Subham Choudhury, Bharath Narayanan, Michael Moret, Vassily Hatzimanikatis, Ljubisa Miskovic
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Through seamless integration of diverse omics data and other relevant information, including extracellular medium composition, physicochemical data and expertise of domain specialists, RENAISSANCE accurately characterizes intracellular metabolic states in Escherichia coli. It also estimates missing kinetic parameters and reconciles them with sparse experimental data, substantially reducing parameter uncertainty and improving accuracy. This framework will be valuable for researchers studying metabolic variations involving changes in metabolite and enzyme levels and enzyme activity in health and biotechnology. Despite the availability of large omics datasets, determining intracellular metabolic states is challenging. Now a generative machine learning framework called RENAISSANCE has been developed to estimate missing kinetic parameters and determine time-resolved metabolic reaction rates and metabolite concentrations without requiring training data.","PeriodicalId":18845,"journal":{"name":"Nature Catalysis","volume":"7 10","pages":"1086-1098"},"PeriodicalIF":42.8000,"publicationDate":"2024-08-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.nature.com/articles/s41929-024-01220-6.pdf","citationCount":"0","resultStr":"{\"title\":\"Generative machine learning produces kinetic models that accurately characterize intracellular metabolic states\",\"authors\":\"Subham Choudhury, Bharath Narayanan, Michael Moret, Vassily Hatzimanikatis, Ljubisa Miskovic\",\"doi\":\"10.1038/s41929-024-01220-6\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Generating large omics datasets has become routine for gaining insights into cellular processes, yet deciphering these datasets to determine metabolic states remains challenging. 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This framework will be valuable for researchers studying metabolic variations involving changes in metabolite and enzyme levels and enzyme activity in health and biotechnology. Despite the availability of large omics datasets, determining intracellular metabolic states is challenging. 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Generative machine learning produces kinetic models that accurately characterize intracellular metabolic states
Generating large omics datasets has become routine for gaining insights into cellular processes, yet deciphering these datasets to determine metabolic states remains challenging. Kinetic models can help integrate omics data by explicitly linking metabolite concentrations, metabolic fluxes and enzyme levels. Nevertheless, determining the kinetic parameters that underlie cellular physiology poses notable obstacles to the widespread use of these mathematical representations of metabolism. Here we present RENAISSANCE, a generative machine learning framework for efficiently parameterizing large-scale kinetic models with dynamic properties matching experimental observations. Through seamless integration of diverse omics data and other relevant information, including extracellular medium composition, physicochemical data and expertise of domain specialists, RENAISSANCE accurately characterizes intracellular metabolic states in Escherichia coli. It also estimates missing kinetic parameters and reconciles them with sparse experimental data, substantially reducing parameter uncertainty and improving accuracy. This framework will be valuable for researchers studying metabolic variations involving changes in metabolite and enzyme levels and enzyme activity in health and biotechnology. Despite the availability of large omics datasets, determining intracellular metabolic states is challenging. Now a generative machine learning framework called RENAISSANCE has been developed to estimate missing kinetic parameters and determine time-resolved metabolic reaction rates and metabolite concentrations without requiring training data.
期刊介绍:
Nature Catalysis serves as a platform for researchers across chemistry and related fields, focusing on homogeneous catalysis, heterogeneous catalysis, and biocatalysts, encompassing both fundamental and applied studies. With a particular emphasis on advancing sustainable industries and processes, the journal provides comprehensive coverage of catalysis research, appealing to scientists, engineers, and researchers in academia and industry.
Maintaining the high standards of the Nature brand, Nature Catalysis boasts a dedicated team of professional editors, rigorous peer-review processes, and swift publication times, ensuring editorial independence and quality. The journal publishes work spanning heterogeneous catalysis, homogeneous catalysis, and biocatalysis, covering areas such as catalytic synthesis, mechanisms, characterization, computational studies, nanoparticle catalysis, electrocatalysis, photocatalysis, environmental catalysis, asymmetric catalysis, and various forms of organocatalysis.