nan Sanchita

Docking and molecular dynamics studies of peptide inhibitors of ornithine decarboxylase: a rate-limiting enzyme for the metabolism of Fusarium solani

Fusarium solani causes a wide variety of diseases in plants. Polyamine biosynthesis is responsible for the growth and pathogenicity of the fungus. The initial step of this pathway involves the decarboxylation of ornithine to putrescine, and is catalyzed by the enzyme ornithine decarboxylase (ODC). Inhibiting this process may be a promising approach for the management of fungal disease in various crops. Therefore, there is a need to develop inhibitors of ODC that have higher binding capacity than ornithine. Fifteen peptides were designed and modeled based on physicochemical properties of residues in the active site of ODC. The peptide GLIWGNGPF showed the highest dock score. It is assumed that the de novo design of peptides could be a potential approach to inhibit polyamine biosynthesis. Molecular dynamics studies make an important contribution to understanding the effect of the binding of peptides and the stability of an ODC-peptide complex system. An animated Interactive 3D Complement (I3DC) is available in Proteopedia at http://proteopedia.org/w/Journal:JBSD:8.

Physiological performance, secondary metabolite and expression profiling of genes associated with drought tolerance in Withania somnifera.

Physiological, biochemical, and gene expression responses under drought stress were studied in Withania somnifera. Photosynthesis rate, stomatal conductance, transpiration rate, relative water content, chlorophyll content, and quantum yield of photosystems I and II (PSI and PSII) decreased in response to drought stress. Comparative expression of genes involved in osmoregulation, detoxification, signal transduction, metabolism, and transcription factor was analyzed through quantitative RT–PCR. The genes encoding 1-pyrroline-5-carboxylate synthetase (P5CS), glutathione S-transferase (GST), superoxide dismutase (SOD), serine threonine-protein kinase (STK), serine threonine protein phosphatase (PSP), aldehyde dehydrogenase (AD), leucoanthocyanidin dioxygenase/anthocyanin synthase (LD/AS), HSP, MYB, and WRKY have shown upregulation in response to drought stress condition in leaf tissues. Enhanced detoxification and osmoregulation along with increased withanolides production were also observed under drought stress. The results of this study will be helpful in developing stress-tolerant and high secondary metabolite yielding genotypes.

Analysis of differentially expressed genes in abiotic stress response and their role in signal transduction pathways

The study of abiotic stress response of plants is important because they have to cope with environmental changes to survive. The plant genomes have evolved to meet environmental challenges. Salt, temperature, and drought are the main abiotic stresses. The tolerance and response to stress vary differently in plants. The idea was to analyze the genes showing differential expression under abiotic stresses. There are many pathways connecting the perception of external stimuli to cellular responses. In plants, these pathways play an important role in the transduction of abiotic stresses. In the present study, the gene expression data have been analyzed for their involvement in different steps of signaling pathways. The conserved genes were analyzed for their role in each pathway. The functional annotations of these genes and their response under abiotic stresses in other plant species were also studied. The enzymes of signal pathways, showing similarity with conserved genes, were analyzed for their role in different abiotic stresses. Our findings will help to understand the expression of genes in response to various abiotic stresses. These genes may be used to study the response of different abiotic stresses in other plant species and the molecular basis of stress tolerance.

Antibiotics potentiating potential of catharanthine against superbug Pseudomonas aeruginosa

Multidrug resistance (MDR) put an alarming situation like preantibiotic era which compels us to invigorate the basic science of anti-infective chemotherapy. Hence, the drug resistant genes/proteins were explored as promising drug targets. Keeping this thing in mind, proteome of Pseudomonas aeruginosa PA01 was explored, which resulted in the identification of tripartite protein complexes (MexA, MexB, and OprM) as promising drug target for the screening of natural and synthetic inhibitors. The purpose of present investigation was to explore the drug resistance reversal potential mechanism of catharanthine isolated from the leaves of Catharanthus roseous. Hence, the test compound catharanthine was in silico screened using docking studies against the above receptors, which showed significant binding affinity with these receptors. In order to validate the in silico findings, in vitro evaluation of the test compound was also carried out. In combination, catharanthine reduced the minimum inhibitory concentration MIC of tetracycline (TET) and streptomycin up to 16 and 8 folds, respectively. Further, in time kill assay, catharanthine in combination with TET reduced the cell viability in concentration dependent manner and was also able to reduce the mutation prevention concentration of TET. It was also deduced that drug resistance reversal potential of catharanthine was due to inhibition of the efflux pumps.

The Interaction Pattern between a Homology Model of 40S Ribosomal S9 Protein of Rhizoctonia solani and 1-Hydroxyphenaize by Docking Study

1-Hydroxyphenazine (1-OH-PHZ), a natural product from Pseudomonas aeruginosa strain SD12, was earlier reported to have potent antifungal activity against Rhizoctonia solani. In the present work, the antifungal activity of 1-OH-PHZ on 40S ribosomal S9 protein was validated by molecular docking approach. 1-OH-PHZ showed interaction with two polar contacts with residues, Arg69 and Phe19, which inhibits the synthesis of fungal protein. Our study reveals that 1-OH-PHZ can be a potent inhibitor of 40S ribosomal S9 protein of R. solani that may be a promising approach for the management of fungal diseases.

Computational gene expression profiling under salt stress reveals patterns of co-expression

Plants respond differently to environmental conditions. Among various abiotic stresses, salt stress is a condition where excess salt in soil causes inhibition of plant growth. To understand the response of plants to the stress conditions, identification of the responsible genes is required. Clustering is a data mining technique used to group the genes with similar expression. The genes of a cluster show similar expression and function. We applied clustering algorithms on gene expression data of Solanum tuberosum showing differential expression in Capsicum annuum under salt stress. The clusters, which were common in multiple algorithms were taken further for analysis. Principal component analysis (PCA) further validated the findings of other cluster algorithms by visualizing their clusters in three-dimensional space. Functional annotation results revealed that most of the genes were involved in stress related responses. Our findings suggest that these algorithms may be helpful in the prediction of the function of co-expressed genes.

Nano Particles: Emerging Warheads Against Bacterial Superbugs.

Infectious diseases are one of the major causes of morbidity and mortality in children in developing and underdeveloped countries. Limited knowledge of targets (cell wall synthesis, replication, transcription, protein synthesis) for antibiotics and lack of novel antibiotics have lead to an emergence of different level of resistance in bacterial pathogens. Multidrug resistance is the phenomenon by which the bacteria exerts resistance against the two or more structurally unrelated drugs/antibiotics. A common goal in the post-genomic era is to identify novel targets/drugs for various life threatening bacterial pathogens. Nanoparticles are broadly defined as submicron colloidal particles of size less than 1μm. Nanoparticles of size less than 100nm are the most promising warheads to overcome microbial drug resistance because they can act as antibacterial/antibiotic modulating agents at the site of infection and may have more than one mode of action. These nanoparticles will be of immense help in transporting drugs directly at the infected sites. Thus prevent drug resistance development to a great extent. In this review, the key mechanisms of resistance in bacterial superbugs have been discussed as well as how nanoparticles can overcome them. It is hypothesized that the nanoparticles can overcome the drug resistance via a novel mechanism of action. Additionaly, nanopaticles may also work synergistically with antibiotics via increased uptake, decreased efflux and inhibition of biofilm formation. The degradation by metallo beta lactamases and synthesis of porins may also be facilitated through these nanoparticles.

Comparative Study of Withanolide Biosynthesis-Related miRNAs in Root and Leaf Tissues of Withania somnifera

Withania somnifera, popularly known as Indian ginseng, is one of the most important medicinal plants. The plant is well studied in terms of its pharmaceutical activities and genes involved in biosynthetic pathways. However, not much is known about the regulatory mechanism of genes responsible for the production of secondary metabolites. The idea was to identify miRNA transcriptome responsible for the regulation of withanolide biosynthesis, specifically of root and leaf tissues individually. The transcriptome data of in vitro culture of root and leaf tissues of the plant was considered for miRNA identification. A total of 24 and 39 miRNA families were identified in root and leaf tissues, respectively. Out of these, 15 and 27 miRNA families have shown their involvement in different biological functions in root and leaf tissues, respectively. We report here, specific miRNAs and their corresponding target genes for corresponding root and leaf tissues. The target genes have also been analyzed for their role in withanolide metabolism. Endogenous root-miR5140, root-miR159, leaf-miR477, and leaf-miR530 were reported for regulation of withanolide biosynthesis.

Modulations in primary and secondary metabolic pathways and adjustment in physiological behaviour of Withania somnifera under drought stress

In general medicinal plants grown under water limiting conditions show much higher concentrations of secondary metabolites in comparison to control plants. In the present study, Withania somnifera plants were subjected to water stress and data related to drought tolerance phenomenon was collected and a putative mechanistic concept considering growth responses, physiological behaviour, and metabolite content and gene expression aspects is presented. Drought induced metabolic and physiological responses as well as drastic decrease in CO2 uptake due to stomatal limitations. As a result, the consumption of reduction equivalents (NADPH2+) for CO2 assimilation via the calvin cycle declines significantly resulting in the generation of a large oxidative stress and an oversupply of antioxidant enzymes. Drought also results in the shifting of metabolic processes towards biosynthetic activities that consume reduction equivalents. Thus, biosynthesis of reduced compounds (isoprenoids, phenols and alkaloids) is enhanced. The dynamics of various metabolites have been discussed in the light of gene expression analysis of control and drought treated leaves. Gene encoding enzymes of pathways leading to glucose, fructose and fructan production, conversion of triose phosphates to hexoses and hexose phosphorylation were up-regulated in the drought stressed leaves. The down-regulated Calvin cycle genes were co-ordinately regulated with the down-regulation of chloroplast triosephosphate/phosphate translocator, cytoplasmic fructose-1,6-bisphosphate aldolase and fructose bisphosphatase. Expression of gene encoding Squalene Synthase (SQS) was highly upregulated under drought stress which is responsible for the diversion of carbon flux towards withanolides biosynthesis from isoprenoid pathway.

Gene Expression Analysis in Medicinal Plants Under Abiotic Stress Conditions

Abstract This article aims to discuss the importance of gene expression analysis research in medicinally important plants. Gene expression analysis is a method of investigating the changes in the transcriptomic or genomic behavior of an organism. The expression of genes changes due to various factors. These factors are categorized as biotic and abiotic stresses. Abiotic stresses are the adverse environmental effects responsible for the variation in the level of gene transcripts in organisms, mainly plants. There are variations in salt balance, fluctuations in external environmental temperature such as heat and cold, lack of water corresponding to drought, etc. Tolerance to these abiotic stresses is a very complex phenomenon since more than one stress simultaneously affects a plant. Most of the stresses show similar responses to plants at biochemical, physiological, and morphological levels. Medicinal plants have a large group of secondary metabolites based on their chemical composition. The secondary metabolites are very useful to human beings due to their pharmaceutical value. The increase in the level of these metabolites is caused by changes in the expression levels of the corresponding genes. In case of medicinal plants, the knowledge of gene expression analysis may lead to the development of stress tolerance with the enhanced production of secondary metabolites. Gene expression studies may help us to develop genetically improved medicinal plants with increased yield and quality.