Highly Promiscuous Oxidases Discovered in the Bovine Rumen Microbiome.

The bovine rumen hosts a diverse microbiota, which is highly specialized in the degradation of lignocellulose. Ruminal bacteria, in particular, are well equipped to deconstruct plant cell wall polysaccharides. Nevertheless, their potential role in the breakdown of the lignin network has never been investigated. In this study, we used functional metagenomics to identify bacterial redox enzymes acting on polyaromatic compounds. A new methodology was developed to explore the potential of uncultured microbes to degrade lignin derivatives, namely kraft lignin and lignosulfonate. From a fosmid library covering 0.7 Gb of metagenomic DNA, three hit clones were identified, producing enzymes able to oxidize a wide variety of polyaromatic compounds without the need for the addition of copper, manganese, or mediators. These promiscuous redox enzymes could thus be of potential interest both in plant biomass refining and dye remediation. The enzymes were derived from uncultured Clostridia, and belong to complex gene clusters involving proteins of different functional types, including hemicellulases, which likely work in synergy to produce substrate degradation.

Discovery of carbamate degrading enzymes by functional metagenomics.

Bioremediation of pollutants is a major concern worldwide, leading to the research of new processes to break down and recycle xenobiotics and environment contaminating polymers. Among them, carbamates have a very broad spectrum of uses, such as toxinogenic pesticides or elastomers. In this study, we mined the bovine rumen microbiome for carbamate degrading enzymes. We isolated 26 hit clones exhibiting esterase activity, and were able to degrade at least one of the targeted polyurethane and pesticide carbamate compounds. The most active clone was deeply characterized. In addition to Impranil, this clone was active on Tween 20, pNP-acetate, butyrate and palmitate, and on the insecticide fenobucarb. Sequencing and sub-cloning of the best target revealed a novel carboxyl-ester hydrolase belonging to the lipolytic family IV, named CE_Ubrb. This study highlights the potential of highly diverse microbiota such as the ruminal one for the discovery of promiscuous enzymes, whose versatility could be exploited for industrial uses.

Functional Metagenomics: Construction and High-Throughput Screening of Fosmid Libraries for Discovery of Novel Carbohydrate-Active Enzymes.

Activity-based metagenomics is one of the most efficient approaches to boost the discovery of novel biocatalysts from the huge reservoir of uncultivated bacteria. In this chapter, we describe a highly generic procedure of metagenomic library construction and high-throughput screening for carbohydrate-active enzymes. Applicable to any bacterial ecosystem, it enables the swift identification of functional enzymes that are highly efficient, alone or acting in synergy, to break down polysaccharides and oligosaccharides.

Metagenomics for the discovery of pollutant degrading enzymes.

Organic pollutants, including xenobiotics, are often persistent and toxic organic compounds resulting from human activities and released in large amounts into terrestrial, fluvial and marine environments. However, some microbial species which are naturally exposed to these compounds in their own habitat are capable of degrading a large range of pollutants, especially poly-aromatic, halogenated and polyester molecules. These microbes constitute a huge reservoir of enzymes for the diagnosis of pollution and for bioremediation. Most are found in highly complex ecosystems like soils, activated sludge, compost or polluted water, and more than 99% have never been cultured. Meta-omic approaches are thus well suited to retrieve biocatalysts from these environmental samples. In this review, we report the latest advances in functional metagenomics aimed at the discovery of enzymes capable of acting on different kinds of polluting molecules.

Discovery of new protein families and functions: new challenges in functional metagenomics for biotechnologies and microbial ecology.

The rapid expansion of new sequencing technologies has enabled large-scale functional exploration of numerous microbial ecosystems, by establishing catalogs of functional genes and by comparing their prevalence in various microbiota. However, sequence similarity does not necessarily reflect functional conservation, since just a few modifications in a gene sequence can have a strong impact on the activity and the specificity of the corresponding enzyme or the recognition for a sensor. Similarly, some microorganisms harbor certain identified functions yet do not have the expected related genes in their genome. Finally, there are simply too many protein families whose function is not yet known, even though they are highly abundant in certain ecosystems. In this context, the discovery of new protein functions, using either sequence-based or activity-based approaches, is of crucial importance for the discovery of new enzymes and for improving the quality of annotation in public databases. This paper lists and explores the latest advances in this field, along with the challenges to be addressed, particularly where microfluidic technologies are concerned.

Inventory of the GH70 enzymes encoded by Leuconostoc citreum NRRL B-1299 - identification of three novel α-transglucosylases.

Leuconostoc citreum NRRL B-1299 has long been known to produce α-glucans containing both α-(1→6) and α-(1→2) linkages, which are synthesized by α-transglucosylases of the GH70 family. We sequenced the genome of Leuconostoc citreum NRRL B-1299 to identify the full inventory of GH70 enzymes in this strain. Three new genes (brsA, dsrM and dsrDP) putatively encoding GH70 enzymes were identified. The corresponding recombinant enzymes were characterized. Branching sucrase A (BRS-A) grafts linear α-(1→6) dextran with α-(1→2)-linked glucosyl units, and is probably involved in the α-(1→2) branching of L. citreum NRRL B-1299 dextran. This is the first report of a naturally occurring α-(1→2) branching sucrase. DSR-M and DSR-DP are dextransucrases that are specific for α-(1→6) linkage synthesis and mainly produce oligomers or short dextrans with molar masses between 580 and 27 000 g·mol(-1) . In addition, DSR-DP contains sequences that diverge from the consensus sequences that are typically present in enzymes that synthesize linear dextran. Comparison of the genome with five other L. citreum genomes further revealed that dsrDP is unique to L. citreum NRRL B-1299. The presence of this gene in a prophage represents the first evidence of phage-mediated horizontal transfer of genes encoding such enzymes in lactic acid bacteria. Finally, brsA and dsrM are located in a chromosomal region in which genes encoding strain-specific GH70 enzymes are consistently located. This region may be a good target on which to focus in order to rapidly evaluate the diversity of GH70 enzymes in L. citreum strains.