Joydeep Chakraborty

Degradation of phenanthrene via meta-cleavage of 2-hydroxy-1-naphthoic acid by Ochrobactrum sp. strain PWTJD

The present study describes the assimilation of phenanthrene by an aerobic bacterium, Ochrobactrum sp. strain PWTJD, isolated from municipal waste-contaminated soil sample utilizing phenanthrene as a sole source of carbon and energy. The isolate was identified as Ochrobactrum sp. based on the morphological, nutritional and biochemical characteristics as well as 16S rRNA gene sequence analysis. A combination of chromatographic analyses, oxygen uptake assay and enzymatic studies confirmed the degradation of phenanthrene by the strain PWTJD via 2-hydroxy-1-naphthoic acid, salicylic acid and catechol. The strain PWTJD could also utilize 2-hydroxy-1-naphthoic acid and salicylic acid, while the former was metabolized by a ferric-dependent meta-cleavage dioxygenase. In the lower pathway, salicylic acid was metabolized to catechol and was further degraded by catechol 2,3-dioxygenase to 2-hydroxymuconoaldehyde acid, ultimately leading to tricarboxylic acid cycle intermediates. This is the first report of the complete degradation of a polycyclic aromatic hydrocarbon molecule by Gram-negative Ochrobactrum sp. describing the involvement of the meta-cleavage pathway of 2-hydroxy-1-naphthoic acid in phenanthrene assimilation.

Role of oxygenases in guiding diverse metabolic pathways in the bacterial degradation of low-molecular-weight polycyclic aromatic hydrocarbons: a review.

Widespread environmental pollution by polycyclic aromatic hydrocarbons (PAHs) poses an immense risk to the environment. Bacteria-mediated attenuation has a great potential for the restoration of PAH-contaminated environment in an ecologically accepted manner. Bacterial degradation of PAHs has been extensively studied and mining of biodiversity is ever expanding the biodegradative potentials with intelligent manipulation of catabolic genes and adaptive evolution to generate multiple catabolic pathways. The present review of bacterial degradation of low-molecular-weight (LMW) PAHs describes the current knowledge about the diverse metabolic pathways depicting novel metabolites, enzyme-substrate/metabolite relationships, the role of oxygenases and their distribution in phylogenetically diverse bacterial species.

An insight into the origin and functional evolution of bacterial aromatic ring-hydroxylating oxygenases

Bacterial aromatic ring-hydroxylating oxygenases (RHOs) are multicomponent enzyme systems which have potential utility in bioremediation of aromatic compounds in the environment. To cope with the enormous diversity of aromatic compounds in the environment, this enzyme family has evolved remarkably exhibiting broad substrate specificity. RHOs are multicomponent enzymes comprising of a homo- or hetero-multimeric terminal oxygenase and one or more electron transport (ET) protein(s). The present study attempts in depicting the evolutionary scenarios that might have occurred during the evolution of RHOs, by analyzing a set of available sequences including those obtained from complete genomes. A modified classification scheme identifying four new RHO types has been suggested on the basis of their evolutionary and functional behaviours, in relation to structural configuration of substrates and preferred oxygenation site(s). The present scheme emphasizes on the fact that the phylogenetic affiliation of RHOs is distributed among four distinct ‘Similarity classes’, independent of the constituent ET components. Similar combination of RHO components that was previously considered to be equivalent and classified together [Kweon et al., BMC Biochemistry 9, 11 (2008)] were found here in distinct similarity classes indicating the role of substrate-binding terminal oxygenase in guiding the evolution of RHOs irrespective of the nature of constituent ET components. Finally, a model for evolution of the multicomponent RHO enzyme system has been proposed, beginning from genesis of the terminal oxygenase components followed by recruitment of constituent ET components, finally evolving into various ‘extant’ RHO types.

Functional characterization of diverse ring-hydroxylating oxygenases and induction of complex aromatic catabolic gene clusters in Sphingobium sp. PNB

Sphingobium sp. PNB, like other sphingomonads, has multiple ring‐hydroxylating oxygenase (RHO) genes. Three different fosmid clones have been sequenced to identify the putative genes responsible for the degradation of various aromatics in this bacterial strain. Comparison of the map of the catabolic genes with that of different sphingomonads revealed a similar arrangement of gene clusters that harbors seven sets of RHO terminal components and a sole set of electron transport (ET) proteins. The presence of distinctly conserved amino acid residues in ferredoxin and in silico molecular docking analyses of ferredoxin with the well characterized terminal oxygenase components indicated the structural uniqueness of the ET component in sphingomonads. The predicted substrate specificities, derived from the phylogenetic relationship of each of the RHOs, were examined based on transformation of putative substrates and their structural homologs by the recombinant strains expressing each of the oxygenases and the sole set of available ET proteins. The RHO AhdA1bA2b was functionally characterized for the first time and was found to be capable of transforming ethylbenzene, propylbenzene, cumene, p‐cymene and biphenyl, in addition to a number of polycyclic aromatic hydrocarbons. Overexpression of aromatic catabolic genes in strain PNB, revealed by real‐time PCR analyses, is a way forward to understand the complex regulation of degradative genes in sphingomonads.

Characterization of the metabolic pathway involved in assimilation of acenaphthene in Acinetobacter sp. strain AGAT-W.

Utilization of an enrichment technique led to isolation of a bacterium from municipal waste-contaminated soil in which acenaphthene was used as the sole source of carbon and energy. The isolate was identified as Acinetobacter sp. strain AGAT-W based on morphological, nutritional and biochemical characteristics and 16S rRNA sequence analysis. Characterization of metabolites by HPLC and GC-MS suggested hydroxylation of acenaphthene to 1-acenaphthenol, which was subsequently transformed to catechol via acenaphthenequinone, naphthalene-1,8-dicarboxylic acid, 1-naphthoic acid and salicylic acid before entering into the tricarboxylic acid cycle. Detection of key enzymes, viz., 1-acenaphthenol dehydrogenase, salicylaldehyde dehydrogenase and catechol 1,2-dioxygenase, in the cell-free extract of Acinetobacter sp. further supported the proposed degradation pathway. This study proposes a metabolic pathway involved in acenaphthene assimilation in strain AGAT-W.

Biological Safety Assessment of Mutant Variant of Allium sativum Leaf Agglutinin (mASAL), a Novel Antifungal Protein for Future Transgenic Application

Genetic engineering has established itself to be an important tool for crop improvement. Despite the success, there is always a risk of food allergy induced by alien gene products. The present study assessed the biosafety of mutant Allium sativum leaf agglutinin (mASAL), a potent antifungal protein generated by site directed mutagenesis of Allium sativum leaf agglutinin (ASAL). mASAL was cloned in pET28a+ and expressed in E. coli, and the safety assessment was carried out according to the FAO/WHO guideline (2001). Bioinformatics analysis, pepsin digestion, and thermal stability assay showed the protein to be nonallergenic. Targeted sera screening revealed no significant IgE affinity of mASAL. Furthermore, mASAL sensitized Balb/c mice showed normal histopathology of lung and gut tissue. All results indicated the least possibility of mASAL being an allergen. Thus, mASAL appears to be a promising antifungal candidate protein suitable for agronomical biotechnology.

Ring‐Hydroxylating Oxygenase database: a database of bacterial aromatic ring‐hydroxylating oxygenases in the management of bioremediation and biocatalysis of aromatic compounds

Bacterial Rieske-type aromatic ring-hydroxylating oxygenases (RHOs) constitute a large family of enzymes, primarily involved in bioremediation of diverse aromatic compounds in the environment. In the present study, we have designed a manually curated database, Ring-Hydroxylating Oxygenase database (RHObase), which provides comprehensive information on all biochemically characterized bacterial RHOs. It consists of ∼ 1000 entries including 196 oxygenase α-subunits, 153 oxygenase β-subunits, 92 ferredoxins and 110 reductases, distributed among 131 different bacterial strains implementing a total of 318 oxygenation reactions. For each protein, users can get detailed information about its structure and conserved domain(s) with motif signature. RHObase allows users to search a query, based on organism, oxygenase, substrate, or protein structure. In addition, this resource provides analysis tools to perform blast search against RHObase for prediction of putative substrate(s) for the query oxygenase and its phylogenetic affiliation. Furthermore, there is an integrated cheminformatics tool to search for structurally similar compound(s) in the database vis-a-vis RHO(s) capable of transforming those compound(s). Resources in the RHObase and multiple search/display options therein are intended to provide oxygenase-related requisite information to researchers, especially working in the field of environmental microbiology and biocatalysis to attain difficult chemistry of biotechnological importance.

Homologous promoter derived constitutive and chloroplast targeted expression of synthetic cry1Ac in transgenic chickpea confers resistance against Helicoverpa armigera

The insecticidal crystal protein derived from gram positive soil bacterium Bacillus thuringiensis plays an important role in controlling lepidopteran infestation. The present study seeks to protect chickpea plants from Helicoverpa armigera infestation by over expressing cry1Ac. Homologous Ubiquitin and RuBisCO small subunit (rbcS) promoters were used to transcribe cry1Ac in transgenic chickpea both constitutively and in a tissue specific manner through Agrobacterium mediated transformation of chickpea var. ICCV89314. Expressed Cry1Ac was specifically targeted to the chloroplast rich tissues using transit peptide sequence. After monitoring transgene integration by Southern hybridization, transgenic chickpea lines were further analyzed by western blot, ELISA and insect bioassay. Expression of cry1Ac in chickpea under the control of above two promoters conferred a high level of protection against pod borer infestation, where chloroplast targeting system was found to be more efficient in controlling this particular devastating lepidopteran pest.

From lipid transport to oxygenation of aromatic compounds: evolution within the Bet v1-like superfamily.

Abstract In absence of significant sequence similarity, remote homology between proteins can be confused with analogy and in such a case, shared ancestry can be inferred in light of certain unique and common features. In the present study, to understand the evolutionary origin of catalytic domain of large subunit of ring-hydroxylating oxygenases (RHOs), belonging to the Bet v1-like superfamily, structure-based phylogenies have been derived from structural alignment of representative proteins of the superfamily. A careful inspection of the structural relatedness of RHOs with the rest of the families showed closest similarity between RHO catalytic domain and PA1206-like protein. In addition, phylogenetic relationship of the Rieske domain of the large subunit of RHOs with functionally and structurally similar proteins has also been elucidated so as to postulate the most possible events leading to the genesis of the large subunit of RHOs.

Cloning and characterization of a p-cymene monooxygenase from Pseudomonas chlororaphis subsp. aureofaciens

p-Cymene monooxygenase is the enzyme system that catalyzes the hydroxylation of p-cymene to 4-isopropylbenzyl alcohol (p-cumic alcohol), the initial step in the assimilation of p-cymene by Pseudomonas chlororaphis subsp. aureofaciens. Cloning and sequencing of single NADH-dependent cytochrome c reductase gene (cymA) present in P. chlororaphis subsp. aureofaciens was described earlier. In this study, analysis of the upstream sequence of cymA revealed two open reading frames, designated as cymB (495 bp) and cymM (1128 bp). Database searches with the cymM gene product showed similarity to integral-membrane di-iron enzymes, while that with cymB showed no significant similarity to other known proteins with the exception of epoxystyrene isomerases. Expression of all three components (cymMBA) in Escherichia coli confirmed its ability for p-cymene methyl group hydroxylation, while expression of cymM and cymA along with the partially truncated cymB gene showed an 85% decrease in the hydroxylation capacity. Our results suggest for the first time that the small protein, CymB, having no conserved domains in protein databases, is involved as enhancer/activator in p-cymene hydroxylation.