Your search keyword '"Ethanol stress"' showing total 340 results

1. Heat Shock Factor 1 forms nuclear condensates and restructures the yeast genome before activating target genes

Author

Linda S Rubio, Suman Mohajan, and David S Gross

Subjects

heat shock response, 3D genome, transcriptional condensates, chromatin, RNA Pol II, ethanol stress, Medicine, Science, Biology (General), QH301-705.5

Abstract

In insects and mammals, 3D genome topology has been linked to transcriptional states yet whether this link holds for other eukaryotes is unclear. Using both ligation proximity and fluorescence microscopy assays, we show that in Saccharomyces cerevisiae, Heat Shock Response (HSR) genes dispersed across multiple chromosomes and under the control of Heat Shock Factor (Hsf1) rapidly reposition in cells exposed to acute ethanol stress and engage in concerted, Hsf1-dependent intergenic interactions. Accompanying 3D genome reconfiguration is equally rapid formation of Hsf1-containing condensates. However, in contrast to the transience of Hsf1-driven intergenic interactions that peak within 10–20 min and dissipate within 1 hr in the presence of 8.5% (v/v) ethanol, transcriptional condensates are stably maintained for hours. Moreover, under the same conditions, Pol II occupancy of HSR genes, chromatin remodeling, and RNA expression are detectable only later in the response and peak much later (>1 hr). This contrasts with the coordinate response of HSR genes to thermal stress (39°C) where Pol II occupancy, transcription, histone eviction, intergenic interactions, and formation of Hsf1 condensates are all rapid yet transient (peak within 2.5–10 min and dissipate within 1 hr). Therefore, Hsf1 forms condensates, restructures the genome and transcriptionally activates HSR genes in response to both forms of proteotoxic stress but does so with strikingly different kinetics. In cells subjected to ethanol stress, Hsf1 forms condensates and repositions target genes before transcriptionally activating them.

Published

2024

2. Exogenous trehalose application promotes survival by alleviating oxidative stress and affecting transcriptome in ethanol-stressed Wickerhamomyces anomalus

Author

Li, Yinfeng, Jiang, Guilan, Long, Hua, Liao, Yifa, Huang, Mingzheng, Yu, Zhihai, Cheng, Shuang, Wang, Ying, and Liu, Xiaozhu

Published

2023

3. 乳酸菌的乙醇耐受机制及其在食醋生产中的应用.

Author

张霖, 夏程程, 王文悦, 余帆, 肖柯, 易弛, 樊鑫, 朱晓青, 肖俊锋, 李琴, 汪超, 穆杨, and 周梦舟

Abstract

Copyright of Modern Food Science & Technology is the property of Editorial Office of Modern Food Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

4. Study on the mechanism on synthesis of higher alcohols in Wickerhamomyces anomalus under ethanol stress.

Author

Chen, Yanru, Wan, Yin, Cai, Wenqin, Che, Xiaming, Peng, Hong, and Fu, Guiming

Subjects

*ETHANOL, *ALCOHOL, *STRESS concentration, *GENETIC engineering, *GENE families

Abstract

Higher alcohols (phenylethyl alcohol and isoamyl alcohol), as the crucial aroma compounds, have been found to associate with the sensory properties of various alcoholic products. The Ehrlich and Harris pathways are the main pathways for yeast to produce phenylethyl alcohol and isoamyl alcohol during the brewing process of alcoholic products, whereas the specific changes of the Ehrlich and Harris pathways in Wickerhamomyces anomalus under ethanol stress are still unclear. In this study, W. anomalus NCU003 with a high capacity for aroma compound production was treated with ethanol stress at different concentrations (3%, v/v, 6%, v/v and 9%, v/v) to study the effects on the expression levels of genes and metabolite content in the Ehrlich and Harris pathways. The results found that ethanol stress inhibited the production of phenylethyl alcohol and isoamyl alcohol, and the content decreased with the increase of ethanol concentrations. In the meantime, the up‐regulation of ARO1, CS, ARO8, Leu1, BAT2 and ilvs family genes in the Ehrlich and Harris pathways could lead to an increase in the synthesis of important precursor substances during the synthesis of phenylethyl alcohol and isoamyl alcohol. However, the significant down‐regulation of ARO10, PDC, ADH1 and AHD2 genes was the main reason for the low production of phenylethyl alcohol and isoamyl alcohol. These results could provide a theoretical reference for the construction of genetic engineering strains of W. anomalus in the future so as to reasonably control the content of higher alcohols during the brewing process of alcoholic products. [ABSTRACT FROM AUTHOR]

Published

2024

5. Adenine DNA methylation is involved in regulating ethanol and osmotic stress responses in Lacticaseibacillus paracasei Zhang

Author

Jiaming Yan, Meiling Wu, Lai‐Yu Kwok, and Wenyi Zhang

Subjects

adenine methylation, bacteriophage exclusion system, ethanol stress, Lacticaseibacillus paracasei, osmotic stress, pglX gene, Nutrition. Foods and food supply, TX341-641, Food processing and manufacture, TP368-456

Abstract

Abstract As an important feature of epigenetics, DNA methylation is a critical way to regulate gene expression and thus bacterial growth and metabolism. Lacticaseibacillus paracasei Zhang is a probiotic strain originated from koumiss. This study hypothesized that adenine methylation was involved in bacterial regulation of physiological adaptations when grown under environmental stress. Thus, this study compared the growth of an adenine methyltransferase‐inactivated mutant (ΔpglX) and the wild‐type L. paracasei Zhang when cultured under ethanol and osmotic stress. Transcriptomic and proteomic analyses were implemented to identify their differentially expressed genes/proteins (DEGs/DEPs) when grown under the stressed environments. The membrane fatty acid composition was also determined. Comparing with the wild‐type, the viable counts of the mutant under ethanol and osmotic stress increased by 2.6 times and decreased by half, respectively (ethanol stress: mutant, 4.30 ± 0.0038 × 108 CFU/mL; wild‐type, 1.64 ± 0.010 × 108 CFU/mL; osmotic stress: mutant, 2.21 ± 0.029 × 108 CFU/mL; wild‐type, 4.30 ± 0.13 × 108 CFU/mL). Common to both conditions, many identified DEGs and DEPs were involved in carbohydrate metabolism and fatty acid biosynthesis, generally, with more carbohydrate metabolism pathways but fewer fatty acid biosynthesis pathways, accompanied by increases in the membrane fatty acids. Our observations suggested that L. paracasei Zhang maximizes its energy metabolism by enhancing carbohydrate metabolism and improves its membrane strength via increasing the fatty acid content under environmental stress. This is the first report analyzing the epigenetic‐level stress responsive mechanism of L. paracasei Zhang, providing insights into methylation‐based regulation of bacterial adaptive responses.

Published

2023

6. Contribution of trehalose to ethanol stress tolerance of Wickerhamomyces anomalus

Author

Yinfeng Li, Guilan Jiang, Hua Long, Yifa Liao, Liuliu Wu, Wenyue Huang, and Xiaozhu Liu

Subjects

Wickerhamomyces anomalus, Ethanol stress, Trehalose, Transcriptomics, Antioxidant, Microbiology, QR1-502

Abstract

Abstract Background The ascomycetous heterothallic yeast Wickerhamomyces anomalus (WA) has received considerable attention and has been widely reported in the winemaking industry for its distinctive physiological traits and metabolic attributes. An increased concentration of ethanol during ethanol fermentation, however, causes ethanol stress (ES) on the yeast cells. Trehalose has been implicated in improving survival under various stress conditions in microorganisms. Herein, we determined the effects of trehalose supplementation on the survival, differentially expressed genes (DEGs), cellular morphology, and oxidative stress tolerance of WA in response to ES. Results The results indicated that trehalose improved the survival and anomalous surface and ultrastructural morphology of WA. Additionally, trehalose improved redox homeostasis by reducing the levels of reactive oxygen species (ROS) and inducing the activities of antioxidant enzymes. In addition, DEGs affected by the application of trehalose were enriched in these categories including in gene expression, protein synthesis, energy metabolism, and cell cycle pathways. Additionally, trehalose increased the content of intracellular malondialdehyde (MDA) and adenosine triphosphate. Conclusions These results reveal the protective role of trehalose in ES mitigation and strengthen the possible uses of WA in the wine fermentation sector.

Published

2023

7. Transcriptome profiling brings new insights into the ethanol stress responses of Spathaspora passalidarum.

Author

Albuini, Fernanda Matias, de Castro, Alex Gazolla, Campos, Valquíria Júnia, Ribeiro, Lílian Emídio, Vidigal, Pedro Marcus Pereira, de Oliveira Mendes, Tiago Antônio, and Fietto, Luciano Gomes

Subjects

*ETHANOL, *TRANSCRIPTOMES, *LIPID metabolism, *LIGNOCELLULOSE, *MEMBRANE lipids, *OSMOTIC pressure, *CELL morphology

Abstract

Spathaspora passalidarum is a xylose-fermenting microorganism promising for the fermentation of lignocellulosic hydrolysates. This yeast is more sensitive to ethanol than Saccharomyces cerevisiae for unclear reasons. An RNA-seq experiment was performed to identify transcriptional changes in S. passalidarum in response to ethanol and gain insights into this phenotype. The results showed the upregulation of genes associated with translation and the downregulation of genes encoding proteins involved in lipid metabolism, transporters, and enzymes from glycolysis and fermentation pathways. Our results also revealed that genes encoding heat-shock proteins and involved in antioxidant response were upregulated, whereas the osmotic stress response of S. passalidarum appears impaired under ethanol stress. A pseudohyphal morphology of S. passalidarum colonies was observed in response to ethanol stress, which suggests that ethanol induces a misperception of nitrogen availability in the environment. Changes in the yeast fatty acid profile were observed only after 12 h of ethanol exposure, coinciding with the recovery of the yeast xylose consumption ability. These findings suggest that the lack of fast membrane lipid adjustments, the halt in nutrient absorption and cellular metabolism, and the failure to induce the expression of osmotic stress-responsive genes are the main aspects underlying the low ethanol tolerance of S. passalidarum. Key points: • Ethanol stress halts Spathaspora passalidarum metabolism and fermentation • Genes encoding nutrient transporters showed downregulation under ethanol stress • Ethanol induces a pseudohyphal cell shape, suggesting a misperception of nutrients [ABSTRACT FROM AUTHOR]

Published

2023

8. Oxidative Phosphorylation for Aerobic Survival, but Not for Growth: The Peculiar 'Make-Accumulate-Consume' Strategy in Zymomonas mobilis.

Author

Strazdina, Inese, Bikerniece, Mara, Paegle, Evelina Rezija, Shvirksts, Karlis, Grube, Mara, Lasa, Zane, Rutkis, Reinis, and Kalnenieks, Uldis

Subjects

ZYMOMONAS mobilis, OXIDATIVE phosphorylation, NADH dehydrogenase, GREEN fluorescent protein, ADENOSINE triphosphatase, METABOLIC regulation

Abstract

Understanding the energy metabolism and its regulation is one of the clues to metabolic engineering of stress-resistant lignocellulose-converting microbial strains, also including the promising ethanologen Zymomonas mobilis. Z. mobilis is an obligately fermentative, facultatively anaerobic bacterium, carrying an active respiratory chain with low energy-coupling efficiency. Its respiration does not supply energy to aerobically growing cultures on sugary media, yet oxidative phosphorylation has been demonstrated in non-growing cells with ethanol. Here, we show, for the first time, that in respiring, non-growing Z. mobilis cells receiving regular small amounts of ethanol, oxidative phosphorylation significantly contributes to the maintenance of their viability. No improvement of viability is seen in the NADH dehydrogenase (ndh)-deficient respiratory mutant, which is unable to oxidize ethanol. The ethanol effect is also hampered by the protonophoric uncoupler CCCP, or the inhibitor of ATP synthase, DCCD. At higher concentrations (6% v/v), ethanol causes stress that slows down culture growth. By monitoring the activity of several respiratory gene promoters under ethanol stress with the green fluorescent protein reporter system, we demonstrate downregulation of these promoters, in particular the ndh promoter. We speculate that the decrease in respiratory chain activity in response to stress conditions mitigates the production of reactive oxygen species. [ABSTRACT FROM AUTHOR]

Published

2023

9. Exogenous Thiamine Application Improves the Survival ofWickerhamomyces anomalusunder Ethanol Stress.

Author

Li, Y. F., Jiang, G. L., Liao, Y. F., Long, H., and Liu, X. Z.

Subjects

*VITAMIN B1, *WATER-soluble vitamins, *ATP-binding cassette transporters, *OXIDATIVE phosphorylation, *ETHANOL, *FOLIC acid

Abstract

All living organisms require thiamine, a water-soluble vitamin, which is also reported to play a role in response to various abiotic stresses. However, the impact of thiamine on the growth of Wickerhamomyces anomalus under ethanol stress is still not completely understood. In this study, we investigated the effects of exogenous thiamine application on the growth of W. anomalus under ethanol stress. We also investigated how thiamine affected the differentially expressed metabolites (DEMs) using a non-targeted metabolomics approach. The results showed that exogenous thiamine application improved the growth of ethanol-stressed W. anomalus. The DEMs affected by exogenous thiamine application were significantly enriched as ABC transporters process, glycerophospholipid metabolism, purine metabolism, and one carbon pool via folate and sulfur relay system using Kyoto Encyclopedia of Genes and Genomics (KEGG) enrichment analysis. Several pathways, such as arginine biosynthesis, cell cycle, oxidative phosphorylation, etc., were also regulated by thiamine because they were not enriched after exogenous thiamine application. Therefore, thiamine helped to protect W. anomalus from the effects of ethanol stress. These findings offer a theoretical basis for further understanding the regulatory mechanism of thiamine-mediated ethanol stress tolerance in W. anomalus. [ABSTRACT FROM AUTHOR]

Published

2023

10. Cellular Stress Impact on Yeast Activity in Biotechnological Processes—A Short Overview.

Author

Postaru, Madalina, Tucaliuc, Alexandra, Cascaval, Dan, and Galaction, Anca-Irina

Subjects

YEAST, MICROBIAL biotechnology, CELLULAR aging, SACCHAROMYCES cerevisiae, ANAEROBIC microorganisms, PHYSIOLOGICAL stress, ETHANOL as fuel

Abstract

The importance of Saccharomyces cerevisiae yeast cells is known worldwide, as they are the most used microorganisms in biotechnology for bioethanol and biofuel production. Also, they are analyzed and studied for their similar internal biochemical processes to human cells, for a better understanding of cell aging and response to cell stressors. The special ability of S. cerevisiae cells to develop in both aerobic and anaerobic conditions makes this microorganism a viable model to study the transformations and the way in which cellular metabolism is directed to face the stress conditions due to environmental changes. Thus, this review will emphasize the effects of oxidative, ethanol, and osmotic stress and also the physiological and genetic response of stress mitigation in yeast cells. [ABSTRACT FROM AUTHOR]

Published

2023

11. Contribution of trehalose to ethanol stress tolerance of Wickerhamomyces anomalus.

Author

Li, Yinfeng, Jiang, Guilan, Long, Hua, Liao, Yifa, Wu, Liuliu, Huang, Wenyue, and Liu, Xiaozhu

Subjects

*TREHALOSE, *HOMEOSTASIS, *ADENOSINE triphosphate, *REACTIVE oxygen species, *GENE expression, *ENERGY metabolism, *ETHANOL

Abstract

Background: The ascomycetous heterothallic yeast Wickerhamomyces anomalus (WA) has received considerable attention and has been widely reported in the winemaking industry for its distinctive physiological traits and metabolic attributes. An increased concentration of ethanol during ethanol fermentation, however, causes ethanol stress (ES) on the yeast cells. Trehalose has been implicated in improving survival under various stress conditions in microorganisms. Herein, we determined the effects of trehalose supplementation on the survival, differentially expressed genes (DEGs), cellular morphology, and oxidative stress tolerance of WA in response to ES. Results: The results indicated that trehalose improved the survival and anomalous surface and ultrastructural morphology of WA. Additionally, trehalose improved redox homeostasis by reducing the levels of reactive oxygen species (ROS) and inducing the activities of antioxidant enzymes. In addition, DEGs affected by the application of trehalose were enriched in these categories including in gene expression, protein synthesis, energy metabolism, and cell cycle pathways. Additionally, trehalose increased the content of intracellular malondialdehyde (MDA) and adenosine triphosphate. Conclusions: These results reveal the protective role of trehalose in ES mitigation and strengthen the possible uses of WA in the wine fermentation sector. [ABSTRACT FROM AUTHOR]

Published

2023

12. Probiotic properties and proteomics analysis of ethanol-induced Lactococcus lactis subsp. lactis IL1403.

Author

Chen, Sisi, Yi, Juanjuan, Suo, Keke, Kang, Qiaozhen, Lu, Laizheng, and Lu, Jike

Subjects

*LACTOCOCCUS lactis, *ETHANOL, *SUCROSE, *PROTEOMICS, *PROBIOTICS, *STARCH metabolism, *PROTEIN expression

Abstract

Our previous study indicated that ethanol-induced intracellular extracts (E-IEs) of Lactococcus lactis subsp. Lactis IL1403 (L. lactis IL1403) alleviated hangovers more effectively in mice than untreated intracellular extracts (U-IEs), but the material basis was unclear. Considering that stress-related proteins might play a significant role, the effects of ethanol induction on probiotic properties of L. lactis IL1403 and the associated stress response mechanism were initially explored in this study. E-IEs of L. lactis IL1403 showed better biological activities, significantly increased bacteria survival rates in oxidative stress environments, increased ADH activity, and enhanced proliferation in RAW264.7 and AML-12 cells. Proteomic analyses revealed that 414 proteins were significantly changed in response to ethanol induction. The expression of proteins involved in the universal stress response, DNA repair, oxidative stress response, and ethanol metabolism was rapidly upregulated under ethanol stress, and quantitative real-time PCR (qRT-PCR) results were consistent with proteomic data. KEGG pathway analysis indicated that citrate metabolism, starch and sucrose metabolism, and pyruvate metabolism were significantly enriched during ethanol stress to increase energy requirements and survival rates of stressed cells. Based on this observation, the active induction is an effective strategy for increasing the biological activity of L. lactis IL1403. Exploring the molecular mechanism and material basis of their functions in vivo can help us understand the adaptive regulatory mechanism of microorganisms. [ABSTRACT FROM AUTHOR]

Published

2023

13. Breeding of Fructilactobacillus sanfranciscensis with excellent ethanol tolerance based on adaptive evolution technology

Author

Yan Liu, Muhammad Danial, Huixin Dong, Min Zhang, Ru Jia, and Guohua Zhang

Subjects

adaptive laboratory evolution, ethanol stress, Fructilactobacillus sanfranciscensis, Food processing and manufacture, TP368-456

Abstract

Abstract Fructilactobacillus (F.) sanfranciscensis LS1 is one of the dominant strains in sourdough. Ethanol produced during fermentation is an inevitable stress factor for this stain. At present, the research on the mechanism of ethanol stress in lactic acid bacteria is limited compared to yeast species (particularly Saccharomyces (S.) cerevisiae). In this study microbial physiology and protein expression analysis technology was used. F. sanfranciscensis LS1 served as the original bacteria, and evolutionary bacteria LS1‐1 were obtained by adaptive evolution. The comparison of the two strains' growth, survival rate, morphology, hydrophobicity, cohesive force and protein expression revealed that the evolved bacteria had a significantly higher ethanol tolerance than the original bacteria. Similarly, the hydrophobicity of evolved bacteria was increased about 6.6 times than that of the original bacteria. With an increase in ethanol concentration, the level of damage on evolved bacteria was less, and the total proportion of damaged cells decreased. After 8 h of culturing, the self‐cohesion of the evolved strain was 1.29 times more than the original strain. Sodium dodecyl‐sulfate polyacrylamide gel electrophoresis analysis has shown that the number of protein bands of the evolved bacteria LS1‐1 increased significantly, indicating that the associated proteins were expressed more and the strain's ability to resist environmental pressure was improved.

Published

2023

14. Analysis of the ethanol stress response mechanism in Wickerhamomyces anomalus based on transcriptomics and metabolomics approaches

Author

Yinfeng Li, Hua Long, Guilan Jiang, Xun Gong, Zhihai Yu, Mingzheng Huang, Tianbing Guan, Yuanyuan Guan, and Xiaozhu Liu

Subjects

Ethanol stress, Growth, W. anomalus, Transcriptomics, Metabolomics, Microbiology, QR1-502

Abstract

Abstract Background Wickerhamomyces anomalus (W. anomalus) is a kind of non-Saccharomyces yeast that has a variety of unique physiological characteristics and metabolic features and is widely used in many fields, such as food preservation, biomass energy, and aquaculture feed protein production. However, the mechanism of W. anomalus response to ethanol stress is still unclear, which greatly limits its application in the production of ethanol beverages and ethanol fuels. Therefore, we checked the effects of ethanol stress on the morphology, the growth, and differentially expressed genes (DEGs) and metabolites (DEMs) of W. anomalus. Results High concentrations of ethanol (9% ethanol and 12% ethanol) remarkably inhibited the growth of W. anomalus. Energy metabolism, amino acid metabolism, fatty acids metabolism, and nucleic acid metabolism were significantly influenced when exposing to 9% ethanol and 12% ethanolstress, which maybe universal for W. anomalus to response to different concentrations of ethanol stressl Furthermore, extracellular addition of aspartate, glutamate, and arginine significantly abated ethanol damage and improved the survival rate of W. anomalus. Conclusions The results obtained in this study provide insights into the mechanisms involved in W. anomalus response to ethanol stress. Therefore, new strategies can be realized to improve the ethanol tolerance of W. anomalus through metabolic engineering.

Published

2022

15. Ethanol Enhances Astaxanthin Production by Aurantiochytrium sp. O5-1-1.

Author

Takaiku Sakamoto, Yusuke Ikeda, Naruho Masuda, and Eiji Sakuradani

Subjects

ASTAXANTHIN, ETHANOL, CAROTENOIDS, MICROALGAE

Abstract

Two-percent ethanol increased the astaxanthin productivity of heterotrophic microalgae Aurantiochytrium sp. O5-1-1 to 2.231 mg/L, 45-fold higher than under ethanol-free condition. Ethanol in the medium decreased at the same rate as spontaneous volatilization, suggesting that it was not a transient signaling factor but a continuous stress on the cells. The triply mutated strain OM3-3 produced 5.075 mg/L astaxanthin under 2% ethanol conditions. Furthermore, the astaxanthin accumulation of the mutant OM3-9 was 0.895 mg/g, which was 150-fold higher than that of strain O5-1-1 in ethanol-free condition. These results are beneficial for the commercial exploitation of carotenoids producing Aurantiochytrium spp. [ABSTRACT FROM AUTHOR]

Published

2023

16. Positive effect of ethanol-induced Lactococcus lactis on alcohol metabolism in mice

Author

Sisi Chen, Shimin Jia, Keke Suo, Qiaozhen Kang, Limin Hao, Laizheng Lu, Xin Liu, Jinyong Huang, and Jike Lu

Subjects

Ethanol stress, Intracellular extracts, Alcohol dehydrogenase, Alcohol metabolism, Nutrition. Foods and food supply, TX341-641

Abstract

It is well known that exposure to environmental stresses could enhance the adaptability of bacteria and up-regulate the expression of a variety of oxidative stress-related genes and antioxidant enzymes. It is unclear whether the adaptability of microorganisms formed naturally in special environments could transfer to other organisms. The study aimed to evaluate the effects of untreated and ethanol-induced Lactococcus lactis intracellular extracts (U-IE and E-IE) on alcohol metabolism in mice. The positive effects of E-IE on alcohol metabolism in mice were revealed by the enhanced latency of loss of righting reflex (LORR), the reduced duration of LORR, the decrease of blood alcohol concentration, as well as the elevation of alcohol dehydrogenase (ADH) activities in the stomach and liver tissues. Furthermore, the potential benefits of E-IE on the liver were evaluated by biochemical parameters including the activities of serum transaminase, the levels of antioxidant enzymes, and the pathological changes of liver tissue. The present work put forward a new point that appropriate ethanol stress could enhance the intracellular ADH activity of L. lactis, and its intracellular extracts could continue to enhance alcohol metabolism in mice.

Published

2022

17. Comparative Genomics Analysis Provides New Insights into High Ethanol Tolerance of Lactiplantibacillus pentosus LTJ12, a Novel Strain Isolated from Chinese Baijiu.

Author

Wang, Jiali, Lu, Chengshun, Xu, Qiang, Li, Zhongyuan, Song, Yajian, Zhou, Sa, Guo, Le, Zhang, Tongcun, and Luo, Xuegang

Subjects

ETHANOL, COMPARATIVE genomics, ALCOHOL dehydrogenase, LACTIC acid bacteria, GENOME size, CARBOHYDRATE metabolism

Abstract

Lactic acid bacteria have received a significant amount of attention due to their probiotic characteristics. The species Lactiplantibacillus plantarum and Lactiplantibacillus pentosus are genotypically closely related, and their phenotypes are so similar that they are easily confused and mistaken. In the previous study, an ethanol-resistant strain, LTJ12, isolated from the fermented grains of soy sauce aroma type baijiu in North China, was originally identified as L. plantarum through a 16S rRNA sequence analysis. Here, the genome of strain LTJ12 was further sequenced using PacBio and Illumina sequencing technology to obtain a better understanding of the metabolic pathway underlying its resistance to ethanol stress. The results showed that the genome of strain LTJ12 was composed of one circular chromosome and three circular plasmids. The genome size is 3,512,307 bp with a GC content of 46.37%, and the number of predicted coding genes is 3248. Moreover, by comparing the coding genes with the GO (Gene Ontology), COG (Cluster of Orthologous Groups) and KEGG (Kyoto Encyclopedia of Genes and Genomes) databases, the functional annotation of the genome and an assessment of the metabolic pathways were performed, with the results showing that strain LTJ12 has multiple genes that may be related to alcohol metabolism and probiotic-related genes. Antibiotic resistance gene analysis showed that there were few potential safety hazards. Further, after conducting the comparative genomics analysis, it was found that strain LTJ12 is L. pentosus but not L. plantarum, but it has more functional genes than other L. pentosus strains that are mainly related to carbohydrate transport and metabolism, transcription, replication, recombination and repair, signal transduction mechanisms, defense mechanisms and cell wall/membrane/envelope biogenesis. These unique functional genes, such as gene 2754 (encodes alcohol dehydrogenase), gene 3093 (encodes gamma-D-glutamyl-meso-diaminopimelate peptidase) and some others may enhance the ethanol tolerance and alcohol metabolism of the strain. Taken together, L. pentosus LTJ12 might be a potentially safe probiotic with a high ethanol tolerance and alcohol metabolism. The findings of this study will also shed light on the accurate identification and rational application of the Lactiplantibacillus species. [ABSTRACT FROM AUTHOR]

Published

2023

18. Cellular Stress Impact on Yeast Activity in Biotechnological Processes—A Short Overview

Author

Madalina Postaru, Alexandra Tucaliuc, Dan Cascaval, and Anca-Irina Galaction

Subjects

Saccharomyces cerevisiae, yeast fermentation, oxidative stress, ethanol stress, osmotic stress, cell response, Biology (General), QH301-705.5

Abstract

The importance of Saccharomyces cerevisiae yeast cells is known worldwide, as they are the most used microorganisms in biotechnology for bioethanol and biofuel production. Also, they are analyzed and studied for their similar internal biochemical processes to human cells, for a better understanding of cell aging and response to cell stressors. The special ability of S. cerevisiae cells to develop in both aerobic and anaerobic conditions makes this microorganism a viable model to study the transformations and the way in which cellular metabolism is directed to face the stress conditions due to environmental changes. Thus, this review will emphasize the effects of oxidative, ethanol, and osmotic stress and also the physiological and genetic response of stress mitigation in yeast cells.

Published

2023

19. Protective effects of thiamine on Wickerhamomyces anomalus against ethanol stress.

Author

Yinfeng Li, Hua Long, Guilan Jiang, Zhihai Yu, Mingzheng Huang, Shiping Zou, Tianbing Guan, Yan Zhao, and Xiaozhu Liu

Abstract

Wickerhamomyces anomalus (W. anomalus) is widely reported in the brewing industry and has positive effects on the aromatic profiles of wines because of its unique physiological characteristics and metabolic features. However, the accumulation of ethanol during fermentation inhibits the growth of W. anomalus. Thiamine is involved in the response against various abiotic stresses in microorganisms. Therefore, we used transcriptomic and metabolomic analyses to study the effect of thiamine on ethanol-stressed W. anomalus. The results indicate that thiamine could alleviate the inhibitory effect of ethanol stress on the survival ofW. anomalus. Differentially expressed genes (DEGs) and differentially expressed metabolites (DEMs) caused by the thiamine intervention were identified as oxidative phosphorylation through integrated transcriptomic and metabolomic analyses. In addition, ethanol treatment decreased the content of intracellular adenosine triphosphate (ATP), while thiamine partially alleviated this phenomenon. The present comprehensive transcriptional overview and metabolomic analysis provide insights about the mechanisms of thiamine protection on W. anomalus under ethanol stress and promote the potential applications of W. anomalus in the fermentation industry. [ABSTRACT FROM AUTHOR]

Published

2022

20. Analysis of the ethanol stress response mechanism in Wickerhamomyces anomalus based on transcriptomics and metabolomics approaches.

Author

Li, Yinfeng, Long, Hua, Jiang, Guilan, Gong, Xun, Yu, Zhihai, Huang, Mingzheng, Guan, Tianbing, Guan, Yuanyuan, and Liu, Xiaozhu

Subjects

*ETHANOL, *STRAINS & stresses (Mechanics), *AMINO acid metabolism, *ETHANOL as fuel, *METABOLOMICS, *BIOMASS energy

Abstract

Background: Wickerhamomyces anomalus (W. anomalus) is a kind of non-Saccharomyces yeast that has a variety of unique physiological characteristics and metabolic features and is widely used in many fields, such as food preservation, biomass energy, and aquaculture feed protein production. However, the mechanism of W. anomalus response to ethanol stress is still unclear, which greatly limits its application in the production of ethanol beverages and ethanol fuels. Therefore, we checked the effects of ethanol stress on the morphology, the growth, and differentially expressed genes (DEGs) and metabolites (DEMs) of W. anomalus. Results: High concentrations of ethanol (9% ethanol and 12% ethanol) remarkably inhibited the growth of W. anomalus. Energy metabolism, amino acid metabolism, fatty acids metabolism, and nucleic acid metabolism were significantly influenced when exposing to 9% ethanol and 12% ethanolstress, which maybe universal for W. anomalus to response to different concentrations of ethanol stressl Furthermore, extracellular addition of aspartate, glutamate, and arginine significantly abated ethanol damage and improved the survival rate of W. anomalus. Conclusions: The results obtained in this study provide insights into the mechanisms involved in W. anomalus response to ethanol stress. Therefore, new strategies can be realized to improve the ethanol tolerance of W. anomalus through metabolic engineering. [ABSTRACT FROM AUTHOR]

Published

2022

21. Effects on Cell Membrane Integrity of Pichia anomala by the Accumulating Excessive Reactive Oxygen Species under Ethanol Stress.

Author

Chen, Yanru, Wan, Yin, Cai, Wenqin, Liu, Na, Zeng, Jiali, Liu, Chengmei, Peng, Hong, and Fu, Guiming

Subjects

ETHANOL, REACTIVE oxygen species, PICHIA, GLUTATHIONE reductase, SUPEROXIDE dismutase, BREWING industry

Abstract

Ethanol stress to yeast is well recognized and exists widely during the brewing process of alcohol products. Pichia anomala is an important ester-producing yeast in the brewing process of Chinese Baijiu and other alcohol products. Therefore, it is of great significance for the alcohol products brewing industry to explore the effects of ethanol stress on the growth metabolism of P. anomala. In this study, the effects of ethanol stress on the growth, esters production ability, cell membrane integrity and reactive oxygen species (ROS) metabolism of P. anomala NCU003 were studied. Our results showed that ethanol stress could inhibit the growth, reduce the ability of non-ethyl ester compounds production and destroy the cell morphology of P. anomala NCU003. The results also showed that 9% ethanol stress produced excessive ROS and then increased the activities of antioxidant enzymes (superoxide dismutase, catalase, aseorbateperoxidase and glutathione reductase) compared to the control group. However, these increased antioxidant enzyme activities could not prevent the damage caused by ROS to P. anomala NCU003. Of note, correlation results indicated that high content of ROS could promote the accumulation of malondialdehyde content, resulting in destruction of the integrity of the cell membrane and leading to the leakage of intracellular nutrients (soluble sugar and protein) and electrolytes. These results indicated that the growth and the non-ethyl ester compounds production ability of P. anomala could be inhibited under ethanol stress by accumulating excessive ROS and the destruction of cell membrane integrity in P. anomala. [ABSTRACT FROM AUTHOR]

Published

2022

22. Increasing Ethanol Tolerance and Ethanol Production in an Industrial Fuel Ethanol Saccharomyces cerevisiae Strain.

Author

Varize, Camila S., Bücker, Augusto, Lopes, Lucas D., Christofoleti-Furlan, Renata M., Raposo, Mariane S., Basso, Luiz C., and Stambuk, Boris U.

Subjects

SUGARCANE, ETHANOL as fuel, SACCHAROMYCES cerevisiae, ETHANOL, GENETIC testing, ENGINEERING laboratories

Abstract

The stress imposed by ethanol to Saccharomyces cerevisiae cells are one of the most challenging limiting factors in industrial fuel ethanol production. Consequently, the toxicity and tolerance to high ethanol concentrations has been the subject of extensive research, allowing the identification of several genes important for increasing the tolerance to this stress factor. However, most studies were performed with well-characterized laboratory strains, and how the results obtained with these strains work in industrial strains remains unknown. In the present work, we have tested three different strategies known to increase ethanol tolerance by laboratory strains in an industrial fuel–ethanol producing strain: the overexpression of the TRP1 or MSN2 genes, or the overexpression of a truncated version of the MSN2 gene. Our results show that the industrial CAT-1 strain tolerates up to 14% ethanol, and indeed the three strategies increased its tolerance to ethanol. When these strains were subjected to fermentations with high sugar content and cell recycle, simulating the industrial conditions used in Brazilian distilleries, only the strain with overexpression of the truncated MSN2 gene showed improved fermentation performance, allowing the production of 16% ethanol from 33% of total reducing sugars present in sugarcane molasses. Our results highlight the importance of testing genetic modifications in industrial yeast strains under industrial conditions in order to improve the production of industrial fuel ethanol by S. cerevisiae. [ABSTRACT FROM AUTHOR]

Published

2022

23. Metabolomics Reveals the Regulatory Mechanisms of Antioxidant Dipeptides Enhancing the Tolerance of Lager Yeast against Ethanol Stress.

Author

Wu C, Jike X, Yang N, Wang C, Zhang H, and Lei H

Subjects

Fermentation, Stress, Physiological, Ethanol metabolism, Ethanol pharmacology, Dipeptides metabolism, Dipeptides pharmacology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae drug effects, Metabolomics, Antioxidants metabolism, Reactive Oxygen Species metabolism

Abstract

The antioxidant dipeptides (Ala-His, AH; Thr-Tyr, TY; and Phe-Cys, FC) significantly enhanced the lager yeast tolerance of ethanol stress. The enhancement mechanisms were further elucidated through physiological responses and metabolomics analysis. The results indicated that antioxidant dipeptides significantly increased the lager yeast biomass and budding rate. The primary mechanisms by which antioxidant dipeptides improved lager yeast tolerance involved decreasing intracellular reactive oxygen species (ROS) levels and increasing energy metabolism. Specifically, the addition of FC resulted in a 27.44% reduction in intracellular ROS content and a 26.14% increase in the ATP level compared to the control. Metabolomics analysis further explored the potential mechanisms underlying the protective effects of FC, identifying 63 upregulated and 103 downregulated metabolites. The analysis revealed that FC altered intracellular metabolites related to glutathione metabolism, purine metabolism, starch and sucrose metabolism, and ABC transporters, thereby enhancing yeast stress tolerance. The results suggest that FC is an effective enhancer for improving lager yeast tolerance to ethanol stress.

Published

2024

24. Heat Shock Factor 1 forms nuclear condensates and restructures the yeast genome before activating target genes.

Author

Rubio LS, Mohajan S, and Gross DS

Subjects

Genome, Fungal, Gene Expression Regulation, Fungal, Heat-Shock Response genetics, Ethanol metabolism, Ethanol pharmacology, Heat Shock Transcription Factors metabolism, Heat Shock Transcription Factors genetics, Transcription Factors metabolism, Transcription Factors genetics, DNA-Binding Proteins metabolism, DNA-Binding Proteins genetics, Heat-Shock Proteins, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins genetics

Abstract

In insects and mammals, 3D genome topology has been linked to transcriptional states yet whether this link holds for other eukaryotes is unclear. Using both ligation proximity and fluorescence microscopy assays, we show that in Saccharomyces cerevisiae , Heat Shock Response ( HSR ) genes dispersed across multiple chromosomes and under the control of Heat Shock Factor (Hsf1) rapidly reposition in cells exposed to acute ethanol stress and engage in concerted, Hsf1-dependent intergenic interactions. Accompanying 3D genome reconfiguration is equally rapid formation of Hsf1-containing condensates. However, in contrast to the transience of Hsf1-driven intergenic interactions that peak within 10-20 min and dissipate within 1 hr in the presence of 8.5% (v/v) ethanol, transcriptional condensates are stably maintained for hours. Moreover, under the same conditions, Pol II occupancy of HSR genes, chromatin remodeling, and RNA expression are detectable only later in the response and peak much later (>1 hr). This contrasts with the coordinate response of HSR genes to thermal stress (39°C) where Pol II occupancy, transcription, histone eviction, intergenic interactions, and formation of Hsf1 condensates are all rapid yet transient (peak within 2.5-10 min and dissipate within 1 hr). Therefore, Hsf1 forms condensates, restructures the genome and transcriptionally activates HSR genes in response to both forms of proteotoxic stress but does so with strikingly different kinetics. In cells subjected to ethanol stress, Hsf1 forms condensates and repositions target genes before transcriptionally activating them., Competing Interests: LR, SM, DG No competing interests declared, (© 2023, Rubio et al.)

Published

2024

25. Ethanol at Subinhibitory Concentrations Enhances Biofilm Formation in Salmonella Enteritidis.

Author

He, Shoukui, Zhan, Zeqiang, Shi, Chunlei, Wang, Siyun, and Shi, Xianming

Subjects

SALMONELLA enteritidis, BIOFILMS, QUORUM sensing, ETHANOL, CELL motility, OPACITY (Optics), MICROPLATES

Abstract

The survival of Salmonella Enteritidis in the food chain is relevant to its biofilm formation capacity, which is influenced by suboptimal environmental conditions. Here, biofilm formation pattern of this bacterium was assessed in the presence of ethanol at sub-minimal inhibitory concentrations (sub-MICs) by microtiter plate assays, cell characteristic analyses, and gene expression tests. It was observed that ethanol at subinhibitory concentrations (1/4 MIC, 2.5%; 1/2 MIC, 5.0%) was able to stimulate biofilm formation in S. Enteritidis. The OD595 value (optical density at 595 nm) used to quantify biofilm production was increased from 0.14 in control groups to 0.36 and 0.63 under 2.5% and 5.0% ethanol stresses, respectively. Ethanol was also shown to reduce bacterial swimming motility and enhance cell auto-aggregation ability. However, other cell characteristics such as swarming activity, initial attachment and cell surface hydrophobicity were not remarkedly impacted by ethanol. Reverse transcription quantitative real-time PCR (RT-qPCR) analysis further revealed that the luxS gene belonging to a quorum-sensing system was upregulated by 2.49- and 10.08-fold in the presence of 2.5% and 5.0% ethanol, respectively. The relative expression level of other biofilm-related genes (adrA, csgB, csgD, and sdiA) and sRNAs (ArcZ, CsrB, OxyS, and SroC) did not obviously change. Taken together, these findings suggest that decrease in swimming motility and increase in cell auto-aggregation and quorum sensing may result in the enhancement of biofilm formation by S. Enteritidis under sublethal ethanol stress. [ABSTRACT FROM AUTHOR]

Published

2022

26. Adaptability of wine yeast to ethanol-induced protein denaturation.

Author

Furutani, Noboru and Izawa, Shingo

Subjects

*DENATURATION of proteins, *WHITE wines, *YEAST, *FERMENTATION, *HEAT shock proteins, *WINES, *GLYCOLYSIS

Abstract

This year marks the 200th anniversary of the birth of Dr Louis Pasteur (1822–1895), who revealed that alcoholic fermentation is performed by yeast cells. Subsequently, details of the mechanisms of alcoholic fermentation and glycolysis in yeast cells have been elucidated. However, the mechanisms underlying the high tolerance and adaptability of yeast cells to ethanol are not yet fully understood. This review presents the response and adaptability of yeast cells to ethanol-induced protein denaturation. Herein, we describe the adverse effects of severe ethanol stress on intracellular proteins and the responses of yeast cells. Furthermore, recent findings on the acquired resistance of wine yeast cells to severe ethanol stress that causes protein denaturation are discussed, not only under laboratory conditions, but also during the fermentation process at 15°C to mimic the vinification process of white wine. [ABSTRACT FROM AUTHOR]

Published

2022

27. Hsp from Lactobacillus plantarum Expression in Lactococcus lactis MG1363

Author

Liu Peng, Jia Jundong, Wu Hanwen, Song Zihan, and He Xi

Subjects

small heat shock proteins, lactobacillus plantarum, heterologous expression, lactococcus lactis, ethanol stress, Microbiology, QR1-502, Physiology, QP1-981, Zoology, QL1-991

Abstract

Small heat shock proteins are protective proteins produced by organisms under thermal stress. They are widely present in living organisms. Here, Hsp18, Hsp18.55 and Hsp19.5 genes were cloned from Lactobacillus plantarum and heterologous expressed in Lactococcus lactis, and their potential functions under ethanol stress were investigated. The results showed that the recombinant strain over expressing Hsp19.5 gene had stronger stress resistance, which provided a basis for further study of the survival ability of other microorganisms under ethanol stress.

Published

2023

28. Improvement of Yeast Fermentation Efficiency Utilizing mRNAs Preferentially Translated Under Translational Repression

Author

Kato, Sae, Izawa, Shingo, Masuda, Seiji, editor, and Izawa, Shingo, editor

Published

2018

29. Comparative Genomics Analysis Provides New Insights into High Ethanol Tolerance of Lactiplantibacillus pentosus LTJ12, a Novel Strain Isolated from Chinese Baijiu

Author

Jiali Wang, Chengshun Lu, Qiang Xu, Zhongyuan Li, Yajian Song, Sa Zhou, Le Guo, Tongcun Zhang, and Xuegang Luo

Subjects

Lactiplantibacillus pentosus LTJ12, whole genome sequencing, gene function annotation, probiotics, ethanol stress, comparative genomics, Chemical technology, TP1-1185

Abstract

Lactic acid bacteria have received a significant amount of attention due to their probiotic characteristics. The species Lactiplantibacillus plantarum and Lactiplantibacillus pentosus are genotypically closely related, and their phenotypes are so similar that they are easily confused and mistaken. In the previous study, an ethanol-resistant strain, LTJ12, isolated from the fermented grains of soy sauce aroma type baijiu in North China, was originally identified as L. plantarum through a 16S rRNA sequence analysis. Here, the genome of strain LTJ12 was further sequenced using PacBio and Illumina sequencing technology to obtain a better understanding of the metabolic pathway underlying its resistance to ethanol stress. The results showed that the genome of strain LTJ12 was composed of one circular chromosome and three circular plasmids. The genome size is 3,512,307 bp with a GC content of 46.37%, and the number of predicted coding genes is 3248. Moreover, by comparing the coding genes with the GO (Gene Ontology), COG (Cluster of Orthologous Groups) and KEGG (Kyoto Encyclopedia of Genes and Genomes) databases, the functional annotation of the genome and an assessment of the metabolic pathways were performed, with the results showing that strain LTJ12 has multiple genes that may be related to alcohol metabolism and probiotic-related genes. Antibiotic resistance gene analysis showed that there were few potential safety hazards. Further, after conducting the comparative genomics analysis, it was found that strain LTJ12 is L. pentosus but not L. plantarum, but it has more functional genes than other L. pentosus strains that are mainly related to carbohydrate transport and metabolism, transcription, replication, recombination and repair, signal transduction mechanisms, defense mechanisms and cell wall/membrane/envelope biogenesis. These unique functional genes, such as gene 2754 (encodes alcohol dehydrogenase), gene 3093 (encodes gamma-D-glutamyl-meso-diaminopimelate peptidase) and some others may enhance the ethanol tolerance and alcohol metabolism of the strain. Taken together, L. pentosus LTJ12 might be a potentially safe probiotic with a high ethanol tolerance and alcohol metabolism. The findings of this study will also shed light on the accurate identification and rational application of the Lactiplantibacillus species.

Published

2022

30. Effects on Cell Membrane Integrity of Pichia anomala by the Accumulating Excessive Reactive Oxygen Species under Ethanol Stress

Author

Yanru Chen, Yin Wan, Wenqin Cai, Na Liu, Jiali Zeng, Chengmei Liu, Hong Peng, and Guiming Fu

Subjects

ethanol stress, Pichia anomala, ester production ability, reactive oxygen species, cell membrane integrity, Chemical technology, TP1-1185

Abstract

Ethanol stress to yeast is well recognized and exists widely during the brewing process of alcohol products. Pichia anomala is an important ester-producing yeast in the brewing process of Chinese Baijiu and other alcohol products. Therefore, it is of great significance for the alcohol products brewing industry to explore the effects of ethanol stress on the growth metabolism of P. anomala. In this study, the effects of ethanol stress on the growth, esters production ability, cell membrane integrity and reactive oxygen species (ROS) metabolism of P. anomala NCU003 were studied. Our results showed that ethanol stress could inhibit the growth, reduce the ability of non-ethyl ester compounds production and destroy the cell morphology of P. anomala NCU003. The results also showed that 9% ethanol stress produced excessive ROS and then increased the activities of antioxidant enzymes (superoxide dismutase, catalase, aseorbateperoxidase and glutathione reductase) compared to the control group. However, these increased antioxidant enzyme activities could not prevent the damage caused by ROS to P. anomala NCU003. Of note, correlation results indicated that high content of ROS could promote the accumulation of malondialdehyde content, resulting in destruction of the integrity of the cell membrane and leading to the leakage of intracellular nutrients (soluble sugar and protein) and electrolytes. These results indicated that the growth and the non-ethyl ester compounds production ability of P. anomala could be inhibited under ethanol stress by accumulating excessive ROS and the destruction of cell membrane integrity in P. anomala.

Published

2022

31. The role of various factors in the process of biofilm formation by bacilli

Author

G.R. Akhmetova, N.L. Rudakova, T.L. Din, and M.R. Sharipova

Subjects

b. subtilis, protease-deficient strains, biofilms, extracellular proteases of b. pumilus, ethanol stress, osmotic stress, Science

Abstract

The strategy of existence of microorganisms in the structure of biofilms determines their adaptation to specific environmental conditions. Bacteria of the genus Bacillus are actively used as models for studying the processes of regulation and formation of biofilms. This work aims to assess the effect of proteases secreted by bacilli on the formation of biofilms, as well as on the resistance of recombinant strains to environmental stress factors. We compared the dynamics of biofilm formation by the wild strain B. subtilis 168 and the following strains with altered expression of extracellular proteases: non-protease strains (B. subtilis BG2036, B. subtilis BRB8, and B. subtilis BRB14) and strains with increased protease secretion (B. subtilis (aprBp), B. subtilis (gseBp), and B. subtilis (mprBp)). We also investigated the effect of ethanol and sodium chloride on the ability of the B. subtilis strains to form biofilms in a liquid medium. The bacterial strains were cultured at pH 7.4 and temperature 37 ?C in a synthetic E-medium in U-shaped 96-well plates. Biofilm formation was identified by incubation with crystal violet (CV). We found that the level of biofilm formation is higher (by an average of 10%) in the protease-deficient strains of B. subtilis. The recombinant strains expressing genes of serine proteases form biofilms with a reduced level (by an average of 40%). A strain with the expression of metalloendopeptidase is characterized by an increased level of biofilm formation (up to 10%), which is possibly due to the functional in vivo role of this new enzyme. The wild and protease-deficient strains of B. subtilis respond similarly to ethanol stress: biofilm formation is reduced in both of them. The wild strain exhibits a greater sensitivity to osmotic stress than the protease-deficient one.

Published

2019

32. Quantitative proteomic analysis reveals the ethanologenic metabolism regulation of Ethanoligenens harbinense by exogenous ethanol addition

Author

Huahua Li, Xiaoxue Mei, Bingfeng Liu, Guojun Xie, Nanqi Ren, and Defeng Xing

Subjects

Hydrogen-producing bacteria, Ethanologenesis, Ethanoligenens harbinense, Ethanol stress, Quantitative proteomics, Fuel, TP315-360, Biotechnology, TP248.13-248.65

Abstract

Abstract Background H2–ethanol-coproducing bacteria, as primary fermenters, play important roles in the microbiome of bioreactors for bioenergy production from organic wastewater or solid wastes. Ethanoligenens harbinense YUAN-3 is an anaerobic ethanol–H2-fermenting bacterium. Ethanol is one of the main end-products of strain YUAN-3 that influence its fermentative process. Until recently, the molecular mechanism of metabolic regulation in strain YUAN-3 during ethanol accumulation has still been unclear. This study aims to elucidate the metabolic regulation mechanisms in strain YUAN-3, which contributes to effectively shape the microbiome for biofuel and bioenergy production from waste stream. Results This study reports that ethanol stress altered the distribution of end-product yields in the H2–ethanol-coproducing Ethanoligenens harbinense strain YUAN-3. Decreasing trends of hydrogen yield from 1888.6 ± 45.8 to 837 ± 64.7 mL L−1 and acetic acid yield from 1767.7 ± 45 to 160.6 ± 44.7 mg L−1 were observed in strain YUAN-3 with increasing exogenous ethanol (0 mM–200 mM). However, the ethanol yield of strain YUAN-3 increased by 15.1%, 30.1%, and 27.4% in 50 mM, 100 mM, and 200 mM ethanol stress, respectively. The endogenous ethanol accounted for 96.1% (w/w) in liquid end-products when exogenous ethanol of 200 mM was added. The molar ratio of ethanol to acetic acid increased 14 times (exogenous ethanol of 200 mM) compared to the control. iTRAQ-based quantitative proteomic analysis indicated that 263 proteins of strain YUAN-3 were differentially expressed in 50 mM, 100 mM, and 200 mM of exogenous ethanol. These proteins are mainly involved in amino acid transport and metabolism, central carbon metabolism, and oxidative stress response. Conclusion These differentially expressed proteins play important roles in metabolic changes necessary for growth and survival of strain YUAN-3 during ethanol stress. The up-regulation of bifunctional acetaldehyde-CoA/alcohol dehydrogenase (ADHE) was the main reason why ethanol production was enhanced, while hydrogen gas and acetic acid yields declined in strain YUAN-3 during ethanol stress. This study also provides a new approach for the enhancement of ethanologenesis by H2–ethanol-coproducing bacteria through exogenous ethanol addition.

Published

2019

33. Increasing Ethanol Tolerance and Ethanol Production in an Industrial Fuel Ethanol Saccharomyces cerevisiae Strain

Author

Camila S. Varize, Augusto Bücker, Lucas D. Lopes, Renata M. Christofoleti-Furlan, Mariane S. Raposo, Luiz C. Basso, and Boris U. Stambuk

Subjects

ethanol stress, ethanol tolerance, industrial yeast strains, high-gravity fermentation, TRP1, MSN2, Fermentation industries. Beverages. Alcohol, TP500-660

Abstract

The stress imposed by ethanol to Saccharomyces cerevisiae cells are one of the most challenging limiting factors in industrial fuel ethanol production. Consequently, the toxicity and tolerance to high ethanol concentrations has been the subject of extensive research, allowing the identification of several genes important for increasing the tolerance to this stress factor. However, most studies were performed with well-characterized laboratory strains, and how the results obtained with these strains work in industrial strains remains unknown. In the present work, we have tested three different strategies known to increase ethanol tolerance by laboratory strains in an industrial fuel–ethanol producing strain: the overexpression of the TRP1 or MSN2 genes, or the overexpression of a truncated version of the MSN2 gene. Our results show that the industrial CAT-1 strain tolerates up to 14% ethanol, and indeed the three strategies increased its tolerance to ethanol. When these strains were subjected to fermentations with high sugar content and cell recycle, simulating the industrial conditions used in Brazilian distilleries, only the strain with overexpression of the truncated MSN2 gene showed improved fermentation performance, allowing the production of 16% ethanol from 33% of total reducing sugars present in sugarcane molasses. Our results highlight the importance of testing genetic modifications in industrial yeast strains under industrial conditions in order to improve the production of industrial fuel ethanol by S. cerevisiae.

Published

2022

34. Ethanol at Subinhibitory Concentrations Enhances Biofilm Formation in Salmonella Enteritidis

Author

Shoukui He, Zeqiang Zhan, Chunlei Shi, Siyun Wang, and Xianming Shi

Subjects

Salmonella Enteritidis, biofilm formation, ethanol stress, cell characteristic, gene expression, quorum sensing, Chemical technology, TP1-1185

Abstract

The survival of Salmonella Enteritidis in the food chain is relevant to its biofilm formation capacity, which is influenced by suboptimal environmental conditions. Here, biofilm formation pattern of this bacterium was assessed in the presence of ethanol at sub-minimal inhibitory concentrations (sub-MICs) by microtiter plate assays, cell characteristic analyses, and gene expression tests. It was observed that ethanol at subinhibitory concentrations (1/4 MIC, 2.5%; 1/2 MIC, 5.0%) was able to stimulate biofilm formation in S. Enteritidis. The OD595 value (optical density at 595 nm) used to quantify biofilm production was increased from 0.14 in control groups to 0.36 and 0.63 under 2.5% and 5.0% ethanol stresses, respectively. Ethanol was also shown to reduce bacterial swimming motility and enhance cell auto-aggregation ability. However, other cell characteristics such as swarming activity, initial attachment and cell surface hydrophobicity were not remarkedly impacted by ethanol. Reverse transcription quantitative real-time PCR (RT-qPCR) analysis further revealed that the luxS gene belonging to a quorum-sensing system was upregulated by 2.49- and 10.08-fold in the presence of 2.5% and 5.0% ethanol, respectively. The relative expression level of other biofilm-related genes (adrA, csgB, csgD, and sdiA) and sRNAs (ArcZ, CsrB, OxyS, and SroC) did not obviously change. Taken together, these findings suggest that decrease in swimming motility and increase in cell auto-aggregation and quorum sensing may result in the enhancement of biofilm formation by S. Enteritidis under sublethal ethanol stress.

Published

2022

35. Heat Adaptation Induced Cross Protection Against Ethanol Stress in Tetragenococcus halophilus: Physiological Characteristics and Proteomic Analysis

Author

Huan Yang, Shangjie Yao, Min Zhang, and Chongde Wu

Subjects

Tetragenococcus halophilus, cross protection, ethanol stress, heat preadaptation, membrane properties, proteomic analysis, Microbiology, QR1-502

Abstract

Ethanol is a toxic factor that damages membranes, disturbs metabolism, and may kill the cell. Tetragenococcus halophilus, considered as the cell factory during the manufacture of traditional fermented foods, encounters ethanol stress, which may affect the viability and fermentative performance of cells. In order to improve the ethanol tolerance of T. halophilus, a strategy based on cross protection was proposed in the current study. The results indicated that cross protection induced by heat preadaptation (45°C for 1.5 h) could significantly improve the stress tolerance (7.24-fold increase in survival) of T. halophilus upon exposure to ethanol (10% for 2.5 h). Based on this result, a combined analysis of physiological approaches and TMT-labeled proteomic technology was employed to investigate the protective mechanism of cross protection in T. halophilus. Physiological analysis showed that the heat preadapted cells exhibited a better surface phenotype, higher membrane integrity, and higher amounts of unsaturated fatty acids compared to unadapted cells. Proteomic analysis showed that a total of 163 proteins were differentially expressed in response to heat preadaptation. KEGG enrichment analysis showed that energy metabolism, membrane transport, peptidoglycan biosynthesis, and genetic information processing were the most abundant metabolic pathways after heat preadaptation. Three proteins (GpmA, AtpB, and TpiA) involved in energy metabolism and four proteins (ManM, OpuC, YidC, and HPr) related to membrane transport were up-regulated after heat preadaptation. In all, the results of this study may help understand the protective mechanisms of preadaptation and contribute to the improvement of the stress resistance of T. halophilus during industrial processes.

Published

2021

36. Heat Adaptation Induced Cross Protection Against Ethanol Stress in Tetragenococcus halophilu s: Physiological Characteristics and Proteomic Analysis.

Author

Yang, Huan, Yao, Shangjie, Zhang, Min, and Wu, Chongde

Subjects

HEAT adaptation, PROTEOMICS, UNSATURATED fatty acids, ETHANOL, FERMENTED foods, PLANT hybridization, BIOLOGICAL transport, ENERGY metabolism

Abstract

Ethanol is a toxic factor that damages membranes, disturbs metabolism, and may kill the cell. Tetragenococcus halophilus , considered as the cell factory during the manufacture of traditional fermented foods, encounters ethanol stress, which may affect the viability and fermentative performance of cells. In order to improve the ethanol tolerance of T. halophilus , a strategy based on cross protection was proposed in the current study. The results indicated that cross protection induced by heat preadaptation (45°C for 1.5 h) could significantly improve the stress tolerance (7.24-fold increase in survival) of T. halophilus upon exposure to ethanol (10% for 2.5 h). Based on this result, a combined analysis of physiological approaches and TMT-labeled proteomic technology was employed to investigate the protective mechanism of cross protection in T. halophilus. Physiological analysis showed that the heat preadapted cells exhibited a better surface phenotype, higher membrane integrity, and higher amounts of unsaturated fatty acids compared to unadapted cells. Proteomic analysis showed that a total of 163 proteins were differentially expressed in response to heat preadaptation. KEGG enrichment analysis showed that energy metabolism, membrane transport, peptidoglycan biosynthesis, and genetic information processing were the most abundant metabolic pathways after heat preadaptation. Three proteins (GpmA, AtpB, and TpiA) involved in energy metabolism and four proteins (ManM, OpuC, YidC, and HPr) related to membrane transport were up-regulated after heat preadaptation. In all, the results of this study may help understand the protective mechanisms of preadaptation and contribute to the improvement of the stress resistance of T. halophilus during industrial processes. [ABSTRACT FROM AUTHOR]

Published

2021

37. Acetaldehyde Stimulation of the Growth of Zymomonas mobilis Subjected to Ethanol and Other Environmental Stresses: Effect of Other Metabolic Electron Acceptors and Evidence for a Mechanism.

Author

Vriesekoop, Frank and Pamment, Neville B.

Subjects

ACETALDEHYDE, ZYMOMONAS mobilis, ELECTROPHILES, ETHANOL, FERMENTATION products industry, PROPIONALDEHYDE

Abstract

Ethanol-stressed cultures of Z. mobilis showed greatly reduced lag times in growth when supplemented with small amounts of acetaldehyde. This effect could be mimicked by other metabolic electron acceptors, including propionaldehyde and oxygen, indicating a redox-based mechanism. Added propionaldehyde was rapidly and stoichiometrically converted to 1-propanol, suggesting that added acetaldehyde is also reduced during early growth. Acetaldehyde addition measurably accelerated glycolysis in nongrowing cells and also slightly stimulated cultures subjected to temperature change, osmotic shock and salt and acetate stress. Acetaldehyde’s stimulatory effect appears to be due to its ability to accelerate glycolysis via its effect on the cellular redox balance. Acetaldehyde reduction opposes the drain on NAD+ concentrations caused by oxidation of the added ethanol, accounting for the particularly strong effect on ethanol-stressed cells. This study provides evidence for our earlier proposed redox-based mechanism for acetaldehyde’s ability to reduce the lag phase of environmentally stressed cultures and suggests that the effect may have applications in industrial fermentations, especially those inhibited by ethanol and toxic compounds present in, for instance, lignocellulosic hydrolysates. [ABSTRACT FROM AUTHOR]

Published

2021

38. Ethanol Enhances Astaxanthin Production by Aurantiochytrium sp

Author

Sakamoto, Takaiku, Ikeda, Yusuke, Masuda, Naruho, and Sakuradani, Eiji

Subjects

astaxanthin, ethanol stress, β-carotene, Aurantiochytrium

Abstract

Two-percent ethanol increased the astaxanthin productivity of heterotrophic microalgae Aurantiochytrium sp. O5-1-1 to 2.231 mg/L, 45-fold higher than under ethanol-free condition. Ethanol in the medium decreased at the same rate as spontaneous volatilization, suggesting that it was not a transient signaling factor but a continuous stress on the cells. The triply mutated strain OM3-3 produced 5.075 mg/L astaxanthin under 2% ethanol conditions. Furthermore, the astaxanthin accumulation of the mutant OM3-9 was 0.895 mg/g, which was 150-fold higher than that of strain O5-1-1 in ethanol-free condition. These results are beneficial for the commercial exploitation of carotenoids producing Aurantiochytrium spp.

Published

2023

39. Transcriptional Rewiring, Adaptation, and the Role of Gene Duplication in the Metabolism of Ethanol of Saccharomyces cerevisiae

Author

Beatriz Sabater-Muñoz, Florian Mattenberger, Mario A. Fares, and Christina Toft

Subjects

RNAseq, adaptive laboratory experimental evolution, clonal populations, transcriptional divergence, ethanol stress, Microbiology, QR1-502

Abstract

ABSTRACT Ethanol is the main by-product of yeast sugar fermentation that affects microbial growth parameters, being considered a dual molecule, a nutrient and a stressor. Previous works demonstrated that the budding yeast arose after an ancient hybridization process resulted in a tier of duplicated genes within its genome, many of them with implications in this ethanol “produce-accumulate-consume” strategy. The evolutionary link between ethanol production, consumption, and tolerance versus ploidy and stability of the hybrids is an ongoing debatable issue. The implication of ancestral duplicates in this metabolic rewiring, and how these duplicates differ transcriptionally, remains unsolved. Here, we study the transcriptomic adaptive signatures to ethanol as a nonfermentative carbon source to sustain clonal yeast growth by experimental evolution, emphasizing the role of duplicated genes in the adaptive process. As expected, ethanol was able to sustain growth but at a lower rate than glucose. Our results demonstrate that in asexual populations a complete transcriptomic rewiring was produced, strikingly by downregulation of duplicated genes, mainly whole-genome duplicates, whereas small-scale duplicates exhibited significant transcriptional divergence between copies. Overall, this study contributes to the understanding of evolution after gene duplication, linking transcriptional divergence with duplicates’ fate in a multigene trait as ethanol tolerance. IMPORTANCE Gene duplication events have been related with increasing biological complexity through the tree of life, but also with illnesses, including cancer. Early evolutionary theories indicated that duplicated genes could explore alternative functions due to relaxation of selective constraints in one of the copies, as the other remains as ancestral-function backup. In unicellular eukaryotes like yeasts, it has been demonstrated that the fate and persistence of duplicates depend on duplication mechanism (whole-genome or small-scale events), shaping their actual genomes. Although it has been shown that small-scale duplicates tend to innovate and whole-genome duplicates specialize in ancestral functions, the implication of duplicates’ transcriptional plasticity and transcriptional divergence on environmental and metabolic responses remains largely obscure. Here, by experimental adaptive evolution, we show that Saccharomyces cerevisiae is able to respond to metabolic stress (ethanol as nonfermentative carbon source) due to the persistence of duplicated genes. These duplicates respond by transcriptional rewiring, depending on their transcriptional background. Our results shed light on the mechanisms that determine the role of duplicates, and on their evolvability.

Published

2020

40. Does Inter-Organellar Proteostasis Impact Yeast Quality and Performance During Beer Fermentation?

Author

Bianca de Paula Telini, Marcelo Menoncin, and Diego Bonatto

Subjects

proteostasis, brewing yeasts, ethanol stress, beer fermentation, inter-organellar communication, transcriptome, Genetics, QH426-470

Abstract

During beer production, yeast generate ethanol that is exported to the extracellular environment where it accumulates. Depending on the initial carbohydrate concentration in the wort, the amount of yeast biomass inoculated, the fermentation temperature, and the yeast attenuation capacity, a high concentration of ethanol can be achieved in beer. The increase in ethanol concentration as a consequence of the fermentation of high gravity (HG) or very high gravity (VHG) worts promotes deleterious pleiotropic effects on the yeast cells. Moderate concentrations of ethanol (5% v/v) change the enzymatic kinetics of proteins and affect biological processes, such as the cell cycle and metabolism, impacting the reuse of yeast for subsequent fermentation. However, high concentrations of ethanol (> 5% v/v) dramatically alter protein structure, leading to unfolded proteins as well as amorphous protein aggregates. It is noteworthy that the effects of elevated ethanol concentrations generated during beer fermentation resemble those of heat shock stress, with similar responses observed in both situations, such as the activation of proteostasis and protein quality control mechanisms in different cell compartments, including endoplasmic reticulum (ER), mitochondria, and cytosol. Despite the extensive published molecular and biochemical data regarding the roles of proteostasis in different organelles of yeast cells, little is known about how this mechanism impacts beer fermentation and how different proteostasis mechanisms found in ER, mitochondria, and cytosol communicate with each other during ethanol/fermentative stress. Supporting this integrative view, transcriptome data analysis was applied using publicly available information for a lager yeast strain grown under beer production conditions. The transcriptome data indicated upregulation of genes that encode chaperones, co-chaperones, unfolded protein response elements in ER and mitochondria, ubiquitin ligases, proteasome components, N-glycosylation quality control pathway proteins, and components of processing bodies (p-bodies) and stress granules (SGs) during lager beer fermentation. Thus, the main purpose of this hypothesis and theory manuscript is to provide a concise picture of how inter-organellar proteostasis mechanisms are connected with one another and with biological processes that may modulate the viability and/or vitality of yeast populations during HG/VHG beer fermentation and serial repitching.

Published

2020

41. Transcriptome profiling of Issatchenkia orientalis under ethanol stress

Author

Yingjie Miao, Guotong Xiong, Ruoyun Li, Zufang Wu, Xin Zhang, and Peifang Weng

Subjects

Issatchenkia orientalis, RNA-Seq, Transcriptome, Ethanol stress, Wine fermentation, Biotechnology, TP248.13-248.65, Microbiology, QR1-502

Abstract

Abstract Issatchenkia orientalis, a non-Saccharomyces yeast that can resist a wide variety of environmental stresses, has potential use in winemaking and bioethanol production. Little is known about gene expression or the physiology of I. orientalis under ethanol stress. In this study, high-throughput RNA sequencing was used to investigate the transcriptome profile of I. orientalis in response to ethanol. 502 gene transcripts were differentially expressed, of which 451 were more abundant, and 51 less abundant, in cells subjected to 4 h of ethanol stress (10% v/v). Annotation and statistical analyses suggest that multiple genes involved in ergosterol biosynthesis, trehalose metabolism, and stress response are differentially expressed under these conditions. The up-regulation of molecular chaperones HSP90 and HSP70, and also genes associated with the ubiquitin–proteasome proteolytic pathway suggests that ethanol stress may cause aggregation of misfolded proteins. Finally, ethanol stress in I. orientalis appears to have a nitrogen starvation effect, and many genes involved in nutrient uptake were up-regulated.

Published

2018

42. Metabolomics analysis of growth inhibition of Lactobacillus plantarum under ethanol stress.

Author

Chen, Xiaoqian, Wang, Tingting, Jin, Man, Tan, Ying, Liu, Libo, Liu, Lihua, Li, Chun, Yang, Yuzhuo, and Du, Peng

Subjects

*KREBS cycle, *METABOLOMICS, *STRESS concentration, *MEMBRANE permeability (Biology), *CARBON metabolism, *BACTERIAL metabolism, *ETHANOL, *MICROBIAL metabolites

Abstract

This experiment investigated the changes in morphology, cell membrane permeability and intracellular metabolites of Lactobacillus plantarum (L. plantarum) under different concentrations of ethanol stress. It was found that when treated with ethanol at the concentration of 8% (v/v), L. plantarum mortality was close to 60%, and the surface of cell was rough and collapsed, and the cell debris is obvious. The extracellular β‐galactosidase activity increased to 1.24 and 1.73 times higher as compared to the control group after 6% (v/v) and 8% (v/v) ethanol stress, respectively. The inhibition of bacterial growth was positively correlated with its concentration. Ethanol stress can cause changes in cell morphology and membrane permeability of L. plantarum, causing physiological damage to cells. Metabolomics analysis revealed that the ethanol stress led to the inhibition of primary metabolic pathways through the suppression of the tricarboxylic acid cycle and glycolysis. It is therefore proposed that the inhibition effect of ethanol on L. plantarum is achieved by inducing intracellular metabolic imbalance via disruption of cell membrane functions. Importance: Lactobacillus plantarum is often subjected to ethanol stress during food processing, production and storage, thus inhibiting the growth of bacteria. However, the detailed inhibition mechanism of ethanol on L. plantarum has not been deeply studied on metabolomics analysis. By measuring the changes of intracellular metabolites under ethanol stress, we found that ethanol destroyed the function of the membrane by changing the membrane structure, which hindered the carbon metabolism in the cell centre and reduced the vitality of bacteria. The results made a contribution for improvement of the target strain physiological and the strain industrial utility under ethanol stress. [ABSTRACT FROM AUTHOR]

Published

2020

43. Transcriptome analysis of Lactobacillus paracasei SMN-LBK under ethanol stress.

Author

Guo, Jinfeng, Li, Xu, Li, Baokun, Yang, Jie, Jin, Dan, and Li, Kaixiong

Subjects

*LACTOCOCCUS lactis, *LACTIC acid bacteria, *SODIUM dodecyl sulfate, *ETHANOL, *PYRUVATES, *NUCLEOTIDE sequence, *POTENTIAL functions

Abstract

Lactobacillus paracasei SMN-LBK (serial number: CCTCC M 2017429) is an ethanol-resistant lactic acid bacteria (LAB) in kumiss. However, the anti-ethanol stress mechanism of L. paracasei SMN-LBK remains unclear. Hence, we performed a transcriptome analysis between L. paracasei SX10 (L. paracasei SMN-LBK under 10% ethanol stress strain, abbreviated as SX10) and L. paracasei SMN-LBK (abbreviated as S10) by RNA sequencing. We performed real-time quantitative PCR (RT-qPCR) to verify the accuracy of the transcription data. The transcriptome data revealed that 315 genes exhibited upregulated expression, and 332 genes were downregulated in the SX10 compared with the S10 group. The PFK , LDH , GPDH , and GK genes were upregulated, with a log 2 -fold change of 1.10, 0.30, 0.56, and 1.512, respectively. A gene ontology enrichment analysis revealed significant enrichment of ribosomes, ribonucleoprotein complex, non-membrane-bounded organelles, and intracellular non-membrane-bound organelles. Analysis using the Kyoto Encyclopedia of Genes and Genomes database revealed differential genes associated with ribosome function, pyruvate metabolism, biosynthesis of amino acids, fatty acid biosynthesis, fatty acid metabolism, ATP-binding cassette (ABC) transporter, glycolysis, and glycerophospholipid metabolism. The RT-qPCR results were consistent with the transcriptome results. Lactococcus lactis NZ9000 is a typical host bacterium. We performed PFK and GK overexpression to verify the function of the L. paracasei SX10 resistance gene in Lactococcus lactis NZ9000. Using sodium dodecyl sulfate (SDS)-PAGE electrophoresis, these resistance genes were successfully expressed in Lactococcus lacti s NZ9000. The survival rate and key enzyme activity of the recombinant strains were determined under ethanol stress. The survival rate of Lactococcus lactis NZ9000-pNZ8148-PFK and Lactococcus lactis NZ9000-pNZ8148-GK under 10% ethanol stress were 3.43- and 3.80-fold higher compared with the Lactococcus lactis NZ9000-pNZ8148 control, respectively. These results indicate that PFK and GK are important for the ethanol tolerance of LAB and can increase the ethanol tolerance of Lactococcus lactis NZ9000. Hence, PFK and G K were identified as key genes of L. paracasei SX10 with a high ethanol tolerance. Our results provide novel insight for further studies to perform a systematic analysis of the differentially expressed genes and to determine their potential functions in the ethanol tolerance mechanism of LAB. [ABSTRACT FROM AUTHOR]

Published

2020

44. Assessment of ethanol tolerance of Kluyveromyces marxianus CCT 7735 selected by adaptive laboratory evolution.

Author

da Silveira, Fernando Augusto, de Oliveira Soares, Dalila Luzia, Bang, Kyung Whan, Balbino, Thércia Rocha, de Moura Ferreira, Maurício Alexander, Diniz, Raphael Hermano Santos, de Lima, Lorena Azevedo, Brandão, Marcelo Mendes, Villas-Bôas, Silas Granato, and da Silveira, Wendel Batista

Subjects

*KLUYVEROMYCES marxianus, *KREBS cycle, *FATTY acid methyl esters, *ETHANOL

Abstract

Kluyveromyces marxianus CCT 7735 shows potential for producing ethanol from lactose; however, its low ethanol tolerance is a drawback for its industrial application. The first aim of this study was to obtain four ethanol-tolerant K. marxianus CCT 7735 strains (ETS1, ETS2, ETS3, and ETS4) by adaptive laboratory evolution. The second aim was to select among them the strain that stood out and to evaluate metabolic changes associated with the improved ethanol tolerance in this strain. The ETS4 was selected for displaying a specific growth rate higher than the parental strain under ethanol stress (122%) and specific ethanol production rate (0.26 g/g/h) higher than those presented by the ETS1 (0.22 g/g/h), ETS2 (0.17 g/g/h), and ETS3 (0.17 g/g/h) under non-stress condition. Further analyses were performed with the ETS4 in comparison with its parental strain in order to characterize metabolic changes. Accumulation of valine and metabolites of the citric acid cycle (isocitric acid, citric acid, and cis-aconitic acid) was observed only in the ETS4 subjected to ethanol stress. Their accumulation in this strain may have been important to increase ethanol tolerance. Furthermore, the contents of fatty acid methyl esters and ergosterol were higher in the ETS4 than in the parental strain. These differences likely contributed to enhance ethanol tolerance in the ETS4. Key points: • K. marxianus ethanol-tolerant strains were selected by adaptive laboratory evolution. • Valine and metabolites of the TCA cycle were accumulated in the ETS4. • High contents of fatty acids and ergosterol contributed to enhance ethanol tolerance. [ABSTRACT FROM AUTHOR]

Published

2020

45. 副干酪乳杆菌SMN-LBK在乙醇 胁迫下的转录组分析.

Author

郭金凤, 杨 婕, 李宝坤, 金 丹, 黎 旭, 卢士玲, 王庆玲, 姬 华, 董 娟, 李应彪, and 蒋彩虹

Abstract

Copyright of Shipin Kexue/ Food Science is the property of Food Science Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

46. Does Inter-Organellar Proteostasis Impact Yeast Quality and Performance During Beer Fermentation?

Author

Telini, Bianca de Paula, Menoncin, Marcelo, and Bonatto, Diego

Subjects

ENDOPLASMIC reticulum, BREWING, FERMENTATION, LAGER beer, UBIQUITIN ligases, YEAST, BEER, ORGANELLES

Abstract

During beer production, yeast generate ethanol that is exported to the extracellular environment where it accumulates. Depending on the initial carbohydrate concentration in the wort, the amount of yeast biomass inoculated, the fermentation temperature, and the yeast attenuation capacity, a high concentration of ethanol can be achieved in beer. The increase in ethanol concentration as a consequence of the fermentation of high gravity (HG) or very high gravity (VHG) worts promotes deleterious pleiotropic effects on the yeast cells. Moderate concentrations of ethanol (5% v/v) change the enzymatic kinetics of proteins and affect biological processes, such as the cell cycle and metabolism, impacting the reuse of yeast for subsequent fermentation. However, high concentrations of ethanol (> 5% v/v) dramatically alter protein structure, leading to unfolded proteins as well as amorphous protein aggregates. It is noteworthy that the effects of elevated ethanol concentrations generated during beer fermentation resemble those of heat shock stress, with similar responses observed in both situations, such as the activation of proteostasis and protein quality control mechanisms in different cell compartments, including endoplasmic reticulum (ER), mitochondria, and cytosol. Despite the extensive published molecular and biochemical data regarding the roles of proteostasis in different organelles of yeast cells, little is known about how this mechanism impacts beer fermentation and how different proteostasis mechanisms found in ER, mitochondria, and cytosol communicate with each other during ethanol/fermentative stress. Supporting this integrative view, transcriptome data analysis was applied using publicly available information for a lager yeast strain grown under beer production conditions. The transcriptome data indicated upregulation of genes that encode chaperones, co-chaperones, unfolded protein response elements in ER and mitochondria, ubiquitin ligases, proteasome components, N- glycosylation quality control pathway proteins, and components of processing bodies (p-bodies) and stress granules (SGs) during lager beer fermentation. Thus, the main purpose of this hypothesis and theory manuscript is to provide a concise picture of how inter-organellar proteostasis mechanisms are connected with one another and with biological processes that may modulate the viability and/or vitality of yeast populations during HG/VHG beer fermentation and serial repitching. [ABSTRACT FROM AUTHOR]

Published

2020

47. Determining the transcriptional response of Saccharomyces cerevisiae to ethanol stress

Author

Toft, Christina, Sabater-Muñoz, Beatriz, Ministerio de Economía y Competitividad (España), Mengual Martí, Jordi, Toft, Christina, Sabater-Muñoz, Beatriz, Ministerio de Economía y Competitividad (España), and Mengual Martí, Jordi

Abstract

[EN] Gene duplication stands out as a crucial molecular mechanism driving biological innovation and genetic diversity, encompassing significant implications for evolution, such as speciation. In Saccharomyces cerevisiae, the budding yeast, a set of duplicated genes originating from an ancestral whole-genome and coetaneous small-scale duplication events, led to the establishment of glucose metabolism as main carbon source, with ethanol as main end product, and glucose-mediated repression, displaying a key role in adaptation to environmental conditions. Ethanol, a primary by-product of yeast sugar fermentation, plays a dual role as both a nutrient and stressor, impacting microbial growth. The "make-accumulate-consume" strategy, wherein S. cerevisiae, during sugar scarcity, utilizes ethanol through respiration as energy source, has been linked to the yeast evolutionary origin. This study explores yeasts response to chronic ethanol exposure, investigating transcriptomic adaptations to ethanol as a nonfermentative carbon source, emphasizing the role of duplicated genes in the adaptive process. The research methodology encompassed an integrative approach, subjecting S. cerevisiae to ethanol as the sole carbon source and conducting a small adaptive experimental evolution. The transcriptomic changes were determined through RNA-seq bioinformatics analysis, shedding light on the stress responses to ethanol and the role of duplicated genes in the process., [ES] La duplicación de genes destaca como un mecanismo molecular impulsor de la innovación biológica, abarcando implicaciones significativas para la evolución, como la especiación. En Saccharomyces cerevisiae, un conjunto de genes duplicados procedentes de una duplicación de genoma completo ancestral y de eventos coetáneos de duplicación a pequeña escala, condujo al establecimiento del metabolismo de la glucosa como principal fuente de carbono, con etanol como producto final principal y a la represión mediada por glucosa, mostrando un papel clave en la adaptación a condiciones ambientales cambiantes. El etanol, un subproducto primario de la fermentación de azúcares en levaduras, desempeña un doble papel como nutriente y factor de estrés, afectando al crecimiento microbiano. La estrategia de "producción-acumulación-consumo", en la que S. cerevisiae, durante la escasez de glucosa, utiliza el etanol a través de la respiración como fuente de energía, se ha relacionado con su origen evolutivo. Este estudio explora la respuesta de las levaduras a la exposición crónica al etanol, investigando las adaptaciones transcriptómicas al crecimiento en etanol como fuente de carbono no fermentativa, enfatizando el papel de los genes duplicados en el proceso adaptativo. La metodología abarca un enfoque integrado, sometiendo a S. cerevisiae al etanol como única fuente de carbono y llevando a cabo una evolución experimental. Los cambios transcriptómicos se determinaron mediante el análisis bioinformático de los datos obtenidos por RNA-seq, arrojando luz sobre las respuestas al estrés por etanol y el papel de los genes duplicados en el proceso.

Published

2023

48. Protective Effects of Melatonin on Saccharomyces cerevisiae under Ethanol Stress

Author

Mercè Sunyer-Figueres, Albert Mas, Gemma Beltran, and María-Jesús Torija

Subjects

ethanol stress, yeast antioxidant response, melatonin supplementation, ROS accumulation, catalase activity, superoxide dismutase, Therapeutics. Pharmacology, RM1-950

Abstract

During alcoholic fermentation, Saccharomyces cerevisiae is subjected to several stresses, among which ethanol is of capital importance. Melatonin, a bioactive molecule synthesized by yeast during alcoholic fermentation, has an antioxidant role and is proposed to contribute to counteracting fermentation-associated stresses. The aim of this study was to unravel the protective effect of melatonin on yeast cells subjected to ethanol stress. For that purpose, the effect of ethanol concentrations (6 to 12%) on a wine strain and a lab strain of S. cerevisiae was evaluated, monitoring the viability, growth capacity, mortality, and several indicators of oxidative stress over time, such as reactive oxygen species (ROS) accumulation, lipid peroxidation, and the activity of catalase and superoxide dismutase enzymes. In general, ethanol exposure reduced the cell growth of S. cerevisiae and increased mortality, ROS accumulation, lipid peroxidation and antioxidant enzyme activity. Melatonin supplementation softened the effect of ethanol, enhancing cell growth and decreasing oxidative damage by lowering ROS accumulation, lipid peroxidation, and antioxidant enzyme activities. However, the effects of melatonin were dependent on strain, melatonin concentration, and growth phase. The results of this study indicate that melatonin has a protective role against mild ethanol stress, mainly by reducing the oxidative stress triggered by this alcohol.

Published

2021

49. Yeast mRNA Flux During Brewing and Under Ethanol Stress Conditions

Author

Izawa, Shingo, Takagi, Hiroshi, editor, and Kitagaki, Hiroshi, editor

Published

2015

50. Development of a core Clostridium thermocellum kinetic metabolic model consistent with multiple genetic perturbations

Author

Satyakam Dash, Ali Khodayari, Jilai Zhou, Evert K. Holwerda, Daniel G. Olson, Lee R. Lynd, and Costas D. Maranas

Subjects

Clostridium thermocellum, Genome-scale metabolic model, Kinetic model, Ensemble modeling, Nitrogen limitation, Ethanol stress, Fuel, TP315-360, Biotechnology, TP248.13-248.65

Abstract

Abstract Background Clostridium thermocellum is a Gram-positive anaerobe with the ability to hydrolyze and metabolize cellulose into biofuels such as ethanol, making it an attractive candidate for consolidated bioprocessing (CBP). At present, metabolic engineering in C. thermocellum is hindered due to the incomplete description of its metabolic repertoire and regulation within a predictive metabolic model. Genome-scale metabolic (GSM) models augmented with kinetic models of metabolism have been shown to be effective at recapitulating perturbed metabolic phenotypes. Results In this effort, we first update a second-generation genome-scale metabolic model (iCth446) for C. thermocellum by correcting cofactor dependencies, restoring elemental and charge balances, and updating GAM and NGAM values to improve phenotype predictions. The iCth446 model is next used as a scaffold to develop a core kinetic model (k-ctherm118) of the C. thermocellum central metabolism using the Ensemble Modeling (EM) paradigm. Model parameterization is carried out by simultaneously imposing fermentation yield data in lactate, malate, acetate, and hydrogen production pathways for 19 measured metabolites spanning a library of 19 distinct single and multiple gene knockout mutants along with 18 intracellular metabolite concentration data for a Δgldh mutant and ten experimentally measured Michaelis–Menten kinetic parameters. Conclusions The k-ctherm118 model captures significant metabolic changes caused by (1) nitrogen limitation leading to increased yields for lactate, pyruvate, and amino acids, and (2) ethanol stress causing an increase in intracellular sugar phosphate concentrations (~1.5-fold) due to upregulation of cofactor pools. Robustness analysis of k-ctherm118 alludes to the presence of a secondary activity of ketol-acid reductoisomerase and possible regulation by valine and/or leucine pool levels. In addition, cross-validation and robustness analysis allude to missing elements in k-ctherm118 and suggest additional experiments to improve kinetic model prediction fidelity. Overall, the study quantitatively assesses the advantages of EM-based kinetic modeling towards improved prediction of C. thermocellum metabolism and develops a predictive kinetic model which can be used to design biofuel-overproducing strains.

Published

2017