Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.

Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.

Growth rate has long been considered one of the most valuable phenotypes that can be measured in cells. Aside from being highly accessible and informative in laboratory cultures, maximal growth rate is often a prime determinant of cellular fitness, and predicting phenotypes that underlie fitness is...

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Main Authors: Raphy Zarecki, Matthew A Oberhardt, Keren Yizhak, Allon Wagner, Ella Shtifman Segal, Shiri Freilich, Christopher S Henry, Uri Gophna, Eytan Ruppin
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2014-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC4035307?pdf=render
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spelling doaj-9b5539e5b43f4d6085f473519d771ff32020-11-25T01:47:07ZengPublic Library of Science (PLoS)PLoS ONE1932-62032014-01-0195e9837210.1371/journal.pone.0098372Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.Raphy ZareckiMatthew A OberhardtKeren YizhakAllon WagnerElla Shtifman SegalShiri FreilichChristopher S HenryUri GophnaEytan RuppinGrowth rate has long been considered one of the most valuable phenotypes that can be measured in cells. Aside from being highly accessible and informative in laboratory cultures, maximal growth rate is often a prime determinant of cellular fitness, and predicting phenotypes that underlie fitness is key to both understanding and manipulating life. Despite this, current methods for predicting microbial fitness typically focus on yields [e.g., predictions of biomass yield using GEnome-scale metabolic Models (GEMs)] or notably require many empirical kinetic constants or substrate uptake rates, which render these methods ineffective in cases where fitness derives most directly from growth rate. Here we present a new method for predicting cellular growth rate, termed SUMEX, which does not require any empirical variables apart from a metabolic network (i.e., a GEM) and the growth medium. SUMEX is calculated by maximizing the SUM of molar EXchange fluxes (hence SUMEX) in a genome-scale metabolic model. SUMEX successfully predicts relative microbial growth rates across species, environments, and genetic conditions, outperforming traditional cellular objectives (most notably, the convention assuming biomass maximization). The success of SUMEX suggests that the ability of a cell to catabolize substrates and produce a strong proton gradient enables fast cell growth. Easily applicable heuristics for predicting growth rate, such as what we demonstrate with SUMEX, may contribute to numerous medical and biotechnological goals, ranging from the engineering of faster-growing industrial strains, modeling of mixed ecological communities, and the inhibition of cancer growth.http://europepmc.org/articles/PMC4035307?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Raphy Zarecki
Matthew A Oberhardt
Keren Yizhak
Allon Wagner
Ella Shtifman Segal
Shiri Freilich
Christopher S Henry
Uri Gophna
Eytan Ruppin
spellingShingle Raphy Zarecki
Matthew A Oberhardt
Keren Yizhak
Allon Wagner
Ella Shtifman Segal
Shiri Freilich
Christopher S Henry
Uri Gophna
Eytan Ruppin
Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.
PLoS ONE
author_facet Raphy Zarecki
Matthew A Oberhardt
Keren Yizhak
Allon Wagner
Ella Shtifman Segal
Shiri Freilich
Christopher S Henry
Uri Gophna
Eytan Ruppin
author_sort Raphy Zarecki
title Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.
title_short Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.
title_full Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.
title_fullStr Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.
title_full_unstemmed Maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.
title_sort maximal sum of metabolic exchange fluxes outperforms biomass yield as a predictor of growth rate of microorganisms.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2014-01-01
description Growth rate has long been considered one of the most valuable phenotypes that can be measured in cells. Aside from being highly accessible and informative in laboratory cultures, maximal growth rate is often a prime determinant of cellular fitness, and predicting phenotypes that underlie fitness is key to both understanding and manipulating life. Despite this, current methods for predicting microbial fitness typically focus on yields [e.g., predictions of biomass yield using GEnome-scale metabolic Models (GEMs)] or notably require many empirical kinetic constants or substrate uptake rates, which render these methods ineffective in cases where fitness derives most directly from growth rate. Here we present a new method for predicting cellular growth rate, termed SUMEX, which does not require any empirical variables apart from a metabolic network (i.e., a GEM) and the growth medium. SUMEX is calculated by maximizing the SUM of molar EXchange fluxes (hence SUMEX) in a genome-scale metabolic model. SUMEX successfully predicts relative microbial growth rates across species, environments, and genetic conditions, outperforming traditional cellular objectives (most notably, the convention assuming biomass maximization). The success of SUMEX suggests that the ability of a cell to catabolize substrates and produce a strong proton gradient enables fast cell growth. Easily applicable heuristics for predicting growth rate, such as what we demonstrate with SUMEX, may contribute to numerous medical and biotechnological goals, ranging from the engineering of faster-growing industrial strains, modeling of mixed ecological communities, and the inhibition of cancer growth.
url http://europepmc.org/articles/PMC4035307?pdf=render
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