Recovery and Functional Validation of Hidden Soil Enzymes in Metagenomic Libraries

Overview

Journal Microbiologyopen

Specialty Microbiology

Date 2019 Mar 10

PMID 30851083

Citations 4

Authors

Dayana Calderon

Luis Pena

Angelica Suarez

Carolina Villamil

Adan Ramirez-Rojas

Juan M Anzola

Juan C Garcia-Betancur

Martha L Cepeda

Daniel Uribe

Patricia Del Portillo

Alvaro Mongui

Affiliations

Soon will be listed here.

Abstract

The vast microbial diversity on the planet represents an invaluable source for identifying novel activities with potential industrial and therapeutic application. In this regard, metagenomics has emerged as a group of strategies that have significantly facilitated the analysis of DNA from multiple environments and has expanded the limits of known microbial diversity. However, the functional characterization of enzymes, metabolites, and products encoded by diverse microbial genomes is limited by the inefficient heterologous expression of foreign genes. We have implemented a pipeline that combines NGS and Sanger sequencing as a way to identify fosmids within metagenomic libraries. This strategy facilitated the identification of putative proteins, subcloning of targeted genes and preliminary characterization of selected proteins. Overall, the in silico approach followed by the experimental validation allowed us to efficiently recover the activity of previously hidden enzymes derived from agricultural soil samples. Therefore, the methodology workflow described herein can be applied to recover activities encoded by environmental DNA from multiple sources.

Citing Articles

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Discovery of Novel Biosynthetic Gene Cluster Diversity From a Soil Metagenomic Library.

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Recovery and functional validation of hidden soil enzymes in metagenomic libraries.

Calderon D, Pena L, Suarez A, Villamil C, Ramirez-Rojas A, Anzola J Microbiologyopen. 2019; 8(4):e00572.

PMID: 30851083 PMC: 6460280. DOI: 10.1002/mbo3.572.

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