Your search keyword '"Kuanyshev, N"' showing total 22 results

1. Compositional and temporal division of labor modulates mixed sugar fermentation by an engineered yeast consortium

Author

Shin, J, Liao, S, Kuanyshev, N, Xin, Y, Kim, C, Lu, T, Jin, Y, Shin J., Liao S., Kuanyshev N., Xin Y., Kim C., Lu T., Jin Y. -S., Shin, J, Liao, S, Kuanyshev, N, Xin, Y, Kim, C, Lu, T, Jin, Y, Shin J., Liao S., Kuanyshev N., Xin Y., Kim C., Lu T., and Jin Y. -S.

Abstract

Synthetic microbial communities have emerged as an attractive route for chemical bioprocessing. They are argued to be superior to single strains through microbial division of labor (DOL), but the exact mechanism by which DOL confers advantages remains unclear. Here, we utilize a synthetic Saccharomyces cerevisiae consortium along with mathematical modeling to achieve tunable mixed sugar fermentation to overcome the limitations of single-strain fermentation. The consortium involves two strains with each specializing in glucose or xylose utilization for ethanol production. By controlling initial community composition, DOL allows fine tuning of fermentation dynamics and product generation. By altering inoculation delay, DOL provides additional programmability to parallelly regulate fermentation characteristics and product yield. Mathematical models capture observed experimental findings and further offer guidance for subsequent fermentation optimization. This study demonstrates the functional potential of DOL in bioprocessing and provides insight into the rational design of engineered ecosystems for various applications.

Published

2024

2. Rewiring yeast metabolism for producing 2,3-butanediol and two downstream applications: Techno-economic analysis and life cycle assessment of methyl ethyl ketone (MEK) and agricultural biostimulant production

Author

Lee, J, Bhagwat, S, Kuanyshev, N, Cho, Y, Sun, L, Lee, Y, Cortes-Pena, Y, Li, Y, Rao, C, Guest, J, Jin, Y, Lee J. W., Bhagwat S. S., Kuanyshev N., Cho Y. B., Sun L., Lee Y. -G., Cortes-Pena Y. R., Li Y., Rao C. V., Guest J. S., Jin Y. -S., Lee, J, Bhagwat, S, Kuanyshev, N, Cho, Y, Sun, L, Lee, Y, Cortes-Pena, Y, Li, Y, Rao, C, Guest, J, Jin, Y, Lee J. W., Bhagwat S. S., Kuanyshev N., Cho Y. B., Sun L., Lee Y. -G., Cortes-Pena Y. R., Li Y., Rao C. V., Guest J. S., and Jin Y. -S.

Abstract

Rising concerns for sustainability and global climate change have driven the development of sustainable production pathways for biofuels and chemicals from lignocellulosic biomass via integrated biological and chemical processes. We constructed an engineered Saccharomyces cerevisiae capable of producing 2,3-butanediol (2,3-BDO) from glucose without accumulating ethanol and glycerol, which hinder downstream processing of 2,3-BDO, through extensive metabolic reprogramming. Specifically, we introduced heterologous 2,3-BDO biosynthetic enzymes and deleted the major isozymes of ethanol and glycerol biosynthetic enzymes. In addition, we introduced an NAD+ regenerating Pyruvate-Malate (PM) cycle and enhanced the NAD+ regenerating capability of the PM cycle to resolve the redox imbalance from the deletion of ethanol and glycerol production pathways. The resulting engineered yeast produced 109.9 g/L of 2,3-BDO with a productivity of 1.0 g/L/h and a yield of 0.36 g/g glucose in a fed-batch fermentation. We also conducted techno-economic analysis (TEA) and life cycle assessment (LCA) of the production of methyl ethyl ketone (MEK) through catalytic dehydration of 2,3-BDO. A TEA based on the experimental results indicated that the minimum product selling price (MPSP) was estimated to be $1.90/kg. Regarding cradle-to-grave LCA, 100-year global warming potential (GWP100) and fossil energy consumption (FEC) were found to be 0.37 kg CO2 eq/kg and 3.1 MJ/kg, respectively. These results demonstrated the feasibility of cost-competitive and sustainable bio-based MEK production via yeast fermentation. In addition, we explored the possibility of using the fermentation broth containing 2,3-BDO as a biostimulant inducing drought tolerance in plants. As a result, the yeast 2,3-BDO fermentation broth can induce drought tolerance in Arabidopsis thaliana without a complicated purification process.

Published

2023

3. Identification and analysis of sugar transporters capable of co-transporting glucose and xylose simultaneously

Author

Kuanyshev, N, Deewan, A, Jagtap, S, Liu, J, Selvam, B, Chen, L, Shukla, D, Rao, C, Jin, Y, Kuanyshev N., Deewan A., Jagtap S. S., Liu J., Selvam B., Chen L. Q., Shukla D., Rao C. V., Jin Y. S., Kuanyshev, N, Deewan, A, Jagtap, S, Liu, J, Selvam, B, Chen, L, Shukla, D, Rao, C, Jin, Y, Kuanyshev N., Deewan A., Jagtap S. S., Liu J., Selvam B., Chen L. Q., Shukla D., Rao C. V., and Jin Y. S.

Abstract

Simultaneous co-fermentation of glucose and xylose is a key desired trait of engineered Saccharomyces cerevisiae for efficient and rapid production of biofuels and chemicals. However, glucose strongly inhibits xylose transport by endogenous hexose transporters of S. cerevisiae. We identified structurally distant sugar transporters (Lipomyces starkeyi LST1_205437 and Arabidopsis thaliana AtSWEET7) capable of co-transporting glucose and xylose from previously unexplored oleaginous yeasts and plants. Kinetic analysis showed that LST1_205437 had lenient glucose inhibition on xylose transport and AtSWEET7 transported glucose and xylose simultaneously with no inhibition. Modelling studies of LST1_205437 revealed that Ala335 residue at sugar binding site can accommodates both glucose and xylose. Docking studies with AtSWEET7 revealed that Trp59, Trp183, Asn145, and Asn179 residues stabilized the interactions with sugars, allowing both xylose and glucose to be co-transported. In addition, we altered sugar preference of LST1_205437 by single amino acid mutation at Asn365. Our findings provide a new mechanistic insight on glucose and xylose transport mechanism of sugar transporters and the identified sugar transporters can be employed to develop engineered yeast strains for producing cellulosic biofuels and chemicals. Graphical Abstract Lay Summary Simultaneous co-fermentation of glucose and xylose, the two most abundant sugars in cellulosic biomass, is a key trait for efficient production of biofuels and chemicals. In this study, the authors identified and characterized two structurally distant transporters with 7 and 12 transmembrane (TM) facilitated partial and complete co-transportation of glucose and xylose. This work not only contributes to the understanding of the sugar co-transport mechanism in yeast and plant, but also enables rapid and efficient co-utilization of cellulosic sugars for the production of biofuels and chemicals.

Published

2021

4. Domesticating a food spoilage yeast into an organic acid-tolerant metabolic engineering host: Lactic acid production by engineered Zygosaccharomyces bailii

Author

Kuanyshev, N, Rao, C, Dien, B, Jin, Y, Kuanyshev N., Rao C. V., Dien B., Jin Y. -S., Kuanyshev, N, Rao, C, Dien, B, Jin, Y, Kuanyshev N., Rao C. V., Dien B., and Jin Y. -S.

Abstract

Lactic acid represents an important class of commodity chemicals, which can be produced by microbial cell factories. However, due to the toxicity of lactic acid at lower pH, microbial production requires the usage of neutralizing agents to maintain neutral pH. Zygosaccharomyces bailii, a food spoilage yeast, can grow under the presence of organic acids used as food preservatives. This unique trait of the yeast might be useful for producing lactic acid. With the goal of domesticating the organic acid-tolerant yeast as a metabolic engineering host, seven Z. bailii strains were screened in a minimal medium with 10 g/L of acetic, or 60 g/L of lactic acid at pH 3. The Z. bailii NRRL Y7239 strain was selected as the most robust strain to be engineered for lactic acid production. By applying a PAN-ARS-based CRISPR-Cas9 system consisting of a transfer RNA promoter and NAT selection, we demonstrated the targeted deletion of ADE2 and site-specific integration of Rhizopus oryzae ldhA coding for lactate dehydrogenase into the PDC1 locus. The resulting pdc1::ldhA strain produced 35 g/L of lactic acid without ethanol production. This study demonstrates the feasibility of the CRISPR-Cas9 system in Z. bailii, which can be applied for a fundamental study of the species.

Published

2021

5. The spoilage yeast Zygosaccharomyces bailii: Foe or friend?

Author

Kuanyshev, N, Adamo, Gm, Porro, D, Branduardi, P., Kuanyshev, N, Adamo, G, Porro, D, and Branduardi, P

Subjects

genetic engineering, weak organic acid, industrial bioprocesse, Zygosaccharomyces, Bioengineering, Food Contamination, Wine, Hydrogen-Ion Concentration, Biochemistry, Applied Microbiology and Biotechnology, CHIM/11 - CHIMICA E BIOTECNOLOGIA DELLE FERMENTAZIONI, Adaptation, Physiological, Sorbic Acid, Drug Resistance, Fungal, Diethyl Pyrocarbonate, Fermentation, Food, Preserved, Genetics, Food Preservatives, Sulfites, Zygosaccharomyces bailii, food spoilage yeast, Biotechnology, Acetic Acid

Abstract

Zygosaccharomyces bailii is a non-Saccharomyces budding yeast known as one of the most aggressive food spoilage microorganisms, often isolated as a contaminant during wine fermentation, as well as from many acidic, high-sugar and canned foods. The spoilage ability relies on the yeast's unique feature of tolerating the most common preservatives such as sulphite, dimethyl dicarbonate, acetic acid and sorbic acid. Therefore, many studies have focused on the description of this peculiar tolerance with the aim of developing preventative measures against Z. bailii food spoilage. These studies demonstrated the involvement of diverse molecular and physiological mechanisms in the yeast resistance, comprising detoxification of preservatives, adaptation of the cytoplasmic pH and modulation of the cell wall/membrane composition. At the same time, the described traits unveiled Z. bailii as a novel potential workhorse for industrial bioprocesses. Here we present the yeast Z. bailii starting from important aspects of its robustness and concluding with the exploitation of its potential in biotechnology. Overall, the article describes Z. bailii from different perspectives, converging in presenting it as one of the most interesting species of the Saccharomycotina subphylum. Copyright © 2017 John Wiley & Sons, Ltd

Published

2016

6. Transcriptional response to lactic acid stress in the hybrid yeast Zygosaccharomyces parabailii

Author

Ortiz-Merino, R, Kuanyshev, N, Byrne, K, Varela, J, Morrissey, J, Porro, D, Wolfe, K, Branduardi, P, Ortiz-Merino, Raúl A., KUANYSHEV, NURZHAN, Byrne, Kevin P., Varela, Javier A., Morrissey, John P., Porro, Danilo, Wolfe, Kenneth H., Branduardi, Paola, Ortiz-Merino, R, Kuanyshev, N, Byrne, K, Varela, J, Morrissey, J, Porro, D, Wolfe, K, Branduardi, P, Ortiz-Merino, Raúl A., KUANYSHEV, NURZHAN, Byrne, Kevin P., Varela, Javier A., Morrissey, John P., Porro, Danilo, Wolfe, Kenneth H., and Branduardi, Paola

Abstract

Lactic acid has a wide range of applications starting from its undissociated form, and its production using cell factories requires stress-tolerant microbial hosts. The interspecies hybrid yeast Zygosaccharomyces parabailii has great potential to be exploited as a novel host for lactic acid production, due to high organic acid tolerance at low pH and a fermentative metabolism with a high growth rate. Here we used mRNA sequencing (RNA-seq) to analyze Z. parabailii's transcriptional response to lactic acid added exogenously, and we explore the biological mechanisms involved in tolerance. Z. parabailii contains two homeologous copies of most genes. Under lactic acid stress, the two genes in each homeolog pair tend to diverge in expression to a significantly greater extent than under control conditions, indicating that stress tolerance is facilitated by interactions between the two gene sets in the hybrid. Lactic acid induces downregulation of genes related to cell wall and plasma membrane functions, possibly altering the rate of diffusion of lactic acid into cells. Genes related to iron transport and redox processes were upregulated, suggesting an important role for respiratory functions and oxidative stress defense. We found differences in the expression profiles of genes putatively regulated by Haa1 and Aft1/Aft2, previously described as lactic acid responsive in Saccharomyces cerevisiae. Furthermore, formate dehydrogenase (FDH) genes form a lactic acid-responsive gene family that has been specifically amplified in Z. parabailii in comparison to other closely related species. Our study provides a useful starting point for the engineering of Z. parabailii as a host for lactic acid production.

Published

2018

7. Evolutionary restoration of fertility in an interspecies hybrid yeast, by whole-genome duplication after a failed mating-type switch

Author

Ortiz-merino, R, Kuanyshev, N, Braun-galleani, S, Byrne, K, Porro, D, Branduardi, P, Wolfe, K, Ortiz-merino, R, Kuanyshev, N, Braun-galleani, S, Byrne, K, Porro, D, Branduardi, P, and Wolfe, K

Abstract

Many interspecies hybrids have been discovered in yeasts, but most of these hybrids are asexual and can replicate only mitotically. Whole-genome duplication has been proposed as a mechanism by which interspecies hybrids can regain fertility, restoring their ability to perform meiosis and sporulate. Here, we show that this process occurred naturally during the evolution of Zygosaccharomyces parabailii, an interspecies hybrid that was formed by mating between 2 parents that differed by 7% in genome sequence and by many interchromosomal rearrangements. Surprisingly, Z. parabailii has a full sexual cycle and is genetically haploid. It goes through mating-type switching and autodiploidization, followed by immediate sporulation. We identified the key evolutionary event that enabled Z. parabailii to regain fertility, which was breakage of 1 of the 2 homeologous copies of the mating-type (MAT) locus in the hybrid, resulting in a chromosomal rearrangement and irreparable damage to 1 MAT locus. This rearrangement was caused by HO endonuclease, which normally functions in mating-type switching. With 1 copy of MAT inactivated, the interspecies hybrid now behaves as a haploid. Our results provide the first demonstration that MAT locus damage is a naturally occurring evolutionary mechanism for whole-genome duplication and restoration of fertility to interspecies hybrids. The events that occurred in Z. parabailii strongly resemble those postulated to have caused ancient whole-genome duplication in an ancestor of Saccharomyces cerevisiae

Published

2017

8. Meccanismi di resistenza agli acidi organici in lieviti non Saccaromiceti. Zygosaccharomyces parabailii e Kluyveromyces marxianus come case study

Author

MORRISSEY, JOHN, Kuanyshev, N, BRANDUARDI, PAOLA, KUANYSHEV, NURZHAN, MORRISSEY, JOHN, Kuanyshev, N, BRANDUARDI, PAOLA, and KUANYSHEV, NURZHAN

Abstract

Al fine di rendere efficiente la produzione di biomolecole e biocarburanti tramite le bioraffinerie, è necessario avere a disposizione materie prime rinnovabili e cell factory microbiche robuste. Fra le diverse opzioni, la lignocellulosa e il siero di latte, sottoprodotti delle industrie forestali, agricole e casearie, rappresentano materie prime economiche e ricche di zuccheri. La conversione della lignocellulosa e del siero di latte nei prodotti desiderati tramite cell factory microbiche è un’opzione interessante per la sostituzione delle raffinerie petrolchimiche. Diversi batteri, alghe e lieviti sono già utilizzati come cell factory, ma è previsto che il loro numero aumenti nei prossimi anni. Scarse richieste nutrizionali e robustezza sono caratteristiche che hanno reso i lieviti una classe di microrganismi largamente utilizzata nelle biotecnologie industriali. Ciò è stato possibile grazie allo sfruttamento delle loro qualità naturali e all’ingegnerizzazione di pathway metabolici per la produzione di prodotti naturali o ricombinanti, tra i quali molecole come gli acidi organici. Lo scopo della tesi di ricerca è stato quello di valutare i meccanismi di risposta allo stress indotto da acidi deboli nei lieviti non-Saccaromiceti Zygosaccharomyces parabailii e Kluyveromyces marxianus. Per capire al meglio la risposta nei confronti dello stress indotto da acidi deboli di Z. parabailii, abbiamo ricapitolato tutti le recenti scoperte riguardo questa specie. Una volta venuti a conoscenza delle scoperte scientifiche più rilevanti, ci siamo focalizzati sull’effetto indotto da acido lattico nei confronti del ceppo di Z. parabailii utilizzato nel nostro laboratorio. Lo studio ha rivelato che le cellule sono in grado di sopportare fino a 40g/L di acido lattico senza mostrare una fase lag nelle cinetiche di crescita, ed una percentuale irrisoria di cellule morte. Ma ancor più importante è da sottolineare il fatto che durante l’esposizione all’acido lattico abbiamo o, The efficient implementation of biorefinery to produce bio-based chemicals and fuels requires sustainable source of feedstock and robust microbial factories. Among others, lignocellulose and whey represent cheap and sugars-enriched feedstock, which are residual wastes deriving from wood/agriculture and dairy industry. The conversion of lignocellulose and whey into the desired products using microbial cell factories is a promising option to replace the fossil based petrochemical refinery. Different bacteria, algae and yeasts are currently used as microbial hosts, but their number is predicted to increase over next years. Minimum nutritional requirements and robustness have made yeasts a class of microbial hosts widely employed in industrial biotechnology, exploiting their natural abilities as well as genetically acquired pathways for production of natural and recombinant products, among which bulk chemicals such as organic acids. However, an efficient and economically viable production of organic acids has to face problems related to low productivity/titer and toxicity of the final product. Therefore, the exploration of yeast biodiversity to exploit unique native features and the understanding of mechanisms to endure harsh conditions are essential to develop ultra-efficient and robust industrial yeast with novel properties. The aim of the research thesis is to evaluate the mechanism of weak acid stress response in the non-Saccharomyces yeasts Zygosaccharomyces parabailii and Kluyveromyces marxianus. To better understand the weak acid stress response of Z. parabailii, we summarized recent finding on the species. Knowing the relevant scientific reports, next study was focused on the effect of lactic acid stress on Z. parabailii. The study revealed that cells are able to tolerate 40g/l of lactic acid without lag phase of growth and exhibiting a negligible percentage of dead cell. More importantly, during lactic acid exposure we observed structural modifications at the l

Published

2017

9. The spoilage yeast Zygosaccharomyces bailii: Foe or friend?

Author

Kuanyshev, N, Adamo, G, Porro, D, Branduardi, P, Adamo, Gm, Branduardi, P., Kuanyshev, N, Adamo, G, Porro, D, Branduardi, P, Adamo, Gm, and Branduardi, P.

Abstract

Zygosaccharomyces bailii is a non-Saccharomyces budding yeast known as one of the most aggressive food spoilage microorganisms, often isolated as a contaminant during wine fermentation, as well as from many acidic, high-sugar and canned foods. The spoilage ability relies on the yeast's unique feature of tolerating the most common preservatives such as sulphite, dimethyl dicarbonate, acetic acid and sorbic acid. Therefore, many studies have focused on the description of this peculiar tolerance with the aim of developing preventative measures against Z. bailii food spoilage. These studies demonstrated the involvement of diverse molecular and physiological mechanisms in the yeast resistance, comprising detoxification of preservatives, adaptation of the cytoplasmic pH and modulation of the cell wall/membrane composition. At the same time, the described traits unveiled Z. bailii as a novel potential workhorse for industrial bioprocesses. Here we present the yeast Z. bailii starting from important aspects of its robustness and concluding with the exploitation of its potential in biotechnology. Overall, the article describes Z. bailii from different perspectives, converging in presenting it as one of the most interesting species of the Saccharomycotina subphylum. Copyright © 2017 John Wiley & Sons, Ltd

Published

2017

10. Assessing physio-macromolecular effects of lactic acid on Zygosaccharomyces bailii cells during microaerobic fermentation

Author

Kuanyshev, N, Ami, D, Signori, L, Porro, D, Morrissey, J, Branduardi, P, KUANYSHEV, NURZHAN, AMI, DILETTA, SIGNORI, LORENZO, PORRO, DANILO, BRANDUARDI, PAOLA, Kuanyshev, N, Ami, D, Signori, L, Porro, D, Morrissey, J, Branduardi, P, KUANYSHEV, NURZHAN, AMI, DILETTA, SIGNORI, LORENZO, PORRO, DANILO, and BRANDUARDI, PAOLA

Abstract

The ability of Zygosaccharomyces bailii to grow at low pH and in the presence of considerable amounts of weak organic acids, at lethal condition for Saccharomyces cerevisiae, increased the interest in the biotechnological potential of the yeast. To understand the mechanism of tolerance and growth effect of weak acids on Z. bailii, we evaluated the physiological and macromolecular changes of the yeast exposed to sub lethal concentrations of lactic acid. Lactic acid represents one of the important commodity chemical which can be produced by microbial fermentation. We assessed physiological effect of lactic acid by bioreactor fermentation using synthetic media at low pH in the presence of lactic acid. Samples collected from bioreactors were stained with propidium iodide (PI) which revealed that, despite lactic acid negatively influence the growth rate, the number of PI positive cells is similar to that of the control. Moreover, we have performed Fourier Transform Infra-Red (FTIR) microspectroscopy analysis on intact cells of the same samples. This technique has been never applied before to study Z. bailii under this condition. The analyses revealed lactic acid induced macromolecular changes in the overall cellular protein secondary structures, and alterations of cell wall and membrane physico-chemical properties.

Published

2016

11. Transcriptional Response to Lactic Acid Stress in the Hybrid Yeast Zygosaccharomyces parabailii

Author

Raúl A. Ortiz-Merino, Kevin P. Byrne, Paola Branduardi, Nurzhan Kuanyshev, Javier A. Varela, Kenneth H. Wolfe, Danilo Porro, John P. Morrissey, Ortiz-Merino, R, Kuanyshev, N, Byrne, K, Varela, J, Morrissey, J, Porro, D, Wolfe, K, and Branduardi, P

Subjects

0301 basic medicine, Transcription, Genetic, Lactic acid stress, 030106 microbiology, Saccharomyces cerevisiae, yeasts, Hybrid yeast, Applied Microbiology and Biotechnology, 03 medical and health sciences, chemistry.chemical_compound, Stress, Physiological, Yeasts, Gene expression, Zygosaccharomyces parabailii, Gene family, RNA, Messenger, Rna-seq, Gene, 2. Zero hunger, chemistry.chemical_classification, Ecology, biology, Sequence Analysis, RNA, Chemistry, Stress response, Zygosaccharomyces, RNA, Fungal, Lactic acid, biology.organism_classification, CHIM/11 - CHIMICA E BIOTECNOLOGIA DELLE FERMENTAZIONI, Hybrid, Yeast, MRNA Sequencing, Biochemistry, RNA-seq, Food Science, Biotechnology, Organic acid

Abstract

Lactic acid has a wide range of applications starting from its undissociated form, and its production using cell factories requires stress-tolerant microbial hosts. The interspecies hybrid yeast Zygosaccharomyces parabailii has great potential to be exploited as a novel host for lactic acid production, due to high organic acid tolerance at low pH and a fermentative metabolism with a high growth rate. Here we used mRNA sequencing (RNA-seq) to analyze Z. parabailii 's transcriptional response to lactic acid added exogenously, and we explore the biological mechanisms involved in tolerance. Z. parabailii contains two homeologous copies of most genes. Under lactic acid stress, the two genes in each homeolog pair tend to diverge in expression to a significantly greater extent than under control conditions, indicating that stress tolerance is facilitated by interactions between the two gene sets in the hybrid. Lactic acid induces downregulation of genes related to cell wall and plasma membrane functions, possibly altering the rate of diffusion of lactic acid into cells. Genes related to iron transport and redox processes were upregulated, suggesting an important role for respiratory functions and oxidative stress defense. We found differences in the expression profiles of genes putatively regulated by Haa1 and Aft1/Aft2, previously described as lactic acid responsive in Saccharomyces cerevisiae . Furthermore, formate dehydrogenase ( FDH ) genes form a lactic acid-responsive gene family that has been specifically amplified in Z. parabailii in comparison to other closely related species. Our study provides a useful starting point for the engineering of Z. parabailii as a host for lactic acid production. IMPORTANCE Hybrid yeasts are important in biotechnology because of their tolerance to harsh industrial conditions. The molecular mechanisms of tolerance can be studied by analyzing differential gene expression under conditions of interest and relating gene expression patterns to protein functions. However, hybrid organisms present a challenge to the standard use of mRNA sequencing (RNA-seq) to study transcriptional responses to stress, because their genomes contain two similar copies of almost every gene. Here we used stringent mapping methods and a high-quality genome sequence to study the transcriptional response to lactic acid stress in Zygosaccharomyces parabailii ATCC 60483, a natural interspecies hybrid yeast that contains two complete subgenomes that are approximately 7% divergent in sequence. Beyond the insights we gained into lactic acid tolerance in this study, the methods we developed will be broadly applicable to other yeast hybrid strains.

Published

2018

12. Meccanismi di resistenza agli acidi organici in lieviti non Saccaromiceti. Zygosaccharomyces parabailii e Kluyveromyces marxianus come case study

Author

KUANYSHEV, NURZHAN, Kuanyshev, N, and BRANDUARDI, PAOLA

Subjects

hybrid, Z.parabailii, biorefinery, K.marxianus, RNA-seq, BIO/10 - BIOCHIMICA

Abstract

Al fine di rendere efficiente la produzione di biomolecole e biocarburanti tramite le bioraffinerie, è necessario avere a disposizione materie prime rinnovabili e cell factory microbiche robuste. Fra le diverse opzioni, la lignocellulosa e il siero di latte, sottoprodotti delle industrie forestali, agricole e casearie, rappresentano materie prime economiche e ricche di zuccheri. La conversione della lignocellulosa e del siero di latte nei prodotti desiderati tramite cell factory microbiche è un’opzione interessante per la sostituzione delle raffinerie petrolchimiche. Diversi batteri, alghe e lieviti sono già utilizzati come cell factory, ma è previsto che il loro numero aumenti nei prossimi anni. Scarse richieste nutrizionali e robustezza sono caratteristiche che hanno reso i lieviti una classe di microrganismi largamente utilizzata nelle biotecnologie industriali. Ciò è stato possibile grazie allo sfruttamento delle loro qualità naturali e all’ingegnerizzazione di pathway metabolici per la produzione di prodotti naturali o ricombinanti, tra i quali molecole come gli acidi organici. Lo scopo della tesi di ricerca è stato quello di valutare i meccanismi di risposta allo stress indotto da acidi deboli nei lieviti non-Saccaromiceti Zygosaccharomyces parabailii e Kluyveromyces marxianus. Per capire al meglio la risposta nei confronti dello stress indotto da acidi deboli di Z. parabailii, abbiamo ricapitolato tutti le recenti scoperte riguardo questa specie. Una volta venuti a conoscenza delle scoperte scientifiche più rilevanti, ci siamo focalizzati sull’effetto indotto da acido lattico nei confronti del ceppo di Z. parabailii utilizzato nel nostro laboratorio. Lo studio ha rivelato che le cellule sono in grado di sopportare fino a 40g/L di acido lattico senza mostrare una fase lag nelle cinetiche di crescita, ed una percentuale irrisoria di cellule morte. Ma ancor più importante è da sottolineare il fatto che durante l’esposizione all’acido lattico abbiamo osservato modificazioni strutturali a livello della parete e della membrana cellulare. Questi risultati hanno confermato la peculiare abilità di Z. parabailii di adattarsi agli acidi deboli tramite il rimodellamento di alcune componenti cellulari. La mancanza di un genoma di riferimento completo ci ha spinto a compiere il lavoro di sequenziamento, assemblaggio ed annotazione: questo lavoro, oltre a permetterci di evidenziare la natura ibrida del ceppo di Z. parabailii considerato, ha aperto la possibilità di ulteriori studi. I risultati hanno rivelato che Z. parabailii sta subendo un ripristino della fertilità, a seguito dell’evento di ibridazione interspecie, cosa che potrebbe chiarire il processo di duplicazione dell’intero genoma avvenuta in S. cerevisiae ed altri lieviti appartenenti al medesimo clade. Avere a disposizione le informazioni riguardo il genoma completo di Z. parabailii ci ha permesso di portare a termine la prima analisi di sequenziamento dell’RNA sulla specie, quando esposta allo stress da acido lattico. I risultati hanno mostrato l’up-regolazione di geni mitocondriali e connessi allo stress ossidativo, e la down-regolazione di una serie di geni codificanti per determinanti della parete cellulare, in aggiunta alle regolazioni specifiche riguardanti il bilanciamento redox e l’omeostasi di ioni, tra cui il Ferro. È degno di nota il fatto che molti geni sono regolati differentemente rispetto alla controparte di S. cerevisiae, o addirittura non sembrano possedere un omologo nel lievito di riferimento. The efficient implementation of biorefinery to produce bio-based chemicals and fuels requires sustainable source of feedstock and robust microbial factories. Among others, lignocellulose and whey represent cheap and sugars-enriched feedstock, which are residual wastes deriving from wood/agriculture and dairy industry. The conversion of lignocellulose and whey into the desired products using microbial cell factories is a promising option to replace the fossil based petrochemical refinery. Different bacteria, algae and yeasts are currently used as microbial hosts, but their number is predicted to increase over next years. Minimum nutritional requirements and robustness have made yeasts a class of microbial hosts widely employed in industrial biotechnology, exploiting their natural abilities as well as genetically acquired pathways for production of natural and recombinant products, among which bulk chemicals such as organic acids. However, an efficient and economically viable production of organic acids has to face problems related to low productivity/titer and toxicity of the final product. Therefore, the exploration of yeast biodiversity to exploit unique native features and the understanding of mechanisms to endure harsh conditions are essential to develop ultra-efficient and robust industrial yeast with novel properties. The aim of the research thesis is to evaluate the mechanism of weak acid stress response in the non-Saccharomyces yeasts Zygosaccharomyces parabailii and Kluyveromyces marxianus. To better understand the weak acid stress response of Z. parabailii, we summarized recent finding on the species. Knowing the relevant scientific reports, next study was focused on the effect of lactic acid stress on Z. parabailii. The study revealed that cells are able to tolerate 40g/l of lactic acid without lag phase of growth and exhibiting a negligible percentage of dead cell. More importantly, during lactic acid exposure we observed structural modifications at the level of cell wall and membrane. These findings confirmed the peculiar ability of Z. parabailii to adapt to the weak acids via remodeling of cellular components. The lack of a complete genome assembly and annotation encouraged us to perform a genome sequencing and genome study of our Z. parabailii strain. The results revealed that Z. parabailii is undergoing fertility restoration after interspecies hybridization event, which may shed a light to the process of whole genome duplication. The availability of Z. parabailii complete genome information allowed us to perform the first RNA-sequencing analysis on the species exposed to lactic acid stress. The results showed upregulation of mitochondrial and oxidative stress genes, and downregulation of a subset of cell wall genes, in addition to other specific regulations related to redox balance and ion homeostasis. Remarkably, several differentially regulated genes differ significantly from the S. cerevisiae counterpart or even seems not to have a homologue. Increased interest of K. marxianus application in industrial biotechnology led us to study its multidrug resistance transporters during acetic and lactic acid stress. The results showed a strain specific response to weak organic acid stress, and a possible involvement of KmPDR12 in acetic and lactic acid stress resistance, opening possibility for future discoveries and novel studies.

Published

2017

13. Assessing physio-macromolecular effects of lactic acid on Zygosaccharomyces bailii cells during microaerobic fermentation

Author

Paola Branduardi, Diletta Ami, John P. Morrissey, Lorenzo Signori, Nurzhan Kuanyshev, Danilo Porro, Kuanyshev, N, Ami, D, Signori, L, Porro, D, Morrissey, J, and Branduardi, P

Subjects

0301 basic medicine, Chemical Phenomena, Protein Conformation, Zygosaccharomyces bailii, Saccharomyces cerevisiae, Bioreactor, Zygosaccharomyces, Microbiology, Applied Microbiology and Biotechnology, Cell wall, Fungal Proteins, 03 medical and health sciences, chemistry.chemical_compound, Bioreactors, Cell Wall, Stress, Physiological, Spectroscopy, Fourier Transform Infrared, Propidium iodide, Anaerobiosis, Lactic Acid, Microbial Viability, biology, Staining and Labeling, Medicine (all), Cell Membrane, food and beverages, General Medicine, Hydrogen-Ion Concentration, biology.organism_classification, CHIM/11 - CHIMICA E BIOTECNOLOGIA DELLE FERMENTAZIONI, Yeast, Lactic acid, Culture Media, 030104 developmental biology, chemistry, Biochemistry, FTIR, Fermentation, Propidium

Abstract

The ability of Zygosaccharomyces bailii to grow at low pH and in the presence of considerable amounts of weak organic acids, at lethal condition for Saccharomyces cerevisiae , increased the interest in the biotechnological potential of the yeast. To understand the mechanism of tolerance and growth effect of weak acids on Z. bailii , we evaluated the physiological and macromolecular changes of the yeast exposed to sub lethal concentrations of lactic acid. Lactic acid represents one of the important commodity chemical which can be produced by microbial fermentation. We assessed physiological effect of lactic acid by bioreactor fermentation using synthetic media at low pH in the presence of lactic acid. Samples collected from bioreactors were stained with propidium iodide (PI) which revealed that, despite lactic acid negatively influence the growth rate, the number of PI positive cells is similar to that of the control. Moreover, we have performed Fourier Transform Infra-Red (FTIR) microspectroscopy analysis on intact cells of the same samples. This technique has been never applied before to study Z. bailii under this condition. The analyses revealed lactic acid induced macromolecular changes in the overall cellular protein secondary structures, and alterations of cell wall and membrane physico-chemical properties.

Published

2016

14. Evolutionary restoration of fertility in an interspecies hybrid yeast, by whole-genome duplication after a failed mating-type switch

Author

Kevin P. Byrne, Danilo Porro, Nurzhan Kuanyshev, Stephanie Braun-Galleani, Kenneth H. Wolfe, Raúl A. Ortiz-Merino, Paola Branduardi, Ortiz-merino, R, Kuanyshev, N, Braun-galleani, S, Byrne, K, Porro, D, Branduardi, P, and Wolfe, K

Subjects

0301 basic medicine, Mating type, Zygosaccharomyce, Immunology and Microbiology (all), Intron, Loss of Heterozygosity, Yeast and Fungal Models, Haploidy, Fungal Reproduction, Gene Duplication, Gene duplication, Biology (General), Centromeres, Gene Rearrangement, Genetics, biology, Chromosome Biology, General Neuroscience, Fungal genetics, Genomics, CHIM/11 - CHIMICA E BIOTECNOLOGIA DELLE FERMENTAZIONI, Biological Evolution, Experimental Organism Systems, Saccharomyces Cerevisiae, Genome, Fungal, General Agricultural and Biological Sciences, Research Article, Chromosome Structure and Function, QH301-705.5, 030106 microbiology, Saccharomyces cerevisiae, BIO/18 - GENETICA, Locus (genetics), Mycology, Chromosomal rearrangement, Research and Analysis Methods, Genome Complexity, Chromosomes, General Biochemistry, Genetics and Molecular Biology, Saccharomyces, 03 medical and health sciences, Model Organisms, Meiosis, Gene Silencing, Fungal Spores, Neuroscience (all), Biochemistry, Genetics and Molecular Biology (all), Sequence Assembly Tools, General Immunology and Microbiology, Organisms, Fungi, Zygosaccharomyces, Biology and Life Sciences, Computational Biology, Cell Biology, Gene rearrangement, Genome Analysis, Genes, Mating Type, Fungal, biology.organism_classification, Yeast, Introns, Fertility, 030104 developmental biology, Agricultural and Biological Sciences (all), Genetic Loci, Hybridization, Genetic

Abstract

Many interspecies hybrids have been discovered in yeasts, but most of these hybrids are asexual and can replicate only mitotically. Whole-genome duplication has been proposed as a mechanism by which interspecies hybrids can regain fertility, restoring their ability to perform meiosis and sporulate. Here, we show that this process occurred naturally during the evolution of Zygosaccharomyces parabailii, an interspecies hybrid that was formed by mating between 2 parents that differed by 7% in genome sequence and by many interchromosomal rearrangements. Surprisingly, Z. parabailii has a full sexual cycle and is genetically haploid. It goes through mating-type switching and autodiploidization, followed by immediate sporulation. We identified the key evolutionary event that enabled Z. parabailii to regain fertility, which was breakage of 1 of the 2 homeologous copies of the mating-type (MAT) locus in the hybrid, resulting in a chromosomal rearrangement and irreparable damage to 1 MAT locus. This rearrangement was caused by HO endonuclease, which normally functions in mating-type switching. With 1 copy of MAT inactivated, the interspecies hybrid now behaves as a haploid. Our results provide the first demonstration that MAT locus damage is a naturally occurring evolutionary mechanism for whole-genome duplication and restoration of fertility to interspecies hybrids. The events that occurred in Z. parabailii strongly resemble those postulated to have caused ancient whole-genome duplication in an ancestor of Saccharomyces cerevisiae., Author summary It has recently been proposed that the whole-genome duplication (WGD) event that occurred during evolution of an ancestor of the yeast S. cerevisiae was the result of a hybridization between 2 parental yeast species that were significantly divergent in DNA sequence, followed by a doubling of the genome content to restore the hybrid’s ability to make viable spores. However, the molecular details of how genome doubling could occur in a hybrid were unclear because most known interspecies hybrid yeasts have no sexual cycle. We show here that Z. parabailii provides an almost exact precedent for the steps proposed to have occurred during the S. cerevisiae WGD. Two divergent haploid parental species, each with 8 chromosomes, mated to form a hybrid that was initially sterile but regained fertility when 1 copy of its mating-type locus became damaged by the mating-type switching apparatus. As a result of this damage, the Z. parabailii life cycle now consists of a 16-chromosome haploid phase and a transient 32-chromosome diploid phase. Each pair of homeologous genes behaves as 2 independent Mendelian loci during meiosis.

Published

2017

15. Compositional and temporal division of labor modulates mixed sugar fermentation by an engineered yeast consortium.

Author

Shin J, Liao S, Kuanyshev N, Xin Y, Kim C, Lu T, and Jin YS

Subjects

Fermentation, Xylose chemistry, Glucose, Saccharomyces cerevisiae genetics, Ecosystem

Abstract

Synthetic microbial communities have emerged as an attractive route for chemical bioprocessing. They are argued to be superior to single strains through microbial division of labor (DOL), but the exact mechanism by which DOL confers advantages remains unclear. Here, we utilize a synthetic Saccharomyces cerevisiae consortium along with mathematical modeling to achieve tunable mixed sugar fermentation to overcome the limitations of single-strain fermentation. The consortium involves two strains with each specializing in glucose or xylose utilization for ethanol production. By controlling initial community composition, DOL allows fine tuning of fermentation dynamics and product generation. By altering inoculation delay, DOL provides additional programmability to parallelly regulate fermentation characteristics and product yield. Mathematical models capture observed experimental findings and further offer guidance for subsequent fermentation optimization. This study demonstrates the functional potential of DOL in bioprocessing and provides insight into the rational design of engineered ecosystems for various applications., (© 2024. The Author(s).)

Published

2024

16. Cas9-Based Metabolic Engineering of Issatchenkia orientalis for Enhanced Utilization of Cellulosic Hydrolysates.

Author

Lee YG, Kim C, Kuanyshev N, Kang NK, Fatma Z, Wu ZY, Cheng MH, Singh V, Yoshikuni Y, Zhao H, and Jin YS

Subjects

Aldehyde Reductase genetics, CRISPR-Cas Systems, D-Xylulose Reductase genetics, Ethanol metabolism, Fermentation, Nitrogen metabolism, Pichia, Saccharomyces cerevisiae metabolism, Metabolic Engineering methods, Xylose metabolism

Abstract

Issatchenkia orientalis , exhibiting high tolerance against harsh environmental conditions, is a promising metabolic engineering host for producing fuels and chemicals from cellulosic hydrolysates containing fermentation inhibitors under acidic conditions. Although genetic tools for I. orientalis exist, they require auxotrophic mutants so that the selection of a host strain is limited. We developed a drug resistance gene (cloNAT)-based genome-editing method for engineering any I. orientalis strains and engineered I. orientalis strains isolated from various sources for xylose fermentation. Specifically, xylose reductase, xylitol dehydrogenase, and xylulokinase from Scheffersomyces stipitis were integrated into an intended chromosomal locus in four I. orientalis strains (SD108, IO21, IO45, and IO46) through Cas9-based genome editing. The resulting strains (SD108X, IO21X, IO45X, and IO46X) efficiently produced ethanol from cellulosic and hemicellulosic hydrolysates even though the pH adjustment and nitrogen source were not provided. As they presented different fermenting capacities, selection of a host I. orientalis strain was crucial for producing fuels and chemicals using cellulosic hydrolysates.

Published

2022

17. Identification and analysis of sugar transporters capable of co-transporting glucose and xylose simultaneously.

Author

Kuanyshev N, Deewan A, Jagtap SS, Liu J, Selvam B, Chen LQ, Shukla D, Rao CV, and Jin YS

Subjects

Arabidopsis genetics, Fermentation, Kinetics, Lipomyces genetics, Saccharomyces cerevisiae genetics, Arabidopsis enzymology, Arabidopsis Proteins genetics, Glucose, Lipomyces enzymology, Monosaccharide Transport Proteins genetics, Xylose

Abstract

Simultaneous co-fermentation of glucose and xylose is a key desired trait of engineered Saccharomyces cerevisiae for efficient and rapid production of biofuels and chemicals. However, glucose strongly inhibits xylose transport by endogenous hexose transporters of S. cerevisiae. We identified structurally distant sugar transporters (Lipomyces starkeyi LST1_205437 and Arabidopsis thaliana AtSWEET7) capable of co-transporting glucose and xylose from previously unexplored oleaginous yeasts and plants. Kinetic analysis showed that LST1_205437 had lenient glucose inhibition on xylose transport and AtSWEET7 transported glucose and xylose simultaneously with no inhibition. Modelling studies of LST1_205437 revealed that Ala335 residue at sugar binding site can accommodates both glucose and xylose. Docking studies with AtSWEET7 revealed that Trp59, Trp183, Asn145, and Asn179 residues stabilized the interactions with sugars, allowing both xylose and glucose to be co-transported. In addition, we altered sugar preference of LST1_205437 by single amino acid mutation at Asn365. Our findings provide a new mechanistic insight on glucose and xylose transport mechanism of sugar transporters and the identified sugar transporters can be employed to develop engineered yeast strains for producing cellulosic biofuels and chemicals., (© 2021 Wiley-VCH GmbH.)

Published

2021

18. Domesticating a food spoilage yeast into an organic acid-tolerant metabolic engineering host: Lactic acid production by engineered Zygosaccharomyces bailii.

Author

Kuanyshev N, Rao CV, Dien B, and Jin YS

Subjects

Fungal Proteins genetics, Fungal Proteins metabolism, L-Lactate Dehydrogenase genetics, L-Lactate Dehydrogenase metabolism, Rhizopus oryzae enzymology, Rhizopus oryzae genetics, Lactic Acid biosynthesis, Metabolic Engineering, Saccharomycetales genetics, Saccharomycetales metabolism

Abstract

Lactic acid represents an important class of commodity chemicals, which can be produced by microbial cell factories. However, due to the toxicity of lactic acid at lower pH, microbial production requires the usage of neutralizing agents to maintain neutral pH. Zygosaccharomyces bailii, a food spoilage yeast, can grow under the presence of organic acids used as food preservatives. This unique trait of the yeast might be useful for producing lactic acid. With the goal of domesticating the organic acid-tolerant yeast as a metabolic engineering host, seven Z. bailii strains were screened in a minimal medium with 10 g/L of acetic, or 60 g/L of lactic acid at pH 3. The Z. bailii NRRL Y7239 strain was selected as the most robust strain to be engineered for lactic acid production. By applying a PAN-ARS-based CRISPR-Cas9 system consisting of a transfer RNA promoter and NAT selection, we demonstrated the targeted deletion of ADE2 and site-specific integration of Rhizopus oryzae ldhA coding for lactate dehydrogenase into the PDC1 locus. The resulting pdc1::ldhA strain produced 35 g/L of lactic acid without ethanol production. This study demonstrates the feasibility of the CRISPR-Cas9 system in Z. bailii, which can be applied for a fundamental study of the species., (© 2020 Wiley Periodicals LLC.)

Published

2021

19. Transcriptional Response to Lactic Acid Stress in the Hybrid Yeast Zygosaccharomyces parabailii.

Author

Ortiz-Merino RA, Kuanyshev N, Byrne KP, Varela JA, Morrissey JP, Porro D, Wolfe KH, and Branduardi P

Subjects

RNA, Fungal analysis, RNA, Messenger analysis, Sequence Analysis, RNA, Stress, Physiological, Zygosaccharomyces genetics, Lactic Acid metabolism, Transcription, Genetic physiology, Zygosaccharomyces physiology

Abstract

Lactic acid has a wide range of applications starting from its undissociated form, and its production using cell factories requires stress-tolerant microbial hosts. The interspecies hybrid yeast Zygosaccharomyces parabailii has great potential to be exploited as a novel host for lactic acid production, due to high organic acid tolerance at low pH and a fermentative metabolism with a high growth rate. Here we used mRNA sequencing (RNA-seq) to analyze Z. parabailii 's transcriptional response to lactic acid added exogenously, and we explore the biological mechanisms involved in tolerance. Z. parabailii contains two homeologous copies of most genes. Under lactic acid stress, the two genes in each homeolog pair tend to diverge in expression to a significantly greater extent than under control conditions, indicating that stress tolerance is facilitated by interactions between the two gene sets in the hybrid. Lactic acid induces downregulation of genes related to cell wall and plasma membrane functions, possibly altering the rate of diffusion of lactic acid into cells. Genes related to iron transport and redox processes were upregulated, suggesting an important role for respiratory functions and oxidative stress defense. We found differences in the expression profiles of genes putatively regulated by Haa1 and Aft1/Aft2, previously described as lactic acid responsive in Saccharomyces cerevisiae Furthermore, formate dehydrogenase ( FDH ) genes form a lactic acid-responsive gene family that has been specifically amplified in Z. parabailii in comparison to other closely related species. Our study provides a useful starting point for the engineering of Z. parabailii as a host for lactic acid production. IMPORTANCE Hybrid yeasts are important in biotechnology because of their tolerance to harsh industrial conditions. The molecular mechanisms of tolerance can be studied by analyzing differential gene expression under conditions of interest and relating gene expression patterns to protein functions. However, hybrid organisms present a challenge to the standard use of mRNA sequencing (RNA-seq) to study transcriptional responses to stress, because their genomes contain two similar copies of almost every gene. Here we used stringent mapping methods and a high-quality genome sequence to study the transcriptional response to lactic acid stress in Zygosaccharomyces parabailii ATCC 60483, a natural interspecies hybrid yeast that contains two complete subgenomes that are approximately 7% divergent in sequence. Beyond the insights we gained into lactic acid tolerance in this study, the methods we developed will be broadly applicable to other yeast hybrid strains., (Copyright © 2018 Ortiz-Merino et al.)

Published

2018

20. The spoilage yeast Zygosaccharomyces bailii: Foe or friend?

Author

Kuanyshev N, Adamo GM, Porro D, and Branduardi P

Subjects

Acetic Acid pharmacology, Adaptation, Physiological, Diethyl Pyrocarbonate analogs & derivatives, Diethyl Pyrocarbonate pharmacology, Fermentation, Food, Preserved microbiology, Hydrogen-Ion Concentration, Sorbic Acid pharmacology, Sulfites pharmacology, Wine microbiology, Zygosaccharomyces genetics, Zygosaccharomyces metabolism, Drug Resistance, Fungal, Food Contamination prevention & control, Food Preservatives pharmacology, Zygosaccharomyces drug effects

Abstract

Zygosaccharomyces bailii is a non-Saccharomyces budding yeast known as one of the most aggressive food spoilage microorganisms, often isolated as a contaminant during wine fermentation, as well as from many acidic, high-sugar and canned foods. The spoilage ability relies on the yeast's unique feature of tolerating the most common preservatives such as sulphite, dimethyl dicarbonate, acetic acid and sorbic acid. Therefore, many studies have focused on the description of this peculiar tolerance with the aim of developing preventative measures against Z. bailii food spoilage. These studies demonstrated the involvement of diverse molecular and physiological mechanisms in the yeast resistance, comprising detoxification of preservatives, adaptation of the cytoplasmic pH and modulation of the cell wall/membrane composition. At the same time, the described traits unveiled Z. bailii as a novel potential workhorse for industrial bioprocesses. Here we present the yeast Z. bailii starting from important aspects of its robustness and concluding with the exploitation of its potential in biotechnology. Overall, the article describes Z. bailii from different perspectives, converging in presenting it as one of the most interesting species of the Saccharomycotina subphylum. Copyright © 2017 John Wiley & Sons, Ltd., (Copyright © 2017 John Wiley & Sons, Ltd.)

Published

2017

21. Evolutionary restoration of fertility in an interspecies hybrid yeast, by whole-genome duplication after a failed mating-type switch.

Author

Ortiz-Merino RA, Kuanyshev N, Braun-Galleani S, Byrne KP, Porro D, Branduardi P, and Wolfe KH

Subjects

Fertility genetics, Gene Rearrangement, Gene Silencing, Genes, Mating Type, Fungal genetics, Haploidy, Introns, Loss of Heterozygosity, Biological Evolution, Gene Duplication, Genome, Fungal, Hybridization, Genetic, Zygosaccharomyces genetics

Abstract

Many interspecies hybrids have been discovered in yeasts, but most of these hybrids are asexual and can replicate only mitotically. Whole-genome duplication has been proposed as a mechanism by which interspecies hybrids can regain fertility, restoring their ability to perform meiosis and sporulate. Here, we show that this process occurred naturally during the evolution of Zygosaccharomyces parabailii, an interspecies hybrid that was formed by mating between 2 parents that differed by 7% in genome sequence and by many interchromosomal rearrangements. Surprisingly, Z. parabailii has a full sexual cycle and is genetically haploid. It goes through mating-type switching and autodiploidization, followed by immediate sporulation. We identified the key evolutionary event that enabled Z. parabailii to regain fertility, which was breakage of 1 of the 2 homeologous copies of the mating-type (MAT) locus in the hybrid, resulting in a chromosomal rearrangement and irreparable damage to 1 MAT locus. This rearrangement was caused by HO endonuclease, which normally functions in mating-type switching. With 1 copy of MAT inactivated, the interspecies hybrid now behaves as a haploid. Our results provide the first demonstration that MAT locus damage is a naturally occurring evolutionary mechanism for whole-genome duplication and restoration of fertility to interspecies hybrids. The events that occurred in Z. parabailii strongly resemble those postulated to have caused ancient whole-genome duplication in an ancestor of Saccharomyces cerevisiae.

Published

2017

22. Assessing physio-macromolecular effects of lactic acid on Zygosaccharomyces bailii cells during microaerobic fermentation.

Author

Kuanyshev N, Ami D, Signori L, Porro D, Morrissey JP, and Branduardi P

Subjects

Anaerobiosis, Bioreactors microbiology, Cell Membrane chemistry, Cell Membrane drug effects, Cell Membrane physiology, Cell Wall chemistry, Cell Wall drug effects, Cell Wall physiology, Chemical Phenomena, Culture Media chemistry, Fungal Proteins chemistry, Hydrogen-Ion Concentration, Propidium analysis, Protein Conformation, Spectroscopy, Fourier Transform Infrared, Staining and Labeling, Zygosaccharomyces growth & development, Fermentation, Lactic Acid metabolism, Lactic Acid toxicity, Microbial Viability drug effects, Stress, Physiological, Zygosaccharomyces drug effects, Zygosaccharomyces physiology

Abstract

The ability of Zygosaccharomyces bailii to grow at low pH and in the presence of considerable amounts of weak organic acids, at lethal condition for Saccharomyces cerevisiae, increased the interest in the biotechnological potential of the yeast. To understand the mechanism of tolerance and growth effect of weak acids on Z. bailii, we evaluated the physiological and macromolecular changes of the yeast exposed to sub lethal concentrations of lactic acid. Lactic acid represents one of the important commodity chemical which can be produced by microbial fermentation. We assessed physiological effect of lactic acid by bioreactor fermentation using synthetic media at low pH in the presence of lactic acid. Samples collected from bioreactors were stained with propidium iodide (PI) which revealed that, despite lactic acid negatively influence the growth rate, the number of PI positive cells is similar to that of the control. Moreover, we have performed Fourier Transform Infra-Red (FTIR) microspectroscopy analysis on intact cells of the same samples. This technique has been never applied before to study Z. bailii under this condition. The analyses revealed lactic acid induced macromolecular changes in the overall cellular protein secondary structures, and alterations of cell wall and membrane physico-chemical properties., (© FEMS 2016. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2016