Dr Pritam Chattopadhyay
@mucwcburdwan.org
Assistant Professor
MUC Women's College
RESEARCH, TEACHING, or OTHER INTERESTS
Biotechnology, Biochemistry, Genetics and Molecular Biology, Applied Microbiology and Biotechnology, Chemical Engineering
Scopus Publications
Scholar Citations
Scholar h-index
Scholar i10-index
Scopus Publications
Agradip Bhattacharyya, Goutam Banerjee, and Pritam Chattopadhyay
MDPI AG
Background: Aeromonas hydrophila is a widely recognized broad-spectrum pathogen that primarily targets the gastrointestinal tract. Type IV pili (T4P) are proteinaceous nano-machines located on the bacterial cell surface, playing a crucial role in host colonization and infection. Regrettably, the T4P systems of A. hydrophila remain largely underexplored. Methods: A. hydrophila genomes with complete genome assembly and annotation reports up to 31 March 2023, were obtained from the NCBI Genome database or KEGG genome database, followed by a global search for T4P secretion system genes. Protein sequences of these manually curetted genes were used as secondary quarry for Synteny analysis. Protein–protein interaction analysis was performed by string analysis and in silico study of genomic islands. Results: We identified 27 orthologs of type IV pili (T4P) nano-machine components in A. hydrophila. These orthologs are primarily distributed across three operons: pilABCD, pilMNOPQ, and pilVWXY. While the first two operons are commonly found in all experimental genomes, the presence of the pilVWXY operon, coding for 11 orthologs, is reported here for the first time in A. hydrophila. Notably, the complete pilVWXY operon is absent in nonvirulent strains. A genomic islands study between a nonvirulent and hypervirulent strain also confirms absence of most of the genes coded by pilVWXY in nonvirulent strain. Interestingly, among the 51 experimental genomes analyzed, the pilVWXY operon was completely absent in 10 strains, most of which are categorized as nonvirulent; Conclusions: The distribution of two major type IV pili (T4P) nano-machines, PilABCDMNOPQ and PilVWXY, is reported here for the first time in A. hydrophila. Additionally, this study suggests a potential role for the PilVWXY nano-machine in establishing human disease.
Pritam Chattopadhyay, Goutam Banerjee, and Pratap J. Handique
Springer Science and Business Media LLC
Goutam Banerjee, Fu-Shi Quan, Amit Mondal, Shantanu Sur, Pratik Banerjee, and Pritam Chattopadhyay
MDPI AG
Ralstonia solanacearum (Rs), the causative agent of devastating wilt disease in several major and minor economic crops, is considered one of the most destructive bacterial plant pathogens. However, the mechanism(s) by which Rs counteracts host-associated environmental stress is still not clearly elucidated. To investigate possible stress management mechanisms, orthologs of stress-responsive genes in the Rs genome were searched using a reference set of known genes. The genome BLAST approach was used to find the distributions of these orthologs within different Rs strains. BLAST results were first confirmed from the KEGG Genome database and then reconfirmed at the protein level from the UniProt database. The distribution pattern of these stress-responsive factors was explored through multivariate analysis and STRING analysis. STRING analysis of stress-responsive genes in connection with different secretion systems of Rs was also performed. Initially, a total of 28 stress-responsive genes of Rs were confirmed in this study. STRING analysis revealed an additional 7 stress-responsive factors of Rs, leading to the discovery of a total of 35 stress-responsive genes. The segregation pattern of these 35 genes across 110 Rs genomes was found to be almost homogeneous. Increasing interactions of Rs stress factors were observed in six distinct clusters, suggesting six different types of stress responses: membrane stress response (MSR), osmotic stress response (OSR), oxidative stress response (OxSR), nitrosative stress response (NxSR), and DNA damage stress response (DdSR). Moreover, a strong network of these stress responses was observed with type 3 secretion system (T3SS), general secretory proteins (GSPs), and different types of pili (T4P, Tad, and Tat). To the best of our knowledge, this is the first report on overall stress response management by Rs and the potential connection with secretion systems.
Pritam Chattopadhyay and Goutam Banerjee
Wiley
Goutam Banerjee, Swarnendu Basak, Tathagato Roy, and Pritam Chattopadhyay
Oxford University Press (OUP)
ABSTRACT Bradyrhizobium is a biologically important bacterial genus. Different Bradyrhizobium strains exhibit distinct niche selection like free living, root nodular and stem nodular. The present in-silico study was undertaken to identify the role of bacterial secretome in the phylogenetic niche conservation (PNC) of Bradyrhizobium sp. Analysis was carried out with the publicly available 19 complete genome assembly and annotation reports. A protocol was developed to screen the secretome related genes using three different database, viz. genome, proteome and gene ortholog. This resulted into 139 orthologs that include type secretion systems (T1SS-T6SS) along with flagella (Flg), type IV pili (T4P) and tight adherence (Tad) systems. Multivariate analysis using bacterial secretome was undertaken to find out the role of these secretion systems in PNC. In free living strains, T3SS, T4SS and T6SS were completely absent. Whereas, in the stem nodulating strains, T3SS and T6SS were absent, but T4SS was found to be present. On the other hand, the T3SS was found to be present only in the root-nodulating strains. The present investigation clearly demonstrated a pattern of PNC based on the distribution of secretion system components. To the best of our knowledge, this is the first report on PNC of Bradyrhizobium using the multivariate analysis of secretome.
Goutam Banerjee and Pritam Chattopadhyay
Wiley
AbstractThe biotechnological production of fragrances is a recent trend that has expanded rapidly in the last two decades. Vanillin is the second most popular flavoring agent after saffron and is extensively used in various applications, e.g., as a food additive in food and beverages and as a masking agent in various pharmaceutical formulations. It is also considered a valuable product for other applications, such as metal plating and the production of other flavoring agents, herbicides, ripening agents, antifoaming agents, and personal and home‐use products (such as in deodorants, air fresheners, and floor‐polishing agents). In general, three types of vanillin, namely natural, biotechnological, and chemical/synthetic, are available on the market. However, only natural and nature‐identical (biotechnologically produced from ferulic acid only) vanillins are considered as food‐grade additives by most food‐safety control authorities worldwide. In the present review, we summarize recent trends in fermentation technology for vanillin production and discuss the importance of the choice of raw materials for the economically viable production of vanillin. We also describe the key enzymes used in the biotechnological production of vanillin as well as their underlying genes. Research to advance our understanding of the molecular regulation of different pathways involved in vanillin production from ferulic acid is still ongoing. The enhanced knowledge is expected to offer new opportunities for the application of metabolic engineering to optimize the production of nature‐identical vanillin. © 2018 Society of Chemical Industry
Pritam Chattopadhyay and Goutam Banerjee
Bentham Science Publishers Ltd.
Background: Several strains of Klebsiella pneumoniae are responsible for causing pneumonia in lung and thereby causing death in immune-suppressed patients. In recent year, few investigations have reported the enhancement of K. pneumoniae population in patients using corticosteroid containing inhaler. Objectives: The biological mechanism(s) behind this increased incidence has not been elucidated. Therefore, the objective of this investigating was to explore the relation between Klebsiella pneumoniae and increment in carbapenamase producing Enterobacteriaceae score (ICS). Methods: The available genomes of K. pneumoniae and the amino acid sequences of steroid catabolism pathway enzymes were taken from NCBI database and KEGG pathway tagged with UniPort database, respectively. We have used different BLAST algorithms (tBLASTn, BLASTp, psiBLAST, and delBLAST) to identify enzymes (by their amino acid sequence) involved in steroid catabolism. Results: A total of 13 enzymes (taken from different bacterial candidates) responsible for corticosteroid degradation have been identified in the genome of K. pneumoniae. Finally, 8 enzymes (K. pneumoniae specific) were detected in four clinical strains of K. pneumoniae. This investigation intimates that this ability to catabolize corticosteroids could potentially be one mechanism behind the increased pneumonia incidence. Conclusion: The presence of corticosteroid catabolism enzymes in K. pneumoniae enhances the ability to utilize corticosteroid for their own nutrition source. This is the first report to demonstrate the corticosteroid degradation pathway in clinical strains of K. pneumoniae.
Dibya J. Saikia, Pritam Chattopadhyay, Goutam Banerjee, Bandita Talukdar, and Dandadhar Sarma
Wiley
AbstractTail and fin rot disease (TFRD) is a big issue in the production of spotted snakehead, Channa punctata Bloch. The aims of the present study were to isolate and identify the bacterial pathogen causing TFRD, to detect histopathological changes in tissues (fin, tail, liver, and kidney), and to ascertain the antibiotic sensitivity pattern of the isolate. Out of six bacterial isolates, only the isolate DJ1990 was found to be the causal candidate of TFRD in C. punctata. Identical histopathological changes were detected in tail, fin, liver, and kidney under light and scanning electron microscope in both collected diseased fish and artificially infected fish. The isolate was identified as Pseudomonas aeruginosa strain DJ1990 (National Center for Biotechnology Information Ace. No. KX709967) based on the biochemical characterization tests and 16S rDNA sequence‐based phylogeny analysis. Artificial challenge test demonstrated that the strain DJ1990 was highly virulent (100% mortality at 48 h of postinjection period at the concentration of 1.5 × 107 CFU/g of body weight) for C. punctata. The isolate exhibited sensitivity to the broad‐spectrum antibiotics but was resistant against aztreonum. To the best of our knowledge, this is the first report of P. aeruginosa as a TFRD‐causing candidate in C. punctata.
Pritam Chattopadhyay, Goutam Banerjee, and Sukanta K. Sen
Elsevier BV
Pritam Chattopadhyay and Goutam Banerjee
Springer Science and Business Media LLC
GOUTAM BANERJEE, SRIKANTH GORTHI, and PRITAM CHATTOPADHYAY
FapUNIFESP (SciELO)
Disease in agricultural field is a big problem that causes a massive loss in production. In this present investigation, we have reported a soil-borne bacterium Bacillus cereus IB311 which is antagonistic to plant pathogens (Pseudomonas syringae and Agrobacterium tumefaciens), and could make a substantial contribution to the prevention of plant diseases. To prove the practical application, the strain was directly applied in agricultural field. The results demonstrated that B. cereus IB311 has increased the production (20% and 26% in term of average pod number per plant, average seed number per pod, and seed yield per experimental plot) in ground nut (Arachis hypogaea var. Koushal, G201) and sesame (Sesamum indicum var. Kanak), respectively. To reduce the production cost, the biomass production was optimized through response surface methodology (RSM). Interactions of three variables (glucose, beef extract and inoculum) were studied using Central Composite Design. According to our analysis, optimum production of Bacillus cereus IB311 (5.383 µg/ mL) may be obtained at glucose 1.985%, beef extract 1.615% and inoculums size 0.757%. Therefore, we strongly believe that the application of this strain in agricultural field as bio-controlling agent will definitely enhance the production yield and will reduce the disease risk.
Pritam Chattopadhyay, Goutam Banerjee, and Nirmalya Banerjee
Mary Ann Liebert Inc
Increasing the resolution of population studies in plant biology is one of the leading frontiers for omics sciences. One of the most pervasive challenges in molecular phylogenetics is the incongruence between phylogenies obtained using different data sets such as individual genes [like ribulose bisphosphate carboxylase large chain (rbcL) and maturase K (matK)] and intergenic spacers (IGS) [like nuclear ribosomal internal transcribed spacer 1 (nrITS 1) and 2 (nrITS 2), and chloroplast IGS between transfer RNA for leucine and phenylalanine (cp trnL-trnF IGS)]. To solve this challenge, we have screened the four well-established candidate gene sequences (i.e., rbcL, matK, trnL-trnF IGS, and 18S-ITS1-5.8S-ITS2-28S nrDNA) of 65 Indian orchid species. We also have included 31 different species of Dendrobium to identify the suitable locus for resolving the phylogeny-related problem below the taxonomic rank of genus. The Consortium for the Barcode of Life has recommended the locus rbcL and matK for barcoding of all land plants, including orchids. However, in this study, matK and rbcL (species resolving capacity 52% and 48%, respectively) were found to work above the taxonomic limit of genus, and thus cannot be considered a suitable tool to resolve closely related species of Dendrobium, whereas, we found that the locus 18S-ITS1-5.8S-ITS2-28S nrDNA is the best choice with the highest species resolving ability (95.23%) and the highest mean Kimura 2-parameter distance (254 for intergeneric and 144 for intrageneric) for phylogeny construction, and thus have been taken as the most promising single-locus barcode for orchids.
Pritam Chattopadhyay, Goutam Banerjee, and Sayantan Mukherjee
Springer Science and Business Media LLC
Manalee Kulkarni, Srikanth Gorthi, Goutam Banerjee, and Pritam Chattopadhyay
Elsevier BV
S. Datta, S. Mitra, P. Chattopadhyay, T. Som, S. Mukherjee, and S. Basu
Springer Science and Business Media LLC
Dibya Jyoti Saikia, Pritam Chattopadhyay, Goutam Banerjee, and Dandadhar Sarma
Central Fisheries Research Institute (SUMAE)
Ramansu Goswami, Pritam Chattopadhyay, Arunima Shome, Sambhu Nath Banerjee, Amit Kumar Chakraborty, Anil K. Mathew, and Shibani Chaudhury
Springer Science and Business Media LLC
Sinha Shelly, Chattopadhyay Pritam, Pan Ieshita, S, Chatterjee ipan, Ch Pompee, a, B Debashis, yopadhyay, Das Kamala,et al.
Academic Journals
The accumulation of recalcitrant xenobiotic compounds is due to continuous efflux from population and industrial inputs that have created a serious impact on the pristine nature of our environment. Apart from this, these compounds are mostly carcinogenic, posing health hazards which persist over a long period of time. Metabolic pathways and specific operon systems have been found in diverse but limited groups of microbes that are responsible for the transformation of xenobiotic compounds. Distinct catabolic genes are either present on mobile genetic elements, such as transposons and plasmids, or the chromosome itself that facilitates horizontal gene transfer and enhances the rapid microbial transformation of toxic xenobiotic compounds. Biotransformation of xenobiotic compounds in natural environment has been studied to understand the microbial ecology, physiology and evolution for their potential in bioremediation. Recent advance in the molecular techniques including DNA fingerprinting, microarrays and metagenomics is being used to augment the transformation of xenobiotic compounds. The present day understandings of aerobic, anaerobic and reductive biotransformation by co-metabolic processes and an overview of latest developments in monitoring the catabolic genes of xenobiotic-degrading bacteria are discussed elaborately in this work. Till date, several reviews have come up, highlighting the problem of xenobiotic pollution, yet a comprehensive understanding of the microbial biodegradation of xenobiotics and its application is in nascent stage. Therefore, this is an attempt to understand the microbial role in biotransformation of xenobiotic compounds in context to the modern day biotechnology.
Tanmay Majumdar, Pritam Chattopadhyay, Dhira Rani Saha, Subrato Sau, and Shibnath Mazumder
Elsevier BV
R. Bhima Rao, P. Chattopadhyay, and G. N. Banerjee
Hindawi Limited
The natural resources of refractory raw materials are declining and at the same time the
consumption rate is increasing, particularly in iron and steel industries. Any attempt to
identify a new raw material source from the waste dumps could solve the national economy
as well as environmental problems. In view of this, fly ash from thermal power plant has
been identified for use in the ceramic/refractory industries after suitable beneficiation. For
this wet high intensity magnetic separation studies carried out on typical fly ash sample
indicate that the non-magnetic fraction (product) containing 24% Al2O3, 67% SiO2, 1.7%
Fe2O3could be achieved with 63% recovery. This product is acceptable as a ceramic and
refractory raw material after the necessary blending.