TY - JOUR
T1 - A systematic computational analysis of biosynthetic gene cluster evolution: lessons for engineering biosynthesis.
AU - Medema, Marnix H
AU - Cimermancic, Peter
AU - Sali, Andrej
AU - Takano, Eriko
AU - Fischbach, Michael A
N1 - AI101018, NIAID NIH HHS, United StatesAI101722, NIAID NIH HHS, United StatesGM081879, NIGMS NIH HHS, United StatesHHSN272200900018C, PHS HHS, United StatesOD007290, NIH HHS, United StatesR01 AI101018, NIAID NIH HHS, United States, Howard Hughes Medical Institute, United States
PY - 2014/12
Y1 - 2014/12
N2 - Bacterial secondary metabolites are widely used as antibiotics, anticancer drugs, insecticides and food additives. Attempts to engineer their biosynthetic gene clusters (BGCs) to produce unnatural metabolites with improved properties are often frustrated by the unpredictability and complexity of the enzymes that synthesize these molecules, suggesting that genetic changes within BGCs are limited by specific constraints. Here, by performing a systematic computational analysis of BGC evolution, we derive evidence for three findings that shed light on the ways in which, despite these constraints, nature successfully invents new molecules: 1) BGCs for complex molecules often evolve through the successive merger of smaller sub-clusters, which function as independent evolutionary entities. 2) An important subset of polyketide synthases and nonribosomal peptide synthetases evolve by concerted evolution, which generates sets of sequence-homogenized domains that may hold promise for engineering efforts since they exhibit a high degree of functional interoperability, 3) Individual BGC families evolve in distinct ways, suggesting that design strategies should take into account family-specific functional constraints. These findings suggest novel strategies for using synthetic biology to rationally engineer biosynthetic pathways.
AB - Bacterial secondary metabolites are widely used as antibiotics, anticancer drugs, insecticides and food additives. Attempts to engineer their biosynthetic gene clusters (BGCs) to produce unnatural metabolites with improved properties are often frustrated by the unpredictability and complexity of the enzymes that synthesize these molecules, suggesting that genetic changes within BGCs are limited by specific constraints. Here, by performing a systematic computational analysis of BGC evolution, we derive evidence for three findings that shed light on the ways in which, despite these constraints, nature successfully invents new molecules: 1) BGCs for complex molecules often evolve through the successive merger of smaller sub-clusters, which function as independent evolutionary entities. 2) An important subset of polyketide synthases and nonribosomal peptide synthetases evolve by concerted evolution, which generates sets of sequence-homogenized domains that may hold promise for engineering efforts since they exhibit a high degree of functional interoperability, 3) Individual BGC families evolve in distinct ways, suggesting that design strategies should take into account family-specific functional constraints. These findings suggest novel strategies for using synthetic biology to rationally engineer biosynthetic pathways.
U2 - 10.1371/journal.pcbi.1004016
DO - 10.1371/journal.pcbi.1004016
M3 - Article
C2 - 25474254
SN - 1553-7358
VL - 10
JO - P L o S Computational Biology (Online)
JF - P L o S Computational Biology (Online)
IS - 12
ER -