Environmental metagenomics: An innovative resource for industrial biocatalysis

The current existing enzymes have been identified from cultivable micro-organisms, most frequently from bacteria. These bacterial biocatalytic capabilities have been widely used for biotransformations, resulting in the development of profitable industrial bioprocesses in the fields of feed and food processing, textiles, agro-chemistry, cosmetics, pharmaceuticals and fine chemistry. However, the originality of this bioresource is progressively drying up, while requests from industry for novel biocatalytic activities are increasing in the face of economic and environmental pressure. Metagenomics, through access to the huge reservoir of uncultivated bacteria which represents the majority of the present biodiversity, opens the door to new industrial sources of enzymes. Surmounting hurdles encountered with this technology (e.g. DNA extraction to obtain high quality DNA libraries with proper statistical representativity, setting up of relevant high throughput screenings assays, combining functional and genome-based identifications), gives unique opportunities to access novel biocatalysts that better fit with the required industrial specifications, thus providing new biocatalysis tool boxes.     

Emerging strategies for expanding the toolbox of enzymes in biocatalysis

Expanding the repertoire of reactions available to enzymes is an enduring challenge in biocatalysis. Owing to the synthetic versatility of transition metals, metalloenzymes have been favored targets for achieving new catalytic functions. Although less well explored, enzymes lacking metal centers can also be effective catalysts for non-natural reactions, providing access to reaction modalities that compliment those available to metals. By understanding how these activation modes can reveal new functions, strategies can be developed to access novel biocatalytic reactions. This review will cover discoveries in the last two years which access catalytic reactions that go beyond the native repertoire of metal-free biocatalysts.     

Biocatalysis--key to sustainable industrial chemistry

The ongoing trends to process improvements, cost reductions and increasing quality, safety, health and environment requirements of industrial chemical transformations have strengthened the translation of global biocatalysis research work into industrial applications. One focus has been on biocatalytic single-step reactions with one or two substrates, the identification of bottlenecks and molecular as well as engineering approaches to overcome these bottlenecks. Robust industrial procedures have been established along classes of biocatalytic single-step reactions. Multi-step reactions and multi-component reactions (MCRs) enable a bottom-up approach with biocatalytic reactions working together in one compartment and recations hindering each other within different compartments or steps. The understanding of the catalytic functions of known and new enzymes is key for the development of new sustainable chemical transformations.     

Expanding the Halohydrin Dehalogenase Enzyme Family: Identification of Novel Enzymes by Database Mining

Halohydrin dehalogenases are very rare enzymes that are naturally involved in the mineralization of halogenated xenobiotics. Due to their catalytic potential and promiscuity, many biocatalytic reactions have been described that have led to several interesting and industrially important applications. Nevertheless, only a few of these enzymes have been made available through recombinant techniques; hence, it is of general interest to expand the repertoire of these enzymes so as to enable novel biocatalytic applications. After the identification of specific sequence motifs, 37 novel enzyme sequences were readily identified in public sequence databases. All enzymes that could be heterologously expressed also catalyzed typical halohydrin dehalogenase reactions. Phylogenetic inference for enzymes of the halohydrin dehalogenase enzyme family confirmed that all enzymes form a distinct monophyletic clade within the short-chain dehydrogenase/reductase superfamily. In addition, the majority of novel enzymes are substantially different from previously known phylogenetic subtypes. Consequently, four additional phylogenetic subtypes were defined, greatly expanding the halohydrin dehalogenase enzyme family. We show that the enormous wealth of environmental and genome sequences present in public databases can be tapped for in silico identification of very rare but biotechnologically important biocatalysts. Our findings help to readily identify halohydrin dehalogenases in ever-growing sequence databases and, as a consequence, make even more members of this interesting enzyme family available to the scientific and industrial community.     

Perspectives and industrial potential of PGA selectivity and promiscuity

Penicillin G acylases (PGAs) are robust industrial catalysts used for biotransformation of β-lactams into key intermediates for chemical production of semi-synthetic β-lactam antibiotics by hydrolysis of natural penicillins. They are used also in reverse, kinetically controlled synthetic reactions for large-scale productions of these antibiotics from corresponding beta-lactam nuclei and activated acyl donors. Further biocatalytic applications of PGAs have recently been described: catalysis of peptide syntheses and the resolutions of racemic mixtures for the production of enantiopure active pharmaceutical ingredients that are based on enantioselective acylation or chiral hydrolysis. Moreover, PGAs rank among promiscuous enzymes because they also catalyze reactions such as trans-esterification, Markovnikov addition or Henry reaction. This particular biocatalytic versatility represents a driving force for the discovery of novel members of this enzyme family and further research into the catalytic potential of PGAs. This review deals with biocatalytic applications exploiting enantioselectivity and promiscuity of prokaryotic PGAs that have been recently reported. Biocatalytic applications are discussed and presented with reaction substrates converted into active compounds useful for the pharmaceutical industry.     

Biocatalytic ketone reduction: A green and efficient access to enantiopure alcohols

Chiral secondary alcohols play an important role in pharmaceutical, agrochemical, and chemical industries. In recent years, impressive steps forward have been achieved towards biocatalytic ketone reduction as a green and useful access to enantiopure alcohols. An increasing number of novel and robust enzymes are now accessible as a result of the ongoing progress in genomics, screening and evolution technologies, while process engineering provides further success in areas of biocatalytic reduction in meeting synthetic challenges. The versatile platform of these techniques and strategies offers the possibility to apply high substrate loading and thus to overcome the limitation of low volumetric productivity of usual enzymatic processes which is the bottleneck for their practical application. In addition, the integration of bioreduction with other enzymatic or chemical steps allows the efficient synthesis of more complex chiral products.     

Glycoside Hydrolases from a targeted Compost Metagenome, activity-screening and functional characterization

ABSTRACT: BACKGROUND: Metagenomics approaches provide access to environmental genetic diversity for biotechnology applications, enabling the discovery of new enzymes and pathways for numerous catalytic processes. Discovery of new glycoside hydrolases with improved biocatalytic properties for the efficient conversion of lignocellulosic material to biofuels is a critical challenge in the development of economically viable routes from biomass to fuels and chemicals. RESULTS: Twenty-two putative ORFs (open reading frames) were identified from a switchgrass-adapted compost community based on sequence homology to related gene families. These ORFs were expressed in E. coli and assayed for predicted activities. Seven of the ORFs were demonstrated to encode active enzymes, encompassing five classes of hemicellulases. Four enzymes were over expressed in vivo, purified to homogeneity and subjected to detailed biochemical characterization. Their pH optima ranged between 5.5 - 7.5 and they exhibit moderate thermostability up to ~60-70degreesC. CONCLUSIONS: Seven active enzymes were identified from this set of ORFs comprising five different hemicellulose activities. These enzymes have been shown to have useful properties, such as moderate thermal stability and broad pH optima, and may serve as the starting points for future protein engineering towards the goal of developing efficient enzyme cocktails for biomass degradation under diverse process conditions.     

Mining of genomic databases to identify novel biodesulfurizing microorganisms

The commercialization of the biocatalytic desulfurization process does not seem to be realistic in the near future because of the low desulfurization rate of the known microorganisms. Hence, the future development will depend on either genetically modifying the currently available bacteria or identifying novel biodesulfurizers. In this study an in silico method to identify new biodesulfurizing microorganisms was adopted. By screening the available genomic databases, 13 novel desulfurizing microorganisms belonging to 12 genera were identified. Several of these could be of immense utility as they have both environment pollutant and industrial waste degrading capability.     

New applications of biocatalysts.

The development of new biocatalytic applications continues to advance in several directions. Over the past year, new enzymes have been discovered and their potential in biocatalyst applications has been researched. In addition, new chemical and genetic modifications have been made in the development of novel fermentation processes.     

Flavoenzymes

Flavoenzymes are colourful oxidoreductases that catalyze a large variety of different types of reactions. Flavoenzymes have been extensively studied for their structural and mechanistic properties and are gaining momentum in industrial biocatalytic applications. Some of these enzymes catalyze the oxidative modification of protein substrates. New insights in oxidative flavoenzymes and in particular in novel family members point towards their potential application in the pharmaceutical, fine-chemical and food industries.     

Laboratory evolution of catabolic enzymes and pathways

The laboratory evolution of environmentally relevant enzymes and proteins has resulted in the generation of optimized and stabilized enzymes, as well as enzymes with activity against new substrates. Numerous methods, including random mutagenesis, site-directed mutagenesis and DNA shuffling, have been widely used to generate variants of existing enzymes. These evolved catabolic enzymes have application for improving biodegradation pathways, generating engineered pathways for the degradation of particularly recalcitrant compounds, and for the development of biocatalytic processes to produce useful compounds. Regulatory proteins associated with catabolic pathways have been utilized to generate biosensors for the detection of bioavailable concentrations of environmentally relevant chemicals.     

The Importance of Thermophilic Bacteria in Biotechnology

Abstract

The development of new analytical techniques and the commercial availability of new substrates have led to the purification and characterization of a large number of xylan-degrading enzymes. Furthermore, the introduction of recombinant DNA technology has resulted in the selection of xylanolytic enzymes that are more suitable for industrial applications. For a successful integration of xylanases in industrial processes, a detailed understanding of the mechanism of enzyme action is, however, required. This review gives an overview of various xylanolytic enzyme systems from bacteria and fungi that have been described recently in more detail.     

Novel biocatalysis by database mining

Broad-based adoption of biocatalytic methods will require widely available database tools, analogous to previous efforts compiling information for the facilitation of chemical synthesis. The analog to chemical reagents are enzymes. The analog to chemical synthetic routes are metabolic pathways. The free on-line database BRENDA exemplifies efforts to compile relevant information on enzymes for biocatalytic purposes. Likewise, the University of Minnesota Biocatalysis/Biodegradation Database focuses on novel enzymes and metabolic pathways useful in environmental and industrial biotechnology. The development of biocatalytic protocols will be facilitated by the increasing availability of well-curated database information on enzymatic enantioselectivity and capabilities for transforming disparate chemical functional groups.     

Enzyme overproduction: Principle and application

The rapprochement between gene physiology and protein chemistry proffered a wishful manipulation or programming of biological blueprint which we now know as recombinant DNA technology. Its premises are very many and ends are manifold. Until rather recently, the recombinant DNA technique could conceive the idea of engineering enzyme molecules by cloning and selection of the gene in question for enzyme production. At least, in principle, the process is too simple but its underlying mechanism is rather much stringent. Various experimental paradigms have been brought to work for production of enzyme at will by introducing a given gene into a high yielding system of microorganisms. It facilitates overproduction of enzymes of interest which can be implicated in several important industrial, biomedical, and environmental processes at a large scale. Such approaches of enzymes made-to-application have already started asserting tremendously in doing their appropriate jobs at the level of molecular interactions. A rapid progress in this important and interesting area of biocatalytic manipulation will certainly achieve the goal of biocatalysis-made-to-order by altering kinetic and thermodynamic components of enzyme molecules.     

New opportunities for biocatalysis: driving the synthesis of chiral chemicals

Various biocatalytic methods have been developed for the synthesis of chiral chemicals, which have made their synthesis more environmentally friendly and product-specific. New opportunities for biocatalysis, including new scientific developments in genomics and protein engineering technologies, novel process developments and the increased availability of useful enzymes, offer many possibilities for the manufacture of new chiral compounds and deliver greener and economically competitive processes. In this review, new opportunities for biocatalysis in the preparation of chiral molecules are outlined and highlighted.     

Microbial diversity in natural asphalts of the Rancho La Brea Tar Pits

Bacteria commonly inhabit subsurface oil reservoirs, but almost nothing is known yet about microorganisms that live in naturally occurring terrestrial oil seeps and natural asphalts that are comprised of highly recalcitrant petroleum hydrocarbons. Here we report the first survey of microbial diversity in ca. 28,000-year-old samples of natural asphalts from the Rancho La Brea Tar Pits in Los Angeles, CA. Microbiological studies included analyses of 16S rRNA gene sequences and DNA encoding aromatic ring-hydroxylating dioxygenases from two tar pits differing in chemical composition. Our results revealed a wide range of phylogenetic groups within the Archaea and Bacteria domains, in which individual taxonomic clusters were comprised of sets of closely related species within novel genera and families. Fluorescent staining of asphalt-soil particles using phylogenetic probes for Archaea, Bacteria, and Pseudomonas showed coexistence of mixed microbial communities at high cell densities. Genes encoding dioxygenases included three novel clusters of enzymes. The discovery of life in the tar pits provides an avenue for further studies of the evolution of enzymes and catabolic pathways for bacteria that have been exposed to complex hydrocarbons for millennia. These bacteria also should have application for industrial microbiology and bioremediation.     

Strategy and success for the directed evolution of enzymes

Directed evolution is widely used to improve enzymes, particularly for industrial biocatalytic processes. Molecular biology advances present many new strategies for directed evolution. Commonly used techniques have led to many successful examples of enzyme improvement, yet there is still a need to improve both the efficiency and capability of directed evolution. Recent strategies aimed at making directed evolution faster and more efficient take better advantage of available structural and sequence information. The underlying principles that lead to early dead-ends for directed evolution experiments are also discussed along with recent strategies designed to by-pass them. Several emerging methods for creating novel enzymes are also discussed including examples of catalytic activity for which there is no precedent in nature. Finally, the combined use of several strategies is likely to be required in practice to improve multiple target properties of an enzyme, as successfully shown by a recent industrial example.     

DyP-type peroxidases: a promising and versatile class of enzymes

DyP peroxidases comprise a novel superfamily of heme-containing peroxidases, which is unrelated to the superfamilies of plant and animal peroxidases. These enzymes have so far been identified in the genomes of fungi, bacteria, as well as archaea, although their physiological function is still unclear. DyPs are bifunctional enzymes displaying not only oxidative activity but also hydrolytic activity. Moreover, these enzymes are able to oxidize a variety of organic compounds of which some are poorly converted by established peroxidases, including dyes, β-carotene, and aromatic sulfides. Interestingly, accumulating evidence shows that microbial DyP peroxidases play a key role in the degradation of lignin. Owing to their unique properties, these enzymes are potentially interesting for a variety of biocatalytic applications. In this review, we deal with the biochemical and structural features of DyP-type peroxidases as well as their promising biotechnological potential.     

Diversity of aerobic and facultative alkalitolerant and halotolerant endospore formers in soil from the Alvord Basin,Oregon

Many proteins produced by Bacillus species isolated from extreme environments have been utilized for industrial purposes, as these extreme environments often promote evolution of unique protein properties. The Borax Lake area is unusual due to its geothermal activity, elevated pH, and high arsenic and salt concentrations in its soils. Soils from this region are likely to harbor alkalitolerant, halotolerant, endospore-forming strains that may be of potential ecological and/or commercial interest. The objectives of this study were to develop new PCR primers that could target Bacillus or closely related 16S rRNA genes, to characterize the diversity of alkalitolerant, halotolerant, endospore-forming organisms in the soils surrounding Borax Lake, and to identify novel organisms that may ultimately provide new enzymes for applied use. A three-pronged approach was used to identify such bacteria in soil samples. Organisms were isolated using two different techniques. Finally, metagenomic DNA from soil samples was subjected to 16S rRNA gene amplification using the newly designed primers. Assays were performed to characterize the halotolerance and alkalitolerance of isolates.