Predictive evolution of metabolic phenotypes using model-designed environments
Adaptive evolution under controlled laboratory conditions has been highly effective in selecting organisms with beneficial phenotypes such as stress tolerance. The evolution route is particularly attractive when the organisms are either difficult to engineer or the genetic basis of the phenotype is complex. However, many desired traits, like metabolite secretion, have been inaccessible to adaptive selection due to their trade-off with cell growth. Here, we utilize genome-scale metabolic models to design nutrient environments for selecting lineages with enhanced metabolite secretion. To overcome the growth-secretion trade-off, we identify environments wherein growth becomes correlated with a secondary trait termed tacking trait. The latter is selected to be coupled with the desired trait in the application environment where the trait manifestation is required. Thus, adaptive evolution in the model-designed selection environment and subsequent return to the application environment is predicted to enhance the desired trait. We experimentally validate this strategy by evolving Saccharomyces cerevisiae for increased secretion of aroma compounds, and confirm the predicted flux-rerouting using genomic, transcriptomic, and proteomic analyses. Overall, model-designed selection environments open new opportunities for predictive evolution.
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2022
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dig-icvv-es-10261-3500582024-03-12T10:21:44Z Predictive evolution of metabolic phenotypes using model-designed environments Jouhten, Paula Konstantinidis, Dimitrios Pereira, Filipa Andrejev, Sergej Grkovska, Kristina Castillo, Sandra Ghiachi, Payam Beltran, Gemma Almaas, Eivind Mas, Albert Warringer, Jonas González García, Ramón Morales, Pilar Patil, Kiran R. Federal Ministry of Education and Research (Germany) Research Council of Norway Ministerio de Ciencia, Innovación y Universidades (España) Agencia Estatal de Investigación (España) Academy of Finland European Research Council European Commission Adaptive evolution under controlled laboratory conditions has been highly effective in selecting organisms with beneficial phenotypes such as stress tolerance. The evolution route is particularly attractive when the organisms are either difficult to engineer or the genetic basis of the phenotype is complex. However, many desired traits, like metabolite secretion, have been inaccessible to adaptive selection due to their trade-off with cell growth. Here, we utilize genome-scale metabolic models to design nutrient environments for selecting lineages with enhanced metabolite secretion. To overcome the growth-secretion trade-off, we identify environments wherein growth becomes correlated with a secondary trait termed tacking trait. The latter is selected to be coupled with the desired trait in the application environment where the trait manifestation is required. Thus, adaptive evolution in the model-designed selection environment and subsequent return to the application environment is predicted to enhance the desired trait. We experimentally validate this strategy by evolving Saccharomyces cerevisiae for increased secretion of aroma compounds, and confirm the predicted flux-rerouting using genomic, transcriptomic, and proteomic analyses. Overall, model-designed selection environments open new opportunities for predictive evolution. 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 Forskningsråd) grant no. 245160) and by the Ministry of Science, Innovation and Universities, Spain (España, Ministerio de Ciencia e Innovación (MCIN)) (Project CoolWine, PCI2018‐092962), under the call ERA‐NET 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's Horizon 2020 research and innovation programme (Grant agreement No. 866028). T. Tenkanen and G. Riddihough are acknowledged for comments on the manuscript. We acknowledge the support of the following core facilities at the European Molecular Biology Laboratory (Heidelberg, Germany): Genomics (V. Benes and R. Hercog), and Proteomics (M. Rettel and F. Stein). 2024-03-12T10:21:43Z 2024-03-12T10:21:43Z 2022 2024-03-12T10:21:44Z artículo doi: 10.15252/msb.202210980 e-issn: 1744-4292 Molecular Systems Biology 18(10): e10980 (2022) http://hdl.handle.net/10261/350058 #PLACEHOLDER_PARENT_METADATA_VALUE# #PLACEHOLDER_PARENT_METADATA_VALUE# info:eu-repo/grantAgreement/AEI/Plan Estatal de Investigación Científica y Técnica y de Innovación 2017-2020/PCI2018-092962/ES/EVOLUCION DIRIGIDA PARA LA REDUCCION DEL CONTENIDO EN ALCOHOL DE LOS VINOS MEDIANTE EL DESARROLLO DE CEPAS DE LEVADURAS NO-OGM Y DE COMUNIDADES MICROBIANAS/ info:eu-repo/grantAgreement/EC/H2020/866028 Publisher's version http://dx.doi.org/10.15252/msb.202210980 Sí open Nature Publishing Group |
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Adaptive evolution under controlled laboratory conditions has been highly effective in selecting organisms with beneficial phenotypes such as stress tolerance. The evolution route is particularly attractive when the organisms are either difficult to engineer or the genetic basis of the phenotype is complex. However, many desired traits, like metabolite secretion, have been inaccessible to adaptive selection due to their trade-off with cell growth. Here, we utilize genome-scale metabolic models to design nutrient environments for selecting lineages with enhanced metabolite secretion. To overcome the growth-secretion trade-off, we identify environments wherein growth becomes correlated with a secondary trait termed tacking trait. The latter is selected to be coupled with the desired trait in the application environment where the trait manifestation is required. Thus, adaptive evolution in the model-designed selection environment and subsequent return to the application environment is predicted to enhance the desired trait. We experimentally validate this strategy by evolving Saccharomyces cerevisiae for increased secretion of aroma compounds, and confirm the predicted flux-rerouting using genomic, transcriptomic, and proteomic analyses. Overall, model-designed selection environments open new opportunities for predictive evolution. |
| author2 |
Federal Ministry of Education and Research (Germany) |
| author_facet |
Federal Ministry of Education and Research (Germany) Jouhten, Paula Konstantinidis, Dimitrios Pereira, Filipa Andrejev, Sergej Grkovska, Kristina Castillo, Sandra Ghiachi, Payam Beltran, Gemma Almaas, Eivind Mas, Albert Warringer, Jonas González García, Ramón Morales, Pilar Patil, Kiran R. |
| format |
artículo |
| author |
Jouhten, Paula Konstantinidis, Dimitrios Pereira, Filipa Andrejev, Sergej Grkovska, Kristina Castillo, Sandra Ghiachi, Payam Beltran, Gemma Almaas, Eivind Mas, Albert Warringer, Jonas González García, Ramón Morales, Pilar Patil, Kiran R. |
| spellingShingle |
Jouhten, Paula Konstantinidis, Dimitrios Pereira, Filipa Andrejev, Sergej Grkovska, Kristina Castillo, Sandra Ghiachi, Payam Beltran, Gemma Almaas, Eivind Mas, Albert Warringer, Jonas González García, Ramón Morales, Pilar Patil, Kiran R. Predictive evolution of metabolic phenotypes using model-designed environments |
| author_sort |
Jouhten, Paula |
| title |
Predictive evolution of metabolic phenotypes using model-designed environments |
| title_short |
Predictive evolution of metabolic phenotypes using model-designed environments |
| title_full |
Predictive evolution of metabolic phenotypes using model-designed environments |
| title_fullStr |
Predictive evolution of metabolic phenotypes using model-designed environments |
| title_full_unstemmed |
Predictive evolution of metabolic phenotypes using model-designed environments |
| title_sort |
predictive evolution of metabolic phenotypes using model-designed environments |
| publisher |
Nature Publishing Group |
| publishDate |
2022 |
| url |
http://hdl.handle.net/10261/350058 |
| work_keys_str_mv |
AT jouhtenpaula predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT konstantinidisdimitrios predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT pereirafilipa predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT andrejevsergej predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT grkovskakristina predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT castillosandra predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT ghiachipayam predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT beltrangemma predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT almaaseivind predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT masalbert predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT warringerjonas predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT gonzalezgarciaramon predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT moralespilar predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments AT patilkiranr predictiveevolutionofmetabolicphenotypesusingmodeldesignedenvironments |
| _version_ |
1794796806343753728 |