Highly parallelized laboratory evolution of wine yeasts for enhanced metabolic phenotypes

Payam Ghiaci; Paula Jouhten; Nikolay Martyushenko; Helena Roca-Mesa; Jennifer Vázquez; Dimitrios Konstantinidis; Simon Stenberg; Sergej Andrejev; Kristina Grkovska; Albert Mas; Gemma Beltran; Eivind Almaas; Kiran R. Patil; Jonas Warringer

doi:10.1038/s44320-024-00059-0

Highly parallelized laboratory evolution of wine yeasts for enhanced metabolic phenotypes

Payam Ghiaci
, Paula Jouhten
, Nikolay Martyushenko
, Helena Roca-Mesa
, Jennifer Vázquez
, Dimitrios Konstantinidis
, Simon Stenberg
, Sergej Andrejev
, Kristina Grkovska
, Albert Mas
, Gemma Beltran
, Eivind Almaas^*
, Kiran R. Patil^*
, Jonas Warringer^*

^*Corresponding author for this work

Bioanalytics and biological data science

Research output: Contribution to journal › Article › Scientific › peer-review

2 Citations (Scopus)

Abstract

Adaptive Laboratory Evolution (ALE) of microorganisms can improve the efficiency of sustainable industrial processes important to the global economy. However, stochasticity and genetic background effects often lead to suboptimal outcomes during laboratory evolution. Here we report an ALE platform to circumvent these shortcomings through parallelized clonal evolution at an unprecedented scale. Using this platform, we evolved 104 yeast populations in parallel from many strains for eight desired wine fermentation-related traits. Expansions of both ALE replicates and lineage numbers broadened the evolutionary search spectrum leading to improved wine yeasts unencumbered by unwanted side effects. At the genomic level, evolutionary gains in metabolic characteristics often coincided with distinct chromosome amplifications and the emergence of side-effect syndromes that were characteristic of each selection niche. Several high-performing ALE strains exhibited desired wine fermentation kinetics when tested in larger liquid cultures, supporting their suitability for application. More broadly, our high-throughput ALE platform opens opportunities for rapid optimization of microbes which otherwise could take many years to accomplish.

Original language	English
Pages (from-to)	1109-1133
Number of pages	25
Journal	Molecular Systems Biology
Volume	20
Issue number	10
DOIs	https://doi.org/10.1038/s44320-024-00059-0
Publication status	Published - 3 Oct 2024
MoE publication type	A1 Journal article-refereed

Funding

This work was sponsored by the ERASysAPP project WINESYS (the German Ministry of Education and Research grant no. 031A605; the Research Council of Norway (Norges Forskningsr\u00E5d) grant no. 245160, the Swedish Research Council grant no. 325-2014-6547) and by the Ministry of Science, Innovation and Universities, Spain (Espa\u00F1a, Ministerio de Ciencia e Innovaci\u00F2n (MCIN)) (Project CoolWine, PCI2018-092962), under the call ERANET ERA COBIOTECH. PJ acknowledges funding from the Academy of Finland, decision numbers 310514, 314125, and 329930. KRP received funding from the European Research Council (ERC) under the European Union\u2019s Horizon 2020 research and innovation programme (Grant Agreement No. 866028). We acknowledge the support of the Genomics core facilities at the European Molecular Biology Laboratory (Heidelberg, Germany).

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

Keywords

Evolutionary Engineering
Experimental Evolution
Fermentation
Metabolism
Yeast

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10.1038/s44320-024-00059-0Licence: CC BY

Cite this

Ghiaci, P., Jouhten, P., Martyushenko, N., Roca-Mesa, H., Vázquez, J., Konstantinidis, D., Stenberg, S., Andrejev, S., Grkovska, K., Mas, A., Beltran, G., Almaas, E., Patil, K. R., & Warringer, J. (2024). Highly parallelized laboratory evolution of wine yeasts for enhanced metabolic phenotypes. Molecular Systems Biology, 20(10), 1109-1133. https://doi.org/10.1038/s44320-024-00059-0

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abstract = "Adaptive Laboratory Evolution (ALE) of microorganisms can improve the efficiency of sustainable industrial processes important to the global economy. However, stochasticity and genetic background effects often lead to suboptimal outcomes during laboratory evolution. Here we report an ALE platform to circumvent these shortcomings through parallelized clonal evolution at an unprecedented scale. Using this platform, we evolved 104 yeast populations in parallel from many strains for eight desired wine fermentation-related traits. Expansions of both ALE replicates and lineage numbers broadened the evolutionary search spectrum leading to improved wine yeasts unencumbered by unwanted side effects. At the genomic level, evolutionary gains in metabolic characteristics often coincided with distinct chromosome amplifications and the emergence of side-effect syndromes that were characteristic of each selection niche. Several high-performing ALE strains exhibited desired wine fermentation kinetics when tested in larger liquid cultures, supporting their suitability for application. More broadly, our high-throughput ALE platform opens opportunities for rapid optimization of microbes which otherwise could take many years to accomplish.",

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Ghiaci, P, Jouhten, P, Martyushenko, N, Roca-Mesa, H, Vázquez, J, Konstantinidis, D, Stenberg, S, Andrejev, S, Grkovska, K, Mas, A, Beltran, G, Almaas, E, Patil, KR & Warringer, J 2024, 'Highly parallelized laboratory evolution of wine yeasts for enhanced metabolic phenotypes', Molecular Systems Biology, vol. 20, no. 10, pp. 1109-1133. https://doi.org/10.1038/s44320-024-00059-0

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AU - Ghiaci, Payam

AU - Jouhten, Paula

AU - Martyushenko, Nikolay

AU - Roca-Mesa, Helena

AU - Vázquez, Jennifer

AU - Konstantinidis, Dimitrios

AU - Stenberg, Simon

AU - Andrejev, Sergej

AU - Grkovska, Kristina

AU - Mas, Albert

AU - Beltran, Gemma

AU - Almaas, Eivind

AU - Patil, Kiran R.

AU - Warringer, Jonas

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N2 - Adaptive Laboratory Evolution (ALE) of microorganisms can improve the efficiency of sustainable industrial processes important to the global economy. However, stochasticity and genetic background effects often lead to suboptimal outcomes during laboratory evolution. Here we report an ALE platform to circumvent these shortcomings through parallelized clonal evolution at an unprecedented scale. Using this platform, we evolved 104 yeast populations in parallel from many strains for eight desired wine fermentation-related traits. Expansions of both ALE replicates and lineage numbers broadened the evolutionary search spectrum leading to improved wine yeasts unencumbered by unwanted side effects. At the genomic level, evolutionary gains in metabolic characteristics often coincided with distinct chromosome amplifications and the emergence of side-effect syndromes that were characteristic of each selection niche. Several high-performing ALE strains exhibited desired wine fermentation kinetics when tested in larger liquid cultures, supporting their suitability for application. More broadly, our high-throughput ALE platform opens opportunities for rapid optimization of microbes which otherwise could take many years to accomplish.

AB - Adaptive Laboratory Evolution (ALE) of microorganisms can improve the efficiency of sustainable industrial processes important to the global economy. However, stochasticity and genetic background effects often lead to suboptimal outcomes during laboratory evolution. Here we report an ALE platform to circumvent these shortcomings through parallelized clonal evolution at an unprecedented scale. Using this platform, we evolved 104 yeast populations in parallel from many strains for eight desired wine fermentation-related traits. Expansions of both ALE replicates and lineage numbers broadened the evolutionary search spectrum leading to improved wine yeasts unencumbered by unwanted side effects. At the genomic level, evolutionary gains in metabolic characteristics often coincided with distinct chromosome amplifications and the emergence of side-effect syndromes that were characteristic of each selection niche. Several high-performing ALE strains exhibited desired wine fermentation kinetics when tested in larger liquid cultures, supporting their suitability for application. More broadly, our high-throughput ALE platform opens opportunities for rapid optimization of microbes which otherwise could take many years to accomplish.

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KW - Experimental Evolution

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KW - Metabolism

KW - Yeast

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ER -

Highly parallelized laboratory evolution of wine yeasts for enhanced metabolic phenotypes

Abstract

Funding

UN SDGs

Keywords

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