A secondary metabolite drives intraspecies antagonism in a gut symbiont that is inhibited by cell-wall acetylation

Mustafa Özçam; Jee Hwan Oh; Restituto Tocmo; Deepa Acharya; Shenwei Zhang; Theresa J. Astmann; Mark Heggen; Silvette Ruiz-Ramírez; Fuyong Li; Christopher C. Cheng; Eugenio Vivas; Federico E. Rey; Jan Claesen; Tim S. Bugni; Jens Walter; Jan Peter van Pijkeren

doi:10.1016/j.chom.2022.03.033

A secondary metabolite drives intraspecies antagonism in a gut symbiont that is inhibited by cell-wall acetylation

Mustafa Özçam
, Jee Hwan Oh
, Restituto Tocmo
, Deepa Acharya
, Shenwei Zhang
, Theresa J. Astmann
, Mark Heggen
, Silvette Ruiz-Ramírez
, Fuyong Li
, Christopher C. Cheng
, Eugenio Vivas
, Federico E. Rey
, Jan Claesen
, Tim S. Bugni
, Jens Walter
, Jan Peter van Pijkeren

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

Abstract

The mammalian microbiome encodes numerous secondary metabolite biosynthetic gene clusters; yet, their role in microbe-microbe interactions is unclear. Here, we characterized two polyketide synthase gene clusters (fun and pks) in the gut symbiont Limosilactobacillus reuteri. The pks, but not the fun, cluster encodes antimicrobial activity. Forty-one of 51 L. reuteri strains tested are sensitive to Pks products; this finding was independent of strains’ host origin. Sensitivity to Pks was also established in intraspecies competition experiments in gnotobiotic mice. Comparative genome analyses between Pks-resistant and -sensitive strains identified an acyltransferase gene (act) unique to Pks-resistant strains. Subsequent cell-wall analysis of wild-type and act mutant strains showed that Act acetylates cell-wall components, providing resistance to Pks-mediated killing. Additionally, pks mutants lost their competitive advantage, while act mutants lost their Pks resistance in in vivo competition assays. These findings provide insight into how closely related gut symbionts can compete and co-exist in the gastrointestinal tract.

Original language	English
Pages (from-to)	824-835.e6
Journal	Cell Host and Microbe
Volume	30
Issue number	6
DOIs	https://doi.org/10.1016/j.chom.2022.03.033
Publication status	Published - 8 Jun 2022

Keywords

acetylation
acyltransferase
antimicrobial
biosynthetic gene clusters
gut symbiont
Limosilactobacillus reuteri
microbial competition
microbial ecology
polyene
polyketide
secondary metabolite

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10.1016/j.chom.2022.03.033

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Özçam, M., Oh, J. H., Tocmo, R., Acharya, D., Zhang, S., Astmann, T. J., Heggen, M., Ruiz-Ramírez, S., Li, F., Cheng, C. C., Vivas, E., Rey, F. E., Claesen, J., Bugni, T. S., Walter, J., & van Pijkeren, J. P. (2022). A secondary metabolite drives intraspecies antagonism in a gut symbiont that is inhibited by cell-wall acetylation. Cell Host and Microbe, 30(6), 824-835.e6. https://doi.org/10.1016/j.chom.2022.03.033

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title = "A secondary metabolite drives intraspecies antagonism in a gut symbiont that is inhibited by cell-wall acetylation",

abstract = "The mammalian microbiome encodes numerous secondary metabolite biosynthetic gene clusters; yet, their role in microbe-microbe interactions is unclear. Here, we characterized two polyketide synthase gene clusters (fun and pks) in the gut symbiont Limosilactobacillus reuteri. The pks, but not the fun, cluster encodes antimicrobial activity. Forty-one of 51 L. reuteri strains tested are sensitive to Pks products; this finding was independent of strains{\textquoteright} host origin. Sensitivity to Pks was also established in intraspecies competition experiments in gnotobiotic mice. Comparative genome analyses between Pks-resistant and -sensitive strains identified an acyltransferase gene (act) unique to Pks-resistant strains. Subsequent cell-wall analysis of wild-type and act mutant strains showed that Act acetylates cell-wall components, providing resistance to Pks-mediated killing. Additionally, pks mutants lost their competitive advantage, while act mutants lost their Pks resistance in in vivo competition assays. These findings provide insight into how closely related gut symbionts can compete and co-exist in the gastrointestinal tract.",

keywords = "acetylation, acyltransferase, antimicrobial, biosynthetic gene clusters, gut symbiont, Limosilactobacillus reuteri, microbial competition, microbial ecology, polyene, polyketide, secondary metabolite",

author = "Mustafa {\"O}z{\c c}am and Oh, \{Jee Hwan\} and Restituto Tocmo and Deepa Acharya and Shenwei Zhang and Astmann, \{Theresa J.\} and Mark Heggen and Silvette Ruiz-Ram{\'i}rez and Fuyong Li and Cheng, \{Christopher C.\} and Eugenio Vivas and Rey, \{Federico E.\} and Jan Claesen and Bugni, \{Tim S.\} and Jens Walter and \{van Pijkeren\}, \{Jan Peter\}",

note = "Publisher Copyright: {\textcopyright} 2022 The Authors",

year = "2022",

month = jun,

day = "8",

doi = "10.1016/j.chom.2022.03.033",

language = "English",

volume = "30",

pages = "824--835.e6",

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Özçam, M, Oh, JH, Tocmo, R, Acharya, D, Zhang, S, Astmann, TJ, Heggen, M, Ruiz-Ramírez, S, Li, F, Cheng, CC, Vivas, E, Rey, FE, Claesen, J, Bugni, TS, Walter, J & van Pijkeren, JP 2022, 'A secondary metabolite drives intraspecies antagonism in a gut symbiont that is inhibited by cell-wall acetylation', Cell Host and Microbe, vol. 30, no. 6, pp. 824-835.e6. https://doi.org/10.1016/j.chom.2022.03.033

TY - JOUR

T1 - A secondary metabolite drives intraspecies antagonism in a gut symbiont that is inhibited by cell-wall acetylation

AU - Özçam, Mustafa

AU - Oh, Jee Hwan

AU - Tocmo, Restituto

AU - Acharya, Deepa

AU - Zhang, Shenwei

AU - Astmann, Theresa J.

AU - Heggen, Mark

AU - Ruiz-Ramírez, Silvette

AU - Li, Fuyong

AU - Cheng, Christopher C.

AU - Vivas, Eugenio

AU - Rey, Federico E.

AU - Claesen, Jan

AU - Bugni, Tim S.

AU - Walter, Jens

AU - van Pijkeren, Jan Peter

PY - 2022/6/8

Y1 - 2022/6/8

N2 - The mammalian microbiome encodes numerous secondary metabolite biosynthetic gene clusters; yet, their role in microbe-microbe interactions is unclear. Here, we characterized two polyketide synthase gene clusters (fun and pks) in the gut symbiont Limosilactobacillus reuteri. The pks, but not the fun, cluster encodes antimicrobial activity. Forty-one of 51 L. reuteri strains tested are sensitive to Pks products; this finding was independent of strains’ host origin. Sensitivity to Pks was also established in intraspecies competition experiments in gnotobiotic mice. Comparative genome analyses between Pks-resistant and -sensitive strains identified an acyltransferase gene (act) unique to Pks-resistant strains. Subsequent cell-wall analysis of wild-type and act mutant strains showed that Act acetylates cell-wall components, providing resistance to Pks-mediated killing. Additionally, pks mutants lost their competitive advantage, while act mutants lost their Pks resistance in in vivo competition assays. These findings provide insight into how closely related gut symbionts can compete and co-exist in the gastrointestinal tract.

AB - The mammalian microbiome encodes numerous secondary metabolite biosynthetic gene clusters; yet, their role in microbe-microbe interactions is unclear. Here, we characterized two polyketide synthase gene clusters (fun and pks) in the gut symbiont Limosilactobacillus reuteri. The pks, but not the fun, cluster encodes antimicrobial activity. Forty-one of 51 L. reuteri strains tested are sensitive to Pks products; this finding was independent of strains’ host origin. Sensitivity to Pks was also established in intraspecies competition experiments in gnotobiotic mice. Comparative genome analyses between Pks-resistant and -sensitive strains identified an acyltransferase gene (act) unique to Pks-resistant strains. Subsequent cell-wall analysis of wild-type and act mutant strains showed that Act acetylates cell-wall components, providing resistance to Pks-mediated killing. Additionally, pks mutants lost their competitive advantage, while act mutants lost their Pks resistance in in vivo competition assays. These findings provide insight into how closely related gut symbionts can compete and co-exist in the gastrointestinal tract.

KW - acetylation

KW - acyltransferase

KW - antimicrobial

KW - biosynthetic gene clusters

KW - gut symbiont

KW - Limosilactobacillus reuteri

KW - microbial competition

KW - microbial ecology

KW - polyene

KW - polyketide

KW - secondary metabolite

UR - https://www.scopus.com/pages/publications/85131368295

U2 - 10.1016/j.chom.2022.03.033

DO - 10.1016/j.chom.2022.03.033

M3 - Article

C2 - 35443156

AN - SCOPUS:85131368295

SN - 1931-3128

VL - 30

SP - 824-835.e6

JO - Cell Host and Microbe

JF - Cell Host and Microbe

IS - 6

ER -

A secondary metabolite drives intraspecies antagonism in a gut symbiont that is inhibited by cell-wall acetylation

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