Next Article in Journal
Ecological and Conservation Correlates of Rarity in New World Pitvipers
Next Article in Special Issue
Genetic Data Suggest Multiple Introductions of the Lionfish (Pterois miles) into the Mediterranean Sea
Previous Article in Journal
A New Species of Terrestrial-Breeding Frog (Amphibia, Strabomantidae, Noblella) from the Upper Madre De Dios Watershed, Amazonian Andes and Lowlands of Southern Peru
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Diversity
Volume 11
Issue 9
10.3390/d11090146
diversity-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

An Alien Invader is the Cause of Homogenization in the Recipient Ecosystem: A Simulation-Like Approach

by
Carla Morri
1,*,
Monica Montefalcone
1,
Giulia Gatti
2,
Paolo Vassallo
1,
Chiara Paoli
1 and
Carlo Nike Bianchi
1
1
DiSTAV (Department of Earth, Environmental and Life Sciences), University of Genoa, 16132 Genova, Italy
2
Mediterranean Institute of Biodiversity and marine and continental Ecology, CNRS, Station Marine d’Endoume, 13007 Marseille, France
*
Author to whom correspondence should be addressed.
Diversity 2019, 11(9), 146; https://0-doi-org.brum.beds.ac.uk/10.3390/d11090146
Submission received: 6 July 2019 / Revised: 18 August 2019 / Accepted: 23 August 2019 / Published: 26 August 2019
(This article belongs to the Special Issue Biological Invasions 2020 Horizon)
Browse Figures
Versions Notes

Abstract

:
Biotic homogenization is an expected effect of biological invasions. Invasive alien species typically show great adaptability to a wide range of environmental conditions and may expand into different habitats, thus reducing the dissimilarity among the recipient communities. We tested this assumption by analyzing a comprehensive database (78 species × 229 samples) collected between 2012 and 2017 in the marine protected area of Portofino (NW Italy), where Caulerpa cylindracea, one of the worst invaders in the Mediterranean Sea, exhibits high substratum cover at depths between 1 m and 45 m in 14 different communities (identified according to the European Nature Information System EUNIS for habitat classification). Five samples for each of the eight depth zones (i.e., 5 m, 10 m, 15 m, 20 m, 25 m, 30 m, 35 m, and 40 m) were randomly re-sampled from the comprehensive database to produce a dataset of 67 species × 40 samples. Then, a second dataset of 66 species × 40 samples was simulated by excluding Caulerpa cylindracea. Both re-sampled datasets underwent multivariate analysis. In the presence of C. cylindracea, the overall similarity among samples was higher, thus indicating homogenization of the rocky reef communities of Portofino Marine Protected Area. Continued monitoring activity is needed to understand and assess the pattern and extent of C. cylindracea’s inclusion in the recipient ecosystems.

1. Introduction

Biological invasions, i.e., the successful establishment and spread of species outside their native range [1,2], are a major component of global change [3,4,5]; they reshuffle the planet’s biota and represent a distinctive mark of the Anthropocene [6,7]. Biological invasions have been dubbed “biological pollution” [8,9] that causes biodiversity loss and alters the composition of communities and ecosystem functioning [10,11], thus compromising ecosystem services [12]. In terrestrial habitats, biological invasions have been the concern of biogeographers and ecologists for decades [13,14], whereas in marine environments they have remained less known until recently [15,16]. Today, meta-analysis and reviews are available that highlight the impact of marine invasions [12,17,18,19]. Studies in the Mediterranean Sea indicate that biological invasions represent a serious ecological and economical menace leading to fishery and tourism impairment [20].
In terrestrial environments, invasive alien species have been considered important agents of biotic homogenization at different spatial scales [21,22,23]. In the present paper, biotic homogenization means the process that diminishes floral and faunal differences among previously distinct communities within a specific region [24,25]. The rationale beyond the idea that biological invasions may cause homogenization in the recipient biota is simple—invasive species typically show great adaptability to a wide range of environmental conditions and may thus enter different habitats, often becoming dominant [26,27]. If an abundant invader replaces or simply adds to the native species that used to characterize the recipient communities, then the dissimilarity among communities is expectedly reduced (Figure 1). This rather simplistic scheme just aims at illustrating the rationale of our study, while more complete schemes illustrating the many ways invaders can impact recipient communities can be found in review papers [24,28,29].
We tested the assumption above by analyzing the change that may be observed in the zonation of communities along a sharp ecological gradient (i.e., depth) in the presence or absence of an alien invader. We used a comprehensive database collected in the marine protected area of Portofino (NW Italy), where Caulerpa cylindracea—one of the worst invaders in the Mediterranean Sea [30,31]—has become abundant in recent years [32]. After a descriptive analysis of the comprehensive database, we generated two distinct datasets to go through multivariate analysis: the first contained observed data, and the second was a “simulated” one where C. cylindracea was excluded from the dataset, under the hypothesis that the latter dataset will exhibit greater dissimilarity than the former one. We used the term “simulated” to make it clear that we did not perform a real, physical removal experiment in the field. Our procedure ties in with the so-called “inclusion versus exclusion” approach, which has been said to be not only relevant to invasion biology, but to any field where the component of interest is an integrated part of the response [18,33].

2. Materials and Methods

2.1. The Invader

Caulerpa cylindracea Sonder, formerly considered a variety of Caulerpa racemosa (Sonder) Verlaque, Huisman, and Boudouresque, but presently recognized as an independent species [34,35], is a green alga with a cylindrical stolon bearing erect fronds up to 20 cm high, with bunches of vesicular branchlets or ramuli (Figure 2a). C. cylindracea is of southwest Australian origin, but in recent decades has expanded its range to many subtropical areas of the Pacific and Atlantic oceans [36].
In the Mediterranean Sea, C. cylindracea was observed for the first time in 1990 [37]. Since then, the species has exhibited an impressive and apparently restless spread across the whole basin [38,39,40], locally covering the substratum to 100% [41]. The rapid spread of this invader has few equivalents among introduced marine macrophytes [42], and ship traffic has been blamed as the main vector [43,44]. C. cylindracea has a high adaptability to physical and biotic factors [45], is resistant to grazing because of the production of toxic metabolites [46], and may colonize virtually all types of substrata, in either sheltered or exposed areas, at depths ranging from the intertidal zone down to 90 m depth [47,48,49,50,51,52] in disturbed or pristine habitats [53,54,55]. C. cylindracea is able to out-compete native algae [56] and seagrass [57], which contrasts with studies dealing with other species of Caulerpa [58].

2.2. Study Area

Field data for this study came from the marine seabed around the Portofino promontory (Figure 3), an impressive 6-km wide rocky headland in the Ligurian Sea (NW Mediterranean). The headland runs out toward the sea for about 5 km, and the southern front exhibits high vertical or sub-vertical cliffs that continue underwater to about 50 m depth, while the eastern and western sides are comparatively shallower. The heterogeneous features of the Portofino promontory allow for the coexistence in a limited area of numerous species and of varied benthic communities and underwater seascapes [59]. Caulerpa cylindracea was first recorded in the area in 1996 [60,61].
In 1999, the Portofino marine protected area (MPA) was established around the promontory, and was organized into three zones subject to different levels of protection: the A zone (“no entry, no take”), limited to a small cove; the B zone (general reserve), covering the southern front of the promontory; the C zone (partial reserve), along the eastern and western sides of the headland (Figure 3). The MPA of Portofino is included in the European Natura 2000 Network as a Site of Community Importance (SCI IT1332674: Fondali Monte di Portofino), and since 2005 has been a Specially Protected Area of Mediterranean Interest (SPAMI) according to the decision of the UNEP-RAC/SPA (the Regional Activity Centre for Specially Protected Areas of the United Nations Environment Programme) office [62].

2.3. Data Sources and Management

Data on the benthic communities of Portofino reefs were collected between 2012 and 2017 by scuba diving between 1 m and 45 m depth in summer months. Cover data of Caulerpa cylindracea and other conspicuous sessile species were obtained using 1 m2 visual quadrats [63].
The resulting comprehensive database of 78 species × 229 samples (Table S1) was used to explore the patterns of abundance and distribution of Caulerpa cylindracea in Portofino MPA and its diffusion within the benthic communities existing there. The latter have been identified and named according to the habitat classification of the European Nature Information System EUNIS (www.eea.europa.eu/data-and-maps/data/eunis-habitat-classification). One-way analysis of variance (ANOVA) was used to assess differences where applicable; in the resulting tables, SS is the sum of squares, df is the degrees of freedom, s2 is the variance (mean square) and F is the ratio between the variance between groups and the variance within groups.
Then, to test the assumption that C. cylindracea may cause biotic homogenization in the recipient ecosystem, we analyzed the change in the zonation of communities along a sharp ecological gradient, i.e., depth. To reduce noise and to have a balanced design, 5 quadrats for each of 8 depth zones (5 m, 10 m, 15 m, 20 m, 25 m, 30 m, 35 m, and 40 m) were randomly re-sampled (in the statistical sense) from the comprehensive database to produce a first dataset of 67 species × 40 samples (Table S2). A second dataset of 66 species × 40 samples was simulated by excluding C. cylindracea. Both the first (“observed”) and the second (“simulated”) datasets underwent principal component analysis (PCA) using the free software PaSt [64]. Significance of the axes was evaluated by 9999 row-wise bootstrap replicates, and 95% bootstrapped confidence intervals were given for the eigenvalues [65]. The eigenvalues expected under a random model (broken stick) were also computed, with lower eigenvalues possibly representing non-significant components [66]. The geometry of the resulting ordination models has been interpreted according to Fresi and Gambi [67]. Prior to the analyses, cover values were arcsine√(x/100) transformed [68]. As the two datasets are not independent of each other, we did not attempt to statistically test the differences between the two ordination models. We drew the convex hulls, i.e., the smallest convex polygons enclosing the sample points, in both scatter plots to visualize and compare graphically the respective multivariate dispersions. In addition, for each dataset we computed the average dissimilarity (1—Bray-Curtis coefficient), the standard deviation, and the coefficient of variation among samples, with lower values of these indices being indicative of reduced β-diversity, and hence homogenization [69].

3. Results

3.1. Descriptive Analysis

Based on the comprehensive database of 78 species × 229 samples, Caulerpa cylindracea proved abundant on the rocky reefs of the marine protected area of Portofino (Figure 2b), exhibiting considerable substratum cover (up to 25%) at all depths investigated (1 m to 45 m), with the highest values especially around 20 m (Figure 4a). No other species in Portofino exhibited similar abundance and ubiquity.
There was no difference in the occurrence of C. cylindracea among areas with varying degree of protection (Figure 4b), nor among the years 2012 to 2017 (Figure 4c), as indicated by the large overlap among error bars. Notwithstanding high variability, a significant negative relationship was found between the cover of C. cylindracea and the total number of species (Figure 4d).
A total of 14 EUNIS habitats have been recognized in the rocky reefs of Portofino MPA between 1 m and 45 m depth. Seven of them were characterized by macroalgae (Lithophyllum incrustans, Ellisolandia elongata, Codium vermilara, Dictyopteris polypodioides, Flabellia petiolata and Peyssonnelia squamaria, Halopteris scoparia, Cystoseira zosteroides), four by gorgonian or soft corals (Eunicella cavolini, Paramuricea clavata, Parazoanthus axinellae, Leptogorgia sarmentosa), two by zooxanthellate corals (Cladocora caespitosa, Eunicella singularis), and one by the seagrass Posidonia oceanica (Table 1).
These 14 habitats were zoned chiefly according to depth and substratum slope (Figure 5a). C. cylindracea was found in all of them, although with different cover values (Table 2)—the most invaded habitats were the Posidonia oceanica beds, the Paramuricea clavata facies, and the Cystoseira zosteroides association, while the least invaded were the Codium vermilara association, the encrusting algae (Lithophyllum incrustans) and sea urchins facies, and the Flabellia petiolata-Peyssonnelia squamaria association (Figure 5b). Even in the least invaded habitats, however, C. cylindracea could occasionally be very abundant (Figure 2c). In the case of zooxanthellate corals, C. cylindracea invasion occurred especially after coral colonies had bleached because of summer warming events (Figure 2d).

3.2. Simulation-Like Approach

As for the re-sampled datasets, PCA on the “observed” dataset of 67 species × 40 samples gave one highly significant component (Figure 6a), represented by the first (horizontal) axis in the resulting ordination model (Figure 6c). Sample points were ordered along a horse-shoe cloud, with shallow (5 m) samples on the left and deep (40 m) samples on the right, and with the remaining samples being regularly spaced among them. This geometry of the ordination model is known to indicate the existence of a major gradient, essentially expressed along the first axis. In this case, the gradient was obviously depth, with scores along the first axis being significantly correlated with depth (R² = 0.913, n = 40, p < 0.001). Consistently, differences among depth scores were highly significant (Table 3).
Also the PCA on the “simulated” dataset of 66 species × 40 samples gave one highly significant component (Figure 6b) and a horse-shoe ordination model (Figure 6d). Even in this case, the first axis was highly correlated with depth (R² = 0.954, n = 40, p < 0.001), and differences among depth scores were again highly significant (Table 3). However, the sample points were not as regularly spaced as in the case of the “observed” dataset (Figure 7a), but rather formed three groups separated by obvious gaps: 5 m depth, 10 m to 20 m depth, and 25 m to 40 m depth (Figure 7b). The difference among these three groups was highly significant (Table 4). The convex hull of the “simulated” dataset was visibly wider—and thus multivariate dispersion was larger—than that of the “observed” dataset (Figure 6c,d). Consistently, average dissimilarity, standard deviation, and coefficient of variation among samples were greater in the absence of C. cylindracea than in its presence (Table 5).

4. Discussion

Caulerpa cylindracea was abundant in the rocky reefs of Portofino, as illustrated by field data. Relative abundance (here expressed as % cover) is a recommended index to gauge the invasion level of an alien species [70]. With an average cover of about 10% (with peaks to 25%), C. cylindracea can be defined a strong invader [54]; nevertheless, its impact to the recipient communities has been shown significant already with low cover [71].
C. cylindracea spread through the whole Marine Protected Area, including the “no entry, no take” zone. MPAs are mostly designed to manage fisheries [72], and may even help restore ecosystems through enhanced top-down control [73], but cannot prevent the introduction of alien species [74,75]. In Portofino, constancy of C. cylindracea cover values for six years (2012 to 2017) suggests that it has reached the so-called phase of persistence—the last of the four phases identified in the process of naturalization of introduced species [76,77].
As already observed in other Mediterranean sites [41], C. cylindracea showed a wide depth range at Portofino, with a preference for about 20 m depth, and invaded all the communities existing there, although with different intensities. Our study is the first to make a direct comparison of the quantitative incidence (in term of % cover) in as many as 14 communities (defined following EUNIS habitat classification). Notwithstanding significant differences of C. cylindracea cover among the 14 individual habitats, no clear pattern (aside from depth) was discernible according to the nature of the habitats, with macroalgal associations, seagrass beds, coral facies, and zooxanthellate coral facies all being colonized by C. cylindracea. It has been recognized that the impacts of invasive species are often context-dependent, both on land [78,79] and in the sea [29], and may depend on the idiosyncrasy of the eco-evolutionary history of the recipient communities [80]. The relationship between species richness and the invasions of alien species may be either positive or negative, mostly depending on scale [81]. At Portofino, increased cover values of C. cylindracea were associated with reduced species richness, as reported in many studies [82,83]. It has been shown that reduced species richness can in turn further accelerate invasion [81].
The depth gradient in the presence of C. cylindracea showed no discontinuity, suggesting that the benthic communities replaced each other gradually. On the contrary, when C. cylindracea was excluded from the analysis three sharply distinguished situations were recognizable, separated by discontinuities that correspond well with known ecological thresholds in light intensity and water movement [84]. Such a result indicates that the high environmental adaptability of C. cylindracea [40] overcomes the severity of the ecological gradients that typically dictate the depth zonation of native communities in the infralittoral and circalittoral zones in Mediterranean rocky reefs [84]. This effect and other indicators and indices (multivariate dispersion, average dissimilarity, standard deviation, and coefficient of variation) consistently point to the homogenization caused by C. cylindracea invasion.
The problem of homogenization in terrestrial ecosystems is better known than in marine ecosystems, which affects our ability to make ecological assessments of change [85]. We used a simulation-like approach to evidence that C. cylindracea is cause of homogenization in the recipient ecosystem. In particular, the depth gradient was better defined, with a greater multivariate dispersion, when the invader was excluded from the analysis. Multivariate dispersion is considered a measure of β diversity [86], i.e., the variability in species composition among communities within an area. Consistently, it has been demonstrated experimentally that C. cylindracea depresses β diversity in invaded ecosystems [87].
Apparently C. cylindracea did not replace any native species, most of them having already disappeared or got rarer due to climatic and local human impacts during the 1980–90s ecosystem shift at Portofino reefs [32]. Thus, C. cylindracea acted more as a “passenger”, i.e., a passive opportunist taking advantage of environmental change, than a “driver”, i.e., a genuine actor of ecosystem degradation [88]. There is presently a debate about whether invasive species act as passengers or drivers of global change [89,90]. Removal experiments led to the conclusion that C. cylindracea acted as a passenger at the beginning of the invasion to become a driver once established [91]. As drivers, invasive species exert an impact on Mediterranean marine ecosystems that may exceed that of sea water warming [92]. The analysis of many correlative and experimental studies led to the conclusion that the invasion by C. cylindracea is one of the most threatening in the Mediterranean Sea [93].

5. Conclusions

This study assessed the abundance and widespread occurrence of Caulerpa cylindracea in Portofino across depth zones and EUNIS habitats. EUNIS, the European Nature Information System, was created to provide European administrators and scientists with a common frame for conservation [94]. Future studies on C. cylindracea should refer to the invaded EUNIS habitats in order to establish their vulnerability ranking and to search for common approaches to the management of biological invasions. Further evidence of the role that invasive species may play in the biotic homogenization of the recipient ecosystem is also needed.
Two recent European Union Directives, the Marine Strategy and the Biodiversity Strategy, stressed the importance of collecting information on trends in abundance, temporal occurrence, and spatial distribution of invasive species [40,95]. Beside experimental studies, continued monitoring activity carried out with a macroecological approach [96] similar to the one undertook in the present paper is needed to understand and assess the pattern and extent of C. cylindracea insertion in the recipient ecosystems.

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/1424-2818/11/9/146/s1. Table S1: Comprehensive database. Table S2: Re-sampled dataset.

Author Contributions

Conceptualization, C.M. and C.N.B.; Methodology, M.M., G.G., P.V., C.P.; Software, P.V., C.P. and C.N.B.; Validation, P.V. and C.P.; Formal Analysis, P.V., C.P. and C.N.B.; Investigation, M.M., G.G., and C.N.B.; Resources, C.M. and C.N.B.; Data Curation, C.M., M.M., G.G. and C.N.B.; Writing – Original Draft Preparation, C.M., M.M., P.V., C.P. and C.N.B.; Writing – Review & Editing, C.M. and C.N.B.; Visualization, C.M. and C.N.B.; Supervision, C.M. and C.N.B.; Project Administration, C.M.; Funding Acquisition, C.M.

Funding

This research received no external funding.

Acknowledgments

Research partly done within the projects The impacts of biological invasions and climate change on the biodiversity of the Mediterranean Sea (Italian Ministry of the Environment) and ScoPro (Marine Protected Area of Portofino). Sara Venturini (MPA Portofino) and Giorgio Barsotti, Claudio De Angelis, and Pino Galletta (GDA, Genova) participated in some of the dives. Thanks are also due to Efisio Piana (Q18, Bogliasco) for logistic support. This paper results from an oral communication to the 10th International Conference on Marine Bioinvasions held in Puerto Madryn, Patagonia, Argentina, October 16–18 2018.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Drake, J.A.; di Castri, F.; Groves, R.H.; Kruger, F.J.; Rejmánek, M.; Williamson, M. Biological Invasions, a Global Perspective; John Wiley & Sons: Chichester, UK, 1989. [Google Scholar]
  2. Blackburn, T.M.; Pyšek, P.; Bacher, S.; Carlton, J.T.; Duncan, R.P.; Jarošík, V.; Wilson, J.R.U.; Richardson, D.M. A proposed unified framework for biological invasions. Trends Ecol. Evol. 2011, 26, 333–339. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  3. Occhipinti-Ambrogi, A.; Savini, D. Biological invasions as a component of global change in stressed marine ecosystems. Mar. Pollut. Bull. 2003, 46, 542–551. [Google Scholar] [CrossRef]
  4. Stock, A.; Crowder Larry, B.; Halpern, B.S.; Micheli, F. Uncertainty analysis and robust areas of high and low modeled human impact on the global oceans. Conserv. Biol. 2018, 32, 1368–1379. [Google Scholar] [CrossRef] [PubMed]
  5. Lowry, E.; Rollinson, E.J.; Laybourn, A.J.; Scott, T.E.; Aiello-Lammens, M.E.; Gray, S.M.; Mickley, J.; Gurevitch, J. Biological invasions: A field synopsis, systematic review, and database of the literature. Ecol. Evol. 2013, 3, 182–196. [Google Scholar] [CrossRef] [PubMed]
  6. Lewis, S.L.; Maslin, M.A. Defining the Anthropocene. Nature 2015, 519, 171–180. [Google Scholar] [CrossRef] [PubMed]
  7. Anthony, L. The Aliens among Us: How Invasive Species Are Transforming the Planet- and Ourselves; University Press: New Haven, CT, USA, 2017. [Google Scholar]
  8. Boudouresque, C.F.; Verlaque, M. Biological pollution in the Mediterranean Sea: Invasive versus introduced macrophytes. Mar. Pollut. Bull. 2002, 44, 32–38. [Google Scholar] [CrossRef]
  9. Kuhlenkamp, R.; Kind, B. Introduction of non-indigenous species. In Handbook on Marine Environment Protection; Salomon, M., Markus, T., Eds.; Springer: Cham, Switzerland, 2018; Chapter 25; pp. 487–516. [Google Scholar]
  10. Ehrenfeld, J.G. Ecosystem consequences of biological invasions. Annu. Rev. Ecol. Evol. Syst. 2010, 41, 59–80. [Google Scholar] [CrossRef]
  11. Fox, C.W. Towards a mechanistic understanding of global change ecology. Funct. Ecol. 2018, 32, 1648–1651. [Google Scholar] [CrossRef]
  12. Katsanevakis, S.; Wallentinus, I.; Zenetos, A.; Leppäkoski, E.; Çinar, M.E.; Oztürk, B.; Grabowski, M.; Golani, D.; Cardoso, A.C. Impacts of invasive alien marine species on ecosystem services and biodiversity: A pan-European review. Aquat. Invasions 2014, 9, 391–423. [Google Scholar] [CrossRef]
  13. Elton, C. The Ecology of Invasions by Animals and Plants; Chapman and Hall: London, UK, 1958. [Google Scholar]
  14. Richardson, D.M.; Pyšek, P.; Carlton, J. A compendium of essential concepts and terminology in invasion ecology. In Fifty Years of Invasion Ecology—The Legacy of Charles Elton; Richardson, D.M., Ed.; John Wiley & Sons Ltd.: Oxford, UK, 2011; pp. 409–420. [Google Scholar]
  15. Carlton, J.T. The scale and ecological consequences of biological invasions in the World’s oceans. In Invasive Species and Biodiversity Management; Sandlund, O.T., Schei, P.J., Viken, A., Eds.; Kluwer Academic Publishers: Dordrecht, The Netherlands, 1999; pp. 195–212. [Google Scholar]
  16. Occhipinti-Ambrogi, A.; Sheppard, C. Marine bioinvasions: A collection of reviews. Mar. Pollut. Bull. 2007, 55, 299–402. [Google Scholar] [CrossRef]
  17. Thomsen, M.S.; Wernberg, T.; Tuya, F.; Silliman, B.R. Evidence for impacts of nonindigenous macroalgae: A meta-analysis of experimental field studies. J. Phycol. 2009, 45, 812–819. [Google Scholar] [CrossRef] [PubMed]
  18. Thomsen, M.S.; Wernberg, T.; Schiel, D. Invasions by non-indigenous species. In Marine Ecosystems, Human Impacts on Biodiversity, Functioning and Services, 1st ed.; Crowe, T.P., Frid, C.L.J., Eds.; Cambridge University Press: Cambridge, UK, 2015; pp. 274–331. [Google Scholar]
  19. Thomsen, M.S.; Wernberg, T.; South, P.M.; Schiel, D.R. Non-native seaweeds drive changes in marine coastal communities around the world. In Seaweed Phylogeography; Hu, Z.-M., Fraser, C., Eds.; Springer: Dordrecht, The Netherlands, 2016; pp. 147–185. [Google Scholar]
  20. Galil, B.S.; Marchini, A.; Occhipinti-Ambrogi, A. Mare nostrum, mare quod invaditur: The history of bioinvasions in the Mediterranean Sea. In Histories of Bioinvasions in the Mediterranean. Environmental History; Queiroz, A., Pooley, S., Eds.; Springer: Cham, Switzerland, 2018; Chapter 2; Volume 8, pp. 21–49. [Google Scholar]
  21. Dar, P.A.; Reshi, Z.A. Do alien plant invasions cause biotic homogenization of terrestrial ecosystems in the Kashmir Valley, India? Trop. Ecol. 2015, 56, 111–123. [Google Scholar]
  22. Lososová, Z.; Chytrý, M.; Danihelka, J.; Tichý, L.; Ricotta, C. Biotic homogenization of urban floras by alien species: The role of species turnover and richness differences. J. Veg. Sci. 2016, 27, 452–459. [Google Scholar] [CrossRef]
  23. Price, E.P.F.; Spyreas, G.; Matthews, J.W. Biotic homogenization of regional wetland plant communities within short time-scales in the presence of an aggressive invader. J. Ecol. 2018, 106, 1180–1190. [Google Scholar] [CrossRef]
  24. Olden, J.D.; Rooney, T.P. On defining and quantifying biotic homogenization. Glob. Ecol. Biogeogr. 2006, 15, 113–120. [Google Scholar] [CrossRef]
  25. Smart, S.M.; Thompson, K.; Marrs, R.H.; Le Duc, M.G.; Maskell, L.C.; Firbank, L.G. Biotic homogenization and changes in species diversity across human-modified ecosystems. Proc. R. Soc. B 2006, 273, 2659–2665. [Google Scholar] [CrossRef] [Green Version]
  26. Vankleunen, M.; Dawson, W.; Schlaepfer, D.; Jeschke, J.M.; Fischer, M. Are invaders different? A conceptual framework of comparative approaches for assessing determinants of invasiveness. Ecol. Lett. 2010, 13, 947–958. [Google Scholar]
  27. Sol, D.; Maspons, J.; Vall-Llosera, M.; Bartomeus, I.; García-Peña, G.E.; Piñol, J.; Freckleton, R.P. Unraveling the life history of successful invaders. Science 2012, 337, 580–583. [Google Scholar] [CrossRef]
  28. Thomsen, M.S.; Olden, J.D.; Wernberg, T.; Griffin, J.N.; Silliman, B.R. A broad framework to organize and compare ecological invasion impacts. Environ. Res. 2011, 111, 899–908. [Google Scholar] [CrossRef]
  29. Thomsen, M.S.; Wernberg, T.; Olden, J.D.; Griffin, J.N.; Silliman, B.R. A framework to study the context-dependent impacts of marine invasions. J. Exp. Mar. Biol. Ecol. 2011, 400, 322–327. [Google Scholar] [CrossRef]
  30. Streftaris, N.; Zenetos, A. Alien marine species in the Mediterranean-the 100 ‘worst invasives’ and their impact. Mediterr. Mar. Sci. 2006, 7, 87–118. [Google Scholar] [CrossRef]
  31. Katsanevakis, S.; Tempera, F.; Teixeira, H. Mapping the impact of alien species on marine ecosystems: The Mediterranean Sea case study. Divers. Distrib. 2016, 22, 694–707. [Google Scholar] [CrossRef]
  32. Gatti, G.; Bianchi, C.N.; Montefalcone, M.; Venturini, S.; Diviacco, G.; Morri, C. Observational information on a temperate reef community helps understanding the marine climate and ecosystem shift of the 1980–1990s. Mar. Pollut. Bull. 2017, 114, 528–538. [Google Scholar] [CrossRef]
  33. Thomsen, M.S.; Wernberg, T.; South, P.M.; Schiel, D.R. To include or not to include (the invader in community analyses)? That is the question. Biol. Invasions 2016, 18, 1515–1521. [Google Scholar] [CrossRef]
  34. Verlaque, M.; Durand, C.; Huisman, J.M.; Boudouresque, C.F.; Le Parco, Y. On the identity and origin of the Mediterranean invasive Caulerpa racemosa (Caulerpales, Chlorophyta). Eur. J. Phycol. 2003, 38, 325–329. [Google Scholar] [CrossRef]
  35. Belton, G.S.; Prud’homme van Reine, W.F.; Huisman, J.M.; Draisma, S.G.A.; Gurgel, C.F.D. Resolving phenotypic plasticity and species designation in the morphologically challenging Caulerpa racemosa-peltata complex (Chlorophyta, Caulerpaceae). J. Phycol. 2014, 50, 32–54. [Google Scholar] [CrossRef]
  36. Klein, J.; Verlaque, M. The Caulerpa racemosa invasion: A critical review. Mar. Pollut. Bull. 2008, 56, 205–225. [Google Scholar] [CrossRef]
  37. Verlaque, M.; Boudouresque, C.F.; Meinesz, A.; Gravez, V. The Caulerpa racemosa complex (Caulerpales, Ulvophyceae) in the Mediterranean Sea. Bot. Mar. 2000, 43, 49–68. [Google Scholar] [CrossRef]
  38. Piazzi, L.; Meinesz, A.; Verlaque, M.; Akçali, B.; Antolić, B.; Argyrou, M.; Balata, D.; Ballesteros, E.; Calvo, S.; Cinelli, F.; et al. Invasion of Caulerpa racemosa var. cylindracea (Caulerpales, Chlorophyta) in the Mediterranean Sea: An assessment of the spread. Cryptogam. Algol. 2005, 26, 189–202. [Google Scholar]
  39. Zenetos, A.; Gofas, S.; Verlaque, M.; Çinar, M.E.; García Raso, J.E.; Bianchi, C.N.; Morri, C.; Azzurro, E.; Bilecenoglu, M.; Froglia, C.; et al. Alien species in the Mediterranean Sea by 2010. A contribution to the application of European Union’s Marine Strategy Framework Directive (MSFD). Part 1. Spatial distribution. Mediterr. Mar. Sci. 2010, 11, 381–493. [Google Scholar] [CrossRef]
  40. Montefalcone, M.; Morri, C.; Parravicini, V.; Bianchi, C.N. A tale of two invaders: Divergent spreading kinetics of the alien green algae Caulerpa taxifolia and Caulerpa cylindracea. Biol. Invasions 2015, 17, 2717–2728. [Google Scholar] [CrossRef]
  41. Mannino, A.M.; Balistreri, P. An updated overview of invasive Caulerpa taxa in Sicily and circum-Sicilian Islands, strategic zones within the NW Mediterranean Sea. Flora Mediterr. 2017, 27, 221–240. [Google Scholar]
  42. Verlaque, M.; Afonso-Carrillo, J.; Gil-Rodriguez, M.C.; Durand, C.; Boudouresque, C.F.; Le Parco, Y. Blitzkrieg in a marine invasion: Caulerpa racemosa var. cylindracea (Bryopsidales, Chlorophyta) reaches the Canary Islands (NE Atlantic). Biol. Invasions 2004, 6, 269–281. [Google Scholar]
  43. Zenetos, A.; Gofas, S.; Morri, C.; Rosso, A.; Violanti, D.; García Raso, J.E.; Çinar, M.E.; Almogi-Labin, A.; Ates, A.S.; Azzurro, E.; et al. Alien species in the Mediterranean Sea by 2010. A contribution to the application of European Union’s Marine Strategy Framework Directive (MSFD). Part 2. Introduction trends and pathways. Mediterr. Mar. Sci. 2012, 13, 328–352. [Google Scholar] [CrossRef]
  44. Cantasano, N.; Pellicone, G.; Di Martino, V. The spread of Caulerpa cylindracea in Calabria (Italy) and the effects of shipping activities. Ocean Coast. Manag. 2017, 144, 51–58. [Google Scholar] [CrossRef]
  45. Raniello, R.; Lorenti, M.; Brunet, C.; Buia, M.C. Photoacclimation of the invasive alga Caulerpa racemosa var. cylindracea to depth and daylight patterns and a putative new role for siphonaxanthin. Mar. Ecol. 2006, 27, 20–30. [Google Scholar]
  46. Dumay, O.; Pergent, G.; Pergent-Martini, C.; Amade, P. Variations in caulerpenyne contents in Caulerpa taxifolia and Caulerpa racemosa. J. Chem. Ecol. 2002, 28, 343–352. [Google Scholar] [CrossRef]
  47. Argyrou, M.; Demetropoulos, A.; Hadjichristophorou, M. Expansion of the macroalga Caulerpa racemosa and changes in soft-bottom macrofaunal assemblages in Moni Bay, Cyprus. Oceanol. Acta 1999, 22, 517–528. [Google Scholar] [CrossRef]
  48. Piazzi, L.; Ceccherelli, G.; Balata, D.; Cinelli, F. Early patterns of Caulerpa racemosa recovery in the Mediterranean Sea: The influence of algal turfs. J. Mar. Biol. Assoc. UK 2003, 83, 27–29. [Google Scholar] [CrossRef]
  49. Piazzi, L.; Balata, D.; Cinelli, F. Invasions of alien macroalgae in Mediterranean coralligenous assemblages. Cryptogam. Algol. 2007, 28, 289–301. [Google Scholar]
  50. Capiomont, A.; Breugnot, E.; Den Haan, M.; Meinesz, A. Phenology of a deep water population of Caulerpa racemosa in the northwestern Mediterranean Sea. Bot. Mar. 2005, 48, 80–83. [Google Scholar] [CrossRef]
  51. Oprandi, A.; Montefalcone, M.; Ferrari, M.; Morri, C.; Bianchi, C.N. Invasion of the alien green alga Caulerpa racemosa and phase shift within the Posidonia oceanica seagrass meadow of Bergeggi. Biol. Mar. Mediterr. 2014, 21, 101–104. [Google Scholar]
  52. Balistreri, P.; Mannino, A.M. Preliminary data on the occurrence of alien macroalgae in the vermetid reef along the coasts of Favignana Island (Southern Tyrrhenian Sea). Biodivers. J. 2017, 8, 105–112. [Google Scholar]
  53. Katsanevakis, S.; Issaris, Y.; Poursanidis, D.; Thessalou-Legaki, M. Vulnerability of marine habitats to the invasive green alga Caulerpa racemosa var. cylindracea within a marine protected area. Mar. Environ. Res. 2010, 70, 210–218. [Google Scholar]
  54. Montefalcone, M.; Albertelli, G.; Morri, C.; Bianchi, C.N. Pattern of wide-scale substitution within Posidonia oceanica meadows of NW Mediterranean Sea: Invaders are stronger than natives. Aquat. Conserv. 2010, 20, 507–515. [Google Scholar] [CrossRef]
  55. Gennaro, P.; Piazzi, L. The indirect role of nutrients in enhancing the invasion of Caulerpa racemosa var. cylindracea. Biol. Invasions 2013, 16, 1709–1717. [Google Scholar] [CrossRef]
  56. Piazzi, L.; Ceccherelli, G.; Cinelli, F. Threat to macroalgal diversity: Effects of the introduced green alga Caulerpa racemosa in the Mediterranean. Mar. Ecol. Progr. Ser. 2001, 210, 161–165. [Google Scholar] [CrossRef]
  57. Ceccherelli, G.; Campo, E.D. Different effects of Caulerpa racemosa on two co-occurring seagrasses. Bot. Mar. 2002, 45, 71–76. [Google Scholar] [CrossRef]
  58. Thomsen, M.S.; Wernberg, T.; Engelen, A.H.; Tuya, F.; Vanderklift, M.A.; Holmer, M.; McGlathery, K.J.; Arenas, F.; Kotta, J.; Silliman, B.R. A meta-analysis of seaweed impacts on seagrasses: Generalities and knowledge gaps. PLoS ONE 2012, 7, e28595. [Google Scholar] [CrossRef]
  59. Morri, C.; Bianchi, C.N.; Damiani, V.; Peirano, A.; Romeo, G.; Tunesi, L. The marine environment between Punta della Chiappa and Sestri Levante (Ligurian Sea): Ecotipological outline and proposal of a biocenotic map. Boll. Mus. Ist Biol. Univ. Genova 1986, 52, 213–231. [Google Scholar]
  60. Bussotti, S.; Conti, M.; Guidetti, P.; Martini, F.; Matricardi, G. First record of Caulerpa racemosa (Forsskål) J. Agardh along the coast of Genoa (North-Western Mediterranean). Doriana 1996, 6, 1–5. [Google Scholar]
  61. Modena, M.; Matricardi, G.; Vacchi, M.; Guidetti, P. Spreading of Caulerpa racemosa (Forsskål) J. Agardh (Bryopsidaceae, Chlorophyta) along the coasts of the Ligurian Sea. Cryptogam. Algol. 2000, 21, 301–304. [Google Scholar]
  62. Paoli, C.; Vassallo, P.; Dapueto, G.; Fanciulli, G.; Massa, F.; Venturini, S.; Povero, P. The economic revenues and the emergy costs of cruise tourism. J. Clean. Prod. 2017, 166, 1462–1478. [Google Scholar] [CrossRef]
  63. Bianchi, C.N.; Pronzato, R.; Cattaneo-Vietti, R.; Benedetti-Cecchi, L.; Morri, C.; Pansini, M.; Chemello, R.; Milazzo, M.; Fraschetti, S.; Terlizzi, A.; et al. Mediterranean marine benthos: A manual of methods for its sampling and study. 6: Hard bottoms. Biol. Mar. Mediterr. 2004, 11, 185–215. [Google Scholar]
  64. Hammer, Ø.; Harper, D.A.T.; Ryan, P.D. PaSt: Paleontological statistics software package for education and data analysis. Palaeontol. Electron. 2001, 4, 4. [Google Scholar]
  65. Peres-Neto, P.R.; Jackson, D.A.; Somers, K.M. Giving meaningful interpretation to ordination axes: Assessing loading significance in principal component analysis. Ecology 2003, 84, 2347–2363. [Google Scholar] [CrossRef]
  66. Jackson, D.A. Stopping rules in principal components analysis: A comparison of heuristical and statistical approaches. Ecology 1993, 74, 2204–2214. [Google Scholar] [CrossRef]
  67. Fresi, E.; Gambi, M.C. Some important aspects of the mathematical analysis of marine ecosystems. Nat. Sicil. 1982, 6 (Suppl. 3), 449–465. [Google Scholar]
  68. Legendre, P.; Legendre, L. Numerical Ecology, 2nd ed.; Elsevier: Amsterdam, The Netherlands, 1998. [Google Scholar]
  69. Bianchi, C.N.; Cocito, S.; Diviacco, G.; Dondi, N.; Fratangeli, F.; Montefalcone, M.; Parravicini, V.; Rovere, A.; Sgorbini, S.; Vacchi, M.; et al. The park never born: Outcome of a quarter of a century of inaction on the sea-floor integrity of a proposed but not established Marine Protected Area. Aquat. Conserv. 2018, 28, 1209–1228. [Google Scholar] [CrossRef]
  70. Catford, J.A.; Vesk, P.A.; Richardson, D.M.; Pyšek, P. Quantifying levels of biological invasion: Towards the objective classification of invaded and invasible ecosystems. Glob. Chang. Biol. 2012, 18, 44–62. [Google Scholar] [CrossRef]
  71. Bulleri, F.; Benedetti-Cecchi, L.; Ceccherelli, G.; Tamburello, L. A few is enough: A low cover of a non-native seaweed reduces the resilience of Mediterranean macroalgal stands to disturbances of varying extent. Biol. Invasions 2017, 19, 2291–2305. [Google Scholar] [CrossRef]
  72. Guidetti, P.; Baiata, P.; Ballesteros, E.; Di Franco, A.; Hereu, B.; Macpherson, E.; Micheli, F.; Pais, A.; Panzalis, P.; Rosenberg, A.A.; et al. Large-scale assessment of Mediterranean marine protected areas effects on fish assemblages. PLoS ONE 2014, 9, e91841. [Google Scholar] [CrossRef]
  73. Guidetti, P.; Sala, E. Community-wide effects of marine reserves in the Mediterranean Sea. Mar. Ecol. Progr. Ser. 2007, 335, 43–56. [Google Scholar] [CrossRef]
  74. Giakoumi, S.; Pey, A.; Di Franco, A.; Francour, P.; Kizilkaya, Z.; Arda, Y.; Raybaud, V.; Guidetti, P. Exploring the relationships between marine protected areas and invasive fish in the world’s most invaded sea. Ecol. Appl. 2019, 29, e01809. [Google Scholar] [CrossRef]
  75. Spiridonov, V.A. Introduced species challenges and opportunities for marine conservation ecology and management practices: Notes inspired by a recent MSC certification. Aquat. Conserv. 2018, 28, 522–526. [Google Scholar] [CrossRef]
  76. Boudouresque, C.F.; Verlaque, M. An overview of species introduction and invasion processes in marine and coastal lagoon habitats. Cah. Biol. Mar. 2012, 53, 309–317. [Google Scholar]
  77. Geburzi, J.C.; McCarthy, M.L. How do they do it?—Understanding the success of marine invasive species. In YOUMARES 8—Oceans across Boundaries: Learning from Each Other; Jungblut, S., Liebich, V., Bode, M., Eds.; Springer: Cham, Switzerland, 2018; pp. 109–144. [Google Scholar]
  78. Pyšek, P.; Jarošík, V.; Hulme, P.E.; Pergl, J.; Hejda, M.; Schaffner, U.; Vilà, M. A global assessment of invasive plant impacts on resident species, communities and ecosystems: The interaction of impact measures, invading species’ traits and environment. Glob. Chang. Biol. 2012, 18, 1725–1737. [Google Scholar] [CrossRef]
  79. Kumschick, S.; Gaertner, M.; Vilà, M.; Essl, F.; Jeschke, J.M.; Pyšek, P.; Ricciardi, A.; Bacher, S.; Blackburn, T.M.; Dick, J.T.A.; et al. Ecological impacts of alien species: Quantification, scope, caveats, and recommendations. BioScience 2015, 65, 55–63. [Google Scholar] [CrossRef]
  80. Davis, K.T.; Callaway, R.M.; Fajardo, A.; Pauchard, A.; Nuñez, M.A.; Brooker, R.W.; Maxwell, B.D.; Dimarco, R.D.; Peltzer, D.A.; Mason, B.; et al. Severity of impacts of an introduced species corresponds with regional eco-evolutionary experience. Ecography 2019, 42, 12–22. [Google Scholar] [CrossRef]
  81. Fridley, J.D.; Stachowicz, J.J.; Naeem, S.; Sax, D.F.; Seabloom, E.W.; Smith, M.D.; Stohlgren, T.J.; Tilman, D.; Von Holle, B. The invasion paradox: Reconciling pattern and process in species invasions. Ecology 2007, 88, 3–17. [Google Scholar] [CrossRef]
  82. Vilà, M.; Espinar, J.L.; Hejda, M.; Hulme, P.E.; Jarošík, V.; Maron, J.L.; Pergl, J.; Schaffner, U.; Sun, Y.; Pyšek, P. Ecological impacts of invasive alien plants: A meta-analysis of their effects on species, communities and ecosystems. Ecol. Lett. 2011, 14, 702–708. [Google Scholar] [CrossRef]
  83. Castro-Díez, P.; Pauchard, A.; Traveset, A.; Vilà, M. Linking the impacts of plant invasion on community functional structure and ecosystem properties. J. Veg. Sci. 2016, 27, 1233–1242. [Google Scholar] [CrossRef]
  84. Morri, C.; Bellan-Santini, D.; Giaccone, G.; Bianchi, C.N. Principles of bionomy: Definition of assemblages and use of taxonomic descriptors (macrobenthos). Biol. Mar. Mediterr. 2004, 11 (Suppl. 1), 573–600. [Google Scholar]
  85. Thrush, S.F.; Gray, J.S.; Hewitt, J.E.; Ugland, K.I. Predicting the effects of habitat homogenization on marine biodiversity. Ecol. Appl. 2006, 16, 1636–1642. [Google Scholar] [CrossRef]
  86. Anderson, M.J.; Ellingsen, K.E.; McArdle, B.H. Multivariate dispersion as a measure of beta diversity. Ecol. Lett. 2006, 9, 683–693. [Google Scholar] [CrossRef]
  87. Piazzi, L.; Balata, D. The spread of Caulerpa racemosa var. cylindracea in the Mediterranean Sea: An example of how biological invasions can influence beta diversity. Mar. Environ. Res. 2008, 65, 50–61. [Google Scholar]
  88. Macdougall, A.S.; Turkington, R. Are invasive species the drivers or passengers of change in degraded ecosystems? Ecology 2005, 86, 42–55. [Google Scholar] [CrossRef]
  89. Cucherousset, J.; Fried, G.; Cote, J.; Renault, D.; Cote, J.; Renault, D. Biological invasions and ecosystem functioning: Assessment of the ecological impacts driven by invasive species. Rev. Ecologie-Terre Vie 2015, 70, 49–52. [Google Scholar]
  90. South, P.M.; Thomsen, M.S. The ecological role of invading Undaria pinnatifida: An experimental test of the driver–passenger models. Mar. Biol. 2016, 163, 175. [Google Scholar] [CrossRef]
  91. Bulleri, F.; Balata, D.; Bertocci, I.; Tamburello, L.; Benedetti-Cecchi, L. The seaweed Caulerpa racemosa on Mediterranean rocky reefs: From passenger to driver of ecological change. Ecology 2010, 91, 2205–2212. [Google Scholar] [CrossRef]
  92. Boudouresque, C.F.; Blanfuné, A.; Fernandez, C.; Lejeusne, C.; Pérez, T.; Ruitton, S.; Thibault, D.; Thibaut, T.; Verlaque, M. Marine biodiversity-warming vs. biological invasions and overfishing in the Mediterranean Sea: Take care, ‘one train can hide another’. MOJ Ecol. Environ. Sci. 2017, 2, 1–13. [Google Scholar] [CrossRef]
  93. Piazzi, L.; Balata, D.; Bulleri, F.; Gennaro, P.; Ceccherelli, G. The invasion of Caulerpa cylindracea in the Mediterranean: The known, the unknown and the knowable. Mar. Biol. 2016, 163, 161. [Google Scholar] [CrossRef]
  94. Vassallo, P.; Bianchi, C.N.; Paoli, C.; Holon, F.; Navone, A.; Bavestrello, G.; CattaneoVietti, R.; Morri, C. A predictive approach to benthic marine habitat mapping: Efficacy and management implications. Mar. Pollut. Bull. 2018, 131, 218–232. [Google Scholar] [CrossRef]
  95. Galil, B.S.; Marchini, A.; Occhipinti-Ambrogi, A.; Minchin, D.; Narščius, A.; Ojaveer, H.; Olenin, S. International arrivals: Widespread bioinvasions in European Seas. Ethol. Ecol. Evol. 2014, 26, 152–171. [Google Scholar] [CrossRef]
  96. Blackburn, T.M. Macroecology and invasion biology. Glob. Ecol. Biogeogr. 2019, 28, 28–32. [Google Scholar] [CrossRef]
Diversity 11 00146 g001 550
Figure 1. A schematic representation of how an invader may cause biotic homogenization in the recipient communities. Community A is characterized by its exclusive species a, and community B is characterized by its exclusive species b; the two communities are evidently highly dissimilar. If an invasive species enters both communities to flank or even replace the exclusive species, then the two communities become more similar, and hence homogenized.
Figure 1. A schematic representation of how an invader may cause biotic homogenization in the recipient communities. Community A is characterized by its exclusive species a, and community B is characterized by its exclusive species b; the two communities are evidently highly dissimilar. If an invasive species enters both communities to flank or even replace the exclusive species, then the two communities become more similar, and hence homogenized.
Diversity 11 00146 g001
Diversity 11 00146 g002 550
Figure 2. Caulerpa cylindracea Sonder: (a) Typical aspect with creeping and jutting stolons and clavate branchlets; (b) exhibiting high cover (22%) amid infralittoral algae in shallow water; (c) invading the Codium vermilara association (EUNIS A3.231); (d) overgrowing a partially bleached colony of the zooxanthellate coral Cladocora caespitosa (EUNIS A3.238).
Figure 2. Caulerpa cylindracea Sonder: (a) Typical aspect with creeping and jutting stolons and clavate branchlets; (b) exhibiting high cover (22%) amid infralittoral algae in shallow water; (c) invading the Codium vermilara association (EUNIS A3.231); (d) overgrowing a partially bleached colony of the zooxanthellate coral Cladocora caespitosa (EUNIS A3.238).
Diversity 11 00146 g002
Diversity 11 00146 g003 550
Figure 3. Geographic situation of the study area: the Portofino promontory in northwest Italy (see arrow in the inset). Capital letters denote the three zones of the marine protected area of Portofino subject to different levels of protection: the A zone is the “no entry, no take” area; the B zone is the general reserve; the C zone is the partial reserve. The three municipalities of the Portofino Promontory are also indicated.
Figure 3. Geographic situation of the study area: the Portofino promontory in northwest Italy (see arrow in the inset). Capital letters denote the three zones of the marine protected area of Portofino subject to different levels of protection: the A zone is the “no entry, no take” area; the B zone is the general reserve; the C zone is the partial reserve. The three municipalities of the Portofino Promontory are also indicated.
Diversity 11 00146 g003
Diversity 11 00146 g004 550
Figure 4. Occurrence of Caulerpa cylindracea in the marine protected area of Portofino (from the comprehensive database of 78 species × 229 samples): (a) Depth distribution of the species cover (circles identify the mean depth, error bars are standard errors) between 1 m and 45 m; the binomial curve (dashed line) represents the best fit of mean data (cover = 0.0196∙depth2 + 0.8313∙depth + 4.1168, R2 = 0.5003, n = 229, p < 0.01); (b) mean (± standard error) cover in the three protection zones (A = “no-entry no-take” area, B = general reserve, C = partial reserve); (c) change in yearly mean (± standard error) cover in the Portofino MPA between 2012 and 2017; (d) linear regression (dashed line) between C. cylindracea cover and species richness (number of species = −0.3653∙cover + 23.111, R2 = 0.3309, n = 229, p < 0.01).
Figure 4. Occurrence of Caulerpa cylindracea in the marine protected area of Portofino (from the comprehensive database of 78 species × 229 samples): (a) Depth distribution of the species cover (circles identify the mean depth, error bars are standard errors) between 1 m and 45 m; the binomial curve (dashed line) represents the best fit of mean data (cover = 0.0196∙depth2 + 0.8313∙depth + 4.1168, R2 = 0.5003, n = 229, p < 0.01); (b) mean (± standard error) cover in the three protection zones (A = “no-entry no-take” area, B = general reserve, C = partial reserve); (c) change in yearly mean (± standard error) cover in the Portofino MPA between 2012 and 2017; (d) linear regression (dashed line) between C. cylindracea cover and species richness (number of species = −0.3653∙cover + 23.111, R2 = 0.3309, n = 229, p < 0.01).
Diversity 11 00146 g004
Diversity 11 00146 g005 550
Figure 5. EUNIS habitats in Portofino MPA and incidence of Caulerpa cylindracea (from the comprehensive database of 78 species × 229 samples): (a) Depth and slope preferences of the 14 EUNIS habitats identified on the rocky reefs of Portofino. See Table 1 for habitat codes and extended names. Codes are centered on mean values, while ellipses depict the 95% confidence region (the two axes of the ellipses represent confidence limits for depth and slope, respectively); (b) mean % cover of C. cylindracea in the 14 EUNIS habitats (error bars represent 1 standard error). For the number of samples belonging to each EUNIS habitat see Table 1 (column n).
Figure 5. EUNIS habitats in Portofino MPA and incidence of Caulerpa cylindracea (from the comprehensive database of 78 species × 229 samples): (a) Depth and slope preferences of the 14 EUNIS habitats identified on the rocky reefs of Portofino. See Table 1 for habitat codes and extended names. Codes are centered on mean values, while ellipses depict the 95% confidence region (the two axes of the ellipses represent confidence limits for depth and slope, respectively); (b) mean % cover of C. cylindracea in the 14 EUNIS habitats (error bars represent 1 standard error). For the number of samples belonging to each EUNIS habitat see Table 1 (column n).
Diversity 11 00146 g005
Diversity 11 00146 g006 550
Figure 6. Results of principal component analysis on the “observed” dataset (67 species × 40 samples) (a,c) and on the “simulated” dataset (66 species × 40 samples) (b,d). Panels (a,b) illustrate the percentage of the total variance explained by each axis (component), with 95% bootstrapped confidence intervals (error bars); the red curves represent the eigenvalues expected under a broken-stick random model. Sample points in (c,d) are indicated by their depth (in m), while the convex hulls visualize the multivariate dispersion of the points, with axes being always drawn at the same scale.
Figure 6. Results of principal component analysis on the “observed” dataset (67 species × 40 samples) (a,c) and on the “simulated” dataset (66 species × 40 samples) (b,d). Panels (a,b) illustrate the percentage of the total variance explained by each axis (component), with 95% bootstrapped confidence intervals (error bars); the red curves represent the eigenvalues expected under a broken-stick random model. Sample points in (c,d) are indicated by their depth (in m), while the convex hulls visualize the multivariate dispersion of the points, with axes being always drawn at the same scale.
Diversity 11 00146 g006
Diversity 11 00146 g007 550
Figure 7. Relationship between PCA first axis scores and sample depth for both the “observed” (a) and the “simulated” datasets (b). In both graphs, circles represent mean scores and error bars are the 95% confidence limits. In the “observed” dataset no discontinuity is apparent, while in the “simulated” dataset three groups can be distinguished (dotted line rectangles). All differences in first axis scores for the three groups are highly significant (Tukey’s pairwise comparisons).
Figure 7. Relationship between PCA first axis scores and sample depth for both the “observed” (a) and the “simulated” datasets (b). In both graphs, circles represent mean scores and error bars are the 95% confidence limits. In the “observed” dataset no discontinuity is apparent, while in the “simulated” dataset three groups can be distinguished (dotted line rectangles). All differences in first axis scores for the three groups are highly significant (Tukey’s pairwise comparisons).
Diversity 11 00146 g007
Table
Table 1. EUNIS habitats recognized in the rocky reefs of Portofino MPA between 1 m and 45 m depth. Here, n is the number of samples belonging to a specific EUNIS habitat. Where necessary (e.g., nomenclatural updates), extended names have been emended with respect to the original ones.
Table 1. EUNIS habitats recognized in the rocky reefs of Portofino MPA between 1 m and 45 m depth. Here, n is the number of samples belonging to a specific EUNIS habitat. Where necessary (e.g., nomenclatural updates), extended names have been emended with respect to the original ones.
CodeExtended Namen
habitats characterized by macroalgae
A3.131Facies with encrusting algae (Lithophyllum incrustans) and sea urchins23
A3.135Association with Ellisolandia elongata17
A3.231Association with Codium vermilara5
A3.23FAssociation with Dictyopteris polypodioides43
A3.23JAssociation with Flabellia petiolata and Peyssonnelia squamaria17
A3.331Association with Halopteris scoparia109
A4.261Association with Cystoseira zosteroides32
habitats characterized by seagrass
A5.535Posidonia oceanica beds31
habitats characterized by zooxanthellate corals
A3.238Facies with Cladocora caespitosa16
A4.26AFacies with Eunicella singularis43
habitats characterized by corals
A4.269Facies with Eunicella cavolini82
A4.26BFacies with Paramuricea clavata29
A4.26CFacies with Parazoanthus axinellae26
A4.322Facies with Leptogorgia sarmentosa9
Table
Table 2. Results of one-way analysis of variance on Caulerpa cylindracea cover data in the 14 EUNIS habitats recognized in the marine protected area of Portofino.
Table 2. Results of one-way analysis of variance on Caulerpa cylindracea cover data in the 14 EUNIS habitats recognized in the marine protected area of Portofino.
Source of VariationSSdfs2F13,468p
Among habitats2077.9113159.842.450.003
Within habitats30478.2646865.12
Total32556.17481
Table
Table 3. Results of one-way analysis of variance on the first axis scores of depth-points in PCA plots for both the “observed” and the “simulated” datasets.
Table 3. Results of one-way analysis of variance on the first axis scores of depth-points in PCA plots for both the “observed” and the “simulated” datasets.
Source of VariationSSdfs2F7,32p
“Observed” Dataset
Among depths3.7370.5383.49.96 × 10−19
Within depths0.20320.01
Total3.9339
“Simulated” Dataset
Among depths6.4270.92111.11.29 × 10−20
Within depths0.26320.01
Total6.6839
Table
Table 4. Results of one-way analysis of variance on PCA first axis scores among the three depth groups recognized in the case of the “simulated” dataset.
Table 4. Results of one-way analysis of variance on PCA first axis scores among the three depth groups recognized in the case of the “simulated” dataset.
Source of VariationSSdfs2F2,37p
Among depth groups23.2559211.6279225.61.87 × 10−21
Within depth groups1.9068370.0515351
Total25.162739
Table
Table 5. Values of the average dissimilarity (1—Bray-Curtis coefficient), standard deviation, and coefficient of variation among samples in the “observed” and in the “simulated” datasets.
Table 5. Values of the average dissimilarity (1—Bray-Curtis coefficient), standard deviation, and coefficient of variation among samples in the “observed” and in the “simulated” datasets.
Indices“Observed” Dataset“Simulated” Dataset
Average dissimilarity 0.510.61
Standard deviation 0.160.19
Coefficient of variation0.320.49

Share and Cite

MDPI and ACS Style

Morri, C.; Montefalcone, M.; Gatti, G.; Vassallo, P.; Paoli, C.; Bianchi, C.N. An Alien Invader is the Cause of Homogenization in the Recipient Ecosystem: A Simulation-Like Approach. Diversity 2019, 11, 146. https://0-doi-org.brum.beds.ac.uk/10.3390/d11090146

AMA Style

Morri C, Montefalcone M, Gatti G, Vassallo P, Paoli C, Bianchi CN. An Alien Invader is the Cause of Homogenization in the Recipient Ecosystem: A Simulation-Like Approach. Diversity. 2019; 11(9):146. https://0-doi-org.brum.beds.ac.uk/10.3390/d11090146

Chicago/Turabian Style

Morri, Carla, Monica Montefalcone, Giulia Gatti, Paolo Vassallo, Chiara Paoli, and Carlo Nike Bianchi. 2019. "An Alien Invader is the Cause of Homogenization in the Recipient Ecosystem: A Simulation-Like Approach" Diversity 11, no. 9: 146. https://0-doi-org.brum.beds.ac.uk/10.3390/d11090146

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop