Metabolic model for diversity-generating biosynthesis

Ma Diarey Tianero; Elizabeth Pierce; Shrinivasan Raghuraman; Debosmita Sardar; John A. McIntosh; John R. Heemstra; Zachary Schonrock; Brett C. Covington; J. Alan Maschek; James E. Cox; Brian O. Bachmann; Baldomero M. Olivera; Duane E. Ruffner; Eric W. Schmidt

doi:10.1073/pnas.1525438113

Metabolic model for diversity-generating biosynthesis

Ma Diarey Tianero
, Elizabeth Pierce
, Shrinivasan Raghuraman
, Debosmita Sardar
, John A. McIntosh
, John R. Heemstra
, Zachary Schonrock
, Brett C. Covington
, J. Alan Maschek
, James E. Cox
, Brian O. Bachmann
, Baldomero M. Olivera
, Duane E. Ruffner
, Eric W. Schmidt

Department of Chemistry

Research output: Contribution to journal › Article › peer-review

54 Scopus citations

Abstract

A conventional metabolic pathway leads to a specific product. In stark contrast, there are diversity-generating metabolic pathways that naturally produce different chemicals, sometimes of great diversity. We demonstrate that for one such pathway, tru, each ensuing metabolic step is slower, in parallel with the increasing potential chemical divergence generated as the pathway proceeds. Intermediates are long lived and accumulate progressively, in contrast with conventional metabolic pathways, in which the first step is rate-limiting and metabolic intermediates are shortlived. Understanding these fundamental differences enables several different practical applications, such as combinatorial biosynthesis, some of which we demonstrate here. We propose that these principles may provide a unifying framework underlying diversity-generating metabolism in many different biosynthetic pathways.

Original language	English
Pages (from-to)	1772-1777
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	113
Issue number	7
DOIs	https://doi.org/10.1073/pnas.1525438113
State	Published - Feb 16 2016

Keywords

Biosynthesis
Cyanobactin
Natural products
RiPP
Secondary metabolism

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10.1073/pnas.1525438113

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Tianero, M. D., Pierce, E., Raghuraman, S., Sardar, D., McIntosh, J. A., Heemstra, J. R., Schonrock, Z., Covington, B. C., Maschek, J. A., Cox, J. E., Bachmann, B. O., Olivera, B. M., Ruffner, D. E., & Schmidt, E. W. (2016). Metabolic model for diversity-generating biosynthesis. Proceedings of the National Academy of Sciences of the United States of America, 113(7), 1772-1777. https://doi.org/10.1073/pnas.1525438113

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title = "Metabolic model for diversity-generating biosynthesis",

abstract = "A conventional metabolic pathway leads to a specific product. In stark contrast, there are diversity-generating metabolic pathways that naturally produce different chemicals, sometimes of great diversity. We demonstrate that for one such pathway, tru, each ensuing metabolic step is slower, in parallel with the increasing potential chemical divergence generated as the pathway proceeds. Intermediates are long lived and accumulate progressively, in contrast with conventional metabolic pathways, in which the first step is rate-limiting and metabolic intermediates are shortlived. Understanding these fundamental differences enables several different practical applications, such as combinatorial biosynthesis, some of which we demonstrate here. We propose that these principles may provide a unifying framework underlying diversity-generating metabolism in many different biosynthetic pathways.",

keywords = "Biosynthesis, Cyanobactin, Natural products, RiPP, Secondary metabolism",

author = "Tianero, \{Ma Diarey\} and Elizabeth Pierce and Shrinivasan Raghuraman and Debosmita Sardar and McIntosh, \{John A.\} and Heemstra, \{John R.\} and Zachary Schonrock and Covington, \{Brett C.\} and Maschek, \{J. Alan\} and Cox, \{James E.\} and Bachmann, \{Brian O.\} and Olivera, \{Baldomero M.\} and Ruffner, \{Duane E.\} and Schmidt, \{Eric W.\}",

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doi = "10.1073/pnas.1525438113",

language = "English",

volume = "113",

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Tianero, MD, Pierce, E, Raghuraman, S, Sardar, D, McIntosh, JA, Heemstra, JR, Schonrock, Z, Covington, BC, Maschek, JA, Cox, JE, Bachmann, BO, Olivera, BM, Ruffner, DE & Schmidt, EW 2016, 'Metabolic model for diversity-generating biosynthesis', Proceedings of the National Academy of Sciences of the United States of America, vol. 113, no. 7, pp. 1772-1777. https://doi.org/10.1073/pnas.1525438113

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T1 - Metabolic model for diversity-generating biosynthesis

AU - Tianero, Ma Diarey

AU - Pierce, Elizabeth

AU - Raghuraman, Shrinivasan

AU - Sardar, Debosmita

AU - McIntosh, John A.

AU - Heemstra, John R.

AU - Schonrock, Zachary

AU - Covington, Brett C.

AU - Maschek, J. Alan

AU - Cox, James E.

AU - Bachmann, Brian O.

AU - Olivera, Baldomero M.

AU - Ruffner, Duane E.

AU - Schmidt, Eric W.

PY - 2016/2/16

Y1 - 2016/2/16

N2 - A conventional metabolic pathway leads to a specific product. In stark contrast, there are diversity-generating metabolic pathways that naturally produce different chemicals, sometimes of great diversity. We demonstrate that for one such pathway, tru, each ensuing metabolic step is slower, in parallel with the increasing potential chemical divergence generated as the pathway proceeds. Intermediates are long lived and accumulate progressively, in contrast with conventional metabolic pathways, in which the first step is rate-limiting and metabolic intermediates are shortlived. Understanding these fundamental differences enables several different practical applications, such as combinatorial biosynthesis, some of which we demonstrate here. We propose that these principles may provide a unifying framework underlying diversity-generating metabolism in many different biosynthetic pathways.

AB - A conventional metabolic pathway leads to a specific product. In stark contrast, there are diversity-generating metabolic pathways that naturally produce different chemicals, sometimes of great diversity. We demonstrate that for one such pathway, tru, each ensuing metabolic step is slower, in parallel with the increasing potential chemical divergence generated as the pathway proceeds. Intermediates are long lived and accumulate progressively, in contrast with conventional metabolic pathways, in which the first step is rate-limiting and metabolic intermediates are shortlived. Understanding these fundamental differences enables several different practical applications, such as combinatorial biosynthesis, some of which we demonstrate here. We propose that these principles may provide a unifying framework underlying diversity-generating metabolism in many different biosynthetic pathways.

KW - Biosynthesis

KW - Cyanobactin

KW - Natural products

KW - RiPP

KW - Secondary metabolism

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AN - SCOPUS:84959018604

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JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

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Metabolic model for diversity-generating biosynthesis

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