Comparative analysis of two members of the metal ion-containing group III-alcohol dehydrogenases from Dickeya zeae

An NAD+-dependent group Ⅲ alcohol dehydrogenase involved in long-chain alkane degradation in Acinetobacter venetianus RAG-1

Alcohol dehydrogenases (ADHs) are a class of key enzymes responsible for the oxidation of alkyl alcohols in the aerobic alkane metabolic pathway. Currently, the degradation mechanisms of short- and medium-chain alkanes are commonly reported, while those of long-chain alkanes have received less attention. In this work, a putative long-chain ADH was screened from Acinetobacter venetianus RAG-1 via RNA-seq with n-octacosane (C28) as the sole carbon source. Conserved sequence analysis revealed that it is a group III (Fe-containing/activated) ADH, which is widespread in the genus Acinetobacter. The deletion of adhA led to a significant reduction in the degradation of C28. AdhA exhibited optimal oxidative activity at pH 8.0 and 50 °C with NAD+ as coenzyme, while showing better tolerability to chemical reagents. Enzyme activity assay showed that AdhA owed the oxidative activity to a wide range of substrates including alkyl alcohols (C1-C32) and some isomeric alcohols, such as isopropanol, isobutanol, isoamyl alcohol, and propanetriol, and could reduce the alkyl aldehyde (C1-C12). Meanwhile, the binding of AdhA to different alkyl alcohols was mediated by different amino acids. AdhA is an ADH with an extremely broad substrate utilization range and excellent biochemical characteristics. These results provided important insights in the subsequent investigation of long-chain alkane degradation and petroleum pollution bioremediation.

Industrial light at the end of the Iron-containing (group III) alcohol dehydrogenase tunnel

There are three prominent alcohol dehydrogenases superfamilies: Short-chain, Medium-chain, and Iron-containing alcohol dehydrogenases (FeADHs). Many members are valuable catalysts for producing industrially relevant products such as Active pharmaceutical Intermediates, Chiral synthons, Biopolymers, Biofuels and secondary metabolites. However, FeADHs are the least explored enzymes among the superfamilies for commercial tenacities. They portray a conserved structure having a 'tunnel-like' cofactor and substrate binding site with particular functions, despite representing high sequence diversity. Interestingly, phylogenetic analysis demarcates enzymes catalyzing distinct native substrates where closely related clades convert similar molecules. Further, homologs from various mesophilic and thermophilic microbes have been explored for designing a solvent and temperature resistant enzyme for industrial purposes. The review explores different Iron-containing alcohol dehydrogenases potential engineering of the enzymes and substrates helpful in manufacturing commercial products. This article is protected by copyright. All rights reserved.

Dynamic Preference for NADP/H Cofactor Binding/Release in E. coli YqhD Oxidoreductase

YqhD, an E. coli alcohol/aldehyde oxidoreductase, is an enzyme able to produce valuable bio-renewable fuels and fine chemicals from a broad range of starting materials. Herein, we report the first computational solution-phase structure-dynamics analysis of YqhD, shedding light on the effect of oxidized and reduced NADP/H cofactor binding on the conformational dynamics of the biocatalyst using molecular dynamics (MD) simulations. The cofactor oxidation states mainly influence the interdomain cleft region conformations of the YqhD monomers, involved in intricate cofactor binding and release. The ensemble of NADPH-bound monomers has a narrower average interdomain space resulting in more hydrogen bonds and rigid cofactor binding. NADP-bound YqhD fluctuates between open and closed conformations, while it was observed that NADPH-bound YqhD had slower opening/closing dynamics of the cofactor-binding cleft. In the light of enzyme kinetics and structural data, simulation findings have led us to postulate that the frequently sampled open conformation of the cofactor binding cleft with NADP leads to the more facile release of NADP while increased closed conformation sampling during NADPH binding enhances cofactor binding affinity and the aldehyde reductase activity of the enzyme.

Bacterial non-specific nucleases of the phospholipase D superfamily and their biotechnological potential

Bacterial non-specific nucleases are ubiquitously distributed and involved in numerous intra- and extracellular processes. Although all nucleases share the basic chemistry for the hydrolysis of phosphodiester bonds in nucleic acid molecules, the catalysis comprises diverse modes of action, which offers great potential for versatile biotechnological applications. A major criterium for their differentiation is substrate specificity. Specific endonucleases are widely used as restriction enzymes in molecular biology approaches, whereas the main applications of non-specific nucleases (NSNs) are the removal of nucleic acids from crude extracts in industrial downstream processing and the prevention of cell clumping in microfabricated channels. In nature, the predominant role of NSNs is the acquisition of nutrient sources such as nucleotides and phosphates. The number of extensively characterized NSNs and available structures is limited. Moreover, their applicability is mostly challenged by the presence of metal chelators that impede the hydrolysis of nucleic acids in a metal ion-dependent manner. However, a few metal ion-independent NSNs that tolerate the presence of metal chelators have been characterized in recent years with none being commercially available to date. The classification and biotechnological potential of bacterial NSNs with a special focus on metal ion-independent nucleases are presented and discussed.Key Points • Bacterial phospholipases (PLD-family) exhibit nucleolytic activity. • Bacterial nucleases of the PLD-family are metal ion-independent. • NSNs can be used in downstream processing approaches.

Comparative analysis of two non-specific nucleases of the phospholipase D family from the plant pathogen competitor bacterium Pantoea agglomerans

Bacterial non-specific nucleases of the phospholipase D family are widely distributed among the members of the Enterobacteriaceae. Each genome mainly contains a single copy of a gene encoding a phospholipase D family protein. However, two distantly related isozymes (< 40% identity at the protein level) were identified by BLAST-analyses in the plant pathogenic competitor enterobacterium Pantoea agglomerans. The two nucleases PaNuc-1 and PaNuc-2 were produced in Escherichia coli. Identical gene constructs and expression conditions resulted in the production of PaNuc-1 in soluble form, while PaNuc-2 remained insoluble in inclusion bodies. PaNuc-2 was refolded and both proteins were purified by a combination of affinity and ion exchange chromatography. Proteolytic removal of the HIS-tag allowed the characterization of pure and mature tag-less proteins. Enzymatic properties of both isozymes revealed that they are non-specific nucleases, displaying activities against RNA, single- and double-stranded genomic DNA as well as circular plasmids. However, their biochemical activity profiles were clearly different, with PaNuc-1 being optimally active at 70 °C and pH 7.0, while PaNuc-2 was most active at 45 °C and pH 7.0. The enzymes retained > 90% nuclease activity at EDTA concentrations of 4 mM (PaNuc-2) and 20 mM (PaNuc-1), respectively. Different enzymatic properties suggest that the roles of PaNuc-1 and PaNuc-2 differ in the cell and might be the result of functional diversification after an ancient gene duplication event took place. The fact that both enzymes could be easily produced in recombinant form and their tolerance against metal ion chelators in combination with a broad substrate promiscuity might pave the way to versatile biotechnological applications.

Group III alcohol dehydrogenase from Pectobacterium atrosepticum: insights into enzymatic activity and organization of the metal ion-containing region

NAD(P)(+)-dependent alcohol dehydrogenases (ADH) are widely distributed in all phyla. These proteins can be assigned to three nonhomologous groups of isozymes, with group III being highly diverse with regards to catalytic activity and primary structure. Members of group III ADHs share a conserved stretch of amino acid residues important for cofactor binding and metal ion coordination, while sequence identities for complete proteins are highly diverse (<20 to >90 %). A putative group III ADH PaYqhD has been identified in BLAST analysis from the plant pathogenic enterobacterium Pectobacterium atrosepticum. The PaYqhD gene was expressed in the heterologous host Escherichia coli, and the recombinant protein was purified in a two-step purification procedure to homogeneity indicating an obligate dimerization of monomers. Four conserved amino acid residues involved in metal ion coordination were substituted with alanine, and their importance for catalytic activity was confirmed by circular dichroism spectrum determination, in vitro, and growth experiments. PaYqhD exhibits optimal activity at 40 °C with short carbon chain aldehyde compounds and NADPH as cofactor indicating the enzyme to be an aldehyde reductase. No oxidative activities towards alcoholic compounds were detectable. EDTA completely inhibited catalytic activity and was fully restored by the addition of Co(2+). Activity measurements together with sequence alignments and structure analysis confirmed that PaYqhD belongs to the butanol dehydrogenase-like enzymes within group III of ADHs.