Metagenomic Sequencing Unravels Gene Fragments with Phylogenetic Signatures of O2-Tolerant NiFe Membrane-Bound Hydrogenases in Lacustrine Sediment.

Jillian M Couto,Vernon R Phoenix,Melanie Schirmer,William T Sloan,Umer Zeeshan Ijaz

doi:10.1007/s00284-015-0846-2

Jillian M Couto, Vernon R Phoenix + Show 3 more

Open Access

https://doi.org/10.1007/s00284-015-0846-2

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Journal: Current microbiology	Publication Date: Jun 5, 2015
Citations: 35	License type: CC BY 4.0

Affiliation: University of Glasgow

Abstract

Many promising hydrogen technologies utilising hydrogenase enzymes have been slowed by the fact that most hydrogenases are extremely sensitive to O2. Within the group 1 membrane-bound NiFe hydrogenase, naturally occurring tolerant enzymes do exist, and O2 tolerance has been largely attributed to changes in iron–sulphur clusters coordinated by different numbers of cysteine residues in the enzyme’s small subunit. Indeed, previous work has provided a robust phylogenetic signature of O2 tolerance [1], which when combined with new sequencing technologies makes bio prospecting in nature a far more viable endeavour. However, making sense of such a vast diversity is still challenging and could be simplified if known species with O2-tolerant enzymes were annotated with information on metabolism and natural environments. Here, we utilised a bioinformatics approach to compare O2-tolerant and sensitive membrane-bound NiFe hydrogenases from 177 bacterial species with fully sequenced genomes for differences in their taxonomy, O2 requirements, and natural environment. Following this, we interrogated a metagenome from lacustrine surface sediment for novel hydrogenases via high-throughput shotgun DNA sequencing using the Illumina™ MiSeq platform. We found 44 new NiFe group 1 membrane-bound hydrogenase sequence fragments, five of which segregated with the tolerant group on the phylogenetic tree of the enzyme’s small subunit, and four with the large subunit, indicating de novo O2-tolerant protein sequences that could help engineer more efficient hydrogenases.Electronic supplementary materialThe online version of this article (doi:10.1007/s00284-015-0846-2) contains supplementary material, which is available to authorized users.

Highlights

The microbial world is a rich reserve of species and metabolic capabilities, which are being exploited to tackle grand challenges in energy, biotechnology and drug discovery
Within the group 1 membrane-bound NiFe hydrogenase, naturally occurring tolerant enzymes do exist, and O2 tolerance has been largely attributed to changes in iron–sulphur clusters coordinated by different numbers of cysteine residues in the enzyme’s small subunit
Making sense of such a vast diversity is still challenging and could be simplified if known species with O2-tolerant enzymes were annotated with information on metabolism and natural environments

Summary

Introduction

The microbial world is a rich reserve of species and metabolic capabilities, which are being exploited to tackle grand challenges in energy, biotechnology and drug discovery. While genetic engineering can be used to enhance performance, it does not always lead to a superior enzyme as has been the case with O2 tolerance and NiFe hydrogenases [2]. Hydrogenases are enzymes of great biotechnological interest because they catalyse the H2 half-cell reaction [2H? While all three types of hydrogenases, [Ni–Fe], [Fe–Fe] and [Feonly], can catalyse this reaction for the vast majority of enzymes that we know about, this reaction is severely attenuated, or even irreversibly halted, in the presence of O2. Given that O2 is either present or produced in every major reaction exploited by these proposed technologies, this intolerance is a major stumbling block that must be

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