Integrative Analysis of the Ethanol Tolerance of 
        Saccharomyces cerevisiae.

Ivan Rodrigo Wolf; Lucas Farinazzo Marques; Lauana Fogaça de Almeida; Lucas Cardoso Lázari; Leonardo Nazário de Moraes; Luiz Henrique Cardoso; Camila Cristina de Oliveira Alves; Rafael Takahiro Nakajima; Amanda Piveta Schnepper; Marjorie de Assis Golim; Thais Regiani Cataldi; Jeroen G Nijland; Camila Moreira Pinto; Matheus Naia Fioretto; Rodrigo Oliveira Almeida; Arnold J M Driessen; Rafael Plana Simōes; Mônica Veneziano Labate; Rejane Maria Tommasini Grotto; Carlos Alberto Labate; Ary Fernandes Junior; Luis Antonio Justulin; Rafael Luiz Buogo Coan; Érica Ramos; Fabiana Barcelos Furtado; Cesar Martins; Guilherme Targino Valente

doi:10.3390/ijms24065646

Integrative Analysis of the Ethanol Tolerance of Saccharomyces cerevisiae.

Ivan Rodrigo Wolf, Lucas Farinazzo Marques, Lauana Fogaça de Almeida, Lucas Cardoso Lázari, Leonardo Nazário de Moraes, Luiz Henrique Cardoso, Camila Cristina de Oliveira Alves, Rafael Takahiro Nakajima, Amanda Piveta Schnepper, Marjorie de Assis Golim, Thais Regiani Cataldi, Jeroen G Nijland, Camila Moreira Pinto, Matheus Naia Fioretto, Rodrigo Oliveira Almeida, Arnold J M Driessen, Rafael Plana Simōes, Mônica Veneziano Labate, Rejane Maria Tommasini Grotto, Carlos Alberto LabateAry Fernandes Junior, Luis Antonio Justulin, Rafael Luiz Buogo Coan, Érica Ramos, Fabiana Barcelos Furtado, Cesar Martins, Guilherme Targino Valente

Moleculaire Microbiologie

Onderzoeksoutput: Article › Academic › peer review

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Ethanol (EtOH) alters many cellular processes in yeast. An integrated view of different EtOH-tolerant phenotypes and their long noncoding RNAs (lncRNAs) is not yet available. Here, large-scale data integration showed the core EtOH-responsive pathways, lncRNAs, and triggers of higher (HT) and lower (LT) EtOH-tolerant phenotypes. LncRNAs act in a strain-specific manner in the EtOH stress response. Network and omics analyses revealed that cells prepare for stress relief by favoring activation of life-essential systems. Therefore, longevity, peroxisomal, energy, lipid, and RNA/protein metabolisms are the core processes that drive EtOH tolerance. By integrating omics, network analysis, and several other experiments, we showed how the HT and LT phenotypes may arise: (1) the divergence occurs after cell signaling reaches the longevity and peroxisomal pathways, with CTA1 and ROS playing key roles; (2) signals reaching essential ribosomal and RNA pathways via SUI2 enhance the divergence; (3) specific lipid metabolism pathways also act on phenotype-specific profiles; (4) HTs take greater advantage of degradation and membraneless structures to cope with EtOH stress; and (5) our EtOH stress-buffering model suggests that diauxic shift drives EtOH buffering through an energy burst, mainly in HTs. Finally, critical genes, pathways, and the first models including lncRNAs to describe nuances of EtOH tolerance are reported here.

Originele taal-2	English
Artikelnummer	5646
Aantal pagina's	25
Tijdschrift	International Journal of Molecular Sciences
Volume	24
Nummer van het tijdschrift	6
DOI's	https://doi.org/10.3390/ijms24065646
Status	Published - 15-mrt.-2023

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10.3390/ijms24065646Licentie: CC BY

Integrative Analysis of the Ethanol Tolerance of Saccharomyces cerevisiaeFinal publisher's version, 3,29 MBLicentie: CC BY

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Wolf, I. R., Marques, L. F., de Almeida, L. F., Lázari, L. C., de Moraes, L. N., Cardoso, L. H., Alves, C. C. D. O., Nakajima, R. T., Schnepper, A. P., Golim, M. D. A., Cataldi, T. R., Nijland, J. G., Pinto, C. M., Fioretto, M. N., Almeida, R. O., Driessen, A. J. M., Simōes, R. P., Labate, M. V., Grotto, R. M. T., ... Valente, G. T. (2023). Integrative Analysis of the Ethanol Tolerance of Saccharomyces cerevisiae. International Journal of Molecular Sciences, 24(6), Artikel 5646. https://doi.org/10.3390/ijms24065646

@article{f2fc5af6e02a45d88f62fc3c69fd65d6,

title = "Integrative Analysis of the Ethanol Tolerance of Saccharomyces cerevisiae.",

abstract = "Ethanol (EtOH) alters many cellular processes in yeast. An integrated view of different EtOH-tolerant phenotypes and their long noncoding RNAs (lncRNAs) is not yet available. Here, large-scale data integration showed the core EtOH-responsive pathways, lncRNAs, and triggers of higher (HT) and lower (LT) EtOH-tolerant phenotypes. LncRNAs act in a strain-specific manner in the EtOH stress response. Network and omics analyses revealed that cells prepare for stress relief by favoring activation of life-essential systems. Therefore, longevity, peroxisomal, energy, lipid, and RNA/protein metabolisms are the core processes that drive EtOH tolerance. By integrating omics, network analysis, and several other experiments, we showed how the HT and LT phenotypes may arise: (1) the divergence occurs after cell signaling reaches the longevity and peroxisomal pathways, with CTA1 and ROS playing key roles; (2) signals reaching essential ribosomal and RNA pathways via SUI2 enhance the divergence; (3) specific lipid metabolism pathways also act on phenotype-specific profiles; (4) HTs take greater advantage of degradation and membraneless structures to cope with EtOH stress; and (5) our EtOH stress-buffering model suggests that diauxic shift drives EtOH buffering through an energy burst, mainly in HTs. Finally, critical genes, pathways, and the first models including lncRNAs to describe nuances of EtOH tolerance are reported here.",

keywords = "Saccharomyces cerevisiae/genetics, RNA, Long Noncoding/genetics, Ethanol/pharmacology",

author = "Wolf, \{Ivan Rodrigo\} and Marques, \{Lucas Farinazzo\} and \{de Almeida\}, \{Lauana Foga{\c c}a\} and L{\'a}zari, \{Lucas Cardoso\} and \{de Moraes\}, \{Leonardo Naz{\'a}rio\} and Cardoso, \{Luiz Henrique\} and Alves, \{Camila Cristina de Oliveira\} and Nakajima, \{Rafael Takahiro\} and Schnepper, \{Amanda Piveta\} and Golim, \{Marjorie de Assis\} and Cataldi, \{Thais Regiani\} and Nijland, \{Jeroen G\} and Pinto, \{Camila Moreira\} and Fioretto, \{Matheus Naia\} and Almeida, \{Rodrigo Oliveira\} and Driessen, \{Arnold J M\} and Simōes, \{Rafael Plana\} and Labate, \{M{\^o}nica Veneziano\} and Grotto, \{Rejane Maria Tommasini\} and Labate, \{Carlos Alberto\} and \{Fernandes Junior\}, Ary and Justulin, \{Luis Antonio\} and Coan, \{Rafael Luiz Buogo\} and {\'E}rica Ramos and Furtado, \{Fabiana Barcelos\} and Cesar Martins and Valente, \{Guilherme Targino\}",

year = "2023",

month = mar,

day = "15",

doi = "10.3390/ijms24065646",

language = "English",

volume = "24",

journal = "International Journal of Molecular Sciences",

issn = "1422-0067",

publisher = "MDPI AG",

number = "6",

}

Wolf, IR, Marques, LF, de Almeida, LF, Lázari, LC, de Moraes, LN, Cardoso, LH, Alves, CCDO, Nakajima, RT, Schnepper, AP, Golim, MDA, Cataldi, TR, Nijland, JG, Pinto, CM, Fioretto, MN, Almeida, RO, Driessen, AJM, Simōes, RP, Labate, MV, Grotto, RMT, Labate, CA, Fernandes Junior, A, Justulin, LA, Coan, RLB, Ramos, É, Furtado, FB, Martins, C & Valente, GT 2023, 'Integrative Analysis of the Ethanol Tolerance of Saccharomyces cerevisiae.', International Journal of Molecular Sciences, vol. 24, nr. 6, 5646. https://doi.org/10.3390/ijms24065646

TY - JOUR

T1 - Integrative Analysis of the Ethanol Tolerance of Saccharomyces cerevisiae.

AU - Wolf, Ivan Rodrigo

AU - Marques, Lucas Farinazzo

AU - de Almeida, Lauana Fogaça

AU - Lázari, Lucas Cardoso

AU - de Moraes, Leonardo Nazário

AU - Cardoso, Luiz Henrique

AU - Alves, Camila Cristina de Oliveira

AU - Nakajima, Rafael Takahiro

AU - Schnepper, Amanda Piveta

AU - Golim, Marjorie de Assis

AU - Cataldi, Thais Regiani

AU - Nijland, Jeroen G

AU - Pinto, Camila Moreira

AU - Fioretto, Matheus Naia

AU - Almeida, Rodrigo Oliveira

AU - Driessen, Arnold J M

AU - Simōes, Rafael Plana

AU - Labate, Mônica Veneziano

AU - Grotto, Rejane Maria Tommasini

AU - Labate, Carlos Alberto

AU - Fernandes Junior, Ary

AU - Justulin, Luis Antonio

AU - Coan, Rafael Luiz Buogo

AU - Ramos, Érica

AU - Furtado, Fabiana Barcelos

AU - Martins, Cesar

AU - Valente, Guilherme Targino

PY - 2023/3/15

Y1 - 2023/3/15

N2 - Ethanol (EtOH) alters many cellular processes in yeast. An integrated view of different EtOH-tolerant phenotypes and their long noncoding RNAs (lncRNAs) is not yet available. Here, large-scale data integration showed the core EtOH-responsive pathways, lncRNAs, and triggers of higher (HT) and lower (LT) EtOH-tolerant phenotypes. LncRNAs act in a strain-specific manner in the EtOH stress response. Network and omics analyses revealed that cells prepare for stress relief by favoring activation of life-essential systems. Therefore, longevity, peroxisomal, energy, lipid, and RNA/protein metabolisms are the core processes that drive EtOH tolerance. By integrating omics, network analysis, and several other experiments, we showed how the HT and LT phenotypes may arise: (1) the divergence occurs after cell signaling reaches the longevity and peroxisomal pathways, with CTA1 and ROS playing key roles; (2) signals reaching essential ribosomal and RNA pathways via SUI2 enhance the divergence; (3) specific lipid metabolism pathways also act on phenotype-specific profiles; (4) HTs take greater advantage of degradation and membraneless structures to cope with EtOH stress; and (5) our EtOH stress-buffering model suggests that diauxic shift drives EtOH buffering through an energy burst, mainly in HTs. Finally, critical genes, pathways, and the first models including lncRNAs to describe nuances of EtOH tolerance are reported here.

AB - Ethanol (EtOH) alters many cellular processes in yeast. An integrated view of different EtOH-tolerant phenotypes and their long noncoding RNAs (lncRNAs) is not yet available. Here, large-scale data integration showed the core EtOH-responsive pathways, lncRNAs, and triggers of higher (HT) and lower (LT) EtOH-tolerant phenotypes. LncRNAs act in a strain-specific manner in the EtOH stress response. Network and omics analyses revealed that cells prepare for stress relief by favoring activation of life-essential systems. Therefore, longevity, peroxisomal, energy, lipid, and RNA/protein metabolisms are the core processes that drive EtOH tolerance. By integrating omics, network analysis, and several other experiments, we showed how the HT and LT phenotypes may arise: (1) the divergence occurs after cell signaling reaches the longevity and peroxisomal pathways, with CTA1 and ROS playing key roles; (2) signals reaching essential ribosomal and RNA pathways via SUI2 enhance the divergence; (3) specific lipid metabolism pathways also act on phenotype-specific profiles; (4) HTs take greater advantage of degradation and membraneless structures to cope with EtOH stress; and (5) our EtOH stress-buffering model suggests that diauxic shift drives EtOH buffering through an energy burst, mainly in HTs. Finally, critical genes, pathways, and the first models including lncRNAs to describe nuances of EtOH tolerance are reported here.

KW - Saccharomyces cerevisiae/genetics

KW - RNA, Long Noncoding/genetics

KW - Ethanol/pharmacology

U2 - 10.3390/ijms24065646

DO - 10.3390/ijms24065646

M3 - Article

C2 - 36982719

SN - 1422-0067

VL - 24

JO - International Journal of Molecular Sciences

JF - International Journal of Molecular Sciences

IS - 6

M1 - 5646

ER -

Integrative Analysis of the Ethanol Tolerance of Saccharomyces cerevisiae.

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