest subnival parts (superpuna) of the open alpine vegetation of the high plateaus (puna) of the Andes of Moquegua, South West Peru, as related to the main environmental gradients. Using TWINSPAN and DCA ordination analysis, 153 phytosociological relevés were analyzed. For each association, subassociation and community, the syntaxonomy, floristic diversity and relation with environmental variables are described. The syntaxonomy and synecology of superpuna vegetation was studied in 19 localities at an altitude of 4450–4800 m. The study area has a pluviseasonal climate with yearly rainfall (December-April). Four main highland vegetation types were distinguished: 1. slope and scree chasmophyte vegetation composed of shrubs, cushions, ground rosettes and grasses, 2. grasslands (grazed and ungrazed) characterized by great species richness in shrubs, cushions, ground rosettes, grasses and herbs, 3. vegetation of plateaus with cushions, shrubs, ground rosettes, herbs and grasses and 4. nitrophilous vegetation with high cover and low species richness. Within the vegetation of the orotropical and cryorotropical bioclimatic belts three phytosociological classes can be distinguished: Argyrochosmetea niveae (chasmophytic vegetation), Calamagrostietea vicunarum (grasslands with cushions), Anthochloo lepidulae-Dielsiochloetea floribundae (highland slopes and plateaus) and a nitrophylous community. One new association from rock and scree slopes was described within the Saxifragion magellanicae (Argyrochosmetea niveae). Within the Calamagrostion minimae, which comprises grasslands with cushions and mat-forming plants, one new association with two subassociations could be distinguished. Within the grassland and cushion associations of the Azorello-Festucion (Calamagrostietea vicunarum), three new associations were described, comprising nine subassociations. In the Anthochloo-Dielsiochloetalia one new and one previously described association and one community are distinguished. In addition, the nitrophilous community of Tarasa nototrichoides and Urtica flabellata has been described. In total the vegetation comprised 172 vascular species belonging to 32 families. Our study provides the first syntaxonomic revision of chasmophytes, cushion associations and high-altitude grasslands in the Andes of North Moquegua. The proposed syntaxonomic scheme contains the associations distributed under similar habitat conditions throughout the Southern Andes of Peru, but also the associations reflecting the local floristic and environmental patterns. The subnival vegetation of Moquegua hosts some rare endangered and/or protected plant species.

1. Introduction

The puna is one of the world’s largest pastoral ecosystems in the tropical mountains and its flora, (including many endemic species) and vegetation are vulnerable to human pressure. A reference and tool for nature conservation is highly needed. Its vegetation is however still insufficiently studied. An overview of plant species assemblages and their relation to environmental conditions is largely missing. This especially applies to the highest part of the Moquegua study area over 4400 m. The relation between diversity and species composition of the superpuna vegetation and environmental factors such as altitude, slope aspect and angle, cover of rocks and stones and soil properties is largely unknown.In the traditional vegetation classification of Bolivia and Peru, the term puna is used to identify the open alpine vegetation of the high plateaus of the Central Andes [1,2,3,4,5,6]. Reference [7] defined the puna as a level area termed Altiplano. References [8,9] use the term superpuna to refer to the highest subnival parts of the puna with isolated patches of snow. The subnival zone of tropical mountains is characterized by a variable climate. This means cold freezing nights and low to moderate temperatures during daytime [7,10,11,12,13]. Night temperature is lowest at ground level before sunrise. Nightly freezing causes daily frost heaving with a number of phenomena at soil surface level, which also has an impact on plant life.
In this research we define the superpuna as the zone between 4450 and 4800 m (permanent snowline in Moquegua) with average annual temperatures ranging from 6 degrees C at 4500 m to 0 degrees C at 4800 m a.s.l. Mean annual precipitation is low: between 400 and 600 mm per year [14].
Growth forms in the extreme habitat of the subnival zone of the puna correspond mainly to low evergreen shrub, low herbs with thick cuticle and/or hairy leaf surface, and lax and compact cushions [7].
In the north of Moquegua growth forms of the superpuna vegetation include the scarce presence of dwarf and erect shrubs, tussock grasses, and annual herbs. More abundant is the presence of ground rosettes, cushions, mats and annual grasses. Cushions are abundant in the superpuna as well; they are known to enhance diversity by nursing other species [8,15,16], although some cushions appear to be non-facilitators [17]. Due to the near absence of tussock grasses grazing and fire are practically absent.
The continuous fumarolic activity of the Ubinas volcano [18] could have strong negative effects (not studied) on the plant communities in North Moquegua.
Several authors [4,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34] have studied plant communities of the superpuna of the Central Andes, their ecology, structure and floristic composition.
References [35,36] presented the first research on the structure and ecology of the prepuna and puna vegetation in the Andes of North Moquegua between 3470 and 4500 m.
The present contribution concerns the upslope communities between 4500 m and the lower border of snow and ice at about 4800 m in the Andes of North Moquegua. We try to provide more insight into the relation between superpuna plant communities with their floristic composition, environmental variables and the rate of anthropic influence.
Finally, we present an overview of the superpuna vegetation between 4450 and 4800 m a.s.l.
The aim of this study is to: (a) present a syntaxonomic characterisation of the superpuna vegetation in South Peru, based on full synoptic tables. This settles the basis for the legend of future vegetation mapping in order to quantify the different vegetation types, important for management and nature conservation. (b) determine the distribution of chasmophytic, grassland and plateau vegetations in Moquegua (South Peru), (c) account for their rare, local occurrence and floristic diversity, and (d) evaluate the importance of superpuna rocky slopes, grasslands and cushion communities as habitats for specific vegetation types, and for some endemic plant species in Moquegua (South Peru).
The relation between the diversity and species composition of the superpuna vegetation and factors such as altitude, slope aspect and angle, cover of rocks and stones, soil properties and the disturbance caused by grazing is described here.

2. Study Area

The research was conducted in an area of approximately 720 km2 in the districts of Ichuña, Ubinas and Yunga, in the General Sánchez Cerro province and the district of Carumas in the Mariscal Nieto province, in the north of the department of Moquegua, South Peru. The study area is located at 70°54′02″, 70°32′32″ W and 16°06′11″, 16°15′31″ S (Figure 1, Table 1) at an altitude between 4450 and 4800 m a.s.l. Average annual precipitation at the Ichuña meteorological station at 3790 m a.s.l. is 460 mm, the mean minimum temperature is 3.7 °C and the mean maximum is 19.4 °C [14]. Precipitation is markedly seasonal, with over 80% of the annual rainfall (600–800 mm) falling between December and April [14] and significant interannual variability [37,38]. Recent floods correspond to the El Niño phenomenon by increased annual precipitation. Soil moisture ranges from 0 in the dry season to below 10% in the rainy season [39]. No glaciers have been observed on the highland mountains of North Moquegua. Nevertheless, after heavy rainfall, snow accumulates temporarily above 4700 m altitude. On the summit of the Ubinas volcano (5672 m a.s.l.), snow can be permanent during the rainy season (December–April) and occasionally during the dry season (May–November).
The study area is located in the high-altitude sectors of the southwestern Andes with Pacific tributaries. Here the geology is volcanic and sedimentary with intercalations of conglomerates and sand. Ravines and crevices have infill of sandy silt and calcareous sediment [40]. The fieldwork area comprises the high plateaus and rocky slopes of the two mountain chains of volcanic origin that form the watersheds of the upper Tambo, Paltuture and Ichuña rivers and their tributaries.
Reference [35] presented the vegetation zonation of the upper Tambo River in the Moquegua region and distinguished the orotropical and cryorotropical bioclimate [41] occurring between 4150 and 4650 m and characterized by chasmophytic associations and grasslands with cushions, which occur above 4500 m in Moquegua. The cryorotropical zone was identified at altitudes above 4870 m where cushion associations are also present.

3. Methods

3.1. Data Collection

Floristics. The plant species were identified directly in the field; unidentified species were collected and later deposited in various herbaria (USM, HUSA, MOL, CPUN, CUZ, HSP, MO, L, WAG; acronyms according to [42]. Information on the taxonomy and species distribution was obtained from the literature. The nomenclature of the taxa is in accordance with [43], the electronic versions of [44,45,46]. Specific information on the taxonomy and species distribution was obtained from different sources [43,47,48,49,50,51,52].
Vegetation. Fieldwork was conducted over a period of five years (2009, 2011–2014) during the months of February, March, April and September.
A total of 153 relevés was made in 11 sites within an altitudinal range of 4450–4800 m a.s.l. Plot size was 25 m2 for grasslands and cushion vegetation and 16 m2, or 25 m2 for chasmophyte and 1 m2 for nitrophilous vegetation [9].
Within the different biotopes, sample plots (relevés) were randomly selected and positioned according to the principle of homogeneity as defined by the Zurich-Montpellier method [53]. We ensured that no sample relevés traversed ravines, clefts or streams. In chasmophytic environments, relevés were selected on pure rock stands including soil pockets and crevices. Contact with zonal grassland vegetation was avoided.
For each relevé, the presence of species was noted and its percentage actual cover was estimated [54,55]. Due to insufficient expertise only the presence of bryophytes and lichens was noted, but the species were not identified.

3.2. Environmental Variables

For each relevé we collected data on altitude (meters above sea level = m a.s.l.), slope inclination (degrees) and slope orientation (compass), cover of rocks and stones (percentage). Within each relevé, five subsamples were taken from the upper 10 cm of the soil and combined into one bulked sample for pH analysis in the laboratory (only for the relevés done in 2009). The presence of manure was determined by the amount of dung found in each relevé and classed as 0: absence; I: 1–30%; II: 31–70%; III: >71% (dung cover). Grazing intensity was determined by the percentage of tussock grasses showing signs of grazing at the moment of field analysis, and was later converted into the same I-III values.

3.3. Data Analysis

For computer calculations the percentage values were transformed into a nine-point ordinal cover/abundance scale [56]. The scales used were: 1% = 1; 2% = 2; 3% = 3; 4–7% = 4; 8–20% = 5; 21–37 = 6; 38–68% = 7; 69–88% = 8 and 89–100% = 9.

3.4. Classification

The relevés were classified by means of TWINSPAN [57]. In Table 2 species constancies are given in percentage values.
The first cluster analysis with 373 nr of relevés (153 this survey and 220 nr from literature) revealed an outgroup (61 relevés by [4,20,22,28,31,32,35,58,59,60,61] which was removed prior to the second run with the remaining 312 relevés including the relevés from the present survey as well as relevés from literature (Table 3, see heading of Table 3 for detailed description of the communities from other studies included in the analysis).
The second TWINSPAN analysis was run with 6 cutlevels resulting in 64 clusters. The clusters were checked for the presence of differentiall species in different hierarchical TWINSPAN cut-levels. Species are considered to be differential by their occurrence in clusters and contrasted with their absence or less frequent occurrence or smaller total estimate in other clusters [56]. Clusters without diferentials species were fused resulting in a final number of 27 clusters.
A synoptic-syntaxon table (Table 2) was constructed by reordering the species into syntaxonomic species groups after comparison with publications from [21,22,24,27,58,59].
Full association tables are presented in Supplementary Tables S1–S9. The character and differential species in the description of the associations are mentioned in order of their diagnostic value.
The assignment to class order, alliance, association and subassociation is based on the presence of diagnostic species as mentioned in relevant syntaxonomic publications. Besides the hierarchical structure of the table clearly shows the syntaxonomic level allowing the distinction and assignment of associations on the lowest level but one and characterised by their own diagnostic species. At the lowest level subassociations are distinguished based on the presence of differential species. Two vegetation types could not be described within the Braun-Blanquet system due to lack of data and were simply named community.
New syntaxa were described following the International Code of Phytosociological Nomenclature [62] and new syntaxonomic units were defined after reviewing [21,22,24,27,58,59].
The relation between each syntaxon and the environmental variables rocks, stones, slope degree and the vegetation cover was presented as box-and-whisker charts. Besides a chart is presented showing their altitudinal distribution.

3.5. Gradient Analysis

Detrended Correspondence Analysis (DCA; CANOCO 4.5, [63]) was used to study the relation between species composition and environmental variables.
The first DCA run with all 153 relevés resulted into two floristically and environmentally very dissimilar groups. The grassland and cushion vegetation was clearly separated from the vegetation from rock fissures (chasmophytic vegetation), scree (cryoturbate vegetation) and the nitrophylous vegetation. In order to better reveale the inner gradients DCA analysis was performed again, but now on both groups separately: the grassland and cushion vegetation with 112 samples and 153 speciesand the rock fissures, scree and the nitrophylous vegetation with 41 samples and 56 species.

4. Results

Classification of Relevés and Description of Vegetation Units

The classification resulted in 17 clusters separated by differential species (see Supplementary Tables S1–S9, in Table 2, the synoptic table only the 7 associations and 2 communities are represented). In this section we present an overview of these vegetation units, with information about physiognomy, composition, ecology and distribution. After comparison with literature, all vegetation units but one could be described as new associations. One vegetation unit could be assigned to the Nototricho obcuneatae-Xenophylletum poposi Galán de Mera, Cáceres & González 2003. The syntaxonomic affinity of the vegetation units is discussed below.
Saxifrago magellanicae-Leucherietum daucifoliae ass. nov.
(Table 2, col. 1; Table 3, col. 1, Supplementary Table S1, Typus: Rel 2; Figure 2).
Physiognomy and composition: Association of chasmophyte vegetation, with a variable cover by cushions, herbs and grasses. It consists of 4–20 cm tall cushions and herbs with a cover of 10–20% in combination with tussock grasses and dwarf shrubs (Ephedra rupestris) with a cover of 5%. Among the surface layer species with substantial cover are Leucheria dauciflora, Saxifraga magellanica, Calandrinia acaulis, Weberbauera spathulifolia and Microsteris gracilis. The cushion Pycnophyllum molle, present in two relevés, facilitates the presence of the rare orange-flowered Gentianella incurva. The grass layer is composed of the tussock Stipa ichu and the small grass Anthochloa lepidula.
Diagnostic species: Character species are Leucheria dauciflora, Perezia nivalis, Saxifraga magellanica, Gentianella incurva, Weberbauera arequipa and Perezia pinnatifida. Differential against other classes are Poa candamoana and Stangea rhizanta.
Ecology and distribution: This Andean chasmophyte association is generally found delimited by grassland, plateaus and steep rock formations, at edges of slopes or on hilltops. It is located at altitudes of 4580–4590 m, on south-facing slopes of 5–25°. The soils are mainly formed by unstable scree high in copper minerals, with stone particles and grayish-green mottling in the upper soil horizons. This association can be found on the rocky slopes of the Ichuña River valley, in the north of the Ichuña district.
Astragalo minimi-Azorelletum diapensioidis ass. nov.
(Table 2, col. 2.1–2.2; Table 3, col. 2; Supplementary Table S2, Typus: Rel. 6; Figure 3A).
Physiognomy and composition: Grassland vegetation with high density and diversity of dwarf shrubs, cushions, grasses, ground rosettes and annual herbs. Vegetation cover is between 20–80%, 57% on average. The 20–40 (50) cm tall resinous shrubs of Parastrephia quadrangularis cover 10% in four relevés only. Cushions attain 15–30% of the total cover and are represented by Azorella diapensioides and Pycnophyllum molle. Pycnophyllum glomeratum attains low cover in two relevés only. The grasses are mostly represented by Festuca orthophylla, which reaches high cover in most of the relevés. The ground layer is represented by few species with relatively higher cover: Dissanthelium calycinum, Hypochaeris meyeniana, Brayopsis calycina, Werneria pectinata, Belloa piptolepis, Astragalus minimus, Werneria apiculata, Aciachne pulvinata, Bouguiera nubicola, Oreomyrrhis andicola, the dwarf shrub Tetraglochin cristatum, among others. The absence of Festuca dolichophylla and Baccharis tricuneata is diagnostic. Ferns are absent. The mat-forming Astragalus minimus is dominant and forms dwarf and compact mats that extend to 30–40 cm in diameter; in common with other species of cushion plants, these cushion plants also host other species. This association is negatively characterized by the absence of Azorella compacta.
Diagnostic species: Character species are: Astragalus minimus, Azorella diapensioides, Bougueria nubicola, Junellia minima, Nototriche turritela, Nototriche longirostris, Ourisia muscosa, Viola hillii and Werneria apiculata. Differential species include: Crassula connata, Gomphrena meyeniana, Oxalis calachaccensis, Cyperus seslerioides and Lupinus cuzcensis.
Ecology and distribution: The association develops between 4460–4670 m altitude, covering extensive plateaus on slopes of about 11° with varied aspect. Soil texture is composed of fine scree, clay and sandy clay, with few rocks and stones. The association occurs in the highlands of the Ichuña district, near Cachilaya, Coriri, Jatun Puqio and Qhaqhaskinkri and the southern lower slopes of Pirhuani peak (Ubinas district). The association borders the syntaxa formed by Azorella compacta, grasslands and chasmophytic units.
Subassociation Typicum
(Table 2, col. 2.1; Supplementary Table S2, Typus: Rel. 6).
Physiognomy and composition: Characterized by the abundance of Astragalus minimus together with Azorella diapensioides, Pycnophyllum molle, Tetraglochin cristatum and Werneria melanandra. Other differences include the absence of several species belonging to the plateaus, which have greater species diversity, probably because more nutrients are available in the soil.
Diagnostic species: The subassociation typicum is differentiated by Werneria melanandra, Nototriche longirostris and Junellia minima.
Ecology and distribution: This subassociation develops on plateaus and slopes with a mixture of clayey sand and scree with concentrations of copper minerals, at altitudes ranging from 4580 to 4590 m in the sector of Puqa Saya, in the Ichuña district.
aciachnetosum pulvinatae subass. nov.
(Table 2, col. 2.2; Supplementary Table S2, Typus: Rel. 20).
Physiognomy and composition: By comparison with the subassociation typicum, the herb layer is more species-rich, herbs and cushions are more abundant; Azorella diapensioides is common.
Diagnostic species: The subassociation is species-rich and many differential species were identified: Aciachne pulvinata, Belloa schultzii, Conyza deserticola, Crassula connata, Cyperus seslerioides, Mancoa hispida, Ourisia muscosa, Oxalis calachaccensis and Viola hillii.
Ecology and distribution: The vegetation of this subassociation grows on extensive plateaus covered by clayey sand and with a relatively high cover of stones; rocks are almost absent. The subassociation develops at altitudes between 4460 and 4670 m a.s.l. greatly in slope orientation, rockiness percentage and grazing.
Astragalo pusilli-Parastrephietum quadrangularis ass. nov.
(Table 2, col. 3.1–3.3; Table 3, col. 3; Supplementary Table S3, Typus: Rel. 20; Figure 3A).
Physiognomy and composition: The association is characterized by the co-occurrence of the aromatic shrub Senecio nutans and the leptophyllous shrub Parastrephia quadrangularis. Ref. [19] refer to this association as orotropical and dry, situated on volcanic sediments and alluvial materials from the Pleistocene, which form large rocky slopes with soils of variable depth.
Diagnostic species: The following species can be considered to be character species of this association: Astragalus pusillus, Sisyrinchium brevipes, Sisyrinchium trinervis, Laennecia artemisioides and with lower frequency Valeriana aschersoniana, Belloa longifolia, Descurainia sp. (# 0940) and Junellia pappigera.
In addition, species such as the nitrophilous Perezia multiflora, Galium corymbosum, Loricaria graveolens, Oxalis nubigena, Lobivia maximiliana, Asplenium peruvianum, Adesmia spinosissima, Oxalis debilis and Weberbauera peruviana are considered to be differential against the other alliances. This association differs from other similar associations by the permanent presence of Parastrephia quadrangularis, Azorella compacta and the tussock Stipa ichu. In contrast with other associations described for the same class, Gomphrena meyeniana, Senecio evacoides, Pycnophyllum glomeratum, Nototriche mandoniana and Werneria aretioides are absent.
Ecology and distribution: The Astragalo pusilli-Parastrephietum quadrangularis is widespread on the southern slopes of Peru in areas with intense grazing. In our study area it occurs between 4450–4560 m a.s.l. The association develops on slopes (mean inclination: 22°) with a relatively high cover of rocks (mean: 28%) and stones (20%). We distinguished three new subassociations distributed in the Rancho-Pirhuani area and environs of Condor Sallana, near Matazo locality (Ubinas district), Siliaca (Yunga district) and Qhaqhaskinkri in the Ichuña district.
sisyrinchietosum trinervis subass. nov.
(Table 2, col. 3.1; Supplementary Table S3, Typus: Rel. 3).
Physiognomy and composition: Characterized by the relative abundance of Sisyrinchium trinervis together with Pycnophyllum molle, Paronychia andina and Parastrephia quadrangularis. Annual herbs are relatively abundant but low in cover; like the cushions and shrubs, their cover is between 15 and 20%. The cushion Azorella compacta is present in four relevés.
Diagnostic species: The sisyrinchietosum trinervis is differentiated by Sisyrinchium trinervis and Nototriche digitulifolia.
Ecology and distribution: The sisyrinchietosum trinervis grows on bare soils on slopes with 5–20° inclination and facing N to NE. Rocks cover between 25–50% and stones between 10–15%. Three out of ten relevés appeared to be intensively grazed. The sisyrinchietosum trinervis occurs around 4450 m a.s.l. in the Rancho-Pirhuani area, near Tassa locality in the Ubinas district and it borders the chasmophytic Loricario graveolentis-Pycnophylletum mollis [51] and the Calamagrostion minimae (this study, [51]).
baccharidetosum tricuneatae subass. nov.
(Table 2, col. 3.2; Supplementary Table S3, Typus: Rel. 8).
Physiognomy and composition: Characterized by the abundance of Baccharis tricuneata together with Stipa ichu, Azorella compacta, Parastrephia quadrangularis and Belloa piptolepis. The herb layer is dominated by Calamagrostis vicunarum, Werneria pectinata, Galium corymbosum and Bartsia diffusa. The cushion Pycnophyllum molle occurs in four relevés and Senecio nutans is found in five relevés only.
Diagnostic species: The baccharidetosum tricuneatae is mainly differentiated by Baccharis tricuneata, Cumulopuntia boliviana subsp. ignescens, Galium corymbosum, Bartsia diffusa, Senecio nutans, Oxalis nubigena, Perezia multiflora, Muhlenbergia peruviana, Werneria pectinata and by some other species with low cover only, such as Descurainia sp. (# 0940), Junellia pappigera and Valeriana aschersoniana.
Ecology and distribution: This subassociation develops on plateaus and slopes with clayey soils; rocks cover 20–50% of the surface. Most relevés are intensively grazed and contain manure. The baccharidetosum tricuneatae grows around 4500 m a.s.l. Its vegetation cover is about 45%. It is found in the surroundings of the road between Carmen Chaclaya and Matazo sites in the Ubinas district.
Subassociation Typicum
(Table 3, col. 3,3; Supplementary Table S3, Typus: Rel. 20).
Physiognomy and composition: By comparison with the other subassociations of the Astragalo pusilli-Parastrephietum quadrangularis, the vegetation cover and species richness are higher. The species composition comprises several companions such as: Adesmia spinosissima, Astragalus peruvianus, Bartsia diffusa, Calamagrostis curvula, Galium corymbosum, Geranium sessiliflorum, Lepidium meyenii, Luzula vulcanica, Microsteris gracilis, Paronychia andina, Senecio nutans and Stipa ichu, the last species probably as an effect of grazing. The shrub Parastrephia quadrangularis is abundant and covers 10–15%, the cushion Azorella compacta also attains a high cover compared to the other units, and so does the spiny shrub Tetraglochin cristatum.
Diagnostic species: This subassociation is mainly differentiated by Astragalus pusillus, Sisyrinchium brevipes and Conyza sp. (# 2601), but also by the low frequency of Cardionema ramosissimum and Mancoa hispida.
Ecology and distribution: The subassociation typicum occurs at altitudes averaging 4500 m on stony slopes in the Coriri and Qhaqhaskinkri sites in the Ichuña district. On average, the measured pH was 5.6.
Senecioni moqueguensis-Pycnophylletum mollis ass. nov.
(Table 2, col. 4.1–4.4; Table 3, col. 4; Supplementary Table S4, Typus: Rel. 7; Figure 4).
Physiognomy and composition: Plateau vegetation with abundant cushion and mat-forming plants. Vegetation cover varies between 30–70%. Bare soil is frequently covered by fine stone particles. Shrubs are less frequent and cover between 4–8% (20–40 cm height); they are mainly represented by Baccharis tricuneata and Parastrephia lucida.
Diagnostic species: Character species are Senecio moqueguensis, Senecio tassaeensis, Nototriche sepaliloba, Cerastium behmianum, Oritrophium sp. (# 2194b), Werneria heteroloba, Xenophyllum weddellii, Nototriche argentea, Arenaria acaulis, Gentainella primuloides, and some other species with lower presence like Perezia coerulescens var. amplibracteata and Senecio sp.1 (# 4217a). Differentials against other associations include: Mniodes coarctata, Geranium sessiliflorum, Calandrinia acaulis, Hypochaeris eriolaena and Werneria aretioides.
Ecology and distribution: The vegetation represented by the Senecioni moqueguensis-Pycnophylletum mollis spreads over areas with partial rock cover (13%) and stones (28%) on the extensive plateaus at an altitude of 4500–4830 m in North Moquegua. The slopes (about 11° with varied aspect) for this association are characterized by the abundance of the cushion Pycnophyllum molle and, with less presence, Azorella compacta. Wild animals were seen in the landscape during fieldwork. Dung from domesticated bull (Bos taurus), vicuña (Vicugna vicugna) and deer (Hippocamelus antisensis) was recognized in a few relevés across the sites. There were no signs of grazing. The wild animals tend to graze other species such as small grasses and herbs. The distribution is limited to Gasawasi-Witopata plateaus, the northern lower slopes of Pirhuani peak, the extensive plateaus surrounding the group of lakes upslope Coalaque and Querala localities, the Matazo locality environs (Ubinas district) and the Choco-Choco lower mountain slopes in Yunga district.
Subassociation typicum
(Table 2, col. 4.1; Supplementary Table S4, Typus: Rel. 7).
Physiognomy and composition: By comparison with the other subassociations of the Senecioni moqueguensis-Pycnophylletum mollis, the vegetation attains lower cover and lower species richness. Stones (24%) have a higher cover than rocks (9%). The cushion Pycnophyllum molle, Senecio moqueguensis (mat-forming), Mniodes sp. (# 2477) (a rigid cushion with grayish leaves in a rosette and inconspicuous yellow flowers) and Azorella compacta are frequent. Tussock grasses are represented by Festuca orthophylla in twelve relevés. Shrubs are well represented by Baccharis tricuneata and Parastrephia lucida.
Diagnostic species: This subassociation typicum is differentiated by Mniodes sp. (# 2477), Myrosmodes sp. (# 2287), Lupinus sp. (# 2424) and Senecio scorzonerifolius. Weberbauera spathulifolia, Hypochaeris eriolaena, Poa candamoana, Perezia coerulescens and Lepidium meyenii are differential against the other subassociations.
Ecology and distribution: The subassociation typicum grows between 4530 and 4700 m, on the extensive plateaus (5–20°) and rocky slopes (20–45°) of the Gasawasi-Witopata site, the northern lower slopes of Pirhuani peak, the extensive plateaus surrounding the group of lakes upslope Coalaque and Querala localities (Ubinas district) and the Choco-Choco lower mountain slopes in Yunga district. Vegetation cover attains 20–70%; soils are mainly clayey sands.
senecionetosum tassaensis subass. nov.
(Table 2, col. 4.2; Supplementary Table S4, Typus: Rel. 17).
Physiognomy and composition: Characterized by the low abundance of Xenophyllum weddellii and of Stangea wandae. Pycnophyllum molle, Senecio moqueguensis, Werneria aretioides and Belloa piptolepis attain high cover. Other differences include the absence of shrubs, except for Tetraglochin cristatum, which acquires a decumbent habit on the slopes. The cushion Azorella compacta is less frequent in the company of Pycnophyllum molle. Species richness is relatively high, probably due to the presence of species related to grazing and manure.
Diagnostic species: The senecionetosum tassaensis is mainly differentiated by species such as Senecio tassaensis, Xenophyllum weddellii, Oritrophium sp. (# 2194b) and Werneria heteroloba.
Ecology and distribution: This subassociation develops on plateaus (5°) and slopes (8–14°) with a mixture of clayey sand, at altitudes between 4510 and 4700 m on the northern plateaus of the Ubinas district.
gentianelletosum primuloides subass. nov.
(Table 2, col. 4.3; Supplementary Table S4, Typus: Rel. 33).
Physiognomy and composition: This subassociation is characterized by thirty-four species recorded from 7 relevés. Senecio moqueguensis has low constancy and cover and occurs in combination with Pycnophyllum molle, P. glomeratum, Azorella compacta, Festuca orthophylla, Parastrephia lucida and Stangea rhizantha.
Diagnostic species: The gentianelletosum primuloides is differentiated by species such as Gentianella primuloides, Senecio graveolens, Xenophyllum digitatum and Viola sp. (# 4217a).
Ecology and distribution: The gentianelletosum primuloides grows between 4590 and 4680 m, on the extensive plateaus (5–10°) of the Yunga district. Vegetation cover attains 35–65%.
arenarietosum acaulis subass. nov.
(Table 2, col. 4.4; Supplementary Table S4, Typus: Rel. 41).
Physiognomy and composition: Characterized by the abundance of Senecio moqueguensis together with Pycnophyllum molle, Azorella compacta, Parastrephia lucida, Mniodes coarctata and Werneria pectinata.
Diagnostic species: The arenarietosum acaulis is differentiated by Arenaria acaulis, Nototriche sepaliloba, Cerastium behmianum, Nototriche pusilla, Senecio sykorae, Poa brevis, Spergularia andina and Werneria sp. (# 3940).
Ecology and distribution: The vegetation of the subassociation grows on rocky soils, on slopes and plateaus at altitudes averaging 4580 m in the Condor Sallana environs close to Matazo locality (Ubinas district).
Calamagrostio trichophyllae-Azorelletum compactae ass. nov.
(Table 2, col. 5.1–5.2; Table 3, col. 5; Supplementary Table S5, Typus: Rel. 14; Figure 5).
Physiognomy and composition: In a total of twenty-two relevés many endemics from Peru were recorded. Shrubs are more frequent than in the preceding associations. The diagnostic cushion Azorella compacta can reach up to 50 cm in height with 1.5 m of diameter. Other cushions and mat-forming species are also common (Pycnophyllum molle, P. glomeratum, Brayopsis calycina, Senecio humillimus, S. evacoides, Erigeron rosulatus), together with many rosette herbs and grasses. Shrubs are mostly represented by the constant Parastrephia lucida and, with low cover, also by Baccharis tricuneata, B. caespitosa, Senecio nutans and the caespitose chamaephyte Ephedra rupestris. Cacti are represented by the cushion-forming Cumulopuntia boliviana subsp. ignescens. Tetraglochin cristatum is absent.
Diagnostic species: Diagnostic species of this species-rich association are Calamagrostis trichophylla, Nototriche mandoniana, Silene mandonii and Perezia pungens. Character species are the following: Chaetanthera peruviana, Cumulopuntia boliviana subsp. ignescens, Microsteris gracilis, Plantago sericea var. lanuginosa, Poa candamoana and Stangea rhizantha.
Ecology and distribution: The vegetation of this association is widely distributed on steep rocky slopes and plateaus with clayey-sandy soils and scree. This vegetation grows on the highest peaks and plateaus of the study sites between 4590–4800 m in Yanapuquio (Ichuña district), Laguna Jallpacocha environs (Ubinas district) and Perusa (Yunga district). The vegetation consists of both annual and perennial species.
Subassociation typicum subass. nov.
(Table 2, col. 5.1; Supplementary Table S5, Typus: Rel. 14).
Physiognomy and composition: The shrub Parastrephia lucida is abundant and covers 8–13%. The cushions Azorella compacta are as well represented as those of Pycnophyllum molle and also have a relatively high cover and presence.
Diagnostic species: This subassociation is differentiated by Mniodes caespititia, Senecio sp.2 (# 3935), Erigeron lanceolatus, Werneria glaberrima and Nototriche pedatiloba. Stangea rhizantha, Microsteris gracilis and Cumulopuntia boliviana subsp. ignescens are differentials against the other subassociation.
Ecology and distribution: The vegetation of the subassociation occurs at an altitude of between 4715 and 4800 m on slopes with a mixture of scree and sandy-clay and has a wide distribution on the lower slopes of the Choco-Choco Mountain (Yunga district).
drabetosum soratensis subass. nov.
(Table 2, col. 5.2; Supplementary Table S5, Typus: Rel. 20).
Physiognomy and composition: This subassociation is characterized by high species diversity; 44 species were recorded from 7 relevés. Draba soratensis has high constancy and cover and occurs in combination with Azorella compacta, Pycnophyllum molle, Parastrephia lucida, Baccharis caespitosa, B. tricuneata, Ephedra rupestris, Belloa piptolepis, Pycnophyllum glomeratum and Poa candamoana.
Diagnostic species: The drabetosum soratensis is differentiated by Draba soratensis, a dwarf rosette herb with greenish ciliated leaves and white flowers, and by species such as Bartsia sp. (# 3092), Poa gilgiana, Agrostis breviculmis, Lupinus chilensis and Viola granulosa.
Ecology and distribution: The drabetosum soratensis grows between 4590 and 4665 m on the summits and slopes of the mountains north of the Ichuña locality in the Yanapuquio site (Ichuña district).
Assoc: Nototricho obcuneatae-Xenophylletum poposi Galán de Mera, Cáceres & González 2003
(Table 2, col. 6.1–6.2; Table 3, col. 6; Supplementary Table S6; Figure 6).
Physiognomy and composition: Plateau vegetation with abundance of cushions represented by Mniodes coarctata (5–10 cm height, 40–60 cm of diameter) and Senecio adenophyllus (60–80 cm) and Xenophyllum poposum (10–20 cm). The vegetation cover is 10–50%. The shrub layer is composed of Senecio adenophyllus, Xenophyllum poposum, and with a lower cover of Parastrephia lucida and Senecio nutans. In the herb layer cushions are relatively abundant (Mniodes coarctata, Pycnophyllum molle, P. glomeratum), attaining 10–20% of the total percentage cover. The herbs comprise Anthochloa lepidula and Calamagrostis curvula.
Diagnostic species: Character species are Xenophyllum poposum and Mniodes coarctata. Moreover, Senecio tassaensis, Pycnophyllum molle, Werneria pectinata, Mniodes sp. (# 2477) and Astragalus uniflorus are differential species against the other syntaxa of the Nototrichion obcuneatae.
Ecology and distribution: The Nototricho obcuneatae-Xenophylletum poposi grows at 4650–4735 m on 2–10° slopes (facing N, NE, NNW, S, SE, SSE, W or WNW). The superficial, stony and bare soils occur on the summits of the Pirhuani peak (Ubinas district), the lower mountain peaks of Choco-Choco (Yunga district) and the scree plateaus of the puna desert of the Janchata lower slopes (Carumas district).
nototrichietosum erinaceae subass. nov.
(Table 2, col. 6.1; Supplementary Table S6, Typus: Rel. 6).
Physiognomy and composition: By comparison with the other subassociation of the Nototricho obcuneatae-Xenophylletum poposi, the vegetation attains higher cover and species richness. Stones (40%) have a higher cover than rocks (4%). The cushion-forming Pycnophyllum molle, Mniodes coarctata and Pycnophyllum glomeratum are frequent. Tussock grasses are absent. Shrubs are represented by Senecio nutans and Parastrephia lucida, both with low cover.
Diagnostic species: This subassociation is differentiated by Nototriche erinacea. Differentials against the other subassociation are: Pycnophyllum molle, P. glomeratum, Senecio nutans, S. tassaensis, Parastrephia lucida, Luzula vulcanica and Mniodes sp. (# 2477)
Ecology and distribution: The nototrichietosum erinaceae grows between 4650 and 4735 m, on the extensive plateaus (5–10°) of the Pirhuani peak (Ubinas district) and the lower mountain peaks of Choco-Choco (Yunga district). Vegetation cover attains 20–45%; soils are a mixture of clayey sand.
senecionetosum trifurcifolii subass. nov.
(Table 2, col. 6.2; Supplementary Table S6, Typus: Rel. 14; Figure 7).
The description of this subassociation is based on 5 relevés containing 12 vascular species.
Physiognomy and composition: Association of vegetation growing on a mixture of scree and volcanic sand deposits, with low diversity of species and extensive bare soils. It consists of 4–20 cm tall resinous shrubs (Senecio trifurcifolius) with a cover of 5–10% in combination with few grasses and herbs attaining less than 5% cover. The cushion Mniodes coarctata and mat-forming Xenophylum poposum co-occur with a cover of 5–7%.
Diagnostic species: Character species are Senecio trifurcifolius and Senecio sp.4 (# 4228b). Differentials against the other subassociation are Nototriche obcuneata and Trisetum spicatum.
Ecology and distribution: This Andean chasmophyte subassociation is generally found on the extensive plateaus formed by the volcanic lower slopes and locally known as “puna desert”. It is located at altitudes of 4700–4710 m (probably extending up to 4800 m a.s.l.), and a slope of 5–10° facing southeast. The soils are mainly formed by scree and white volcanic sand deposits. This vegetation can be found on the Janchata lower slopes (Carumas district) and presumably also occur on the lower pumice slopes of the Huaynaputina and Ticsani volcanoes. It is worth mentioning that several herds of vicuña (Vicugna vicugna) were seen during fieldwork.
Poo aequiglumae-Xenophylletum dactylophylli ass. nova
(Table 2, col. 7; Table 3, col. 7; Supplementary Table S7, Typus: Rel. 2).
Five relevés were made, containing 15 species.
Physiognomy and composition: Characteristic are the rocky and scree slopes with low vegetation cover and low species diversity. The resinous dwarf shrub Xenophyllum dactylophyllum is common, together with the short grass Anthochloa lepidula and the ground rosette Nototriche obcuneata. Vegetation cover is about 10–15%. Cushion plants are almost absent, except for Pycnophyllum glomeratum, which was found in only one relevé, with low cover. Shrubs are represented by Senecio nutans and Parastrephia lucida with very low cover. Tussock grasses are absent.
Diagnostic species: Character species are Xenophyllum dactylophyllum, Nototriche sp.3 (# 2447), Poa aequigluma and Poa spicigera.
Ecology and distribution: Cryorotropical association with SSW aspect, with extension to an altitude of 4800 m a.s.l. The association was only found on the Choco-Choco rocky slopes (Yunga district) and is assumed to occur on other slopes and summits above 4800 m in the neighboring departments in South Peru.

5. Community of Senecio algens

(Table 2, col. 8; Table 3, col. 8; Supplementary Table S8, representative Rel. 2).
Physiognomy and composition: Almost bare scree slopes with low species diversity. The unique appearance of the shrub Senecio sp.5 (# 3942) (apparently a new species) is very characteristic of the landscape and the less than 10 cm high Senecio algens develops with low cover between the scree stones. 90% of the soils are formed by white scree and rarely by volcanic rocks (except in one relevé). Vegetation cover is about 5%, the slope is 35–45°, facing W or NW.
Diagnostic species: Characteristic species are Senecio algens and Senecio sp.5 (# 3942). Stangea rhizantha is differential against the other units of the alliance.
Ecology and distribution: Cryorotropical community distributed at about 4750 m a.s.l. The community was only found on the Choco-Choco scree slopes (Yunga district) and is assumed to occur on other mountain summits above 4700 m in the neighboring departments of South Peru. Ref. [22] recognized the occurrence of the community at lower altitude with a mixture of species belonging to grasslands. Ref. [64] indicates that S. algens can be found on chasmophytic rocky slopes as well as in cryoturbate conditions, however, [22] recognized the occurrence of the community at lower and higher altitude with a mixture of species belonging to the puna grasslands.
Tarasa nototrichoides and Urtica flabellata community
(Table 2, col. 9; Table 3, col. 9; Supplementary Table S9, representative Rel. 8, Figure 8).
Physiognomy, composition and syntaxonomy: Due to the nitrogen-rich accumulations of manure, species such as Urtica flabellata become dominant; in some areas, together with other species, it covers almost 100% of the soil surface.
Diagnostic species:Urtica flabellata, Jaborosa squarrosa and Valeriana sp. (Image DSC075, 03/2014) have only been found in this community. Other diagnostic species are Lachemilla pinnata, Perezia multiflora and Tarasa nototrichoides. Dissanthelium calycinum occurs in all relevés.
Ecology and distribution: Nitrophilous community growing on llama and alpaca patches in grassland plateaus near grazing sites. The vegetation typically develops during the rainy season within a short 2–3-month period. The community of Tarasa nototrichoides and Urtica flabellata can be found between 4460 to 4650 m in North Moquegua, in a wide variety of habitats. Ref. [46] Includes the distribution of Urtica flabellata in the high Andes from Colombia to Argentina; there fore this puna and superpuna community can be assumed to occur in a wide geographical area in the high Andes. The ecological and floristical optimum for this unit is found in the orotropical and cryorotropical bioclimatic belts. The distribution range of the unit is approximately between 4000–4800 m a.s.l.

6. Gradients and Zonation

As after the first DCA with all 153 samples the relevés clearly fell into two very dissimilar groups representing very different site conditions, subsequently two separate analyses were performed. One group contains the grasslands and tussock vegetation of the Calamagrostion and Azorello-Festucion and the other group consists of vegetation growing on mobile scree slopes (Nototrichion). The DCA diagrams (Figure 9 and Figure 10) show the relation between the vegetation units and environmental variables. In Figure 9, the main gradient in species composition (axis 1) is strongly correlated with altitude (r = 0.65), scree (r = 0.31), vegetation cover (r = −0.24), grazing (r = −0.22), manure (r = −0.16), stones (r = 0.03) and number of species (r = −0.06). The relation between the second axis and environmental variables is low, except for number of species (r = 0.34), vegetation cover (r = 0.31) and slope inclination (r = 0.27).
The grasslands with cushions (Astragalo pusilli-Parastrephietum quadrangularis and Astragalo minimi-Azorelletum diapensioidis) are positively correlated with grazing, number of species, vegetation cover and manure. The cushion association (Senecioni moqueguensis-Pycnophylletum mollis) is correlated with rocks, altitude and scree. The other cushion associations from higher altitudes (Calamagrostio trichophyllae-Azorelletum compactae) are correlated with altitude, percentage of stones, slope and rocks.
In Figure 10, the main gradient in species composition (axis 1) is strongly correlated with vegetation cover (r = 0.81), manure (r = 0.88), and further with stone cover percentage (r = −0.57), scree (r = −0.56), number of species (r = −0.54), slope inclination (r = −0.43), altitude (r = −0.31), grazing (r = −0.28), and rock percentage (r = −0.16). The relation between the second axis and environmental variables is relatively low except, for inclination (r = 0.67), grazing (r = −0.29), scree (r = 0.25), altitude (r = 0.20) and number of species (r = −0.19). The nitrophilous community of Tarasa nototrichoides and Urtica flabellata is positively correlated with manure and vegetation cover and negatively correlated with stones, scree, slope, number of species and rock percentage. The chasmophytic unit, Saxifrago magellanicae-Leucherietum daucifoliae, plotted on the lower side of axis 2 is positively correlated with number of species, stones, slope and scree but negatively with manure and vegetation cover.
The Nototricho obcuneatae-Xenophylletum poposi correlated positively with number of species and negatively with manure and vegetation cover. The community of Senecio algens shows a positive correlation with scree, stone percentage and slope degree.
The relation between vegetation and environmental factors as shown by the ordination diagrams corresponds to the results as shown by Figure 11 in which the mean values for (a) slope degree, (b) vegetation cover, (c) rocks and (d) stones are given. The Calamagrostio trichophyllae-Azorelletum compactae develops on steeper slopes, as does the community of Senecio algens. In contrast, the community of Tarasa nototrichoides and Urtica flabellata develops on level surfaces. In graph b, vegetation cover is higher in the following units: community of Tarasa nototrichoides and Urtica flabellata, Astragalo pusilli-Parastrephietum quadrangularis subassociation typicum, Astragalo minimi-Azorelletum diapensioidis aciachnetosum pulvinatae and Senecioni moqueguensis-Pycnophylletum mollis subassociation typicum. The lowest vegetation cover (less than 20%) was recorded for the community of Senecio algens, Nototricho obcuneatae-Xenophylletum poposi senecionetosum trifurcifolii, Poo aequiglumae-Xenophylletum dactylophylli and Astragalo pusilli-Parastrephietum quadrangularis sisyrinchietosum trinervis. Astragalo pusilli-Parastrephietum quadrangularis grows on sites with a high rock cover. This is especially the case in two subassociations belonging to this association: the sisyrinchietosum trinervis and baccharidetosum tricuneatae. The mean rock cover is less than 10% in the Saxifrago magellanicae-Leucherietum daucifoliae (comm. 1), Astragalo pusilli-Azorelletum diapensioidis (comm. 2) and community of Senecio algens (comm. 8). The community of Tarasa nototrichoides and Urtica flabellata (comm. 9) grows on sites without bare rock.
In the community of Senecio algens (comm. 8) the surface is almost fully covered by stones (>90%) as well as in the Nototricho obcuneatae-Xenophylletum poposi senecionetosum trifurcifolii. Within the Saxifrago magellanicae-Leucherietum daucifoliae (comm. 1) the stone cover is 40 to 50%. Stones are almost absent in the community of Tarasa nototrichoides and Urtica flabellata (comm. 9).
Figure 12 shows the observed and expected altitudinal distribution of the syntaxa described in this overview. The gray boxes represent the distribution as based on the present field survey and the boxes in dashed lines the expected distribution based on the co-occurrence of the following character species of the syntaxa distinguished [48,65,66,67]: Saxifraga magellanica with Leucheria daucifolia; Astragalus minimus and Azorella diapensioides; Senecio nutans and Parastrephia quadrangularis; Senecio moqueguensis together with Azorella compacta; Anthochloa lepidula and Azorella compacta; Nototriche obcuneata with Xenophyllum poposum; Xenophyllum dactylophyllum; Senecio algens; Dissanthelium calycinum with Urtica flabellata. The expected altitudinal distribution of the different associations and community of Tarasa nototrichoides and Urtica flabellata is as follows: (1) Saxifrago magellanicae-Leucherietum daucifoliae (4500–4800 m a.s.l.), (2) Astragalo minimi-Azorelletum diapensioidis (4350–4700 m a.s.l.), (3) Astragalo pusilli-Parastrephietum quadrangularis (4250–4650 m a.s.l.), (4) Senecioni moqueguensis-Pycnophylletum mollis (4500–4800 m a.s.l.), (5) Calamagrostio trichophyllae-Azorelletum compactae (4550–4800 m a.s.l.), (6) Nototricho obcuneatae-Xenophylletum poposi (4600–4800 m a.s.l.), (7) Poo aequiglumae-Xenophylletum dactylophylli (4750–4950 m a.s.l.), (8) Community of Senecio algens (4450–4800 m a.s.l.) and (9) community of Tarasa nototrichoides and Urtica flabellata (4200–4700 m a.s.l.).
Family composition shows the same trend as observed in the Andean prepuna and puna of Moquegua [35,36], where the Composites dominate the vegetation. In the grasslands of Moquegua, species richness is greatest within the woody species belonging to the Composites, Fabaceae and Orobanchaceae, while in the ground layer the number of species is highest in the Malvaceae, Caryophyllaceae and Poaceae, followed by Plantaginaceae and Violaceae.

7. Floristic Composition Alfa-Diversity

In total, 172 vascular species belonging to 80 genera and 32 families were recorded. The flora list of the total relevé dataset is dominated by Asteraceae (60 spp.), Malvaceae (14 spp.), Poaceae (14 spp.), Brassicaceae (11 spp.), Caryophyllaceae (10 spp.), Fabaceae (9 spp.) and Apiaceae (4 spp.). The shrubs (postrate or erect, 5–70 cm height) are represented by 26 species, herbs (including rosettes) by 93 species, cushions by 14 species, mat-forming plants by 22 species, grasses by 13 species), and ferns and succulents by one species each.
In Figure 13, box-and-whisker plots show the species diversity of the different associations, subassociations and one community. The species richness of the Chasmophytic association can not be compared to the richness of the grassland and cushion vegetation as with 16 m2 the plot size is 9 m2 smaller (see Figure 13). The chasmophytic association Saxifrago magellanicae-Leucherietum daucifoliae) has a maximum of 15 species and a median of 11 species.
The highest species diversity was recorded in the Senecioni moqueguensis-Pycnophylletum mollis (comm. 4) and Calamagrostio trichophyllae-Azorelletum compactae (comm. 5), which have a median of 15 species and a maximum of 26 and 25 species respectively. Within the grasslands with cushions, species diversity in the Astragalo minimi-Azorelletum diapensioidis (comm. 2, median of 18 species and maximum of 23 species) is greater than that of the Astragalo pusilli-Parastrephietum quadrangularis (comm. 3), median of 13 species and maximum of 22 species. The species diversity is least in the Nototricho obcuneatae-Xenophylletum poposi (comm. 7) and in the community of Senecio algens (comm. 9), with a median of 6 species and maximum of 16 species; this is probably due to the extreme conditions in their high altitude growth sites.
The plot sizes of the relevés made in the nitrophilous community are only 1 m2 and only 4 to 6 species were counted per plot.
Within the chasmophytic association species richness generally decreases with elevation. However, species richness was observed to increase locally between 4500 and 4700 m in the cushion associations, probably as a result of nursing effects, sometimes in great abundance as seen in Azorella and Pycnophyllum [8,16]. Although lichens and mosses were not included in our phytosociological analysis, we noted their low diversity in the study sites. Low cover of Thamnolia vermicularis was observed in the Poo aequiglumae-Xenophylletum dactylophylli.

8. Syntaxonomic Affinity

The syntaxonomic relation of the communities described in this research was studied by comparison with literature. A large dataset was collected from [4,20,21,22,24,25,27,31,32,58,59,60,61,68]. After cluster analysis with all data an outgroup was detected and these relevés were excluded from a second run. The remaining 27 clusters are represented in Table 3 in which the species are ordered into syntaxonomic species groups to show their syntaxonomic affinity. New syntaxonomic units were defined after reviewing [20,21,22,25,27,58,59].
The vegetation vegetation of rock crevices, grassland and cushion vegetation, and vegetation of mobile scree slopes could respectively be assigned to the Argyrochosmetea niveae, Calamagrostietea vicunarum, Anthochloo lepidulae-Dielsiochloetea floribundae. The class, order and alliance of the nitrophilous community should be defined by further research.
Based on the presence of Saxifraga magellanica, the new association Saxifrago magellanicae-Leucherietum daucifoliae has been assigned to the class Argyrochosmetea niveae, the order Saxifragetalia magellanicae and the alliance Saxifragion magellanicae. It grows on deep soils with fine scree across rock crevices, in the north of Moquegua, South Peru. Ref. [61] described the class Argyrochosmetea niveae as occurring at an altitude of 2500–3500 m in Junín (Central Peru), with Argyrochosma nivea, a fern species characteristic of rock crevices. Ref. [20] confirmed the presence of this species in the south of Peru, and we refer to the Argyrochosmetea niveae based on the occurrence of the superpuna alliance Saxifragion magellanicae [19] represented by Saxifraga magellanica.
The order and alliance combine the basaltic and andesite soils along the Andes of Peru, from Lima to Tacna regions [22].
Saxifraga magellanica grows on the south-facing highlands of the Yanahuara River in the Ichuña district. Saxifraga magellanica is a cushion-forming herbaceous rosette with whitish flowers; its distribution area is from Ecuador to South Argentina [46].
Four new associations were assigned to the order Parastrephietalia quadrangularis of the class Calamagrostietea vicunarum based on the presence of Calamagrostis vicunarum and many species of the Parastrephietalia (see Table 3).
Reference [22] proposed the class name Deyeuxietea vicunarum. According to [46] Deyeuxia vicunarum should be considered to be a synonym for Calamagrostis vicunarum and Calamagrostis vicunarum is the most frequently used name in the main taxonomic databases. Consequently, we suggest that the name Calamagrostietea vicunarum Rivas-Martínez & Tovar 1982 should be maintained instead of the new class name Deyeuxietea vicunarum Rivas-Martínez & Tovar 1982.
The Calamagrostietea vicunarum grows on clay and loamy clay (rarely on sand) on rocky slopes, plateaus and hills at 4450–4800 m a.s.l. in the Andean regions of North Moquegua, downslope it is in contact with the grassland vegetation dominated by Lupinus paruroensis and the giant bromeliad Puya raimondii and upslope with units of the Anthochloo-Dielsiochloetea.
The Parastrephietalia quadrangularis combines the puna grasslands extending from southwest Peru to West Bolivia, Northwest Argentina and Northwest Chile.
The Astragalo minimi-Azorelletum diapensioidis ass. nov. is assigned to the alliance Calamagrostion minimae. It is characterized by the presence of cushion plants, dwarf shrubs, tussock grasses, annual grasses and herbs. The high cover of the cushion Azorella diapensioides together with the mat-forming Astragalus minimus characterizes the association described within this alliance. The alliance occurs in the grassland puna known as “cesped de puna” formed by small herbs and ground rosettes with long root systems, mostly developing on open and uniform slopes with shallow soils. The alliance is known to occur in the highlands of Peru and Bolivia, between 4500 and 5000 m [29,58].
The Astragalo minimi-Azorelletum diapensioidis (Calamagrostion minimae) differs greatly from the Belloo piptolepis-Dissanthelietum calycini azorelletosum diapensioidis [20] and Baccharido caespitosae-Azorelletum diapensioidis [36] because of the absence of Festuca dolichophylla, Baccharis caespitosa and other elements of the puna. We have included this association in the Calamagrostion minimae [29] because of the abundance of cushion plants such as Azorella diapensioides and the presence of small grasses such as Calamagrostis minima, and the absence of some species characterizing the Azorello-Festucion and Nototrichion obcuneatae.
Three new associations, Astragalo pusilli-Parastrephietum quadrangularis, the Senecioni moqueguensis-Pycnophylletum mollis and the Calamagrostio trichophyllae-Azorelletum compactae were assigned to the alliance Azorello compactae-Festucion orthophyllae (Supplementary Tables S3–S5).
The grassland with cushion vegetation of South Peru is grouped into the Azorello compactae-Festucion orthophyllae [20,21,59]. Azorella compacta can be found in some restricted Andean regions in South Peru [6,39,65,69], Bolivia [70], Argentina [71,72] and Chile [73,74]. The Azorello compactae-Festucion orthophyllae represents the large tracts of superpuna grasslands in South Peru, in the Moquegua region where Festuca orthophylla, Tetraglochin cristatum, Parastrephia quadrangularis and P. lucida are common. Festuca orthophylla is the tussock grass that dominates the superpuna grasslands of Moquegua in association with the resinous shrub Parastrephia quadrangularis, which is replaced by Parastrephia lucida at altitudes higher than 4500 m and is well represented in the superpuna.
The Azorello compactae-Festucion orthophyllae comprises vegetation represented by grasslands with cushions, open plateaus with cushions, vertical cushion formations and scree units with cushions and dwarf shrubs. The relatively high presence and cover of the composite resinous shrub Parastrephia lucida that replaces Parastrephia quadrangularis in the altitudinal gradient characterize the associations described. The cushions Pycnophyllum molle and Azorella compacta are relatively abundant, together with the relative high cover of the tussock Festuca orthophylla which replaces Festuca dolichophylla as well as from the higher altitudinal gradient context. Festuca dolichophylla (which is a species from the lower altitudinal gradient)
This alliance dominates extensive areas in the puna and superpuna of North Moquegua [36], occurring in the Arequipa, Tacna and Puno departments [20,59]. In our study region, it occurs between 4450–4800 m a.s.l. The inclination varies from 0 to 90° and the orientation is variable. Grazing intensity varies; some grasslands are heavily grazed while others can be considered to be ungrazed.
The tussock Festuca orthophylla is distributed in our study sites at altitudes between 4450 and 4800 m, becoming more abundant at 4650 m and higher. The tussock grass distribution is in agreement with [75], who recorded Festuca dolichophylla in the subhumid puna of Bolivia at 3500–4000 m and 4500 m and Festuca orthophylla at higher altitudes, in the super puna and subnival puna (uppermost part of the superpuna). Above 4500 m Festuca orthophylla co-occurs with cushion plants such as Azorella and Pycnophyllum.
The new associations and subassociations with Azorella compacta described here differ from each other not only in species composition but also in altitude and distribution.
In the Calamagrostio trichophyllae-Azorelletum compactae ass. nov. the character species of the alliance Azorello-Festucion, Azorella compacta and Festuca orthophylla are very frequent. Anthochloa lepidula, considered to be a character species of the Anthochloo-Dielsiochloetea, appears to have a very wide syntaxonomic amplitude. Anthochloa lepidula, Dissanthelium calycinum and Senecio adenophyllus, character species of the Nototrichion obcuneatae, are only present at low frequency. By contrast, Azorella compacta and Baccharis caespitosa, both character species of the Azorello-Festucion, are relatively frequent. Consequently, this association is considered to belong to the Azorello-Festucion instead of the Anthochloo-Dielsiochloetea and Nototrichion obcuneatae.
Two associations and one community have been assigned to the alliance Nototrichion obcuneatae of the order and class, Anthochloo lepidulae-Dielsiochloetalia floribundae Rivas-Martínez & Tovar 1982 and Anthochloo lepidulae-Dielsiochloetea floribundae (for diagnostic species see Table 2).
According to [29] Anthochloa lepidula and Dielsiochloa floribunda are character species of the Anthochloo lepidulae-Dielsiochloetea floribundae. According to our table, however, although Anthochloa lepidula has a higher presence in this class, it appears to have a very wide syntaxonomic amplitude. Although the associations are well represented by character species, these are almost absent from the higher units. This might be due to the very extreme climatic conditions on the mountain summits.
The Anthochloo-Dielsiochloetea is highland vegetation characterized by ground rosettes, cushion and dwarf subshrubs, herbs and grasses. Soils are of cryoturbate origin with sparse stoniness and fissures in gelid rocks, located near the vegetation line [29] in the superpuna region.
The alliance of Nototrichion obcuneatae [19], combines a series of subnival associations identified in the Andean regions of the Moquegua department.
The Anthochloo lepidulae-Dielsiochloetalia occurs in the central Andes of Peru [68], southern Andes of Peru [20], Bolivia, Chile and NW Argentina [24,25,29] above 4600 m a.s.l.
The cryorotropical units described within Nototrichion obcuneatae (Supplementary Tables S6–S8) under the names Nototricho obcuneatae-Xenophylletum poposi [20] and Poo aequiglumae-Xenophylletum dactylophylli are similar to those described in Peru [60] and Bolivia [28,32] as having similar floristic affinities, such as Anthochloa lepidula, Nototriche obcuneata and Senecio adenophyllus. Both associations are more similar to those units described in Arequipa by [22] and Bolivia [32]. Our knowledge about the structure of these cryorotropical communities is incomplete because of the lack of studies in the different geographical regions of South Peru and Nortwest Bolivia.
The alliance is found on mobile scree slopes. As a consequence of solifluction, the plants are dispersed in sheltered hollows [20]. Based on the distribution of its character elements (Nototriche obcuneata, Xenophyllum poposum) it is a cryorotropical (dry-humid) alliance of the southern highlands of Peru and Bolivia [20,22,43,76]. It is characterized by the presence of ground rosettes with thick roots, resinous shrubs and cushions, herbs and small grasses. The associations belonging to this alliance can further be found in South Peru [20,22], SW Bolivia and NW Argentina (described as Chaetantherion sphaeroidalis by [20] where the species Chaetanthera sphaeroidalis is absent in our study region.

9. Nitrophilous Vegetation

Nitrophilous communities dominated by nitrophytes are found on patches of llama and alpaca dung in grassland plateaus and slopes in the South Andes of Peru. The communities have been found in rock shelters, where cattle and wildlife shelter during the night and heavy rain, and near traditional cattle corrals and farmhouses. Little is known about the occurrence of these specific plant communities in the Andes. It seems that populations of Urtica flabellata are widespread in the C Andes [77]. According to [6], Urtica flabellata as a ruderal species and colonizer of llama dung that can often be found in puna regions together with Cajophora cirsiifolia and tall Lupinus species.
We distinguished two nitrophylous communities, the community of Senecio algens and the Tarasa nototrichoides and Urtica flabellata community. As these vegetation types are still insuffiently studied and suggestions of proper alliances or associations are still missing in literature, no association names were suggested in this paper.
The community resembling the community of Senecio algens [22] was named accordingly.
Nitrophilous communities, but floristically more impoverished, can also be recognized in northern, Central and southern Peru [60,61], and Bolivia [60,61,77]. Reference [61] was based on data from the Central Andes; he was not aware of Bolivian records. Ref. [60] describe the close affinity of these communities to the class Nicotiano glutinosae-Ambrosietea arborescentis Galán de Mera & Cáceres in [19], which represents ruderal vegetation from lower altitudes with a very distinct structure and floristic composition.
In the prepuna (supratropical belt) in Central Peru (Prov. Yauli, dept. Junín) [61] described the Urtico flabellatae-Cajophoretum sepiariae between 3600 and 3800 m in the region South of La Oroya. He supposed that this association could belong to a still undescribed class. Additional observations were made of alpine Urtica flabellata communities on the West slope of the Andes between 3000 and 3600 m, above Huánuco 3900–4000 m, in North Peru above Cajamarca and near Huaraz and Cusco. We agree with the concept of Gutte that a true ruderal class seems to exist in the alpine zone of Peru. However, in our relevés of the superpuna of Moquegua the only species in common with [61] are the character species Urtica flabellata and Perezia multiflora. Urtica flabellata is also shared with the Urtico flabellatae-Urocarpidetum peruviani [60] (3320–3850 m a.s.l.). Urtica flabellata is found throughout the country and also from neighbouring Bolivia. It is known that Urtica flabellata also occurs in the páramos of Ecuador and Colombia [9]. On calcareous bedrock (Colombian Páramo Almorzadero) Lachemilla pinnata is associated with Urtica flabellata as well. For an adequate description of the class on the level of order and alliances, more relevés are needed. Thus far there are no relevés available for páramos. We conclude that these communities need further research using relevé data collection from both puna and páramo.

10. Discussion

There are few previous studies on species composition and diversity of superpuna grassland syntaxa in South Peru for comparison with our vegetation description. Refs. [4,20,21,22,60,61,77] address the phytosociological classification and description of plant associations and communities in the central and southern Peruvian Andes. Other studies from North Chile [24,25] and Bolivia [27,28,31,32,33]; were compared with our results and appear to differ significantly in species composition and distribution. Refs. [35,36] describe the prepuna shrublands, puna chasmophytes and grassland associations and communities occurring in the north of Moquegua under the classes Echinopsio-Proustietea cuneifoliae (prepuna shrublands) occurring at an average altitude of 3500 m, Argyrochosmetea niveae (chasmophytic vegetation) and Calamagrostietea vicunarum (puna grasslands) occurring between 3800 and 4500 m a.s.l. These associations lack the presence of cushion plants (Azorella compacta, Pycnophyllum spp.) and the tussock grass Festuca orthophylla.

11. Conspectus of the Syntaxa

Chasmophytic vegetation (Argyrochosmetea niveae)
Class: Argyrochosmetea niveae Gutte 1986
Order: Saxifragetalia magellanicae Galán de Mera & Cáceres in Galán de Mera et al. 2002
Alliance: Saxifragion magellanicae Galán de Mera & Cáceres in Galán de Mera et al. 2002
Association:
Saxifrago magellanicae-Leucherietum daucifoliae ass. nov.

12. Grassland and Cushion Vegetation (Calamagrostietea vicunarum)

Class: Calamagrostietea vicunarum Rivas-Martínez & Tovar 1982
Order: Parastrephietalia quadrangularis Navarro 1993
Alliance: Calamagrostion minimae Rivas-Martínez & Tovar 1982
Association and subassociations:
Astragalo minimi-Azorelletum diapensioidis ass. nov.
Subassociation typicum
aciachnetosum pulvinatae subass. nov.
Alliance: Azorello compactae-Festucion orthophyllae Galán de Mera, Cáceres & González 2003
Associations and subassociations:
Astragalo pusilli-Parastrephietum quadrangularis ass. nov.
sisyrinchietosum trinervis subass. nov.
baccharidetosum tricuneatae subass. nov.
Subassociation typicum
Senecioni moqueguensis-Pycnophylletum mollis ass. nov.
Subassociation typicum
senecionetosum tassaensis subass. nov.
gentianelletosum primuloides subass. nov.
arenarietosum acaulis subass. nov.
Calamagrostio trichophyllae-Azorelletum compactae ass. nov.
Subassociation typicum
drabetosum soratensis subass. nov.

13. Cryoturbate Vegetation (Anthochloo lepidulae-Dielsiochloetea Floribundae)

Class: Anthochloo lepidulae-Dielsiochloetea floribundae Rivas-Martínez & Tovar 1982
Order: Anthochloo lepidulae-Dielsiochloetalia floribundae Rivas-Martínez & Tovar 1982
Alliance: Nototrichion obcuneatae Galán de Mera, Cáceres & González 2003
Associations and subassociations:
Nototricho obcuneatae-Xenophylletum poposi Galán de Mera, Cáceres & González 2003
nototrichietosum erinaceae subass. nov.
senecionetosum trifurcifolii subass. nov.
Poo aequiglumae-Xenophylletum dactylophylli ass. nov.
Community of Senecio algens

14. Nitrophilous Vegetation

Class, order and alliance: Still to be defined by further research.
Community of Tarasa nototrichoides and Urtica flabellata

15. Concluding Remarks

Our vegetation research in northern Moquegua (South Peru), an area not studied previously, extends the knowledge of the syntaxonomy, floristic diversity and synecology of Azorella compacta and Pycnophyllum molle vegetation structure, and of chasmophytic and nitrophilous communities. It comprises four alliances, seven new associations and thirteen subassociations, representing an important basis for a future overview and synopsis of the Andean vegetation of tropical South America. The vegetation studied in Moquequa appears to be floristically different from comparable vegetation in North Chile and Bolivia. Further research is needed, however, to study the relation with chasmophytic and plateau associations with cushions in the highlands of other mountainous regions in South America.
The present overview is also important as a reference and tool for nature conservation. Apart from the impressive cushions plants, many endemic species are found in the newly described syntaxa, highlighting the need for conservation schemes and measures. In recent years, the superpuna syntaxa have been increasingly affected by grazing and road construction. The natural vegetation is being disturbed and cushions of Azorella compacta have regularly been removed for use as fuel. Fire has been regularly observed on several mountain slopes. These fires were probably set on purpose as part of a festivity in June. Fortunately, due to advice and information given to the local communities by the first author, this practice is now gradually decreasing (personal observation), and conservation programs have been started. At the same time, interviews with the local communities suggest that the pastures are being grazed in a way that prevents overgrazing. Negative effects have been observed only in some grassland syntaxa where livestock and wild grazers are abundant. In addition to livestock, wild grazers including vicuñas (Vicugna vicugna), viscacha (Lagidium peruanum), taruca (Hippocamelus antisensis) and suri (lesser rhea, Rhea pennata) are known to occur in the region. This highlights the vulnerability of the flora and vegetation of the Andes to human pressure, and requires further studies.

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/2673-4133/2/1/5/s1: Supplementary Table S1. Saxifrago magellanicae-Leucherietum daucifoliae, Supplementary Table S2. Astragalo minimi-Azorelletum diapensioidis, Supplementary Table S3. Astragalo pusilli-Parastrephietum quadrangularis, Supplementary Table S4. Senecioni moqueguensis-Pycnophylletum mollis, Supplementary Table S5. Calamagrostio trichophyllae-Azorelletum compactae, Supplementary Table S6. Nototricho obcuneatae-Xenophylletum poposi, Supplementary Table S7. Poo aequiglumae-Xenophylletum dactylophylli, Supplementary Table S8. Community of Senecio algens, Supplementary Table S9. Community of Tarasa nototrichoides and Urtica flabellate.

Author Contributions

D.B.M.-T. planned the research and conducted the field sampling, D.B.M.-T. and K.V.S. performed the statistical analyses and all authors (D.B.M.-T., A.M.C. and K.V.S.) jointly wrote and revised the manuscript. Conceptualization, D.B.M.-T., A.M.C. and K.V.S.; Methodology, D.B.M.-T. and K.V.S.; Software, D.B.M.-T.; Validation, D.B.M.-T., A.M.C. and K.V.S.; Formal Analysis, A.M.C. and K.V.S.; Investigation, D.B.M.-T.; Resources, A.M.C. and K.V.S.; Data Curation, D.B.M.-T., A.M.C. and K.V.S.; Writing—Original Draft Preparation, D.B.M.-T.; Writing—Review & Editing, D.B.M.-T., A.M.C. and K.V.S.; Visualization, D.B.M.-T., A.M.C. and K.V.S.; Supervision, A.M.C. and K.V.S.; Project Administration, K.V.S.; Funding Acquisition, A.M.C. and K.V.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Alberta Mennega Stichting, Utrecht, The Netherlands, grant number [11062014], and by the Nature Conservation & Plant Ecology Group (Wageningen University, The Netherlands).

Acknowledgments

Special thanks to the supervisors of the herbaria USM, HUSA, MOL, CPUN, CUZ, HSP, MO, WAG, L and WAG for the admission to their collections for the study of the botanical specimens. We are also thankful to the DGFFS (Dirección General de Flora y Fauna Silvestre—Ministry of Agriculture, Peru) for the permits (N°014-2009-AG-DGFFS-DGEFFS and N°283-2012-AG-DGFFS-DGEFFS) to make botanical collections during our study. We also thank I. Al-Shehbaz, H. Ballard, J. Campos, S. Castillo, M. Chanco, W. Galiano, P. Goldblatt, M.I. La Torre, B. León, C. Ostolaza, A. Pauca, J. Pringle, V. Quipuscoa, J. Roque, A. Meerow, E. Navarro, O. Tovar, H. Trinidad and D. Trujillo for their support in the taxonomical identification of species. We also thank the Alpine Garden Society members who surveyed the Andean regions of Mouquegua in 2014. Special thanks also to E. Banegas, F. Calisaya, J.C. Quiroz, A.C. Pinto, C. Tejada and D. Figueroa for fieldwork support. A. Noatzsch helped with German translations. M. Coler and E. Ventura gave support on the linguistics of the site names. E.M. Álvarez for the map image development. J. Burrough advised on the English of the paper.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Beck, S.; García, E. Flora y Vegetación en los Diferentes Pisos Altitudinales. In Historia Natural de un Valle en Los Andes: La Paz; Forno, E., Baudoin, M., Eds.; Instituto de Ecología, Universidad Mayor de San Andrés: La Paz, Bolivia, 1991; pp. 65–108. [Google Scholar]
  2. Brack Egg, A.; Mendiola, C. Ecología del Perú; Editorial Bruño: Lima, Perú, 2004; p. 495. [Google Scholar]
  3. Brako, L.; Zarucchi, J. Catalogue of the Flowering Plants and Gymnosperms of Peru. Monogr. Syst. Bot. Mo. Bot. Gard. 1993, 45, 1–1286. [Google Scholar]
  4. Braun-Blanquet, J. Plant Sociology, the Study of Plant Communities; McGraw Hill: New York, NY, USA, 1979; 438p. [Google Scholar]
  5. Cabrera, A.L. Ecología Vegetal de la Puna. Geoecology of the Mountainous Regions of the Tropical Americas. In Colloquium Geographicum 9; Troll, C., Ed.; Dümmlers Verlag: Bonn, Germany, 1968; pp. 91–116. [Google Scholar]
  6. Cano, A.; Delgado, A.; Mendoza, W.; Trinidad, H.; González, P.; La Torre, M.I.; Chanco, M.; Aponte, H.; Roque, J.; Valencia, N.; et al. Flora y vegetación de suelos crioturbados y hábitats asociados en los alrededores del abra Apacheta, Ayacucho-Huancavelica (Perú). Rev. Peru. Biol. 2011, 18, 169–178. [Google Scholar] [CrossRef]
  7. Catorci, A.; Piermarteri, K.; Tardella, F.M. Distribution of the nurse species Pycnophyllum molle J. Rémy and P. weberbaueri Muschl. in the Andean dry Puna (Arequipa District-Southern Peru): Role of topographic/soil variability and disturbance regime. Pol. J. Ecol. 2014, 62, 385–390. [Google Scholar] [CrossRef]
  8. Cleef, A. The Vegetation of the Paramos of the Colombian Cordillera Oriental; Dissertationes Botanicae Series; Lubrecht & Cramer Ltd.: Vaduz, Liechtenstein, 1981; Volume 61, 316p. [Google Scholar]
  9. de Bello, F.; Doležal, J.; Dvorský, M.; Chlumská, Z.; Řeháková, K.; Klimešová, J.; Klimeš, L. Cushions of Thylacospermum caespitosum (Caryophyllaceae) do not facilitate other plants under extreme altitude and dry conditions in the north-west Himalayas. Ann. Bot. 2011, 108, 567–573. [Google Scholar] [CrossRef] [PubMed]
  10. Estudio de Impacto Ambiental Semidetallado. Proyecto de Exploración “Chucapaca” EIAS-PEC; Compañia de Minas Buenaventura: Lima, Peru, 2009; pp. 1–32. [Google Scholar]
  11. Freire, S.E.; Chemisquy, M.A.; Anderberg, A.A.; Beck, S.G.; Meneses, R.L.; Loeuille, B.; Urtubey, E. The Lucilia group (Asteraceae, Gnaphalieae): Phylogenetic and taxonomic considerations based on molecular and morphological evidence. Plant Syst. Evol. 2015, 301, 1227–1248. [Google Scholar] [CrossRef]
  12. Funk, V.A. Xenophyllum, a new Andean genus extracted from Werneria s.l. (Compositae: Senecioneae). Novon 1997, 7, 235–241. [Google Scholar] [CrossRef]
  13. Galán de Mera, A. Clasificación fitosociológica de la vegetación de la región del Caribe y América del Sur. Arnaldoa 2005, 12, 86–111. [Google Scholar]
  14. Galán de Mera, A.; Rosa, M.; Cáceres, C. Una aproximación sintaxonómica sobre la vegetación del Perú. Clases, órdenes y alianzas. Acta Bot. Malacit. 2002, 27, 75–103. [Google Scholar] [CrossRef] [Green Version]
  15. Galán de Mera, A.; Cáceres, C.; González, A. La vegetación de la alta montaña andina del sur de Perú. Acta Bot. Malacit. 2003, 28, 121–147. [Google Scholar] [CrossRef]
  16. Galán de Mera, A.; Baldeón, S.; Beltrán, H.; Benavente, M.; Gómez, J. Datos sobre la vegetación del centro del Perú. Acta Bot. Malacit. 2004, 29, 89–115. [Google Scholar] [CrossRef] [Green Version]
  17. Galán de Mera, A.; Perea, E.L.; de la Cruz, J.C.; Orellana, J.V. Nuevas observaciones sobre la vegetación del sur del Perú. Del desierto pacífico al altiplano. Acta Bot. Malacit. 2009, 34, 1–35. [Google Scholar] [CrossRef] [Green Version]
  18. Galán de Mera, A.; Perea, E.L.; de la Cruz, J.C.; Vera, C.T.; Villasante-Benavides, F.; Orellana, J.V. Novedades sobre la vegetación del departamento de Arequipa (Perú). Arnaldoa 2011, 18, 125–144. [Google Scholar]
  19. Galán de Mera, A.; del Monte, B.; Linares Perea, E.; de la Cruz, J.C.; Trujillo Vera, F.; Vicente Orellana, J.A. Las comunidades vegetales relacionadas con los ambientes humanos en el sur del Perú. Phytocoenologia 2012, 41, 265–305. [Google Scholar] [CrossRef]
  20. Galán de Mera, A.; Méndez, E.; Linares, E.; de la Cruz, C.; Vicente Orellana, J.A. Las comunidades vegetales relacionadas con los procesos criogénicos en los Andes peruanos. Phytocoenologia 2014, 44, 121–161. [Google Scholar] [CrossRef]
  21. García, E.; Beck, S.G. Puna. In Botánica Económica de los Andes Centrales; Moraes, M., Øllgaard, B., Kvist, L.P., Borchsenius, F., Balslev, H., Eds.; Universidad Mayor de San Andrés: La Paz, Bolivia, 2006; 557p. [Google Scholar]
  22. Gonzáles, P.; Cano, A.; Müller, J. An unusual new record of Baccharis (Asteraceae) from the Peruvian Andes and its relation with the northern limit of the dry puna. Acta Botánica Mex. 2019, 126. [Google Scholar] [CrossRef] [Green Version]
  23. Gutte, P. Beitrag zur Kenntnis zentralperuanischer Pflanzengesellschaften IV. Die grasreiche Vegetation der alpine Stufe. Wissenschaftliche Zeitschrift Karl-Marx-Universität Leipzig. Math. Nat. Reihe 1985, 34, 357–401. [Google Scholar]
  24. Gutte, P. Beitrag zur Kenntnis zentralperuanischer Pflanzengesellschaften III. Pflanzengesellschaften der subalpinen Stufe. Feddes Repert. 1986, 97, 319–371. [Google Scholar] [CrossRef]
  25. Gutte, P. Beitrag zur Kenntnis zentralperuanischer Pflanzengesellschaften V. Die Vegetation der subnivalen Stufe. Feddes Repert. 1987, 98, 447–460. [Google Scholar] [CrossRef]
  26. Gutte, P. Segetal- und Ruderalpflanzengesellschaften im Wohngebiet der Kallawaya (Bolivianische Anden). Phytocoenologia 1995, 25, 33–67. [Google Scholar] [CrossRef]
  27. Hedberg, O. Evolution and speciation in a tropical high mountain flora. Biol. J. Linn. Soc. 1969, 1, 135–148. [Google Scholar] [CrossRef]
  28. Hill, M.O. Twinspan, a Fortran Program for Arranging Multivariate Data in an Ordered Two-Way Table by Classification of the Individuals and the Attributes; Cornell University, Department of Ecology and Systematics: Ithaca, NY, USA, 1979. [Google Scholar]
  29. Holmgren, C.A.; Betancourt, J.L.; Rylander, K.A.; Roque, J.; Tovar, O.; Zeballos, H.; Linares, E.; Quade, J. Holocene vegetation history from fossil rodent middens near Arequipa, Peru. Quat. Res. 2001, 56, 242–251. [Google Scholar] [CrossRef]
  30. Josse, C.; Cuesta, F.; Navarro, G.; Barrena, V.; Becerra, M.T.; Cabrera, E.; Chacón-Moreno, E.; Ferreira, W.; Peralvo, M.; Saito, J.; et al. Physical Geography and Ecosystems in the Tropical Andes. In Climate Change and Biodiversity in the Tropical Andes; Herzog, S.K., Martinez, R., Jørgensen, P.M., Tiessen, H., Eds.; MacArthur Foundation: Chicago, IL, USA; IAI: San Jose dos Campos, Brazil; SCOPE: Paris, France, 2011; Chapter 10; pp. 152–169. [Google Scholar]
  31. JSTOR Global Plants. Available online: https://0-plants-jstor-org.brum.beds.ac.uk/ (accessed on 26 December 2020).
  32. Kleier, C.; Trenary, T.; Graham, E.A.; Stenzel, W.; Rundel, P.W. Size class structure, growth rates, and orientation of the central Andean cushion Azorella compacta. PeerJ 2015, 3, e843. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Knapp, R. Considerations on Quantitative Parameters and Qualitative Attributes in Vegetation Analysis and in Phytosociological Relevés. In Sampling Methods and Taxon Analysis in Vegetation Science; Knapp, R., Ed.; Dr. W. Junk Publishers: Heidelberg, The Netherlands; Boston, MS, USA; Lancaster, UK, 1984; pp. 77–100. [Google Scholar]
  34. Kuentz, A.; Galán de Mera, A.; Ledru, M.P.; Thouret, J.C. Phytogeographical data and modern pollen rain of the Puna belt in southern Peru (Nevado Coropuna, Western Cordillera). J. Biogeogr. 2007, 34, 1762–1776. [Google Scholar] [CrossRef]
  35. Lauer, W. Zur hygrischen Höhenstufung tropischer Gebirge. Neotropische Ökosysteme. Biogeographica 1976, 7, 169–182. [Google Scholar]
  36. Luebert, F.; Gajardo, R. Vegetación de los Andes áridos del norte de Chile. Lazaroa 2000, 21, 111–130. [Google Scholar]
  37. Luebert, F.; Gajardo, R. Vegetación altoandina de Parinacota (norte de Chile) y una sinopsis de la vegetación de la puna meridional. Phytocoenologia 2005, 35, 79–128. [Google Scholar] [CrossRef]
  38. Martinez, S. El género Azorella (Apiaceae-Hydrocotyloideae) en la Argentina. Darwiniana 1989, 29, 139–178. [Google Scholar]
  39. Mendez, E. La Vegetación de los Altos Andes Centrales: Bardas Blancas-Paso Pehuenche (Malargüe, Mendoza, Argentina). Boletín Soc. Argent. Botánica 2014, 49, 257–281. [Google Scholar] [CrossRef]
  40. Montenegro, B.; Zúñiga, S.; Zeballos, H. Climatología de la Reserva Nacional Salinas y Aguada Blanca, Suroeste del Perú. In Diversidad Biológica de la Reserva Nacional de Salinas y Aguada Blanca; Zeballos, H., Ochoa, J.A., López, E., Eds.; LITHO & ARTE S.A.C: Lima, Peru, 2010; pp. 261–273. [Google Scholar]
  41. Montesinos, D.B.; Cleef, A.M.; Sýkora, K.V. Andean shrublands of Moquegua, South Peru: Prepuna plant communities. Phytocoenologia 2012, 42, 29–55. [Google Scholar] [CrossRef]
  42. Montesinos-Tubée, D.B. Diversidad florística de la cuenca alta del río Tambo-Ichuña (Moquegua, Perú). Rev. Peru. Biol. 2011, 18, 119–132. [Google Scholar] [CrossRef]
  43. Montesinos-Tubée, D.B. Lista anotada de nuevas adiciones para la flora andina de Moquegua, Perú. Rev. Peru. Biol. 2012, 19, 303–312. [Google Scholar] [CrossRef] [Green Version]
  44. Montesinos-Tubée, D.B. Flora de los Andes de Moquegua. Etnobotánica de la Cuenca de los ríos Alto Tambo-Ichuña; CDH-Gold Fields. DL. 2013–06310; Inca Legacy Cultural Society: Lima, Peru, 2013; pp. 1–300. [Google Scholar]
  45. Montesinos-Tubée, D.B. Three new caespitose species of Senecio (Asteraceae: Senecioneae) from South Peru. Phytokeys 2014, 39, 1–17. [Google Scholar] [CrossRef] [PubMed]
  46. Montesinos-Tubée, D.B. Pycnophyllum molle and its tenants in southern Peru. J. Alp. Gard. Soc. 2015, 82, 438–443. [Google Scholar]
  47. Montesinos-Tubée, D.B. Flora Moqueguana. Guía Práctica para la Identificación de Flora Silvestre; Anglo American: Lima, Perú, 2015; 252p. [Google Scholar]
  48. Montesinos-Tubée, D.B.; Kool, A. Arenaria acaulis (Caryophyllaceae): A new species from South Peru. Phytotaxa 2015, 220, 77–82. [Google Scholar] [CrossRef] [Green Version]
  49. Montesinos-Tubée, D.B.; Sýkora, K.V.; Quipuscoa-Silvestre, V.; Cleef, A.M. Species composition and phytosociology of xerophytic plant communities after extreme rainfall in South Peru. Phytocoenologia 2015, 48, 203–250. [Google Scholar] [CrossRef]
  50. Montesinos-Tubée, D.B.; Cleef, A.M.; Sýkora, K.V. The Puna vegetation of Moquegua, South Peru: Chasmophytes, grasslands and Puya raimondii stands. Phytocoenologia 2015, 45, 365–397. [Google Scholar] [CrossRef]
  51. Mueller-Dombois, D.; Ellenberg, H. Aims and Methods of Vegetation Ecology; John Wiley & Sons: Hoboken, NJ, USA, 1974. [Google Scholar]
  52. Myers, N.; Mittermeier, R.A.; Mittermeier, C.G.; Da Fonseca, G.A.B.; Kent, J. Biodiversity hotspots for conservation priorities. Nature 2000, 403, 853–858. [Google Scholar] [CrossRef]
  53. Navarro, G. Vegetación de Bolivia: El Altiplano meridional. Rivasgodaya 1993, 7, 69–98. [Google Scholar]
  54. Navarro, G.; Ferreira, W. Zonas de vegetación potencial de Bolivia: Una base para el análisis de vacíos de conservación. Rev. Boliv. Ecol. 2004, 15, 1–40. [Google Scholar]
  55. Navarro, G.; Maldonado, M. Geografía Ecológica de Bolivia. Vegetación y Ambientes Acuáticos; Fundación Simón 1 ; Patiño: Santa Cruz, Bolivia, 2005; pp. 247–268, 454–499. [Google Scholar]
  56. PBI Solanum Project. Solanaceae Source. Available online: http://www.solanaceaesource.org (accessed on 30 November 2014).
  57. Pugnaire, F.I.; Morillo, J.A.; Armas, C.; Rodríguez-Echeverría, S.; Gaxiola, A. Azorella compacta: Survival champions in extreme, high-elevation environments. Ecosphere 2020, 11, e03031. [Google Scholar] [CrossRef] [Green Version]
  58. Quipuscoa-Silvestre, V.; Dillon, M. Tres nuevas especies de Mniodes a. Gray (Gnaphaliinae, Gnaphalieae, Asteraceae) de Bolivia y Perú y cambios nomenclaturales en el grupo Lucilia. Arnaldoa 2020, 27, 2. [Google Scholar]
  59. Ralph, C.P. Observations on Azorella compacta (Umbelliferae), a tropical Andean cushion plant. Biotropica 1978, 10, 62–67. [Google Scholar] [CrossRef]
  60. Reese, C.A.; Liu, K.B. Pollen dispersal and deposition on the Quelccaya Ice Cap, Peru. Phys. Geogr. 2002, 23, 44–58. [Google Scholar] [CrossRef] [Green Version]
  61. Reese, C.A.; Liu, K.B. A modern pollen rain study from the central Andes region of South America. J. Biogeogr. 2005, 32, 709–718. [Google Scholar] [CrossRef]
  62. Rivas-Martínez, S. Worldwide Bioclimatic Classification System. Phytosociological Research Center. 2004. Available online: www.globalbioclimatic.org (accessed on 12 December 2010).
  63. Rivas-Martínez, S.; Tovar, O. Vegetatio Andinae, I. Datos sobre las comunidades vegetales altoandinas de los Andes Centrales del Perú. Lazaroa 1982, 4, 167–187. Available online: https://dialnet.unirioja.es/servlet/articulo?codigo=905920.
  64. Rivera, M.; Thouret, J.C.; Samaniego, P.; Le Pennec, J.L. The 2006–2009 activity of the Ubinas volcano (Peru): Petrology of the 2006 eruptive products and insights into genesis of andesite magmas, magma recharge and plumbing system. J. Volcanol. Geotherm. Res. 2014, 270, 122–141. [Google Scholar] [CrossRef]
  65. Ruthsatz, B. Pflanzengesellschaften und ihre Lebensbedingungen in den Andinen Halbwüsten Nordwest-Argentiniens. Diss. Bot. 1977, 39, 1–90. [Google Scholar]
  66. Sarmiento, G. Ecological Features of Climate in High Tropical Mountains. In High Altitude Tropical Biogeography; Monasterio, M., Ed.; Oxford University Press: Oxford, UK, 1986; pp. 11–45. [Google Scholar]
  67. Seibert, P.; Menhofer, X. Die Vegetation des Wohngebietes der Kallawaya und des Hochlandes von Ulla-Ulla in den bolivianischen Anden. Phytocoenologia 1991, 20, 145–276. [Google Scholar] [CrossRef]
  68. Seibert, P.; Menhofer, X. Die Vegetation des Wohngebietes der Kallawaya und des Hochlandes von Ulla-Ulla in den bolivianischen Anden. Phytocoenologia 1992, 20, 289–438. [Google Scholar] [CrossRef]
  69. Seibert, P.; Menhofer, X. Die Vegetation des Wohngebietes der Kallawaya und des Hochlandes von Ulla-Ulla in den bolivianischen Anden. Phytocoenologia 1993, 22, 275–278. [Google Scholar] [CrossRef]
  70. Servicio Nacional de Meteorología e Hidrología del Perú (SENAMHI). Información Meteorológica de las Estaciones de Ichuña y Ubinas (Moquegua); Servicio Nacional de Meteorología e Hidrología del Perú: Arequipa, Peru, 2013.
  71. Talavera, C.; Ortega, A.; Villegas, L. Flora y Vegetación de la Reserva Nacional de Salinas y Aguada Blanca, Perú. In Diversidad Biológica de la Reserva Nacional de Salinas y Aguada Blanca (Arequipa-Moquegua); Zeballos, H., Ochoa, J.A., López, E., Eds.; DESCO, PROFONANPE, SERNANP: Lima, Peru, 2010. [Google Scholar]
  72. Teillier, S. Flora y vegetación alto-andina del área de Collaguasi-Salar de Coposa, Andes del norte de Chile. Rev. Chil. Hist. Nat. 1998, 71, 313–329. [Google Scholar]
  73. Ter Braak, C.J.F.; Šmilauer, P.; CANOCO. Reference manual and CanoDraw for Windows User’s Guide: Software for Canonical Community Ordination (version 4.5); Microcomputer Power: Ithaca, NY, USA, 2002. [Google Scholar]
  74. NYBG STEERE HERBARIUM. Index Herbariorum. Available online: http://sweetgum.nybg.org/ih/ (accessed on 15 January 2019).
  75. Troll, C. Geo-Ecology of the Mountainous Regions of the Tropical Americas; Dümmlers Verlag: Bonn, Germany, 1968. [Google Scholar]
  76. Tropicos. Missouri Botanical Garden. Available online: http://www.tropicos.org (accessed on 1 January 2015).
  77. Weber, H.E.; Moravec, J.; Theurillat, J.P. International Code of Phytosociological Nomenclature. 3rd edition. J. Veg. Sci. 2000, 11, 739–768. [Google Scholar] [CrossRef]
Figure 1. Location of the upper reaches of the Tambo and Ichuña rivers in the Andes of Moquegua, Peru. The numbers show the locations of the study sites as listed in Table 1.
Figure 1. Location of the upper reaches of the Tambo and Ichuña rivers in the Andes of Moquegua, Peru. The numbers show the locations of the study sites as listed in Table 1.
Ecologies 02 00005 g001
Figure 2. Superpuna landscape at 4500–4800 m (Cachilaya-Yanapuquio sites, Ichuña district). A. Community of Misbrookea strigosissima & Stipa ichu (Calamagrostietea vicunarum). B. Saxifrago magellanicae-Leucherietum daucifoliae (Argyrochosmetea niveae). C. Astragalo minimi-Azorelletum diapensioidis subassociation typicum (Calamagrostietea vicunarum). D. Nototrichion obcuneatae (Anthochloo lepidulae-Dielsiochloetea floribundae).
Figure 2. Superpuna landscape at 4500–4800 m (Cachilaya-Yanapuquio sites, Ichuña district). A. Community of Misbrookea strigosissima & Stipa ichu (Calamagrostietea vicunarum). B. Saxifrago magellanicae-Leucherietum daucifoliae (Argyrochosmetea niveae). C. Astragalo minimi-Azorelletum diapensioidis subassociation typicum (Calamagrostietea vicunarum). D. Nototrichion obcuneatae (Anthochloo lepidulae-Dielsiochloetea floribundae).
Ecologies 02 00005 g002
Figure 3. Overview of the grasslands with cushions of Azorella compacta in the surroundings of the road between Carmen Chaclaya and Matazo in the Ubinas district (4460–4830 m a.s.l. A. Astragalo pusilli-Parastrephietum quadrangularis (Calamagrostietea vicunarum). B. Senecioni moqueguensis-Pycnophylletum mollis (Calamagrostietea vicunarum). C. Plantagini rigidae-Distichietea muscoidis. D. Nototrichion obcuneatae (Anthochloo lepidulae-Dielsiochloetea floribundae).
Figure 3. Overview of the grasslands with cushions of Azorella compacta in the surroundings of the road between Carmen Chaclaya and Matazo in the Ubinas district (4460–4830 m a.s.l. A. Astragalo pusilli-Parastrephietum quadrangularis (Calamagrostietea vicunarum). B. Senecioni moqueguensis-Pycnophylletum mollis (Calamagrostietea vicunarum). C. Plantagini rigidae-Distichietea muscoidis. D. Nototrichion obcuneatae (Anthochloo lepidulae-Dielsiochloetea floribundae).
Ecologies 02 00005 g003
Figure 4. Overview of the extensive slopes with Senecioni moqueguensis-Pycnophylletum mollis subassociation typicum in the surroundings of the group of lakes between the localities of Coalaque and Querala, in the Ubinas district at an altitude of 4550 m a.s.l. Species visible in the Figure: Azorella compacta (cushion), Festuca orthophylla (tussock grass), Baccharis tricuneata and Parastrephia lucida (shrubs).
Figure 4. Overview of the extensive slopes with Senecioni moqueguensis-Pycnophylletum mollis subassociation typicum in the surroundings of the group of lakes between the localities of Coalaque and Querala, in the Ubinas district at an altitude of 4550 m a.s.l. Species visible in the Figure: Azorella compacta (cushion), Festuca orthophylla (tussock grass), Baccharis tricuneata and Parastrephia lucida (shrubs).
Ecologies 02 00005 g004
Figure 5. Overview of the scree slopes with cushions of Azorella compacta on the lower slopes of Choco-Choco mountain in the Yunga district at 4750 m a.s.l.
Figure 5. Overview of the scree slopes with cushions of Azorella compacta on the lower slopes of Choco-Choco mountain in the Yunga district at 4750 m a.s.l.
Ecologies 02 00005 g005
Figure 6. Overview of the Nototricho obcuneatae-Xenophylletum poposi on the summits of Pirhuani peak (4730 m a.s.l.) in the Ubinas district. Occasional snow cover occurs during the rainy season.
Figure 6. Overview of the Nototricho obcuneatae-Xenophylletum poposi on the summits of Pirhuani peak (4730 m a.s.l.) in the Ubinas district. Occasional snow cover occurs during the rainy season.
Ecologies 02 00005 g006
Figure 7. Overview of the scree and volcanic sand deposits at the Janchata lower slopes (4700 m a.s.l.) where Nototricho obcuneatae-Xenophylletum poposi senecionetosum trifurcifolii occurs.
Figure 7. Overview of the scree and volcanic sand deposits at the Janchata lower slopes (4700 m a.s.l.) where Nototricho obcuneatae-Xenophylletum poposi senecionetosum trifurcifolii occurs.
Ecologies 02 00005 g007
Figure 8. Detail of Urtica flabellata among llama and alpaca dung at 4460 m a.s.l.
Figure 8. Detail of Urtica flabellata among llama and alpaca dung at 4460 m a.s.l.
Ecologies 02 00005 g008
Figure 9. Ordination diagram (DCA, axis 1 and 2) of associations 2–5. The relevés belonging to the 4 different associations have been delineated. # SPP refers to the total number of species, % rocks and stones = estimated cover of rocks and stones in each relevé. VC refers to total vegetation cover, altitude is expressed in meters above sea level, manure and grazing is expressed in I: 1–30%; II: 31–70%; III: >71%, and scree is expressed by the percentage total cover.
Figure 9. Ordination diagram (DCA, axis 1 and 2) of associations 2–5. The relevés belonging to the 4 different associations have been delineated. # SPP refers to the total number of species, % rocks and stones = estimated cover of rocks and stones in each relevé. VC refers to total vegetation cover, altitude is expressed in meters above sea level, manure and grazing is expressed in I: 1–30%; II: 31–70%; III: >71%, and scree is expressed by the percentage total cover.
Ecologies 02 00005 g009
Figure 10. Ordination diagram (DCA, axis 1 and 2) of communities 1, 6–9. The relevés of three associations, one community and one provisional association have been delineated. For caption definitions refer to Figure 9.
Figure 10. Ordination diagram (DCA, axis 1 and 2) of communities 1, 6–9. The relevés of three associations, one community and one provisional association have been delineated. For caption definitions refer to Figure 9.
Ecologies 02 00005 g010
Figure 11. Bar charts showing the mean percentage values with standard deviation for (a) slope degree, (b) vegetation cover, (c) rocks and (d) stones.
Figure 11. Bar charts showing the mean percentage values with standard deviation for (a) slope degree, (b) vegetation cover, (c) rocks and (d) stones.
Ecologies 02 00005 g011
Figure 12. Altitudinal distribution of syntaxa (association, subassociation) and communities of the study area based on the relevés (solid lines) and references and field observations (dashed lines) from Moquegua by the first author [43,44,45,48]. (1) Saxifrago magellanicae-Leucherietum daucifoliae, (2) Astragalo minimi-Azorelletum diapensioidis, (3) Astragalo pusilli-Parastrephietum quadrangularis, (4) Senecioni moqueguensis-Pycnophylletum mollis, (5) Calamagrostio trichophyllae-Azorelletum compactae, (6) Nototricho obcuneatae-Xenophylletum poposi, (7) Poo aequiglumae-Xenophylletum dactylophylli, (8) Community of Senecio algens, (9) community of Tarasa nototrichoides and Urtica flabellata.
Figure 12. Altitudinal distribution of syntaxa (association, subassociation) and communities of the study area based on the relevés (solid lines) and references and field observations (dashed lines) from Moquegua by the first author [43,44,45,48]. (1) Saxifrago magellanicae-Leucherietum daucifoliae, (2) Astragalo minimi-Azorelletum diapensioidis, (3) Astragalo pusilli-Parastrephietum quadrangularis, (4) Senecioni moqueguensis-Pycnophylletum mollis, (5) Calamagrostio trichophyllae-Azorelletum compactae, (6) Nototricho obcuneatae-Xenophylletum poposi, (7) Poo aequiglumae-Xenophylletum dactylophylli, (8) Community of Senecio algens, (9) community of Tarasa nototrichoides and Urtica flabellata.
Ecologies 02 00005 g012
Figure 13. Box-and-whisker plots representing species richness per syntaxon in chasmophyte vegetation (1, plot sizes 16 m2), grasslands with cushions (2–4, 25 m2), cushion communities (5–8, 25 m2) and one nitrophilous unit (9, 1 m2). The line in the boxes represents the median values, the boxes the 25 and 75% percentiles and the lines the minimum and maximum values found in each syntaxon.
Figure 13. Box-and-whisker plots representing species richness per syntaxon in chasmophyte vegetation (1, plot sizes 16 m2), grasslands with cushions (2–4, 25 m2), cushion communities (5–8, 25 m2) and one nitrophilous unit (9, 1 m2). The line in the boxes represents the median values, the boxes the 25 and 75% percentiles and the lines the minimum and maximum values found in each syntaxon.
Ecologies 02 00005 g013
Table 1. Overview of parameters for each research site (1–11) in the superpuna of the Andes of Moquegua, Peru. #rel = number of relevés at the site in question, year = year(s) in which fieldwork was done, Elevation = the altitudinal range within which the relevés were made, Slope (°) = minimal and maximal slope angle, Aspect. = orientation, and vegetation = general description of the vegetation structure.
Table 1. Overview of parameters for each research site (1–11) in the superpuna of the Andes of Moquegua, Peru. #rel = number of relevés at the site in question, year = year(s) in which fieldwork was done, Elevation = the altitudinal range within which the relevés were made, Slope (°) = minimal and maximal slope angle, Aspect. = orientation, and vegetation = general description of the vegetation structure.
SitesLocalityDistrict# rel.YearElevation (m)Slope (°)AspectEnvironment
1Janchata slopesNevadosCarumas520154700–4710′5–10SEScree plateaus
2Cerro Santo Tomas, C. Huarmaca, Puqa SayaYanahuaraIchuña152009, 20124530–46650–60N, NW, S, SEChasmophyte, scree slopes with copper, steppe grasslands with cushions, rocky slopes, open plateaus, manure communities
3Coriri, Jatun Puqio, QhaqhaskinkriIchuñaIchuña920094460–4540′3–43NW, S, SE, E, WSteppe grasslands with cushions, grazed grasslands
4Choco-Choco environsYungaYunga1020124660–4760′2–35N, WGrasslands with cushions, scree slopes, open plateaus with cushions
5Sura, Perusa-Chaquisura, Siliaca, YanasayaYungaYunga282011, 20124510–4800′10–50NW, N, SSW, SW, WChasmophyte, rocky slopes, steppe grasslands with cushions, grasslands, scree, open plateaus with cushions
6Rancho-Pirhuani; Laguna JallpacochaTassa/PachamayoUbinas1820144450–4565′5–45NE, SE, ESteppe grasslands with cushions, grazed grasslands, rocky slopes, scree slopes
7PirhuaniTassaUbinas1820114470–46600–17NNW, SSE, WSteppe cushion communities
8Cochapata lake environsTassaUbinas1020134680–4700′4–5SESteppe grasslands with cushions
9Pacosani, Yaretaq, LarsepescaCoalaqueUbinas1020094615–4690′5–47N, NE, S, SWSteppe grasslands with cushions, rock slopes
10Janaqpampa, Gasawasi, WitopataQueralaUbinas1020114500–4640′4–15S, E, WSteppe grasslands with cushions, open plateaus
11Condor SallanaMatazoUbinas202013, 20144460–45900–25N, SGrazed grasslands with cushions, manure communities, rocky slopes
Table 2. Table with the type relevés of associations and subassociations described as new (including one community and a pro-visional association). Community # indicated for each association and subassociation; Relevé# for the type relevé or representa-tive relevé. Altitude (meters above sea level). Inclination (degrees). Orientation. Total number of species (# SPP). VEGC % for vegetation cover percentage in that single relevé. Rocks and stones in percentage cover. Grazing and manure (expressed as I: 1–30%; II: 31–70%; III: >71%).
Table 2. Table with the type relevés of associations and subassociations described as new (including one community and a pro-visional association). Community # indicated for each association and subassociation; Relevé# for the type relevé or representa-tive relevé. Altitude (meters above sea level). Inclination (degrees). Orientation. Total number of species (# SPP). VEGC % for vegetation cover percentage in that single relevé. Rocks and stones in percentage cover. Grazing and manure (expressed as I: 1–30%; II: 31–70%; III: >71%).
Community #12.12.23.13.23.34.14.24.34.45.15.26.16.2789
Relevé #2620382071733411420614228
ALTITUDE45804585447044504510450046704610468045904800459046504710479047454460
INCLINATION255552045105510102551015450
ORIENTATIONSNWNENNWSWWSENWSSSESESSWNW-
# SPP818228152218126201622881465
VEGC %205545203560503035354045301515580
ROCKS %5510404010020105201005880
STONES %55520101030353530304024309034900
GRAZING (I-III)00101110000010013
Argyrochosmetea niveae
Saxifragetalia magellanicae, Saxifragion magellanicae
Saxifraga magellanica4................
Saxifrago magellanicae-Leucherietum daucifoliae
Leucheria daucifolia4................
Weberbauera arequipa2................
Calamagrostietea vicunarum
Calamagrostis vicunarum..11...2.1.......
Parastrephietalia quadrangularis
Parastrephia quadrangularis..4448...........
Tetraglochin cristatum.83..8.2.........
Descurainia depressa......1..........
Pycnophyllum molle.104...20101578.8....
Hypochaeris meyeniana..2.12...........
Ephedra rupestris...........3.....
Weberbauera spathulifolia2.3..1...........
Belloa piptolepis....1112.........
Senecio candollei.........12......
Senecio humillimus....2......4.....
Brayopsis calycina.11......11......
Chaetanthera stuebelii......1..1.......
Nototriche anthemidifolia.1....21.11......
Draba macleanii.2.........2.....
Hypochaeris eriolaena......1..........
Plantago sericea var. lanuginosa..1........1.....
Werneria aretioides..2....22........
Senecio spinosus.3....1..........
Werneria pectinata....1.1..2.......
Wahlenbergia peruviana.....1...........
Nototriche digitulifolia...1.............
Nototriche pedicularifolia.2...............
Lupinus ananeanus..3..3...........
Cerastium subspicatum...1.............
Conyza deserticola..1..............
Gomphrena meyeniana..2..............
Calamagrostietea minimae
Calamagrostis minima.11..............
Oreomyrrhis andicola 1...............
Werneria nubigena..2..............
Astragalo minimi-Azorelletum diapensioidis
Azorella diapensioides.64..............
Astragalus minimus.102.221..........
Bougueria nubicola.21..11..........
Werneria apiculata.22..............
Junellia minima.1...............
Subassociation Typicum
Werneria melanandra.1...............
Nototriche longirostris.2...1...........
aciachnetosum pulvinatae
Aciachne pulvinada..2..............
Azorello-Festucion
Azorella compacta...81015..12444.....
Festuca orthophylla.....25..........
Baccharis caespitosa....1......2.....
Belloa sp. (# 3945).....1....1......
Bowlesia tropaeolifolia...........1.....
Cumulopuntia boliviana subsp. ignescens....3............
Senecio evacoides..........2......
Stangea wandae.......1.1.......
Astragalo pusillii-Parastrephietum quadrangularis
Astragalus pusillus...112...........
sisyrinchietosum trinervis
Sisyrinchium trinervis...1.............
baccharidetosum tricuneatae
Baccharis tricuneata....2.....34.....
Descurainia sp. (# 0940)....1............
Subassociation Typicum
Sisyrinchium brevipes.1...1...........
Senecioni moqueguensis-Pycnophylletum molle
Senecio moqueguensis......3344.......
Nototriche argentea.......1.........
Perezia coerulescens var. amplibracteata......1..........
Subassociation Typicum
Mniodes sp. (# 2477)......3....2.....
Senecio helianthemoides......1..........
senecionetosum tassaensis
Senecio tassaensis.......1.........
Xenophyllum weddellii.......2.........
gentianelletosum primuloides
Gentianella primuloides........1........
Senecio graveolens........1........
arenarietosum acaulis
Arenaria acaulis.........1.......
Nototriche sepaliloba.........1.......
Cerastium behmianum.........1.......
Nototriche pusilla.........1.......
Senecio sykorae.........1.......
Poa brevis.........1.......
Calamagrostio trichophyllae-Azorelletum compactae
Calamagrostis trichophylla..........12.....
Nototriche mandoniana..........1......
Silene mandonii...........1.....
Perezia pungens...........2.....
Subassociation Typicum
Mniodes caespititia..........5......
Senecio sp.2 (# 3935)..........3......
drabetosum soratensis
Draba soratensis...........2.....
Bartsia sp. (# 3092)...........2.....
Poa gilgiana...........1.....
Agrostis breviculmis...........1.....
Viola granulosa...........1.....
Anthochloo-Dielsiochloetea
Anthochloa lepidula2.....1.....1121.
Dielsiochloa floribunda..............1..
Nototrichion obcuneatae
Nototriche obcuneata.............22..
Senecio adenophyllus............3..1.
Senecio sp.3 (# 3931)............112..
Dissanthelium calycinum.1...1...1....1.3
Nototriche sp.1 (# 3104)..............2..
Nototricho obcuneatae-Xenophylletum poposi Galán de Mera et al. 2003
Xenophyllum poposum............73...
Mniodes coarctata.........2..73...
nototrichietosum erinaceae
Nototriche erinacea............2....
senecionetosum trifurcifolii
Senecio trifurcifolius.............3...
Senecio sp.4 (# 4228b).............1...
Poo aequiglumae-Xenophylletum dactylophyllum
Xenophyllum dactylophyllum..............6..
Nototriche sp.3 (# 2447)..............2..
Poa aequigluma..............2..
Poa spicigera..............1..
Community of Senecio algens
Senecio algens...............1.
Senecio sp.5 (# 3942)...............1.
Class ¿?
Community of Tarasa nototrichoides and Urtica flabellata
Urtica flabellata................50
Tarasa nototrichoides................10
Lachemilla pinnata................10
Perezia multiflora.....1..........5
Solanum acaule................2
Crassuletea connatae
Muhlenbergia peruviana.1...............
Salpichroetalia glandulosae; Argyrochosmetea niveae
Valeriana nivalis..........2......
Companions
Bartsia diffusa.....1...........
Calamagrostis curvula..........1.1.21.
Cardionema ramosissimum.....1...........
Galium corymbosum....1............
Geranium sessiliflorum.........1.......
Lepidium meyenii......1..........
Luzula vulcanica..1........1.....
Mancoa hispida.....2...........
Microsteris gracilis1................
Oxalis nubigena....1............
Parastrephia lucida......5..244..4..
Paronychia andina..1.1............
Poa candamoana2..........1.....
Pycnophyllum glomeratum.......2...2..4..
Senecio nutans.....2....1...3..
Stangea rhizanta...............1.
Stipa ichu3.3333...........
Trisetum spicatum...........2.1...
Table 3. Synoptic table with percentage constancy (frequency) values (1–100%). # Order refers to the association and community number (this study and literature). # REL refers to the total number of relevés in that unit and #SPP to the total number of species in that unit. 1. Saxifrago magellanicae-Leucherietum daucifoliae, 2. Astragalo minimi-Azorelletum diapensioidis, 3. Astragalo pusilli-Parastrephietum quadrangularis, 4. Senecioni moqueguensis-Pycnophylletum mollis, 5. Calamagrostio trichophyllae-Azorelletum compactae, 6. Nototricho obcuneatae-Xenophylletum poposi [20], 7. Poo aequiglumae-Xenophylletum dactylophylli, 8. Community of Senecio algens, 9. Community of Tarasa nototrichoides and Urtica flabellata (this study), 10. Parastrephio lucidae-Festucetum orthophyllae festucetosum orthophyllae, azorelletosum compactae, polylepidetosum tarapacanae, Stipa ichu BC, Pycnophyllum molle BC [20], 11. Senecioni nutantis-Parastrephietum quadrangularis (Calamagrostietea vicunarum, Parastrephietalia lepidophyllae, Azorello-Festucion) [21], 12. Parastrephio quadrangularis-Festucetum dolichophyllae [21], 13. Parastrephio quadrangularis-Festucetum dolichophyllae festucetosum orthophyllae (21), 14. Parastrephio quadrangularis-Festucetum dolichophyllae agrostietosum gelidae [21], 15. Community of Senecio algens [22], 16. Senecioni culcitioides-Valerianetum nivalis. Draba brackenridgei race I [22], 17. Senecioni culcitioides-Valerianetum nivalis. Draba cryptantha race I [22], 18. Senecioni culcitioides-Valerianetum nivalis. Draba cryptantha race II [22], 19. Senecioni culcitioides-Valerianetum nivalis. Draba brackenridgei race II [22], 20. Senecioni culcitioides-Valerianetum nivalis. Draba cuzcoensis race [22], 21. Senecioni culcitioides-Valerianetum nivalis mniodetosum andinae [22]. 22. Senecioni culcitioides-Valerianetum nivalis saxifragetosum magellanicae [22], 23. Xenophyllo ciliolati-Plettkeetum cryptanthae, Chaetanthera cochlearifolia BC, Stangeo rhizanthae-Weberbaueretum rosulantis [22], 24. Community of Poa gymnantha-Cerastium subspicatum; Valeriana globularis-Anthochloa lepidula DC; Community of Caiophora horrida-Senecio adenophyllus: Community of Xenophyllum dactylophyllum; Nototricho obcuneatae-Xenophylletum ciliolatae [22], 25. Nototricho obcuneatae-Xenophylletum poposi (incl. valerianetosum, mniodetosum) [22]. 26. Nototricho obcuneatae-Mniodetum coarctatae [22], 27. Wernerio aretioidis-Parastrephietum lucidae [22]. 28. Parastrephietum lepidophyllo-quadrangulare (Parastrephion lepidophyllae) [25]. 29. Wernerio aretioidis-Parastrephietum lucidae (Azorello compactae-Festucion orthophyllae). 30. Senecioni zoellneri-Azorelletum compactae (Senecionion zoellneri-scorzoneraefolii) [25].
Table 3. Synoptic table with percentage constancy (frequency) values (1–100%). # Order refers to the association and community number (this study and literature). # REL refers to the total number of relevés in that unit and #SPP to the total number of species in that unit. 1. Saxifrago magellanicae-Leucherietum daucifoliae, 2. Astragalo minimi-Azorelletum diapensioidis, 3. Astragalo pusilli-Parastrephietum quadrangularis, 4. Senecioni moqueguensis-Pycnophylletum mollis, 5. Calamagrostio trichophyllae-Azorelletum compactae, 6. Nototricho obcuneatae-Xenophylletum poposi [20], 7. Poo aequiglumae-Xenophylletum dactylophylli, 8. Community of Senecio algens, 9. Community of Tarasa nototrichoides and Urtica flabellata (this study), 10. Parastrephio lucidae-Festucetum orthophyllae festucetosum orthophyllae, azorelletosum compactae, polylepidetosum tarapacanae, Stipa ichu BC, Pycnophyllum molle BC [20], 11. Senecioni nutantis-Parastrephietum quadrangularis (Calamagrostietea vicunarum, Parastrephietalia lepidophyllae, Azorello-Festucion) [21], 12. Parastrephio quadrangularis-Festucetum dolichophyllae [21], 13. Parastrephio quadrangularis-Festucetum dolichophyllae festucetosum orthophyllae (21), 14. Parastrephio quadrangularis-Festucetum dolichophyllae agrostietosum gelidae [21], 15. Community of Senecio algens [22], 16. Senecioni culcitioides-Valerianetum nivalis. Draba brackenridgei race I [22], 17. Senecioni culcitioides-Valerianetum nivalis. Draba cryptantha race I [22], 18. Senecioni culcitioides-Valerianetum nivalis. Draba cryptantha race II [22], 19. Senecioni culcitioides-Valerianetum nivalis. Draba brackenridgei race II [22], 20. Senecioni culcitioides-Valerianetum nivalis. Draba cuzcoensis race [22], 21. Senecioni culcitioides-Valerianetum nivalis mniodetosum andinae [22]. 22. Senecioni culcitioides-Valerianetum nivalis saxifragetosum magellanicae [22], 23. Xenophyllo ciliolati-Plettkeetum cryptanthae, Chaetanthera cochlearifolia BC, Stangeo rhizanthae-Weberbaueretum rosulantis [22], 24. Community of Poa gymnantha-Cerastium subspicatum; Valeriana globularis-Anthochloa lepidula DC; Community of Caiophora horrida-Senecio adenophyllus: Community of Xenophyllum dactylophyllum; Nototricho obcuneatae-Xenophylletum ciliolatae [22], 25. Nototricho obcuneatae-Xenophylletum poposi (incl. valerianetosum, mniodetosum) [22]. 26. Nototricho obcuneatae-Mniodetum coarctatae [22], 27. Wernerio aretioidis-Parastrephietum lucidae [22]. 28. Parastrephietum lepidophyllo-quadrangulare (Parastrephion lepidophyllae) [25]. 29. Wernerio aretioidis-Parastrephietum lucidae (Azorello compactae-Festucion orthophyllae). 30. Senecioni zoellneri-Azorelletum compactae (Senecionion zoellneri-scorzoneraefolii) [25].
#order123456789101112131415161718192021222324252627
# rel52423432216551023886525217188582112119
# spp1968739459281497503845322672289221914245951183418
Argyrochosmetea niveae_________
Saxifrago magellanicae-Leucherietum daucifoliae_______
Saxifraga magellanica100 2311 8013
Leucheria daucifolia100 25
Weberbauera arequipa60
Gentianella sp.40
Perezia pinnatifida40 5 25
Valeriana coarctata40 2 20
Calamagrostietea vicunarum
Calamagrostis vicunarum 33525318 6150506720 613 50224
Parastrephietalia quadrangularis
Parastrephia quadrangularis 13832 651008810040 +1
Tetraglochin cristatum 923514 4313638360 2
Descurainia depressa608137
Pycnophyllum molle4010043936838 57 50 1125 13 22+
Hypochaeris meyeniana6050703014 13 1 1
Ephedra rupestris20892632 3025 67 1 1
Weberbauera spathulifolia604261618 1 14 40
Belloa piptolepis 386551326 3013 + 6 20 +1
Senecio candollei 417375 4413 2
Senecio humillimus 13221418 251 1
Brayopsis calycina 4643323
Chaetanthera stuebelii20 4423
Nototriche anthemidifolia 58 4964
Draba macleanii 17 2818 63
Erigeron rosulatus 25 3718
Hypochaeris eriolaena 13 12 17
Plantago sericea var. lanuginosa 813 23
Werneria aretioides 38 42 13 4
Senecio spinosus 29269 3913253340 +
Werneria pectinata 461723 6 4 1
Silene genovevae 33227
Perezia coerulescens 13139 413 43625 381 +
Wahlenbergia peruviana 1317 14
Nototriche digitulifolia 8225
Nototriche pedicularifolia 29 16 1
Lupinus ananeanus 8265
Cerastium subspicatum 21225 2
Conyza deserticola 89
Lobivia maximiliana 9
Oxalis calachaccensis 8
Gomphrena meyeniana 8 20
Calamagrostion minimae
Calamagrostis minima 29 132+
Werneria nubigena 17 20
Oreomyrrhis andicola 42 1
Calandrinia acaulis8013 19 + 4
Astragalo minimi-Azorelletum diapensioidis
Azorella diapensioides 679 13 50 1 +
Astragalus minimus 83262
Bougueria nubicola 67175
Werneria apiculata 584 13
Werneria melanandra 38
Nototriche longirostris 3813 1
Junellia minima 29
Aciachne pulvinata 464 4
Nototriche turritela 63 25 13
Ourisia muscosa 13
Viola hillii 4
Azorello compactae-Festucion orthophyllae
Azorella compacta 78747710 4888 38 14+
Festuca orthophylla 63225146 100100 50 1+24
Baccharis caespitosa 131236 913 17 +1 43 20383++
Belloa sp. (# 3945) 17727
Bowlesia tropaeolifolia 4218 + 436 20
Baccharis tricuneata 353346 22757533100 1
Cumulopuntia boliviana subsp. ignescens 22 14 43 25 20 +
Bartsia elongata 914 25 40
Caiophora rosulata 918
Senecio evacoides 232 20 14 25
Stangea wandae 1627
Astragalo pusillii-Parastrephietum quadrangularis
Astragalus pusillus 65 4 3
Sisyrinchium brevipes 822
Sisyrinchium trinervis 17
Laennecia artemisioides 17
Valeriana aschersoniana 4
Belloa longifolia 4 1350 20 1
Descurainia sp. (# 0940) 4
Junellia pappigera 4
Senecioni moqueguensis-Pycnophylletum molle
Senecio moqueguensis 84
Senecio tassaensis 426 13
Nototriche argentea 215 1
Arenaria acaulis 16
Gentianella primuloides 16
Nototriche sepaliloba 16
Cerastium behmianum 14
Xenophyllum weddellii 14
Nototriche pusilla 12
Oritrophium sp. (# 2194b) 12
Senecio sykorae 12
Perezia coerulescens var. amplibracteata 9
Werneria heteroloba 9
Myrosmodes sp. (# 2287) 7
Poa brevis 7
Senecio graveolens 7 413 17 13
Senecio sp.1 (# 4217a) 7
Spergularia andina 4 7
Lupinus sp. (# 2424) 5
Senecio scorzonerifolius 5
Viola sp. (# 4217a) 5
Werneria sp. (# 3940) 5
Xenophyllum digitatum 5
Calamagrostio trichophyllae-Azorelletum compactae
Nototriche mandoniana 77
Calamagrostis trichophylla 77
Mniodes caespititia 686
Silene mandonii 68
Senecio sp.2 (# 3935) 64
Erigeron lanceolatus 46
Werneria glaberrima 941
Nototriche pedatiloba 36
Perezia pungens 36 25 20
Draba soratensis 32
Bartsia sp. (# 3092) 218
Poa gilgiana 18 2 60
Agrostis breviculmis 14
Viola granulosa 14 1
Lupinus chilensis 5
Anthochloo-Diesliochloetea
Anthochloa lepidula4013 59948040 13 254++
Dielsiochloa floribunda 5 316060 4 881 4
Nototrichion obcuneatae (Nototricho obcuneatae-Xenophylletum poposi)
Nototriche obcuneata 66020 9 214
Senecio adenophyllus 514562040 1138 63412
Senecio sp.3 (# 3931) 14254040
Dissanthelium calycinum 38262618660 1009 381
Nototriche sp.1 (# 3104) 5 1340
Nototricho obcuneatae-Xenophylletum poposi Galán de Mera, Cáceres & Gonzáles 2003
Mniodes coarctata 16 88 +4
Xenophyllum poposum 81 9 4
Nototriche erinacea 56
Senecio trifurcifolius 31
Poa sp. (# 3099) 25
Nototriche sp.2 (# 4228a) 19
Senecio sp.4 (# 4228b) 13
Poo aequiglumae-Xenophylletum dactylophyllum
Nototriche sp.3 (# 2447) 100
Poa aequigluma 100
Poa spicigera 100 63
Xenophyllum dactylophyllum 80 1
Community of Senecio algens
Senecio algens 2 80 2 1713 131 1
Senecio sp.5 (# 3942) 100
Class
Community of Tarasa nototrichoides and Urtica flabellata
Urtica flabellata 100
Lachemilla pinnata 384 100 1+
Tarasa nototrichoides 44 90
Perezia multiflora 17 50 13
Jaborosa squarrosa 40 13
Valeriana sp. (Image DSC075, 03/2014) 10
CRASSULETEA CONNATAE
Muhlenbergia peruviana 25132 1383
Crassula connata 17
ARGYROCHOSMETEA NIVEAE; Salpichroetalia glandulosae
Asplenium peruvianum 9 4 7111 100
Belloa kunthiana 9
Belloa schultzii 4 2 29638
Loricaria graveolens 13
Salpichroa glandulosa 25 + 4322 20
Valeriana nivalis 95 21149425 132+
Companions
Calamagrostis curvula 1744365610080 39 13100 13 4+
Trisetum spicatum4033423619 + 2038
Luzula vulcanica 3313442713
Parastrephia lucida 451861960 30 144
Pycnophyllum glomeratum 8444234420 13 144
Microsteris gracilis1002126 23
Paronychia andina 3339914 3 3
Senecio nutans 30 462560 17100 67 1+
Stangea rhizanta60 1232 60 2013
Astragalus peruvianus 17172
Bartsia diffusa 8265 13 1 6 13
Lepidium meyenii 1395 1
Cardionema ramosissimum 842
Mniodes sp. (# 2477) 26913
Poa candamoana40 950 135083100
Stipa ichu602978 26387510020 1
Astragalus uniflorus 7 6 13
Chaetanthera peruviana 4 14 13
Geranium sessiliflorum 923 13 20 + 20 1 1
Mancoa hispida 134
Adesmia spinosissima 9 2213 20
Cyperus seslerioides 13 13
Descurainia athrocarpa 2 6 131
Galium corymbosum 35 13 2 296 60
Lupinus cuzcensis 4
Oxalis debilis 4
Oxalis nubigena 9 29 1
Weberbauera peruviana 4
Species from other communities
Lupinus paruroensis 1713 67
Chersodoma jodopappa 4 133320
Deyeuxia heterophylla 25136720
Deyeuxia breviaristata 13 +3
Astragalus arequipensis 13
Festuca rigescens 13 13 +
Lupinus saxatilis 38 40
Erigeron incarum 13 17
Luzula racemosa 4 381
Festuca dolichophylla 100100100 14 25
Deyeuxia cabrerae 17 613 13 +2
Paranephelius ovatus 751760 1
Coreopsis fasciculata 75 60
Plantago sericea 1367
Plantago linearis 25 20
Nassella pubiflora 2517
Dissanthelinum macusaniense 17 25
Nassella mucronata 388360
Trifolium amabile 6317
Bromus catharticus 38 20
Lupinus microphyllus 1720
Senecio modestus 11 4013
Draba brackenridgei + 29
Mniodes andina + 88
Oxalis andina 1+ 60 1
Senecio rhizomatus 1+ 20
Cystopteris fragilis + 20
Asplenium triphyllum 1 11 40
Senecio culcitioides 1 142813 50
Woodsia montevidensis 114
Caiophora horrida 1 1
Sisymbium peruvianum 1 6
Stipa rigida 1 2063
Xenophyllum ciliolatum 252
Silene andicola 131+2
Poa humilluma 381
Adesmia patancana 1
Perezia ciliosa 1
Other species: In 10 Baccharis incarum 57; in 10 Nassella brachyphylla 13, Echinopsis pamparuizii 9, Baccharis genistelloides 9, Hypochaeris taraxacoides 9, Stipa nardoides 4, Stipa rigidiseta 4, Plantago monticola 4, Nassella asplundii 4, Polylepis tarapacana 13, Arenaria serpens 9, Dissanthelium peruvianum 9, Werneria sp. 4, Oxalis pachyrrhiza 4, Calamagrostis intermedia 4, Caiophora chuquitensis 4, Bomarea dulcis 4, Dissanthelinum breve 4; in 11 Stipa obtusa 25, Opuntia lagopus 13, Baccharis buxifolia 13, Adesmia miraflorensis 13, Polylepis rugulosa 25, Senecio adenophylloides 13, Senecio rudbeckiifolius 13, Stipa annua 13; in 12 Nassella pubiflora 25, Tunilla soehrensii 13, Quinchamalium procumbens 13, Echinopsis pampana 13, Vulpia megalura 38, Tagetes multiflora 25, Bidens pilosa 25, Gilia laciniata 13, Lepechinia meyenii 13, Nassella depauperata 13, Schkhuria multiflora 13, Chondrosum simplex 13, Hordeum muticum 13, Hypochaeris chillensis 13, Erodium cicutarium 13, Lepidium chichicara 13; in 13 Bartsia camporum 50, Mutisia arequipensis 17, Gnaphalium dombeyanum 17; in 14 Agrostis gelida 100; in 16 Asplenium castaneum +, Peperomia peruviana 2, Oxalis arenaria 1; in 17 Draba cryptantha 2; in 18 Gnaphalium sp. 1, Cerastium mucronatum 1, Phacelia pinnata 1, Lobivia caespitosa 1; in 19 Bomarea uniflora 57, Bowlesia sodiroana 14, Oxalis petrophila 14, Valeriana plectritoides var. pallida 14, Galium aparine 14, Poa horridula 14; in 20 Draba cuzcoensis 6, Ribes brachybothrys 6; in 22 Peperomia peruviana 60, Oxalis arenaria 40, Asplenium castaneum 20, Englerocharis peruviana 20; in 23 Xenophyllum decorum 88, Plettkea cryptantha 38, Xenophyllum digitatum 13, Chaetanthera cochlearifolia 63, Weberbauera rosulans 13, Niphogeton dissecta 25, Gentianella weberbaueri 13, Englerocharis peruviana 50, Nototriche aretioides 38, Nototriche pinnata 13, Plantago lamprophylla 13, Bromus villosissimus 38, Pycnophyllum weberbaueri 13, Pernettya prostrata 13, Niphogeton scabra 13, Astragalus brackenridgei 13, Deyeuxia tarmensis 13, Senecio tephrosioides 13, Deyeuxia ovata 25, Deyeuxia rigescens 13, Deyeuxia glacialis 13, Senecio canescens 13, Ephedra americana 38, Melpomene moliniformis 13, Valeriana candamoana 38; in 24 Poa gymnantha 18, Astragalus micranthellus 1, Bartsia crenata 1, Bromus lanatus 1, Chaetanthera boliviensis 1, Chaetanthera villosa 1, Deyeuxia cephalanta 1, Deyeuxia densiflora 1, Deyeuxia glaciaris 1, Gnaphalium badium 1, Niphogetom scabra 1, Poa aequigluma 1, Pycnophyllum filiforme 1, Senecio puchii 1, Valeriana interrupta 1, Viola nivalis 1; in 25 Deyeuxia deserticola 9; in 26 Nototriche sp.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Montesinos-Tubée, D.B.; Cleef, A.M.; Sýkora, K.V. The Subnival Vegetation of Moquegua, South Peru: Chasmophytes, Grasslands and Cushion Communities. Ecologies 2021, 2, 71-111. https://0-doi-org.brum.beds.ac.uk/10.3390/ecologies2010005

AMA Style

Montesinos-Tubée DB, Cleef AM, Sýkora KV. The Subnival Vegetation of Moquegua, South Peru: Chasmophytes, Grasslands and Cushion Communities. Ecologies. 2021; 2(1):71-111. https://0-doi-org.brum.beds.ac.uk/10.3390/ecologies2010005

Chicago/Turabian Style

Montesinos-Tubée, Daniel B., Antoine M. Cleef, and Karlè V. Sýkora. 2021. "The Subnival Vegetation of Moquegua, South Peru: Chasmophytes, Grasslands and Cushion Communities" Ecologies 2, no. 1: 71-111. https://0-doi-org.brum.beds.ac.uk/10.3390/ecologies2010005

Article Metrics

Back to TopTop