Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome

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Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome. / Neves, André L.A.; Yu, Jiangkun; Suzuki, Yutaka; Baez-Magana, Marisol; Arutyunova, Elena; O’Hara, Eóin; McAllister, Tim; Ominski, Kim H.; Lemieux, M. Joanne; Guan, Le Luo.

I: Microbiome, Bind 9, 229, 2021.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Neves, ALA, Yu, J, Suzuki, Y, Baez-Magana, M, Arutyunova, E, O’Hara, E, McAllister, T, Ominski, KH, Lemieux, MJ & Guan, LL 2021, 'Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome', Microbiome, bind 9, 229. https://doi.org/10.1186/s40168-021-01147-1

APA

Neves, A. L. A., Yu, J., Suzuki, Y., Baez-Magana, M., Arutyunova, E., O’Hara, E., McAllister, T., Ominski, K. H., Lemieux, M. J., & Guan, L. L. (2021). Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome. Microbiome, 9, [229]. https://doi.org/10.1186/s40168-021-01147-1

Vancouver

Neves ALA, Yu J, Suzuki Y, Baez-Magana M, Arutyunova E, O’Hara E o.a. Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome. Microbiome. 2021;9. 229. https://doi.org/10.1186/s40168-021-01147-1

Author

Neves, André L.A. ; Yu, Jiangkun ; Suzuki, Yutaka ; Baez-Magana, Marisol ; Arutyunova, Elena ; O’Hara, Eóin ; McAllister, Tim ; Ominski, Kim H. ; Lemieux, M. Joanne ; Guan, Le Luo. / Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome. I: Microbiome. 2021 ; Bind 9.

Bibtex

@article{00a4ee1df92a4fa8b767b7b4b6caa3b2,
title = "Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome",
abstract = "Background: Carbohydrate-active enzymes (CAZymes) form the most widespread and structurally diverse set of enzymes involved in the breakdown, biosynthesis, or modification of lignocellulose that can be found in living organisms. However, the structural diversity of CAZymes has rendered the targeted discovery of novel enzymes extremely challenging, as these proteins catalyze many different chemical reactions and are sourced by a vast array of microbes. Consequently, many uncharacterized members of CAZyme families of interest have been overlooked by current methodologies (e.g., metagenomic screening) used to discover lignocellulolytic enzymes. Results: In the present study, we combined phenotype-based selective pressure on the rumen microbiota with targeted functional profiling to guide the discovery of unknown CAZymes. In this study, we found 61 families of glycoside hydrolases (GH) (out of 182 CAZymes) from protein sequences deposited in the CAZy database—currently associated with more than 20,324 microbial genomes. Phenotype-based selective pressure on the rumen microbiome showed that lignocellulolytic bacteria (e.g., Fibrobacter succinogenes, Butyrivibrio proteoclasticus) and three GH families (e.g., GH11, GH13, GH45) exhibited an increased relative abundance in the rumen of feed efficient cattle when compared to their inefficient counterparts. These results paved the way for the application of targeted functional profiling to screen members of the GH11 and GH45 families against a de novo protein reference database comprised of 1184 uncharacterized enzymes, which led to the identification of 18 putative xylanases (GH11) and three putative endoglucanases (GH45). The biochemical proof of the xylanolytic activity of the newly discovered enzyme validated the computational simulations and demonstrated the stability of the most abundant xylanase. Conclusions: These findings contribute to the discovery of novel enzymes for the breakdown, biosynthesis, or modification of lignocellulose and demonstrate that the rumen microbiome is a source of promising enzyme candidates for the biotechnology industry. The combined approaches conceptualized in this study can be adapted to any microbial environment, provided that the targeted microbiome is easy to manipulate and facilitates enrichment for the microbes of interest. [MediaObject not available: see fulltext.].",
keywords = "Cattle, Feed efficiency, Microbial enzymes, Rumen microbiota",
author = "Neves, {Andr{\'e} L.A.} and Jiangkun Yu and Yutaka Suzuki and Marisol Baez-Magana and Elena Arutyunova and E{\'o}in O{\textquoteright}Hara and Tim McAllister and Ominski, {Kim H.} and Lemieux, {M. Joanne} and Guan, {Le Luo}",
note = "Publisher Copyright: {\textcopyright} 2021, The Author(s).",
year = "2021",
doi = "10.1186/s40168-021-01147-1",
language = "English",
volume = "9",
journal = "Microbiome",
issn = "2049-2618",
publisher = "BioMed Central Ltd.",

}

RIS

TY - JOUR

T1 - Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome

AU - Neves, André L.A.

AU - Yu, Jiangkun

AU - Suzuki, Yutaka

AU - Baez-Magana, Marisol

AU - Arutyunova, Elena

AU - O’Hara, Eóin

AU - McAllister, Tim

AU - Ominski, Kim H.

AU - Lemieux, M. Joanne

AU - Guan, Le Luo

N1 - Publisher Copyright: © 2021, The Author(s).

PY - 2021

Y1 - 2021

N2 - Background: Carbohydrate-active enzymes (CAZymes) form the most widespread and structurally diverse set of enzymes involved in the breakdown, biosynthesis, or modification of lignocellulose that can be found in living organisms. However, the structural diversity of CAZymes has rendered the targeted discovery of novel enzymes extremely challenging, as these proteins catalyze many different chemical reactions and are sourced by a vast array of microbes. Consequently, many uncharacterized members of CAZyme families of interest have been overlooked by current methodologies (e.g., metagenomic screening) used to discover lignocellulolytic enzymes. Results: In the present study, we combined phenotype-based selective pressure on the rumen microbiota with targeted functional profiling to guide the discovery of unknown CAZymes. In this study, we found 61 families of glycoside hydrolases (GH) (out of 182 CAZymes) from protein sequences deposited in the CAZy database—currently associated with more than 20,324 microbial genomes. Phenotype-based selective pressure on the rumen microbiome showed that lignocellulolytic bacteria (e.g., Fibrobacter succinogenes, Butyrivibrio proteoclasticus) and three GH families (e.g., GH11, GH13, GH45) exhibited an increased relative abundance in the rumen of feed efficient cattle when compared to their inefficient counterparts. These results paved the way for the application of targeted functional profiling to screen members of the GH11 and GH45 families against a de novo protein reference database comprised of 1184 uncharacterized enzymes, which led to the identification of 18 putative xylanases (GH11) and three putative endoglucanases (GH45). The biochemical proof of the xylanolytic activity of the newly discovered enzyme validated the computational simulations and demonstrated the stability of the most abundant xylanase. Conclusions: These findings contribute to the discovery of novel enzymes for the breakdown, biosynthesis, or modification of lignocellulose and demonstrate that the rumen microbiome is a source of promising enzyme candidates for the biotechnology industry. The combined approaches conceptualized in this study can be adapted to any microbial environment, provided that the targeted microbiome is easy to manipulate and facilitates enrichment for the microbes of interest. [MediaObject not available: see fulltext.].

AB - Background: Carbohydrate-active enzymes (CAZymes) form the most widespread and structurally diverse set of enzymes involved in the breakdown, biosynthesis, or modification of lignocellulose that can be found in living organisms. However, the structural diversity of CAZymes has rendered the targeted discovery of novel enzymes extremely challenging, as these proteins catalyze many different chemical reactions and are sourced by a vast array of microbes. Consequently, many uncharacterized members of CAZyme families of interest have been overlooked by current methodologies (e.g., metagenomic screening) used to discover lignocellulolytic enzymes. Results: In the present study, we combined phenotype-based selective pressure on the rumen microbiota with targeted functional profiling to guide the discovery of unknown CAZymes. In this study, we found 61 families of glycoside hydrolases (GH) (out of 182 CAZymes) from protein sequences deposited in the CAZy database—currently associated with more than 20,324 microbial genomes. Phenotype-based selective pressure on the rumen microbiome showed that lignocellulolytic bacteria (e.g., Fibrobacter succinogenes, Butyrivibrio proteoclasticus) and three GH families (e.g., GH11, GH13, GH45) exhibited an increased relative abundance in the rumen of feed efficient cattle when compared to their inefficient counterparts. These results paved the way for the application of targeted functional profiling to screen members of the GH11 and GH45 families against a de novo protein reference database comprised of 1184 uncharacterized enzymes, which led to the identification of 18 putative xylanases (GH11) and three putative endoglucanases (GH45). The biochemical proof of the xylanolytic activity of the newly discovered enzyme validated the computational simulations and demonstrated the stability of the most abundant xylanase. Conclusions: These findings contribute to the discovery of novel enzymes for the breakdown, biosynthesis, or modification of lignocellulose and demonstrate that the rumen microbiome is a source of promising enzyme candidates for the biotechnology industry. The combined approaches conceptualized in this study can be adapted to any microbial environment, provided that the targeted microbiome is easy to manipulate and facilitates enrichment for the microbes of interest. [MediaObject not available: see fulltext.].

KW - Cattle

KW - Feed efficiency

KW - Microbial enzymes

KW - Rumen microbiota

U2 - 10.1186/s40168-021-01147-1

DO - 10.1186/s40168-021-01147-1

M3 - Journal article

C2 - 34814938

AN - SCOPUS:85119659549

VL - 9

JO - Microbiome

JF - Microbiome

SN - 2049-2618

M1 - 229

ER -

ID: 285796166