Underground metabolism: network-level perspective and biotechnological potential

Richard A Notebaart; Bálint Kintses; Adam Feist; Balázs Papp

doi:10.1016/j.copbio.2017.07.015

Underground metabolism: network-level perspective and biotechnological potential

Richard A Notebaart^*, Bálint Kintses, Adam Feist, Balázs Papp

^*Corresponding author for this work

Novo Nordisk Foundation Center for Biosustainability

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

A key challenge in molecular systems biology is understanding how new pathways arise during evolution and how to exploit them for biotechnological applications. New pathways in metabolic networks often evolve by recruiting weak promiscuous activities of pre-existing enzymes. Here we describe recent systems biology advances to map such ‘underground’ activities and to predict and analyze their contribution to new metabolic functions. Underground activities are prevalent in cellular metabolism and can form novel pathways that either enable evolutionary adaptation to new environments or provide bypass to genetic lesions. We also illustrate the potential of integrating computational models of underground metabolism and experimental approaches to study the evolution of novel metabolic phenotypes and advance the field of biotechnology.

Original language	English
Journal	Current Opinion in Biotechnology
Volume	49
Pages (from-to)	108-114
ISSN	0958-1669
DOIs	https://doi.org/10.1016/j.copbio.2017.07.015
Publication status	Published - 2018

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abstract = "A key challenge in molecular systems biology is understanding how new pathways arise during evolution and how to exploit them for biotechnological applications. New pathways in metabolic networks often evolve by recruiting weak promiscuous activities of pre-existing enzymes. Here we describe recent systems biology advances to map such {\textquoteleft}underground{\textquoteright} activities and to predict and analyze their contribution to new metabolic functions. Underground activities are prevalent in cellular metabolism and can form novel pathways that either enable evolutionary adaptation to new environments or provide bypass to genetic lesions. We also illustrate the potential of integrating computational models of underground metabolism and experimental approaches to study the evolution of novel metabolic phenotypes and advance the field of biotechnology.",

author = "Notebaart, {Richard A} and B{\'a}lint Kintses and Adam Feist and Bal{\'a}zs Papp",

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AU - Kintses, Bálint

AU - Feist, Adam

AU - Papp, Balázs

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N2 - A key challenge in molecular systems biology is understanding how new pathways arise during evolution and how to exploit them for biotechnological applications. New pathways in metabolic networks often evolve by recruiting weak promiscuous activities of pre-existing enzymes. Here we describe recent systems biology advances to map such ‘underground’ activities and to predict and analyze their contribution to new metabolic functions. Underground activities are prevalent in cellular metabolism and can form novel pathways that either enable evolutionary adaptation to new environments or provide bypass to genetic lesions. We also illustrate the potential of integrating computational models of underground metabolism and experimental approaches to study the evolution of novel metabolic phenotypes and advance the field of biotechnology.

AB - A key challenge in molecular systems biology is understanding how new pathways arise during evolution and how to exploit them for biotechnological applications. New pathways in metabolic networks often evolve by recruiting weak promiscuous activities of pre-existing enzymes. Here we describe recent systems biology advances to map such ‘underground’ activities and to predict and analyze their contribution to new metabolic functions. Underground activities are prevalent in cellular metabolism and can form novel pathways that either enable evolutionary adaptation to new environments or provide bypass to genetic lesions. We also illustrate the potential of integrating computational models of underground metabolism and experimental approaches to study the evolution of novel metabolic phenotypes and advance the field of biotechnology.

U2 - 10.1016/j.copbio.2017.07.015

DO - 10.1016/j.copbio.2017.07.015

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VL - 49

SP - 108

EP - 114

JO - Current Opinion in Biotechnology

JF - Current Opinion in Biotechnology

ER -

Underground metabolism: network-level perspective and biotechnological potential

Abstract

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