{"status":"ok","message-type":"work","message-version":"1.0.0","message":{"indexed":{"date-parts":[[2026,4,16]],"date-time":"2026-04-16T07:59:13Z","timestamp":1776326353967,"version":"3.50.1"},"reference-count":43,"publisher":"Springer Science and Business Media LLC","issue":"1","license":[{"start":{"date-parts":[[2021,6,16]],"date-time":"2021-06-16T00:00:00Z","timestamp":1623801600000},"content-version":"tdm","delay-in-days":0,"URL":"https:\/\/creativecommons.org\/licenses\/by\/4.0"},{"start":{"date-parts":[[2021,6,16]],"date-time":"2021-06-16T00:00:00Z","timestamp":1623801600000},"content-version":"vor","delay-in-days":0,"URL":"https:\/\/creativecommons.org\/licenses\/by\/4.0"}],"funder":[{"DOI":"10.13039\/501100001871","name":"Funda\u00e7\u00e3o para a Ci\u00eancia e a Tecnologia","doi-asserted-by":"publisher","award":["PD\/BD\/135204\/2017"],"award-info":[{"award-number":["PD\/BD\/135204\/2017"]}],"id":[{"id":"10.13039\/501100001871","id-type":"DOI","asserted-by":"publisher"}]},{"DOI":"10.13039\/501100001871","name":"Funda\u00e7\u00e3o para a Ci\u00eancia e a Tecnologia","doi-asserted-by":"publisher","award":["PD\/BD\/105975\/2014"],"award-info":[{"award-number":["PD\/BD\/105975\/2014"]}],"id":[{"id":"10.13039\/501100001871","id-type":"DOI","asserted-by":"publisher"}]},{"DOI":"10.13039\/501100001871","name":"Funda\u00e7\u00e3o para a Ci\u00eancia e a Tecnologia","doi-asserted-by":"publisher","award":["PD\/BD\/150339\/2019"],"award-info":[{"award-number":["PD\/BD\/150339\/2019"]}],"id":[{"id":"10.13039\/501100001871","id-type":"DOI","asserted-by":"publisher"}]}],"content-domain":{"domain":["link.springer.com"],"crossmark-restriction":false},"short-container-title":["Sci Rep"],"abstract":"Abstract<\/jats:title>This work describes a coordinate and comprehensive view on the time course of the alterations occurring at the level of the cell wall during adaptation of a yeast cell population to sudden exposure to a sub-lethal stress induced by acetic acid. Acetic acid is a major inhibitory compound in industrial bioprocesses and a widely used preservative in foods and beverages. Results indicate that yeast cell wall resistance to lyticase activity increases during acetic acid-induced growth latency, corresponding to yeast population adaptation to sudden exposure to this stress. This response correlates with: (i) increased cell stiffness, assessed by atomic force microscopy (AFM); (ii) increased content of cell wall \u03b2-glucans, assessed by fluorescence microscopy, and (iii) slight increase of the transcription level of the GAS1<\/jats:italic> gene encoding a \u03b2-1,3-glucanosyltransferase that leads to elongation of (1\u21923)-\u03b2-d<\/jats:sc>-glucan chains. Collectively, results reinforce the notion that the adaptive yeast response to acetic acid stress involves a coordinate alteration of the cell wall at the biophysical and molecular levels. These alterations guarantee a robust adaptive response essential to limit the futile cycle associated to the re-entry of the toxic acid form after the active expulsion of acetate from the cell interior.<\/jats:p>","DOI":"10.1038\/s41598-021-92069-3","type":"journal-article","created":{"date-parts":[[2021,6,16]],"date-time":"2021-06-16T10:03:04Z","timestamp":1623837784000},"update-policy":"https:\/\/doi.org\/10.1007\/springer_crossmark_policy","source":"Crossref","is-referenced-by-count":54,"title":["Yeast adaptive response to acetic acid stress involves structural alterations and increased stiffness of the cell wall"],"prefix":"10.1038","volume":"11","author":[{"given":"Ricardo A.","family":"Ribeiro","sequence":"first","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]},{"given":"Miguel V.","family":"Vitorino","sequence":"additional","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]},{"given":"Cl\u00e1udia P.","family":"Godinho","sequence":"additional","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]},{"given":"Nuno","family":"Bourbon-Melo","sequence":"additional","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]},{"given":"Tiago T.","family":"Robalo","sequence":"additional","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]},{"given":"F\u00e1bio","family":"Fernandes","sequence":"additional","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]},{"given":"M\u00e1rio S.","family":"Rodrigues","sequence":"additional","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]},{"given":"Isabel","family":"S\u00e1-Correia","sequence":"additional","affiliation":[],"role":[{"role":"author","vocabulary":"crossref"}]}],"member":"297","published-online":{"date-parts":[[2021,6,16]]},"reference":[{"key":"92069_CR1","doi-asserted-by":"crossref","unstructured":"Palma, M. & S\u00e1-Correia, I. Physiological Genomics of the Highly Weak-Acid-Tolerant Food Spoilage Yeasts of Zygosaccharomyces bailii sensu lato. in\u00a0Progress in molecular and subcellular biology\u00a0vol. 58 85\u2013109 (Springer International Publishing, 2019).","DOI":"10.1007\/978-3-030-13035-0_4"},{"key":"92069_CR2","doi-asserted-by":"publisher","first-page":"274","DOI":"10.3389\/fmicb.2018.00274","volume":"9","author":"M Palma","year":"2018","unstructured":"Palma, M., Guerreiro, J. F. & S\u00e1-Correia, I. Adaptive response and tolerance to acetic acid in Saccharomyces cerevisiae and Zygosaccharomyces bailii: A physiological genomics perspective. Front. Microbiol. 9, 274 (2018).","journal-title":"Front. Microbiol."},{"key":"92069_CR3","doi-asserted-by":"publisher","first-page":"159","DOI":"10.1007\/s00253-018-9478-3","volume":"103","author":"JT Cunha","year":"2019","unstructured":"Cunha, J. T., Roman\u00ed, A., Costa, C. E., S\u00e1-Correia, I. & Domingues, L. Molecular and physiological basis of Saccharomyces cerevisiae tolerance to adverse lignocellulose-based process conditions. Appl. Microbiol. Biotechnol. 103, 159\u2013175 (2019).","journal-title":"Appl. Microbiol. Biotechnol."},{"key":"92069_CR4","unstructured":"Lide, D. R. DISSOCIATION CONSTANTS OF ORGANIC ACIDS AND BASES. in CRC Handbook of Chemistry and Physics 8\u201346 (CRC Press, 2003)."},{"key":"92069_CR5","doi-asserted-by":"publisher","first-page":"924","DOI":"10.1111\/j.1567-1364.2006.00089.x","volume":"6","author":"M Kawahata","year":"2006","unstructured":"Kawahata, M., Masaki, K., Fujii, T. & Iefuji, H. Yeast genes involved in response to lactic acid and acetic acid: Acidic conditions caused by the organic acids in Saccharomyces cerevisiae cultures induce expression of intracellular metal metabolism genes regulated by Aft1p. FEMS Yeast Res. 6, 924\u2013936 (2006).","journal-title":"FEMS Yeast Res."},{"key":"92069_CR6","doi-asserted-by":"publisher","first-page":"79","DOI":"10.1186\/1475-2859-9-79","volume":"9","author":"NP Mira","year":"2010","unstructured":"Mira, N. P., Palma, M., Guerreiro, J. F. & S\u00e1-Correia, I. Genome-wide identification of Saccharomyces cerevisiae genes required for tolerance to acetic acid. Microb. Cell Fact. 9, 79 (2010).","journal-title":"Microb. Cell Fact."},{"key":"92069_CR7","doi-asserted-by":"publisher","first-page":"819","DOI":"10.1111\/j.1567-1364.2007.00242.x","volume":"7","author":"DA Abbott","year":"2007","unstructured":"Abbott, D. A. et al. Generic and specific transcriptional responses to different weak organic acids in anaerobic chemostat cultures of Saccharomyces cerevisiae. FEMS Yeast Res. 7, 819\u2013833 (2007).","journal-title":"FEMS Yeast Res."},{"key":"92069_CR8","doi-asserted-by":"publisher","first-page":"1915","DOI":"10.1007\/s00253-010-2518-2","volume":"86","author":"BZ Li","year":"2010","unstructured":"Li, B. Z. & Yuan, Y. J. Transcriptome shifts in response to furfural and acetic acid in Saccharomyces cerevisiae. Appl. Microbiol. Biotechnol. 86, 1915\u20131924 (2010).","journal-title":"Appl. Microbiol. Biotechnol."},{"key":"92069_CR9","doi-asserted-by":"publisher","first-page":"587","DOI":"10.1089\/omi.2010.0048","volume":"14","author":"NP Mira","year":"2010","unstructured":"Mira, N. P., Becker, J. D. & S\u00e1-Correia, I. Genomic expression program involving the Haa1p-regulon in Saccharomyces cerevisiae response to acetic acid. Omi. A J. Integr. Biol. 14, 587\u2013601 (2010).","journal-title":"Omi. A J. Integr. Biol."},{"key":"92069_CR10","doi-asserted-by":"publisher","first-page":"1281","DOI":"10.1007\/s10482-013-9909-1","volume":"103","author":"PK Bajwa","year":"2013","unstructured":"Bajwa, P. K. et al. Transcriptional profiling of Saccharomyces cerevisiae T2 cells upon exposure to hardwood spent sulphite liquor: Comparison to acetic acid, furfural and hydroxymethylfurfural. Antonie van Leeuwenhoek Int. J. Gen. Mol. Microbiol. 103, 1281\u20131295 (2013).","journal-title":"Antonie van Leeuwenhoek Int. J. Gen. Mol. Microbiol."},{"key":"92069_CR11","doi-asserted-by":"publisher","first-page":"42659","DOI":"10.1038\/srep42659","volume":"7","author":"Y Dong","year":"2017","unstructured":"Dong, Y., Hu, J., Fan, L. & Chen, Q. RNA-Seq-based transcriptomic and metabolomic analysis reveal stress responses and programmed cell death induced by acetic acid in Saccharomyces cerevisiae. Sci. Rep. 7, 42659 (2017).","journal-title":"Sci. Rep."},{"key":"92069_CR12","first-page":"1","volume":"2","author":"M Antunes","year":"2018","unstructured":"Antunes, M., Palma, M. & S\u00e1-correia, I. Transcriptional profiling of Zygosaccharomyces bailii early response to acetic acid or copper stress mediated by ZbHaa1. Sci. Rep. 2, 1\u201314 (2018).","journal-title":"Sci. Rep."},{"key":"92069_CR13","doi-asserted-by":"publisher","first-page":"173","DOI":"10.1016\/j.jprot.2015.08.003","volume":"128","author":"V Longo","year":"2015","unstructured":"Longo, V. et al. Proteome and metabolome profiling of wild-type and YCA1-knock-out yeast cells during acetic acid-induced programmed cell death. J. Proteomics 128, 173\u2013188 (2015).","journal-title":"J. Proteomics"},{"key":"92069_CR14","doi-asserted-by":"publisher","first-page":"720","DOI":"10.1002\/pmic.200700816","volume":"9","author":"B Almeida","year":"2009","unstructured":"Almeida, B. et al. Yeast protein expression profile during acetic acid-induced apoptosis indicates causal involvement of the TOR pathway. Proteomics 9, 720\u2013732 (2009).","journal-title":"Proteomics"},{"key":"92069_CR15","first-page":"1","volume":"8","author":"CP Godinho","year":"2018","unstructured":"Godinho, C. P. et al. Pdr18 is involved in yeast response to acetic acid stress counteracting the decrease of plasma membrane ergosterol content and order. Sci. Rep. 8, 1\u201313 (2018).","journal-title":"Sci. Rep."},{"key":"92069_CR16","first-page":"1","volume":"8","author":"L Lindberg","year":"2013","unstructured":"Lindberg, L., Santos, A. X. S., Riezman, H., Olsson, L. & Bettiga, M. Lipidomic profiling of Saccharomyces cerevisiae and Zygosaccharomyces bailii reveals critical changes in lipid composition in response to acetic acid stress. PLoS ONE 8, 1\u201312 (2013).","journal-title":"PLoS ONE"},{"key":"92069_CR17","doi-asserted-by":"publisher","first-page":"744","DOI":"10.1002\/bit.25845","volume":"113","author":"L Lindahl","year":"2016","unstructured":"Lindahl, L., Genheden, S., Eriksson, L. A., Olsson, L. & Bettiga, M. Sphingolipids contribute to acetic acid resistance in Zygosaccharomyces bailii. Biotechnol. Bioeng. 113, 744\u2013753 (2016).","journal-title":"Biotechnol. Bioeng."},{"key":"92069_CR18","first-page":"1","volume-title":"Yeasts in Biotechnology and Human Health\u2013Physiological Genomic Approaches","author":"CP Godinho","year":"2019","unstructured":"Godinho, C. P. & S\u00e1-Correia, I. Physiological genomics of multistress resistance in the yeast cell model and factory: Focus on MDR\/MXR transporters. In Yeasts in Biotechnology and Human Health\u2013Physiological Genomic Approaches (ed. S\u00e1-Correia, I.) 1\u201335 (Springer International Publishing, 2019)."},{"key":"92069_CR19","doi-asserted-by":"publisher","first-page":"142","DOI":"10.3389\/fmicb.2013.00142","volume":"4","author":"A Ullah","year":"2013","unstructured":"Ullah, A., Chandrasekaran, G., Brul, S. & Smits, G. J. Yeast adaptation to weak acids prevents futile energy expenditure. Front. Microbiol. 4, 142 (2013).","journal-title":"Front. Microbiol."},{"key":"92069_CR20","doi-asserted-by":"publisher","first-page":"11","DOI":"10.1007\/978-3-319-25304-6_2","volume":"892","author":"JM Francois","year":"2016","unstructured":"Francois, J. M. Cell surface interference with plasma membrane and transport processes in yeasts. Adv. Exp. Med. Biol. 892, 11\u201331 (2016).","journal-title":"Adv. Exp. Med. Biol."},{"key":"92069_CR21","doi-asserted-by":"publisher","first-page":"673","DOI":"10.1002\/yea.1801","volume":"27","author":"E Dague","year":"2010","unstructured":"Dague, E. et al. An atomic force microscopy analysis of yeast mutants defective in cell wall architecture. Yeast 27, 673\u2013684 (2010).","journal-title":"Yeast"},{"key":"92069_CR22","doi-asserted-by":"publisher","first-page":"1806","DOI":"10.3389\/fmicb.2017.01806","volume":"8","author":"M Schiavone","year":"2017","unstructured":"Schiavone, M., D\u00e9jean, S., Sieczkowsk, N., Dague, E. & Fran\u00e7ois, J. M. Integration of biochemical, biophysical and transcriptomics data for investigating the structural and nanomechanical properties of the yeast cell wall. Front. Microbiol. 8, 1806 (2017).","journal-title":"Front. Microbiol."},{"key":"92069_CR23","doi-asserted-by":"publisher","first-page":"1","DOI":"10.1186\/1741-7007-12-6","volume":"12","author":"F Pillet","year":"2014","unstructured":"Pillet, F. et al. Uncovering by Atomic Force Microscopy of an original circular structure at the yeast cell surface in response to heat shock. BMC Biol. 12, 1\u201311 (2014).","journal-title":"BMC Biol."},{"key":"92069_CR24","doi-asserted-by":"publisher","first-page":"4789","DOI":"10.1128\/AEM.01213-16","volume":"82","author":"M Schiavone","year":"2016","unstructured":"Schiavone, M. et al. An Atomic Force Microscopy study of yeast response to ethanol stress: Evidence for a role of the plasma membrane in the nanomechanical properties of the cell walls. Appl. Environ. Microbiol. 82, 4789\u20134801 (2016).","journal-title":"Appl. Environ. Microbiol."},{"key":"92069_CR25","doi-asserted-by":"publisher","first-page":"107","DOI":"10.1186\/s13568-016-0285-x","volume":"6","author":"Y Kitichantaropas","year":"2016","unstructured":"Kitichantaropas, Y. et al. Cellular mechanisms contributing to multiple stress tolerance in Saccharomyces cerevisiae strains with potential use in high-temperature ethanol fermentation. AMB Express 6, 107 (2016).","journal-title":"AMB Express"},{"key":"92069_CR26","doi-asserted-by":"publisher","first-page":"4589","DOI":"10.1007\/s00253-018-8955-z","volume":"102","author":"JT Cunha","year":"2018","unstructured":"Cunha, J. T. et al. HAA1 and PRS3 overexpression boosts yeast tolerance towards acetic acid improving xylose or glucose consumption: Unravelling the underlying mechanisms. Appl. Microbiol. Biotechnol. 102, 4589\u20134600 (2018).","journal-title":"Appl. Microbiol. Biotechnol."},{"key":"92069_CR27","doi-asserted-by":"publisher","first-page":"469","DOI":"10.1046\/j.1365-2958.2001.02242.x","volume":"39","author":"JC Kapteyn","year":"2001","unstructured":"Kapteyn, J. C. et al. Low external ph induces HOG1-dependent changes in the organization of the Saccharomyces cerevisiae cell wall. Mol. Microbiol. 39, 469\u2013479 (2001).","journal-title":"Mol. Microbiol."},{"key":"92069_CR28","doi-asserted-by":"publisher","first-page":"7168","DOI":"10.1128\/AEM.01476-06","volume":"72","author":"T Sim\u00f5es","year":"2006","unstructured":"Sim\u00f5es, T., Mira, N. P., Fernandes, A. R. & S\u00e1-Correia, I. The SPI1 gene, encoding a glycosylphosphatidylinositol-anchored cell wall protein, plays a prominent role in the development of yeast resistance to lipophilic weak-acid food preservatives. Appl. Environ. Microbiol. 72, 7168\u20137175 (2006).","journal-title":"Appl. Environ. Microbiol."},{"key":"92069_CR29","doi-asserted-by":"publisher","first-page":"781","DOI":"10.1046\/j.1365-2958.2002.03198.x","volume":"42","author":"US Jung","year":"2002","unstructured":"Jung, U. S., Sobering, A. K., Romeo, M. J. & Levin, D. E. Regulation of the yeast Rlm1 transcription factor by the Mpk1 cell wall integrity MAP kinase. Mol. Microbiol. 42, 781\u2013789 (2002).","journal-title":"Mol. Microbiol."},{"key":"92069_CR30","doi-asserted-by":"publisher","first-page":"55","DOI":"10.1080\/mmy.39.1.55.66","volume":"39","author":"CM Douglas","year":"2001","unstructured":"Douglas, C. M. Fungal \u03b2(1,3)-d-glucan synthesis. Med. Mycol. Suppl. 39, 55\u201366 (2001).","journal-title":"Med. Mycol. Suppl."},{"key":"92069_CR31","doi-asserted-by":"publisher","first-page":"e00619-17","DOI":"10.1128\/mBio.00619-17","volume":"8","author":"V Aimanianda","year":"2017","unstructured":"Aimanianda, V. et al. The dual activity responsible for the elongation and branching of \u03b2-(1,3)- glucan in the fungal cell wall. MBio 8, e00619-17 (2017).","journal-title":"MBio"},{"key":"92069_CR32","doi-asserted-by":"publisher","first-page":"702","DOI":"10.3390\/ijms18040702","volume":"18","author":"S Gohlke","year":"2017","unstructured":"Gohlke, S., Muthukrishnan, S. & Merzendorfer, H. In vitro and in vivo studies on the structural organization of Chs3 from Saccharomyces cerevisiae. Int. J. Mol. Sci. 18, 702 (2017).","journal-title":"Int. J. Mol. Sci."},{"key":"92069_CR33","doi-asserted-by":"publisher","first-page":"715","DOI":"10.1111\/febs.13176","volume":"282","author":"N Blanco","year":"2015","unstructured":"Blanco, N. et al. Structural and functional analysis of yeast Crh1 and Crh2 transglycosylases. FEBS J. 282, 715\u2013731 (2015).","journal-title":"FEBS J."},{"key":"92069_CR34","doi-asserted-by":"publisher","first-page":"1418","DOI":"10.1128\/JB.180.6.1418-1424.1998","volume":"180","author":"AFJ Ram","year":"1998","unstructured":"Ram, A. F. J. et al. Loss of the plasma membrane-bound protein Gas1p in Saccharomyces cerevisiae results in the release of \u03b21,3-glucan into the medium and induces a compensation mechanism to ensure cell wall integrity. J. Bacteriol. 180, 1418\u20131424 (1998).","journal-title":"J. Bacteriol."},{"key":"92069_CR35","doi-asserted-by":"publisher","first-page":"525","DOI":"10.1089\/omi.2010.0072","volume":"14","author":"NP Mira","year":"2010","unstructured":"Mira, N. P., Teixeira, M. C. & S\u00e1-Correia, I. Adaptive response and tolerance to weak acids in Saccharomyces cerevisiae: A genome-wide view. OMICS 14, 525\u2013540 (2010).","journal-title":"OMICS"},{"key":"92069_CR36","doi-asserted-by":"publisher","first-page":"4311","DOI":"10.1042\/BCJ20160565","volume":"473","author":"JF Guerreiro","year":"2016","unstructured":"Guerreiro, J. F., Muir, A., Ramachandran, S., Thorner, J. & S\u00e1 Correia, I. Sphingolipid biosynthesis upregulation by TOR complex 2-Ypk1 signaling during yeast adaptive response to acetic acid stress. Biochem. J. 473, 4311\u20134325 (2016).","journal-title":"Biochem. J."},{"key":"92069_CR37","doi-asserted-by":"publisher","first-page":"3304","DOI":"10.1099\/mic.0.030502-0","volume":"155","author":"M Mollapour","year":"2009","unstructured":"Mollapour, M., Shepherd, A. & Piper, P. W. Presence of the Fps1p aquaglyceroporin channel is essential for Hog1p activation, but suppresses Slt2(Mpk1)p activation, with acetic acid stress of yeast. Microbiology 155, 3304\u20133311 (2009).","journal-title":"Microbiology"},{"key":"92069_CR38","doi-asserted-by":"publisher","first-page":"244","DOI":"10.1111\/j.1567-1364.2006.00162.x","volume":"7","author":"A Ando","year":"2007","unstructured":"Ando, A., Nakamura, T., Murata, Y., Takagi, H. & Shima, J. Identification and classification of genes required for tolerance to freeze-thaw stress revealed by genome-wide screening of Saccharomyces cerevisiae deletion strains. FEMS Yeast Res. 7, 244\u2013253 (2007).","journal-title":"FEMS Yeast Res."},{"key":"92069_CR39","doi-asserted-by":"publisher","first-page":"1","DOI":"10.3390\/genes11060656","volume":"11","author":"RM Lucena","year":"2020","unstructured":"Lucena, R. M., Dolz-Edo, L., Brul, S., de Morais, M. A. & Smits, G. Extreme low cytosolic pH is a signal for cell survival in acid stressed yeast. Genes 11, 1\u201325 (2020).","journal-title":"Genes"},{"key":"92069_CR40","doi-asserted-by":"publisher","first-page":"e00551","DOI":"10.1128\/AEM.00551-19","volume":"85","author":"N Udom","year":"2019","unstructured":"Udom, N., Chansongkrow, P., Charoensawan, V. & Auesukaree, C. Coordination of the cell wall integrity and highosmolarity glycerol pathways in response to ethanol stress in Saccharomyces cerevisiae. Appl. Environ. Microbiol. 85, e00551-e619 (2019).","journal-title":"Appl. Environ. Microbiol."},{"key":"92069_CR41","doi-asserted-by":"publisher","first-page":"093711","DOI":"10.1063\/1.4962866","volume":"87","author":"JE Sader","year":"2016","unstructured":"Sader, J. E. et al. A virtual instrument to standardise the calibration of atomic force microscope cantilevers. Rev. Sci. Instrum. 87, 093711 (2016).","journal-title":"Rev. Sci. Instrum."},{"key":"92069_CR42","unstructured":"Collart. M. A. & Oliviero, S. Preparation of yeast RNA. Curr. Protoc. Mol. Biol.\u00a013(13), 12 (2001)."},{"key":"92069_CR43","doi-asserted-by":"publisher","first-page":"1","DOI":"10.1128\/mBio.01318-18","volume":"9","author":"A Pradhan","year":"2018","unstructured":"Pradhan, A. et al. Hypoxia promotes immune evasion by triggering-glucan masking on the Candida albicans cell surface via mitochondrial and cAMP-protein kinase A signaling. MBio 9, 1\u201318 (2018).","journal-title":"MBio"}],"container-title":["Scientific Reports"],"original-title":[],"language":"en","link":[{"URL":"https:\/\/www.nature.com\/articles\/s41598-021-92069-3.pdf","content-type":"application\/pdf","content-version":"vor","intended-application":"text-mining"},{"URL":"https:\/\/www.nature.com\/articles\/s41598-021-92069-3","content-type":"text\/html","content-version":"vor","intended-application":"text-mining"},{"URL":"https:\/\/www.nature.com\/articles\/s41598-021-92069-3.pdf","content-type":"application\/pdf","content-version":"vor","intended-application":"similarity-checking"}],"deposited":{"date-parts":[[2022,12,3]],"date-time":"2022-12-03T09:45:37Z","timestamp":1670060737000},"score":1,"resource":{"primary":{"URL":"https:\/\/www.nature.com\/articles\/s41598-021-92069-3"}},"subtitle":[],"short-title":[],"issued":{"date-parts":[[2021,6,16]]},"references-count":43,"journal-issue":{"issue":"1","published-online":{"date-parts":[[2021,12]]}},"alternative-id":["92069"],"URL":"https:\/\/doi.org\/10.1038\/s41598-021-92069-3","relation":{},"ISSN":["2045-2322"],"issn-type":[{"value":"2045-2322","type":"electronic"}],"subject":[],"published":{"date-parts":[[2021,6,16]]},"assertion":[{"value":"8 November 2020","order":1,"name":"received","label":"Received","group":{"name":"ArticleHistory","label":"Article History"}},{"value":"3 June 2021","order":2,"name":"accepted","label":"Accepted","group":{"name":"ArticleHistory","label":"Article History"}},{"value":"16 June 2021","order":3,"name":"first_online","label":"First Online","group":{"name":"ArticleHistory","label":"Article History"}},{"value":"The authors declare no competing interests.","order":1,"name":"Ethics","group":{"name":"EthicsHeading","label":"Competing interests"}}],"article-number":"12652"}}