Next Article in Journal
Steam Explosion Pretreatment of Sludge for Pharmaceutical Removal and Heavy Metal Release to Improve Biodegradability and Biogas Production
Next Article in Special Issue
PTR-ToF-MS for the Online Monitoring of Alcoholic Fermentation in Wine: Assessment of VOCs Variability Associated with Different Combinations of Saccharomyces/Non-Saccharomyces as a Case-Study
Previous Article in Journal
Suitability of the Lebanese “Ace Spur” Apple Variety for Cider Production Using Hanseniaspora sp. Yeast
Previous Article in Special Issue
Yeast Nanometric Scale Oscillations Highlights Fibronectin Induced Changes in C. albicans
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Fermentation
Volume 6
Issue 1
10.3390/fermentation6010033
fermentation-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:
Review

The Xylose Metabolizing Yeast Spathaspora passalidarum is a Promising Genetic Treasure for Improving Bioethanol Production

by
Khaled A. Selim
1,*,
Saadia M. Easa
2 and
Ahmed I. El-Diwany
1
1
Pharmaceutical and Drug Industries Research Division, National Research Centre, 33-El-Bohouth St. (former El Tahrir St.), Dokki, P.O. Box, Giza 12622, Egypt
2
Microbiology Department, Faculty of Science, Ain Shams University, Cairo 11566, Egypt
*
Author to whom correspondence should be addressed.
Fermentation 2020, 6(1), 33; https://0-doi-org.brum.beds.ac.uk/10.3390/fermentation6010033
Submission received: 15 February 2020 / Revised: 15 March 2020 / Accepted: 16 March 2020 / Published: 18 March 2020
(This article belongs to the Special Issue Yeast Biotechnology 3.0)
Browse Figures
Versions Notes

Abstract

:
Currently, the fermentation technology for recycling agriculture waste for generation of alternative renewable biofuels is getting more and more attention because of the environmental merits of biofuels for decreasing the rapid rise of greenhouse gas effects compared to petrochemical, keeping in mind the increase of petrol cost and the exhaustion of limited petroleum resources. One of widely used biofuels is bioethanol, and the use of yeasts for commercial fermentation of cellulosic and hemicellulosic agricultural biomasses is one of the growing biotechnological trends for bioethanol production. Effective fermentation and assimilation of xylose, the major pentose sugar element of plant cell walls and the second most abundant carbohydrate, is a bottleneck step towards a robust biofuel production from agricultural waste materials. Hence, several attempts were implemented to engineer the conventional Saccharomyces cerevisiae yeast to transport and ferment xylose because naturally it does not use xylose, using genetic materials of Pichia stipitis, the pioneer native xylose fermenting yeast. Recently, the nonconventional yeast Spathaspora passalidarum appeared as a founder member of a new small group of yeasts that, like Pichia stipitis, can utilize and ferment xylose. Therefore, the understanding of the molecular mechanisms regulating the xylose assimilation in such pentose fermenting yeasts will enable us to eliminate the obstacles in the biofuels pipeline, and to develop industrial strains by means of genetic engineering to increase the availability of renewable biofuel products from agricultural biomass. In this review, we will highlight the recent advances in the field of native xylose metabolizing yeasts, with special emphasis on S. passalidarum for improving bioethanol production.

1. Fermentation Technology and Challenges

The modern biotechnological applications for generation of alternative and renewable sources of biofuels are receiving more attention due to global worries over the climate change, rapid global warming, and the rising of fossil fuel costs. One of such growing biotechnological trends is the fermentation technology to convert the sugar-rich agriculture waste into bioethanol by conventional or non-conventional yeasts [1,2,3,4]. In general, yeasts have advantages over bacteria for commercial fermentation due to the thickness of their cell walls, less stringent nutritional requirements, large sizes, utmost resistance to contamination, and better growth at acidic pH of bioreactor fermenters.
In nature, the second most abundant hemicellulosic sugar in fast-growing hardwoods and agricultural biomass is xylose. Xylose sugar forms up to 15–25% of all angiosperm biomass, and it could supply an alternative fuel source for its ability to be commercially fermented into ethanol. Several approaches have been employed to engineer xylose assimilation metabolism into conventional fermenting yeasts, such as Saccharomyces cerevisiae [4,5,6]. Therefore, efficient hemicellulosic sugar fermentation is crucial for the economic conversion of lignocellulose biomass to renewable biofuels [4,6,7,8]. The discovery of xylose-fermenting yeasts in new niches and genetic engineering of yeasts to be capable of rapid fermentation of xylose and other sugars to recoverable concentrations of bioethanol could provide alternative biofuel sources for the future (Figure 1) [4,9].
As a rule of thumb for metabolizing the xylose in most of xylose-fermenting yeasts [4], firstly the xylose is reduced by xylose reductase (XR) to xylitol. In the second step, the xylitol is oxidized by xylitol dehydrogenase (XDH) to xylulose. Afterward, the xylulose passes into the pentose phosphate pathway being metabolized into glyceraldehyde-3-P which is further reduced to pyruvate. Finally, the pyruvate is decarboxylated to acetaldehyde which is further reduced to ethanol by alcohol dehydrogenase (Figure 1). Notably, most xylose reductase enzymes have dual cofactor specificity, using both NADH and NADPH, but typically favor NADPH. However, xylitol dehydrogenase enzymes use NAD+ specifically as a cofactor, which could cause imbalance between the cofactor’s source for the XR-XDH pathway and xylitol accumulation under uncontrolled oxygen conditions (Figure 2) [10].
One of pioneer xylose fermenting yeasts is Pichia stipites. P. stipitis is heterothallic ascomycetous yeast, predominantly haploid and related to pentose fermenting yeasts, such as Candida shehatae [1,4,11,12,13,14,15]. P. stipitis was recently renamed to be Scheffersomyces stipitis [15] and it is natively one of the highest xylose-utilizing and fermenting yeasts. In type culture collections, the P. stipitis strains are among the best xylose-metabolizing microbes [16]. Under controlled low O2 conditions, P. stipitis is able to consume xylose and produce up to 57 g/L of bioethanol at 30°C [4,13,14,17]. Pichia uses an alternative nuclear genetic code (ANGC) in which CUG encodes for Ser rather than Leu [17], which makes the genetic manipulation of Pichia with the commercial drug resistance markers unusually problematic because essentially all of these markers are derived from bacteria that use the universal codon system. Moreover, one of classical challenges in fermentation technology is that some of key enzymes of bioethanol production pathway are expressed relatively in low levels [1,4,13,14]. Therefore, the metabolic engineering of the bioethanol pathway in yeasts, which can ferment the sugars of the agriculture biomass with considerable and recoverable bioethanol concentrations, could enhance the productivity and sustainability of renewable biofuel sources [1,13,14]. To improve bioethanol production and xylose metabolism, a stable and manipulatable genetic system that enables overexpression or deletion of one or more of key enzymes and sugar transporters in xylose-fermenting yeast P. stipitis, was developed [1,3,18]. This approach comprises modelling, metabolic and flux analysis, quantitative metabolomics and transcriptomics followed by the targeted overexpression or deletion of genes of the rate-limiting steps [1,3,4,13,14]. Since there is reasonable information about the metabolic capacity of P. stipitis to ferment xylose on various omics levels, this makes it an attractive model system for metabolic engineering.
Recently, a new xylose-fermenting yeast Spathaspora passalidarum was discovered, which naturally co-ferments xylose, glucose, and cellobiose and demonstrates potentials in the effective conversion of mixed sugars from hemicellulosic hydrolysates into ethanol [9]. S. passalidarum was initially isolated from extremely O2-limited and hemicellulosic sugar rich environments from the gut of a wood-boring beetle (as will be discussed below). Although the anaerobic fermentation of glucose is broadly known, the xylose fermentation typically needs a controlled oxygen condition. Uncontrolled oxygen conditions in another xylose-fermenting yeast, such as P. stipitis, leads to accumulation of xylitol due to insufficient amounts of NAD+, and as consequence the xylose metabolism will be blocked (Figure 2) [9,13,14]. To solve this problem, precise controlled O2 (very low O2 concentrations) during the xylose fermentation is required in P. stipitis to generate NAD+ from NADH.
The bioethanol production from the bioconversion of lignocellulose biomass must be achieved at high rates and yields for economically recoverable concentrations. The achieving of such targets for efficient bioethanol production are more difficult with cellulose and hemicellulose. The major barrier for cellulose utilization is enzymatic saccharification, while for hemicellulose it is the utilization of mixed sugars (hexose sugars: glucose, galactose, mannose, and rhamnose; and pentose sugars: xylose and arabinose) in the presence of ferulic and acetic acids along with other byproducts of the thermochemical pretreatment of the hydrolysates [13,14]. However, S. passalidarum and P. stipitis yeasts possess a set of unique physiological merits that make them very useful biodegradable organisms for bioconversion of lignocellulosic biomass [4,9,13,14]. Pichia can utilize and ferment effectively cellobiose, glucose, galactose, and mannose along with xylan high oligomeric sugars xylan and mannan, in addition to its extensively studied ability to metabolize and ferment the xylose [4,13,14]. The primary sugar released in enzymatic hydrolysis is cellobiose and, remarkably, P. stipitis and S. passalidarum have the capability to utilize the cellobiose, which make such yeasts potent organisms for simultaneous saccharification and fermentation (SSF) or hydrolysate, because most commercially available cellulase products are often deficient in β-glucosidase enzyme so the accumulation of cellobiose inhibits cellulose activities. Since P. stipitis and S. passalidarum can directly metabolize the cellobiose, they have the potential to improve SSF processes [4,9,10,13,14,19,20].
Collectively, the native ability of P. stipitis and S. passalidarum to metabolize the oligomeric sugars is of high importance as the mild acidic pretreatments of agriculture waste biomass can prevent the formation of the sugar degradation byproducts, which could inhibit significantly the fermentation process, but can release about 15–55% of soluble oligomeric sugars. Therefore, with low cost and high yield, the hemicellulosic sugars can be more readily recovered and underutilized from cellulose biomass than glucose. Although such easy recoverable sugars can be utilized for formation of a number of useful products such as xylitol, butanol, lactic acid, and other chemicals, bioethanol is still the major product with the largest potential market. Hence, bioethanol production from the lignocellulosic biomasses is receiving a lot of attention as a consequence of agriculture policies and energy demands to improve the production of alternative renewable biofuels and to reduce CO2 emissions [2,4,13,14].

2. Spathaspora passalidarum a Promising Genetic Source

The Spathaspora clade contains many bioethanol producer yeasts, including Spathaspora arborariae, Spathaspora brasiliensis, Spathaspora gorwiae, Spathaspora hagerdaliae, Spathaspora passalidarum, Spathaspora roraimanensis, Spathaspora suhii, Spathaspora xylofermentans. They are usually endosymbioticly associated with wood-boring-beetles that occupy rotting wood. Spathaspora passalidarum (Figure 3), the first identified species of genus Spathaspora, was isolated from the gut of passalid beetle Odontotaenius disjunctus [9,21,22,23,24]. Notably, S. arborariae, S. gorwiae, S. hagerdaliae, and S. passalidarum ferment xylose to produce bioethanol, whereas the rest within the Spathaspora clade are thought to be xylitol producers [9].
S. passalidarum was firstly described in 2006 by Nguyen et al. [21]. The authors speculated that Spathaspora mainly exists in the beetle’s biosphere rather than the beetle’s gut microbiota, and it may be only by coincidence that O. disjunctus beetles ingested decaying wood contaminated by yeasts. Later in 2012 and 2017, another 12 strains were described in two independent studies from wood-boring beetles and wood samples of Amazonian forest in Brazil [23,25]. Among these strains, only one isolate was obtained from the gut of Popilus marginatus beetle, while the rest of the strains were obtained from the woody samples inhabited by the beetles [23,25]. In 2014, two more strains were isolated from rotted wood in China [26]. Additionally, Rodrussamee and colleges in 2018 reported a new thermotolerant strain, named S. passalidarum CMUWF1–2, which was isolated from Thailand soil [27]. The frequency of finding S. passalidarum mainly among the woody samples supports the notion that those yeasts are probably associated with decaying wood niches rather than with the gut microbiota of wood-boring beetles. However, the fact of the low frequency of finding S. passalidarum among other yeast species keeps an open possibility that they inhabit mainly the wood-related beetles [9].

3. Fermentation Capability of Spathaspora passalidarum

It is believed that the beetle’s gut is truly anaerobic or microaerobic, therefore it was speculated that S. passalidarum possess a unique adaptation capability to survive under oxygen-depleted conditions on mixtures of hemicellulosic sugars in the midgut of wood-boring beetles [10,19]. Currently, S. passalidarum is among the best xylose-utilizing and fermenting yeasts. Under anaerobic or microaerobic conditions, S. passalidarum possess rapid utilization and consumption rates for xylose and produces up to 0.48 g/g bioethanol (near to the maximum theoretical bioethanol production of 0.51 g/g), in contrast to P. stipitis which can hardly metabolize xylose anaerobically, accumulating xylitol and a very low yield of bioethanol [10,19,20,28,29]. Under anaerobic conditions, Hou in 2012 showed that S. passalidarum has a high growth rate with rapid consumption rate of sugars and can ferment xylose into a high yield of bioethanol with higher production efficiency than P. stipitis [10]. Similarly, Veras and colleges in 2017 showed that under anaerobic conditions, S. passalidarum accumulates 1.5 times more bioethanol than S. stipitis, while both stains accumulate around 0.44 g/g under O2 limiting conditions [30]. The previous work by Hou (2012) defined strictly that S. passalidarum can metabolize and ferment xylose in tightly capped flasks [10]. In contrast to the previous report by Hou (2012) [10], under stringent O2 limiting conditions, the S. passalidarum was not able virtually to utilize the sugars, indicating that native wild-type S. passalidarum does not ferment sugars under truly anaerobic conditions [19,20]. Therefore, it is still under debate whether S. passalidarum can ferment xylose truly anaerobically or whether it requires a controlled microoxygenic condition similar to P. stipitis.
One of the major challenges in fermentation technology is the inability of the majority of known microbes to co-ferment xylose and glucose, since glucose usually inhibits the metabolization of the other sugars in lignocellulose hydrolysate, as in the case of P. stipitis [13,14]. Astonishingly, in a recent study to address the metabolic profiling and fermentation capacity of S. passalidarum, S. passalidarum was found to co-ferment xylose, cellobiose, and glucose simultaneously with high bioethanol yields ranging from 0.31 to 0.42 g/g [19,20]. Moreover, an adapted S. passalidarum strain was found to accumulate up to 39 g/L bioethanol with a 0.37 g/g yield from a lignocellulosic hydrolysate. The specific production rate of bioethanol on xylose as a carbon source was superior with three times more than the corresponding rate on glucose, where the flux of glycolytic intermediates was meaningfully lower on glucose than on xylose and its xylose reductase enzyme had a higher affinity for NADH than NADPH [19,20]. Thus, the allosteric activation of glycolytic routes associated with the xylose utilization and the NADH-dependent xylose reductase are most likely the causes for such unique ability of S. passalidarum to co-ferment mixed sugars [19,23]. Later, such results were confirmed in a metabolic flux study, where S. passalidarum showed about 1.5–2 times high flux rate in the NADH-dependent xylose reductase reaction [31], which caused continuous recycling and reduction of xylitol levels. Such directed high flux rates to glycolytic routes and pentose phosphate pathway was the cause for high levels of bioethanol production in S. passalidarum [31]. In large scale fed-batch fermentation study, S. passalidarum was able metabolize around 90% of xylose sugar and all of glucose of sugarcane bagasse hydrolysate, even so glucose had approximately three-fold higher xylose content; and produced a high ethanol yield of 0.46 g/g with volumetric productivity of 0.81 g/L/h in contrast to P. stipitis which produced 0.32 g/g ethanol with productivity of 0.36 g/L/h [32]. In follow up study, S. passalidarum UFMG-CM-Y473 strain was able to simultaneously utilize and co-ferment about 78% of the released sugars (xylose, glucose, and cellobiose) of pretreated sugarcane bagasse hydrolysate (delignified and enzymatically hydrolyzed) to yield up to 0.32 g/g bioethanol with productivity of 0.34 g/L/h without any nutritional supplementation [33]. Moreover, the new thermotolerant strain, S. passalidarum CMUWF1–2, was able to co-ferment various sugars (mannose, galactose, xylose, and arabinose) of lignocellulosic biomass, even in presence of glucose, to accumulate considerable amounts of bioethanol and low amounts of xylitol at higher temperatures. For example, it was able to accumulate 0.43, 0.40, and 0.20 g/g ethanol per xylose at 30, 37, and 40 °C, respectively [27]. Constant with absence of the glucose repression effect on the utilization of other sugars, S. passalidarum CMUWF1–2 exhibited a resistance to 2-deoxy glucose, the nonmetabolizable glucose analog, and tolerance to elevated levels of glucose (35.0% of w/v) and ethanol (8.0% of v/v) [27]. In contrast, the first discovered S. passalidarum NRRL Y-27907 strain was sensitive to 2-deoxy glucose, as 2-deoxy glucose suppressed the xylose consumption under anaerobic conditions. While under aerobic conditions, the 2-deoxy glucose inhibited, only partially, S. passalidarum NRRL Y-27907 [10]. Therefore, the author speculated that xylose uptake in S. passalidarum NRRL Y-27907 may take place by different xylose transport systems under aerobic and anaerobic conditions. Under aerobic conditions, xylose is taken up by means of ATP-dependent/high affinity xylose-proton symporter and low affinity transporter via facilitated diffusion driven only by the sugar gradient. While, under anaerobic condition, the yeasts are most likely to use only the low affinity xylose pump, as the active transport via xylose-proton symporter will deplete the ATP levels. The inhibitory effect of 2-deoxy glucose on S. passalidarum NRRL Y-27907 can be therefore explained by (1) blocking of the low-affinity-facilitated diffusion transporters which are occupied with transporting 2-deoxy glucose, and (2) the inhibition xylose active transport due to the depletion of the intracellular ATP levels to actively phosphorate the 2-deoxy glucose into the non-metabolizable phospho-2-deoxy glucose [10].

4. Genetic and Physiological Features of Spathaspora passalidarum Emphasis Special Roles for Xylose Reductase and Xylitol Dehydrogenase

These unusual unique traits of S. passalidarum are very attractive for studying on a molecular level. The complete genome sequence of xylose-fermenting yeast S. passalidarum was therefore necessary and it was accomplished and published for first time in 2011 [34]. The comparative genomic, transcriptomic, and metabolomic analysis between two of the native xylose-fermenting yeasts, the relatively newly discovered S. passalidarum, and the deeply studied P. stipitis, allowed a better understanding of the regulatory mechanisms of lignocellulose utilization, and identified the target key genes involved in xylose metabolism [9,10,19,31,34]. The comparative genomic and phylogenetic analysis clearly revealed that S. passalidarum is one of the CUG yeast clades, similar to P. stipites [34]. In addition, the transcriptome analysis indicated upregulation of the genes implicated in transporting carbohydrate and xylose- and carbohydrate-metabolisms under xylose growth. Several of genes, which are involved in regulation of redox balance and recycling of NAD(P)H/+, were upregulated to probably keep the redox balance during xylose utilization. Additionally, the genes encoding for cellulases and β-glucosidases were also upregulated, which suggests a positive feedback of xylose on the upstream genes to activate its own liberation from the higher oligomeric sugars of hemicelluloses by means of the catalytic activities of cellulases and β-glucosidases [34].
The previously mentioned capabilities of S. passalidarum to co-ferment different sugars and accumulate high levels of bioethanol with very low concentrations of xylitol, can be explained by the presence of a set of physiological characters encoded by unique set of genes [10,19,34]. Thus, the high capacity of xylose fermentation and low levels of xylitol accumulation by S. passalidarum was speculated to be due to the cofactor’s equilibrium between the intracellular demand and supply of the cofactors via NADH-favored xylose reductase enzyme and NAD+-specific xylitol dehydrogenase enzyme, the key enzymes of the xylose utilization pathway [10,28]. Normally, the xylose metabolization occurs through the reduction of xylose to xylitol with xylose reductase, which requires NADPH or NADH as a cofactor with preference for NADPH. Only few NADH-favored xylose reductase enzymes have been described so far [10,35,36,37]. Then the xylitol is metabolized further by xylitol dehydrogenase which is strictly NAD+ dependent (Figure 2). The unbalance between NAD+ supplement and requirement can block the xylose metabolization and leads to accumulation of xylitol. Later, S. passalidarum was found to harbor two genes encoding for xylose reductase (SpXYL1.1 and SpXYL1.2) [28]. The SpXYL1.1 gene product is more equivalent to XYL1 found in other yeasts. The expression levels of SpXYL1.2 were found to be higher than SpXYL1.1 and bioethanol production in S. passalidarum was attributed to higher xylose reductase activity with NADH than with NADPH [28]. The SpXYL1.2 was found to use both NADH and NADPH with preference for NADH, while SpXYL1.1 was stringently NADPH-dependent. Furthermore, the transformation of S. cerevisiae with SpXYL1.2 of S. passalidarum enabled the overexpressing S. cerevisiae::SpXYL1.2 strain to grow anaerobically on xylose and to ferment it to higher ethanol yield than the isogenic S. cerevisiae TMB 3422 strain, which overexpresses P. stipitis XYL1. While, the S. cerevisiae::SpXYL1.1 overexpressing strain was not able to grow on xylose [28]. Similarly, in the yeast-like fungus Aureobasidium pullulans, the overexpression of SpXYL1.2 xylose reductase along with S. passalidarum xylitol dehydrogenase encoded by SpXYL2.2 enhanced the xylose metabolization by 17.76% and improved the fermentation capability and the pullulan production by 97.72% of the overexpressing mutants compared with the parental strain [38].
Finally, a metabolic analysis of S. passalidarum speculated that NADH-preferred xylose reductase and NAD+-dependent xylitol dehydrogenase would tend to drive both of xylose assimilation via the oxidoreductase pathway and the acetaldehyde reduction to ethanol by the alcohol dehydrogenase enzyme [19]. Recently, a metabolic flux analysis of different xylose-fermenting yeasts confirmed a better cofactors balance within S. passalidarum cells during xylose catabolism to bioethanol production than within P. stipitis cells [31], which further supports the growth characteristics of S. passalidarum.
Collectively, those unique and unusual traits of S. passalidarum encourage using it as a source for genes to improve xylose utilization and bioethanol production from lignocellulosic biomass in the current xylose fermenting yeasts, such as P. stipites, or to introduce xylose metabolism genes to develop industrial strains of Saccharomyces cerevisiae capable of co-fermentation of pentose and hexose sugars. Or alternatively, to domesticate it given the excellent results already accomplished by wild-type representatives of that species for co-fermentation of mixed sugars. To facilitate that purpose, Li et al. (2017) developed a stable genetic expression system compatible with the CUG yeasts clade for genomic integration of Gene Of Interest (GOI) into several yeasts [39]. The developed multi-host integrative system was functional in several of the xylose-fermenting yeasts including S. passalidarum, P. stipitis, and Candida jeffriesii and Candida amazonensis, as well as in a hexose metabolizing yeast Saccharomyces cerevisiae, for heterologous expression of green fluorescent protein (GFP) or lactate dehydrogenase. For lactate dehydrogenase overexpressing strains, all the engineered yeast strains were able to metabolize either glucose (in case of S. cerevisiae) or xylose (in case of xylose-fermenting yeasts) to produce lactate [39].

5. New Adaptive Strains of Spathaspora passalidarum for Potential Industrial Applications

One of the unique features of those xylose metabolizing yeasts, is the ability to use not only the monomeric hexose and pentose sugars but also the high oligomeric disaccharide sugar in mixed co-fermentation [9,19], which can be an advantage for large scale industrial applications. The mild acid pretreatment of agriculture waste biomasses is relatively cheap and prevents the accumulation of harmful compounds, which inhibits the fermentation processes, but releases the sugars in higher oligomeric stats. Therefore, the ability of such native xylose fermenting strains, P. stipitis, and S. passalidarum, to use the high oligomeric sugar can be a great advantage for various biotechnological applications.
One of the major problems that hinders the use of S. passalidarum for industrial bioethanol production, even with its remarkable ability for bioethanol production, is the high sensitivity of S. passalidarum to the chemical inhibitors, such as ferulic and acetic acids, which are released in preparation of hemicellulosic hydrolysates [9]. Several elaborative studies have focused mainly on improving the tolerability of S. passalidarum to the hydrolysates inhibitors with keeping in mind the bioethanol productivity of the strains [19,40,41,42,43]. Hou and Yao in (2012) reported a strong strain [40], which is able to grow on furfurals and many other inhibitors of wheat straw hydrolysate (75%) and able to accumulate up to 0.40 g/g ethanol. Such strain was generated through hybridization of a S. cerevisiae and a UV-mutagenized S. passalidarum [40]. In 2012 also, another resistant strain was developed under O2 limiting conditions through several passage of the wild-type S. passalidarum NRRL Y-27907 on wood hydrolysate, followed by adaptive growth of the strain on corn stover AFEX (ammonia fiber expansion) hydrolysate [19]. Even with such efforts, the strain was not able to accumulate significant amounts of ethanol during the fermentation of the AFEX hydrolysate, despite its ability to grow in AFEX hydrolysate media. When the acetic acid was depleted from AFEX hydrolysate media, ethanol production was surprisingly observed with a yield of 0.45 g/g and most of the xylose content was consumed [19]. Later in 2017, Morales and colleagues developed an evolutionary adapted strain [41] with high tolerance toward the classical inhibitor of the fermentation processes, acetic acid, and that produces ethanol with a yield of 0.48 g/g. In a non-detoxified hydrolysate of Eucalyptus globulus, the authors reported also the ability of this strain to co-utilize mixed sugars of xylose, glucose, and cellobiose under microaerobic conditions [41]. This strain was generated by UV irradiation followed by successive growing of the strain under elevated acetic acid concentrations [41]. In similar way, another group also obtained a mutated S. passalidarum strain but via plasma mutagenesis and continuous cultivation in alkaline liquor pretreated corncob [42]. Under a simultaneous saccharification and co-fermentation, the obtained strain produced bioethanol with efficiency of 75% [42]. Finally, Su et al. in 2018 developed an adaptive S. passalidarum strain (named YK208-E11) [43], which is designated for resistance to AFEX hydrolysate inhibitors, from the wild-type NRRL Y-27907 through high-throughput screen via combining several approaches of batch adaptation, cell recycling, and cell mating [43]. The S. passalidarum YK208-E11 strain produced less biomass (about 40% compared to the wild-type), co-metabolized mixed sugars of xylose, glucose, and cellobiose, and exhibited a three-fold improvement in the ethanol production rate with a yield of 0.45 g/g. The whole genome sequence of S. passalidarum YK208-E11 strain revealed a deletion of about 11 kb in this strain. The ORF, which was deleted in S. passalidarum YK208-E11, is encoding for proteins predicted to be involved in cell division and respiration. Therefore, the authors speculated that this deletion may account for those unique adaptive/physiological features of this AFEX-acclimatized S. passalidarum YK208-E11 strain [43].

6. Future Perspective for Engineering New Strains for Better Bioethanol Production

The metabolic engineering approaches involve targeted overexpression and/or deletion of fermentative key genes that facilities quick and efficient conversion of sugars into bioethanol with high recoverable yields [1,3]. As we discussed above, S. passalidarum xylose reductase and xylitol dehydrogenase are among the promising candidates for targeted overexpression. The cumulative knowledge of the transcriptomics, metabolomics, and comparative genomics studies for P. stipitis and S. passalidarum, identified other key enzymes controlling the xylose assimilation, rather than XDH and XR (Figure 2). One of such promising key genes is adh that encodes for fermentative isozyme alcohol dehydrogenase (ADH), which is vital for production and/or assimilation of ethanol (Figure 2). Generally, ADH catalyzes the final (rate limiting) step in the yeast glycolytic pathway, the reduction of acetaldehyde to ethanol and NAD+, and therefore it accepts NADH as a co-factor [44,45]. However, ADH enzymes are also able to perform the reverse reaction from ethanol to acetaldehyde, enabling the yeasts to oxidize and grow on ethanol as a carbon source. In P. stipitis, the ADH fermentative activities is crucial not only for ethanol production and/or consumption but also for maintenance redox balance within the yeast cell, so it is considered to be a part of the cofactor balance system in P. stipitis [44].
The sequencing projects of S. passalidarum NRRL Y-27907 and P. stipitis CBS6054 (JGI-MycoCosm) revealed the presence of several/different alcohol dehydrogenase (ADH) encoding genes. For example, in P. stipitis, sevem genes were predicted to encode for alcohol dehydrogenase (PsADH1 to PsADH7) enzymes [13,17]. Among them PsADH1 and PsADH2 were found to be essential for xylose assimilation and ethanol production [44,46]. Each of the ADH proteins in S. passalidarum and P. stipitis are supposed to have different kinetic properties. Some of the enzymes could be mainly responsible for producing ethanol while others might be responsible for oxidizing it. In S. passalidarum, the gene encoding for SpADH1 was found to be expressed at a very high level during xylose metabolization [34]. In addition, metabolic analysis and metabolic flux analysis revealed that alcohol dehydrogenase is one of key enzymes driving ethanol production in S. passalidarum [19,31]. Notably, owing to relative SpADH1 abundance, the SpADH1 promotor was used to develop a multi-host integrative system for xylose-fermenting yeast [39].
While in P. stipitis, the function of some ADH enzymes are better understood, in particular PsADH1 and PsADH2 [13,17,44,46,47,48,49]. Transcriptomic studies of the P. stipites adh system indicated that the PsADH activities are correlated with and induced under O2 limited/microaerobic conditions [46,48]. Under xylose fermentation, the PsADH1 was found to be the primary key enzyme among the PsADH system. The deletion of PsADH1 caused a reduction in P. stipites growth rate and a notable increase in xylitol accumulation accompanied with a dramatic decrease in ethanol production, due to intracellular cofactors imbalance [44]. The PsADH2 is not expressed under microaerobic or aerobic conditions unless PsADH1 is deleted [44,46], which further confirms that the significant role of PsADH1 is in sugar assimilation and ethanol production. The levels of PsADH1 and PsADH2 transcripts were observed, however, to be low through xylose metabolism relative to the transcript levels of other fermentative and glycolytic enzymes [13,17]. In addition, PsADH1 and PsADH2 were able to complement the growth of the S. cerevisiae Δadh mutant on ethanol as a sole carbon source [47]. Moreover, PsADH3 to PsADH7 were speculated to keep the balance between the cofactors NADPH and NADH [17]. However, the expression patterns of the other PsADHs on xylose and glucose under microaerobic conditions, in particular, for PsADH7 and PsADH4 are not fully understood [13]. PsADH5 was found in proximity to NADPH dehydrogenase, implying a function in maintenance the intracellular cofactors balance, however, it is not proven yet. Notably, PsADH7 was found to be upregulated under aerobic growth on xylose [50]. PsADH7 was described as a strictly NADP(H) dependant enzyme with broad spectrum for substrates-specificity, including variety of aromatic and linear aldehydes (e.g., acetaldehyde, butanal, propanal, and furfural) and alcohols (e.g., ethanol, butanol, pentanol, hexanol, and octanol) for forward and reverse reactions, respectively [50]. Surprisingly, PsADH7 was able to utilize xylitol as a substrate too with moderate activity. In the same context, the overexpression of PsADH7 into a P. stipites xylitol dehydrogenase mutant (∆PsXDH) [18], which cannot metabolize xylitol and therefore cannot grow on xylose as a sole carbon source, was able exclusively to complement the growth of ∆PsXDH on xylose, in contrast to PsADH1, 2, 4, and 5 [50]. Hence, there is a need to understand the kinetic characteristics of each of PsADH and SpADH enzymes in order to target the correct genes for overexpression and/or deletion. Finally, we would like to state that genes encoding for adh isozymes are worth studying, especially of S. passalidarum, owning to their significant functions in bioethanol production/consumption and/or intracellular cofactor balance.

7. Conclusions

Taken together, the advances in fermentation performance by S. passalidarum pave the way for engineering the conventional and the nonconventional fermenting yeasts, such as S. cerevisiae and P. stipites, for economical fermentation of hexose and pentose sugars in hemicellulosic hydrolysates on industrial scales. Keeping in mind that the efficient metabolization and fermentation of xylose is essential for the bioconversion of lignocellulosic biomasses into biofuels and chemicals, but the conventional wildtype strains like S. cerevisiae cannot use the xylose. Therefore, researchers keep trying to engineer the xylose utilization pathway into the conventional yeast. The genomes of the natural xylose-fermenting yeasts, in particular of P. stipitis and S. passalidarum, are of huge importance, as their genomics features and regulatory patterns can serve as guides and genomic resources for further genetic engineering development in those native xylose-metabolizing yeasts or to engineer non-xylose fermenting yeasts. Therefore, S. passalidarum and P. stipitis can be considered as genomic treasure sources for various genes to engineer the xylose metabolism and to improve the bioethanol production [1,24,34].

Author Contributions

K.A.S. undertook extensive literature review and wrote the manuscript. S.M.E. and A.I.E.-D. supervised the research. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Acknowledgments

The authors would like to thank Thomas Jeffries (University of Wisconsin Madison), Laura Willis (Forest Products Laboratory, USDA), Amal rabeá, Ali Selim, and Katerina Peros for the invaluable and unlimited support to complete this project. K.A.S. received the Parwon scholarship at Institute for Microbial and Biochemical Technology, FPL, USDA.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Jeffries, T.W. Engineering yeasts for xylose metabolism. Curr. Opin. Biotechnol. 2006, 17, 320–326. [Google Scholar] [CrossRef] [PubMed]
  2. Balat, M.; Balat, H. Recent trends in global production and utilization of bio-ethanol fuel. Appl. Energy 2009, 86, 2273–2282. [Google Scholar] [CrossRef]
  3. Jarboe, L.R.; Zhang, X.; Wang, X.; Moore, J.C.; Shanmugam, K.T.; Ingram, L.O. Metabolic Engineering for Production of Biorenewable Fuels and Chemicals: Contributions of Synthetic Biology. J. Biomed. Biotechnol. 2010, 2010, 761042. [Google Scholar] [CrossRef] [PubMed]
  4. Selim, K.A.; El-Ghwas, D.E.; Easa, S.M.; Hassan, M.I.A. Bioethanol a Microbial Biofuel Metabolite; New Insights of Yeasts Metabolic Engineering. Fermentation 2018, 4, 16. [Google Scholar] [CrossRef] [Green Version]
  5. Jeffries, T.W.; Shi, N.Q. Genetic engineering for improved xylose fermentation by yeasts. Adv. Biochem. Eng. Biotechnol. 1999, 65, 117–161. [Google Scholar]
  6. Ruchala, J.; Kurylenko, O.O.; Dmytruk, K.V.; Sibirny, A.A. Construction of advanced producers of first- and second-generation ethanol in Saccharomyces cerevisiae and selected species of non-conventional yeasts (Scheffersomyces stipitis, Ogataea polymorpha). J. Ind. Microbiol. Biotechnol. 2020, 47, 109–132. [Google Scholar] [CrossRef] [Green Version]
  7. Hinmann, N.D.; Wright, J.D.; Hoagland, W.; Wyman, C.E. Xylose fermentation—An economic analysis. Appl. Biochem. Biotechnol. 1989, 20, 391–401. [Google Scholar] [CrossRef]
  8. Saha, B.C.; Dien, B.S.; Bothast, R.J. Fuel ethanol production from corn fiber—Current status and technical prospects. Appl. Biochem. Biotechnol. 1998, 70, 115–125. [Google Scholar] [CrossRef]
  9. Cadete, R.M.; Rosa, C.A. The yeasts of the genus Spathaspora: Potential candidates for second-generation biofuel production. Yeast 2018, 35, 191–199. [Google Scholar] [CrossRef] [Green Version]
  10. Hou, X. Anaerobic xylose fermentation by Spathaspora passalidarum. Appl. Microbiol. Biotechnol. 2012, 94, 205–214. [Google Scholar] [CrossRef] [Green Version]
  11. Kurtzman, C.P. Candida shehatae—Genetic diversity and phylogenetic relationships with other xylose-fermenting yeasts. Antonie Leeuwenhoek 1990, 57, 215–222. [Google Scholar] [CrossRef] [PubMed]
  12. Melake, T.; Passoth, V.V.; Klinner, D. Characterization of the genetic system of the xylose-fermenting yeast Pichia stipitis. Curr. Microbial. 1996, 33, 237–242. [Google Scholar] [CrossRef] [PubMed]
  13. Jeffries, T.W.; Van Vleet, J.R.H. Pichia stipitis genomics, transcriptomics, and gene clusters. FEMS Yeast Res. 2009, 9, 793–807. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  14. Van Vleet, J.H.; Jeffries, T.W. Yeast metabolic engineering for hemicellulosic ethanol production. Curr. Opin. Biotechnol. 2009, 20, 300–306. [Google Scholar] [CrossRef] [PubMed]
  15. Kurtzman, C.P.; Suzuki, M. Phylogenetic analysis of the ascomycete yeasts that form coezyme Q-9 and the proposal of the new genera Babjeviella, Meyerozyma, Millerozyma, Priceomyces and Scheffersomyces. Mycoscience 2010, 51, 2–14. [Google Scholar] [CrossRef]
  16. Van Dijken, J.P.; van den Bosch, E.; Hermans, J.J.; de Miranda, L.R.; Scheffers, W.A. Alcoholic fermentation by ‘nonfermentative’ yeasts. Yeast 1986, 2, 123–127. [Google Scholar] [CrossRef] [Green Version]
  17. Jeffries, T.W.; Grigoriev, I.V.; Grimwood, J.; Laplaza, J.M.; Aerts, A.; Salamov, A.; Schmutz, J.; Lindquist, E.; Dehal, P.; Shapiro, H.; et al. Genome sequence of the lignocellulose-bioconverting and xylose fermenting yeast Pichia stipitis. Nat. Biotechnol. 2007, 25, 319–326. [Google Scholar] [CrossRef] [Green Version]
  18. Laplaza, J.M.; Torres, B.R.; Jin, Y.S.; Jeffries, T.W. Sh ble and Cre adapted for functional genomics and metabolic engineering of Pichia stipitis. Enzym. Microb. Technol. 2006, 38, 741–747. [Google Scholar] [CrossRef]
  19. Long, T.M.; Su, Y.K.; Headman, J.; Higbee, A.; Willis, L.B.; Jeffries, T.W. Cofermentation of glucose, xylose, and cellobiose by the beetle-associated yeast, Spathaspora passalidarum. Appl. Environ. Microbiol. 2012, 78, 5492–5500. [Google Scholar] [CrossRef] [Green Version]
  20. Su, Y.K.; Willis, L.B.; Jeffries, T.W. Effects of aeration on growth, ethanol and polyol accumulation by Spathaspora passalidarum NRRL Y-27907 and Scheffersomyces stipitis NRRL Y-7124. Biotechnol. Bioeng. 2015, 112, 457–469. [Google Scholar] [CrossRef]
  21. Nguyen, N.H.; Suh, S.O.; Marshall, C.J.; Blackwell, M. Morphological and ecological similarities: Wood-boring beetles associated with novel xylose-fermenting yeasts, Spathaspora passalidarum gen. sp. nov. and Candida jeffriesii sp. nov. Mycol. Res. 2006, 110, 1232–1241. [Google Scholar] [CrossRef] [PubMed]
  22. Cadete, R.M.; Santos, R.O.; Melo, M.A.; Mouro, A.; Gonc¸alves, D.L.; Stambuk, B.U.; Gomes, F.C.O.; Lachance, M.A.; Rosa, C.A. Spathaspora arborariae sp. nov., a D-xylose-fermenting yeast species isolated from rotting wood in Brazil. FEMS Yeast Res. 2009, 9, 1338–1342. [Google Scholar] [PubMed] [Green Version]
  23. Cadete, R.M.; Melo, M.A.; Dussán, K.J.; Rodrigues, R.C.; Silva, S.S.; Zilli, J.E.; Vital, M.J.; Gomes, F.C.; Lachance, M.A.; Rosa, C.A. Diversity and physiological characterization of D-xylose-fermenting yeasts isolated from the Brazilian Amazonian Forest. PLoS ONE 2012, 7, e43135. [Google Scholar] [CrossRef] [PubMed]
  24. Cadete, R.M.; Melo, M.A.; Zilli, J.E.; Vital, M.J.; Mouro, A.; Prompt, A.H.; Gomes, F.C.; Stambuk, B.U.; Lachance, M.A.; Rosa, C.A. Spathaspora brasiliensis sp. nov., Spathaspora suhii sp. nov., Spathaspora roraimanensis sp. nov. and Spathaspora xylofermentans sp. nov., four novel (D)-xylose-fermenting yeast species from Brazilian Amazonian forest. Antonie Leeuwenhoek 2013, 103, 421–431. [Google Scholar] [CrossRef] [PubMed]
  25. Souza, G.F.L.; Valentim, L.T.C.N.; Nogueira, S.R.P.; Abegg, M.A. Efficient production of second generation ethanol and xylitol by yeasts from Amazonian beetles (Coleoptera) and their galleries. Afr. J. Microbiol. Res. 2017, 11, 814–824. [Google Scholar]
  26. Ren, Y.; Chen, L.; Niu, Q.; Hui, F. Description of Scheffersomyces henanensis sp. nov., a new D-xylose-fermenting yeast species isolated from rotten wood. PLoS ONE 2014, 9, e92315. [Google Scholar] [CrossRef] [Green Version]
  27. Rodrussamee, N.; Sattayawat, P.; Yamada, M. Highly efficient conversion of xylose to ethanol without glucose repression by newly isolated thermotolerant Spathaspora passalidarum CMUWF1-2. BMC Microbiol. 2018, 18, 73. [Google Scholar] [CrossRef]
  28. Cadete, R.M.; de las Heras, A.M.; Sandström, A.G.; Ferreira, C.; Gírio, F.; Gorwa-Grauslund, M.-F.; Rosa, C.A.; Fonseca, C. Exploring xylose metabolism in Spathaspora species: XYL1.2 from Spathaspora passalidarum as the key for efficient anaerobic xylose fermentation in metabolic engineered Saccharomyces cerevisiae. Biotechnol. Biofuels 2016, 9, 167. [Google Scholar]
  29. Kwak, S.; Jin, Y.S. Production of fuels and chemicals from xylose by engineered Saccharomyces cerevisiae: A review and perspective. Microb. Cell Fact. 2017, 16, 82. [Google Scholar] [CrossRef] [Green Version]
  30. Veras, H.C.T.; Parachin, N.S.; Almeida, J.R.M. Comparative assessment of fermentative capacity of different xylose-consuming yeasts. Microb. Cell Fact. 2017, 16, 153. [Google Scholar] [CrossRef] [Green Version]
  31. Veras, H.C.T.; Campos, C.G.; Nascimento, I.F.; Abdelnur, P.V.; Almeida, J.R.M.; Parachin, N.S. Metabolic flux analysis for metabolome data validation of naturally xylose-fermenting yeasts. BMC Biotechnol. 2019, 19, 58. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  32. Nakanishi, S.C.; Soares, L.B.; Biazi, L.E.; Nascimento, V.M.; Costa, A.C.; Rocha, G.J.M.; Ienczak, J.L. Fermentation strategy for second generation ethanol production from sugarcane bagasse hydrolyzate by Spathaspora passalidarum and Scheffersomyces stipitis. Biotechnol. Bioeng. 2017, 114, 2211–2221. [Google Scholar] [CrossRef] [PubMed]
  33. De Souza, R.D.F.R.; Dutra, E.D.; Leite, F.C.B.; Cadete, R.M.; Rosa, C.A.; Stambuk, B.U.; Stamford, T.L.M.; de Morais, M.A., Jr. Production of ethanol fuel from enzyme-treated sugarcane bagasse hydrolysate using d-xylose-fermenting wild yeast isolated from Brazilian biomes. 3 Biotech. 2018, 8, 312. [Google Scholar] [CrossRef] [PubMed]
  34. Wohlbach, D.J.; Kuo, A.; Sato, T.K.; Potts, K.M.; Salamov, A.A.; Labutti, K.M.; Sun, H.; Clum, A.; Pangilinan, J.L.; Lindquist, E.A.; et al. Comparative genomics of xylose-fermenting fungi for enhanced biofuel production. Proc. Natl. Acad. Sci. USA 2011, 108, 13212–13217. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  35. Jeppsson, M.; Bengtsson, O.; Franke, K.; Lee, H.; Hahn-Hagerdal, B.; Gorwa-Grauslund, M.F. The expression of a Pichia stipitis xylose reductase mutant with higher K(m) for NADPH increases ethanol production from xylose in recombinant Saccharomyces cerevisiae. Biotechnol. Bioeng. 2006, 93, 665–673. [Google Scholar] [CrossRef]
  36. Petschacher, B.; Nidetzky, B. Altering the coenzyme preference of xylose reductase to favor utilization of NADH enhances ethanol yield from xylose in a metabolically engineered strain of Saccharomyces cerevisiae. Microb. Cell 2008, 7, 9. [Google Scholar] [CrossRef] [Green Version]
  37. Bengtsson, O.; Hahn-Hagerdal, B.; Gorwa-Grauslund, M.F. Xylose reductase from Pichia stipitis with altered coenzyme preference improves ethanolic xylose fermentation by recombinant Saccharomyces cerevisiae. Biotechnol. Biofuels 2009, 2, 9. [Google Scholar] [CrossRef] [Green Version]
  38. Guo, J.; Huang, S.; Chen, Y.; Guo, X.; Xiao, D. Heterologous expression of Spathaspora passalidarum xylose reductase and xylitol dehydrogenase genes improved xylose fermentation ability of Aureobasidium pullulans. Microb. Cell Fact. 2018, 17, 64. [Google Scholar] [CrossRef]
  39. Li, H.; Fan, H.; Li, Y.; Shi, G.Y.; Ding, Z.Y.; Gu, Z.H.; Zhang, L. Construction and application of multi-host integrative vector system for xylose-fermenting yeast. FEMS Yeast Res. 2017, 17, 6. [Google Scholar] [CrossRef] [Green Version]
  40. Hou, X.; Yao, S. Improved inhibitor tolerance in xylosefermenting yeast Spathaspora passalidarum by mutagenesis and protoplast fusion. Appl. Microbiol. Biotechnol. 2012, 93, 2591–2601. [Google Scholar] [CrossRef] [Green Version]
  41. Morales, P.; Gentina, J.C.; Aroca, G.; Mussatto, S.I. Development of an acetic acid tolerant Spathaspora passalidarum strain through evolutionary engineering with resistance to inhibitors compounds of autohydrolysate of Eucalyptus globulus. Ind. Crop Prod. 2017, 106, 5–11. [Google Scholar] [CrossRef]
  42. Yu, H.; Guo, J.; Chen, Y.; Fu, G.; Li, B.; Guo, X.; Xiao, D. Efficient utilization of hemicellulose and cellulose in alkali liquor-pretreated corncob for bioethanol production at high solid loading by Spathaspora passalidarum U1–58. Bioresour. Technol. 2017, 232, 168–175. [Google Scholar] [CrossRef] [PubMed]
  43. Su, Y.K.; Willis, L.B.; Rehmann, L.; Smith, D.R.; Jeffries, T.W. Spathaspora passalidarum selected for resistance to AFEX hydrolysate shows decreased cell yield. FEMS Yeast Res. 2018, 18. [Google Scholar] [CrossRef] [PubMed]
  44. Cho, J.Y.; Jeffries, T.W. Pichia stipitis genes for alcohol dehydrogenase with fermentative and respiratory functions. Appl. Environ. Microbiol. 1998, 64, 1350–1358. [Google Scholar] [CrossRef] [Green Version]
  45. Lin, Y.; He, P.; Wang, Q.; Lu, D.; Li, Z.; Wu, C.; Jiang, N. The alcohol dehydrogenase system in the xylose-fermenting yeast Candida maltosa. PLoS ONE 2010, 5, e11752. [Google Scholar] [CrossRef] [Green Version]
  46. Cho, J.Y.; Jeffries, T.W. Transcriptional control of ADH genes in the xylose fermenting yeast Pichia stipitis. Appl. Environ. Microbiol. 1999, 65, 2363–2368. [Google Scholar] [CrossRef] [Green Version]
  47. Passoth, V.; Schafer, B.; Liebel, B.; Weierstall, T.; Klinner, U. Molecular cloning of alcohol dehydrogenase genes of the yeast Pichia stipitis and identification of the fermentative ADH. Yeast 1998, 14, 1311–1325. [Google Scholar] [CrossRef]
  48. Passoth, V.; Cohn, M.; Schafer, B.; Hahn-Hagerdal, B.; Klinner, U. Molecular analysis of the hypoxia induced ADH2-promoter in the respiratory yeast Pichia stipitis. Yeast 2003, 20, S199. [Google Scholar] [CrossRef]
  49. Passoth, V.; Cohn, M.; Schafer, B.; Hahn-Hagerdal, B.; Klinner, U. Analysis of the hypoxia-induced ADH2 promoter of the respiratory yeast Pichia stipitis reveals a new mechanism for sensing of oxygen limitation in yeast. Yeast 2003, 20, 39–51. [Google Scholar] [CrossRef]
  50. Lu, C.; Chapter, V. In Elucidating Physiological Roles of Pichia stipitis Alcohol Dehydrogenases in Xylose Fermentation and Shuffling Promoters for Multiple Genes in Saccharomyces cerevisiae to Improve Xylose Fermentation. Ph.D. Thesis, University of Wisconsin, Madison, WI, USA, 2007. [Google Scholar]
Fermentation 06 00033 g001 550
Figure 1. Model of yeast fermentation machinery for bioethanol production using the agriculture waste to feed yeasts [4]. The metabolic pathways for xylose and glucose assimilation and fermentation are indicated including the pentose phosphate pathway and glycolysis. The agriculture waste is treated through the enzymatic and chemical simultaneous saccharification and fermentation (SSF) processes to release the cellulosic and hemicellulosic sugars. The hexose and pentose sugars are transported by specific hexose and pentose sugar transporters into yeast for further metabolizing processes.
Figure 1. Model of yeast fermentation machinery for bioethanol production using the agriculture waste to feed yeasts [4]. The metabolic pathways for xylose and glucose assimilation and fermentation are indicated including the pentose phosphate pathway and glycolysis. The agriculture waste is treated through the enzymatic and chemical simultaneous saccharification and fermentation (SSF) processes to release the cellulosic and hemicellulosic sugars. The hexose and pentose sugars are transported by specific hexose and pentose sugar transporters into yeast for further metabolizing processes.
Fermentation 06 00033 g001
Fermentation 06 00033 g002 550
Figure 2. Schematic model of the central metabolism for bioethanol production from xylose indicating the rate limiting steps (XR: xylose reductase; XDH: xylitol dehydrogenase, and ADH: alcohol dehydrogenase) and cofactors demand/balance in most of native xylose metabolizing yeasts. Xylose assimilation reactions starts with XR to produce xylitol. The xylitol is further metabolized by XDH to produce xylulose, which further metabolized to xylulose-phosphate to enter the glycolysis (indicate by black dotted arrow and summarized in Figure 1) to produce acetaldehyde. The acetaldehyde finally converted to ethanol by ADH.
Figure 2. Schematic model of the central metabolism for bioethanol production from xylose indicating the rate limiting steps (XR: xylose reductase; XDH: xylitol dehydrogenase, and ADH: alcohol dehydrogenase) and cofactors demand/balance in most of native xylose metabolizing yeasts. Xylose assimilation reactions starts with XR to produce xylitol. The xylitol is further metabolized by XDH to produce xylulose, which further metabolized to xylulose-phosphate to enter the glycolysis (indicate by black dotted arrow and summarized in Figure 1) to produce acetaldehyde. The acetaldehyde finally converted to ethanol by ADH.
Fermentation 06 00033 g002
Fermentation 06 00033 g003 550
Figure 3. Spathaspora passalidarum budding cells with characteristic curved and elongated ascospore.
Figure 3. Spathaspora passalidarum budding cells with characteristic curved and elongated ascospore.
Fermentation 06 00033 g003

Share and Cite

MDPI and ACS Style

Selim, K.A.; Easa, S.M.; El-Diwany, A.I. The Xylose Metabolizing Yeast Spathaspora passalidarum is a Promising Genetic Treasure for Improving Bioethanol Production. Fermentation 2020, 6, 33. https://0-doi-org.brum.beds.ac.uk/10.3390/fermentation6010033

AMA Style

Selim KA, Easa SM, El-Diwany AI. The Xylose Metabolizing Yeast Spathaspora passalidarum is a Promising Genetic Treasure for Improving Bioethanol Production. Fermentation. 2020; 6(1):33. https://0-doi-org.brum.beds.ac.uk/10.3390/fermentation6010033

Chicago/Turabian Style

Selim, Khaled A., Saadia M. Easa, and Ahmed I. El-Diwany. 2020. "The Xylose Metabolizing Yeast Spathaspora passalidarum is a Promising Genetic Treasure for Improving Bioethanol Production" Fermentation 6, no. 1: 33. https://0-doi-org.brum.beds.ac.uk/10.3390/fermentation6010033

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