Novel PLGA-encapsulated-nanopiperine promotes synergistic interaction of p53/PARP-1/Hsp90 axis to combat ALX-induced-hyperglycemia.

The present study predicts the molecular targets and druglike properties of the phyto-compound piperine (PIP) by in silico studies including molecular docking simulation, druglikeness prediction and ADME analysis for prospective therapeutic benefits against diabetic complications. PIP was encapsulated in biodegradable polymer poly-lactide-co-glycolide (PLGA) to form nanopiperine (NPIP) and their physico-chemical properties were characterized by AFM and DLS. ∼ 30 nm sized NPIP showed 86.68% encapsulation efficiency and - 6 mV zeta potential, demonstrated great interactive stability and binding with CT-DNA displaying upsurge in molar ellipticity during CD spectroscopy. NPIP lowered glucose levels in peripheral circulation by > 65 mg/dL compared to disease model and improved glucose influx in alloxan-induced in vivo and in vitro diabetes models concerted with 3-folds decrease in ROS production, ROS-induced DNA damage and 27.24% decrease in nuclear condensation. The 25% increase in % cell viability and inhibition in chromosome aberration justified the initiation of p53 and PARP DNA repairing protein expression and maintenance of Hsp90. Thus, the experimental study corroborated well with in silico predictions of modulating the p53/PARP-1/Hsp90 axis, with predicted dock score value of - 8.72, - 8.57, - 8.76 kcal/mol respectively, validated docking-based preventive approaches for unravelling the intricacies of molecular signalling and nano-drug efficacy as therapeutics for diabetics.

Enhanced Drug Carriage Efficiency of Curcumin-Loaded PLGA Nanoparticles in Combating Diabetic Nephropathy via Mitigation of Renal Apoptosis.

Objectives: The Curcuma-derived diferuloylmethane compound CUR, loaded on Poly (lactide-co-glycolic) acid (PLGA) nanoparticles was utilized to combat DN-induced renal apoptosis by selectively targeting and modulating Bcl2. Methods: Upon in silico molecular docking and screening study CUR was selected as the core phytocompound for nanoparticle formulation. PLGA-nano-encapsulated-curcumin (NCUR) were synthesized following standard solvent displacement method. The NCUR were characterized for shape, size and other physico-chemical properties by Atomic Force Microscopy (AFM), Dynamic Light Scattering (DLS) and Fourier-Transform Infrared (FTIR) Spectroscopy studies. For in vivo validation of nephro-protective effects, Mus musculus were pre-treated with CUR at a dose of 50 mg/kg b.w. and NCUR at a dose of 25 mg/kg b.w. (dose 1), 12.5 mg/kg b.w (dose 2) followed by alloxan administration (100 mg/kg b.w) and serum glucose levels, histopathology and immunofluorescence study were conducted. Results: The in silico study revealed a strong affinity of CUR towards Bcl2 (dock score -10.94 Kcal/mol). The synthesized NCUR were of even shape, devoid of cracks and holes with mean size of ~80 nm having -7.53 mV zeta potential. Dose 1 efficiently improved serum glucose levels, tissue-specific expression of Bcl2 and reduced glomerular space and glomerular sclerosis in comparison to hyperglycaemic group. Conclusion: This study essentially validates the potential of NCUR to inhibit DN by reducing blood glucose level and mitigating glomerular apoptosis by selectively promoting Bcl2 protein expression in kidney tissue.

Morroniside interaction with poly (ADP-ribose) polymerase accentuates metabolic mitigation of alloxan-induced genotoxicity and hyperglycaemia: a molecular docking based in vitro and in vivo experimental therapeutic insight.

The present study tends to evaluate the possible potential of bio-active Morroniside (MOR), against alloxan (ALX)-induced genotoxicity and hyperglycaemia. In silico prediction revealed the interaction of MOR with Poly (ADP-ribose) polymerase (PARP) protein which corroborated well with experimental in vitro L6 cell line and in vivo mice models. Data revealed the efficacy of MOR in the selective activation of PARP protein and modulating other stress proteins NF-κB, and TNF-α to initiate protective potential against ALX-induced genotoxicity and hyperglycaemia. Further, the strong interaction of MOR with CT-DNA (calf thymus DNA) analyzed through CD spectroscopy, UV-Vis study and ITC data revealed the concerted action of bio-factors involved in inhibiting chromosomal aberration and micronucleus formation associated with DNA damage. Finally, MOR does not play any role in microbial growth inhibition which often occurs due to hyperglycemic dysbiosis. Thus, from the overall findings, we may conclude that MOR could be a potential drug candidate for the therapeutic management of induced-hyperglycaemia and genotoxicity.Communicated by Ramaswamy H. Sarma.

Poly lactide-co-glycolide encapsulated nano-curcumin promoting antagonistic interactions between HSP 90 and XRCC1 proteins to prevent cypermethrin-induced toxicity: An in silico predicted in vitro and in vivo approach.

The present study describes the preparation and characterization of poly-lactide-co-glycolide encapsulated nano-curcumin (NCUR) drug, and its potential efficacy against the pesticide, such as cypermethrin-induced DNA damage and genotoxicity. Cypermethrin, the chosen pesticide, contaminates the aquatic environment after being washed off from the agricultural field to nearby water bodies leading to biomagnification-related perturbation of the ecological balance and overall environmental health by elevating adverse effects on non-target organisms producing toxic metabolites through biotransformation. The physico-chemical properties of NCUR were evaluated by employing the AFM, DLS and UV-Vis techniques. Sustainable release of NCUR, their bio-availability and ability to cross the blood-brain-barrier was assessed in the fish model. The in silico molecular docking study to identify the signalling proteins that interact with phyto-core-compound curcumin (CUR) was undertaken to predict the effectiveness of NCUR to combat pesticide-induced toxicity by modulating p53, PARP, HSP 90 and XRCC1 stress proteins, and other associated parameters in in vivo model using tilapia fish and in vitro model using L6 (mammalian skeletal muscle) cell line. Overall results revealed that negatively charged poly-lactide-co-glycolide (PLGA)-encapsulated NCUR (∼46 nm) showed hyperchromic binding with DNA and modulated the signalling cascades involved in stress and DNA repair mechanisms, corroborating well with the in silico prediction that would pave a new pathway in the arena of chemical and biological sciences to serve mankind.

Exploring the Targets of Novel Corona Virus and Docking-based Screening of Potential Natural Inhibitors to Combat COVID-19.

There is a need to explore natural compounds against COVID-19 due to their multitargeted actions against various targets of nCoV. They act on multiple sites rather than single targets against several diseases. Thus, there is a possibility that natural resources can be repurposed to combat COVID-19. However, the biochemical mechanisms of these inhibitors were not known. To reveal the mode of anti-nCoV action, structure-based docking plays a major role. The present study is an attempt to explore various potential targets of SARS-CoV-2 and the structure-based screening of various potential natural inhibitors to combat the novel coronavirus.

Selected Phytochemicals to Combat Lungs Injury: Natural Care.

The human has two lungs responsible for respiration and drug metabolism. Severe lung infection caused by bacteria, mycobacteria, viruses, fungi, and parasites may lead to lungs injury. Smoking and tobacco consumption may also produce lungs injury. Inflammatory and pain mediators are secreted by alveolar macrophages. The inflammatory mediators, such as cytokines, interleukin (IL)-1, IL-6, IL-8, IL-10, and tumor necrosis factor (TNF)-α, neutrophils, and fibroblasts are accumulated in the alveoli sac, which becomes infected. It may lead to hypoxia followed by severe pulmonary congestion and the death of the patient. There is an urgent need for the treatment of artificial respiration and ventilation. However, the situation may be the worst for patients suffering from lung cancer, pulmonary tuberculosis, and acute pneumonia caused by acute respiratory distress syndrome (ARDS). Re-urgency has been happening in the case of coronavirus disease of 2019 (COVID-19) patients. Therefore, it is needed to protect the lungs with the intake of natural phytomedicines. In the present review, several selected phyto components having the potential role in lung injury therapy have been discussed. Regular intake of natural vegetables and fruits bearing these constituents may save the lungs even in the dangerous attack of SARS-CoV-2 in lung cancer, pulmonary TB, and pneumatic patients.

Naturally Sourced CDK Inhibitors and Current Trends in Structure-Based Synthetic Anticancer Drug Design by Crystallography.

Cyclin-Dependent Kinases (CDKs) are the chief regulators in cell proliferation; the kinase activities are largely regulated by their interactions with CDK Inhibitors (CKIs) and Cyclins. The association of different CDKs with CDKIs and Cyclins at the cell-cycle checkpoints of different stages of mitotic cell cycle function act more likely as the molecular switches that regulate different transcriptional events required for progression through the cell cycle. A fine balance in response to extracellular and intracellular signals is highly maintained in the orchestrated function of CDKs along with Cyclins and CDKIs for normal cell proliferation. This fine-tuning in mitotic cell cycle progression sometimes gets lost due to dysregulation of CDKs. The aberrant functioning of the CDKIs is therefore studied for its contributions as a vital hallmark of cancers. It has attracted our focus to maneuver cancer therapy. Hence, several synthetic CDKIs and their crystallography-based drug design have been explained to understand their mode of action with CDKs. Since most of the synthetic drugs function by inhibiting the CDK4/6 kinases by competitively binding to their ATP binding cleft, these synthetic drugs are reported to attack the normal, healthy growing cells adjacent to the cancer cells leading to the decrease in the life span of the cancer patients. The quest for traditional natural medicines may have a great impact on the treatment of cancer. Therefore, in the present studies, a search for naturally sourced CDK inhibitors has been briefly focused. Additionally, some synthetic crystallography-based drug design has been explained to elucidate different avenues to develop better anticancer chemotherapeutics, converting natural scaffolds into inhibitors of the CDK mediated abnormal signal transduction with lesser side effects.

Natural Inhibitors against Potential Targets of Cyclooxygenase, Lipoxygenase and Leukotrienes.

BACKGROUND: Cyclooxygenase (COX) and Lipoxygenase (LOX) enzymes catalyze the production of pain mediators like Prostaglandins (PGs) and Leukotrienes (LTs), respectively from arachidonic acid. INTRODUCTION: The COX and LOX enzyme modulators are responsible for the major PGs and LTs mediated complications like asthma, osteoarthritis, rheumatoid arthritis, cancer, Alzheimer's disease, neuropathy and Cardiovascular Syndromes (CVS). Many synthetic Nonsteroidal Anti- Inflammatory Drugs (NSAIDs) used in the treatment have serious side effects like nausea, vomiting, hyperacidity, gastrointestinal ulcers, CVS, etc. Methods: The natural inhibitors of pain mediators have great acceptance worldwide due to fewer side effects on long-term uses. The present review is an extensive study of the advantages of plantbased vs synthetic inhibitors. RESULTS: These natural COX and LOX inhibitors control inflammatory response without causing side-effect-related complicacy. CONCLUSION: Therefore, the natural COX and LOX inhibitors may be used as alternative medicines for the management of pain and inflammation due to their less toxicity and resistivity.

Natural Sourced Inhibitors of EGFR, PDGFR, FGFR and VEGFRMediated Signaling Pathways as Potential Anticancer Agents.

The molecular mechanisms of mitotic cell cycle progression involve very tightly restricted types of machinery which are highly regulated by a fine balance between the positive and negative accelerators (or regulators). These regulators include several checkpoints that have proteins acting as enzymes and their activating partners. These checkpoints incessantly monitor the external as well as internal environments such as growth signals, favorable conditions for growth, cell size, DNA integrity of the cell and hence function to maintain the highly ordered cell cycle progression by sustaining cell homeostasis and promoting error-free DNA replication and cell cycle division. To progress through the mitotic cell cycle, the cell has to successfully drive past the cell cycle checkpoints. Due to the abnormal behavior of some cell cycle proteins, the cells tend to divide continuously overcoming the tight regulation of cell cycle checkpoints. Such anomalies may lead to unwanted cell division, and this deregulation of cell cycle events is considered as one of the main reasons behind tumor development, and thus, cancer progression. So the understanding of the molecular mechanisms in cancer progression might be insightful for designing several cancer treatment strategies. The deregulation in the checkpoints is caused due to the changes in the tyrosine residues of TPKs via PDGFR, EGFR, FGFR, and VEGFR-mediated signaling pathways. Therefore, the inhibitors of PDGFR, EGFR, FGFR, and VEGFR-mediated signaling pathways could be potential anticancer agents. The resistance and toxicity in the existing synthetic anticancer chemotherapeutics may decrease the life span of a patient. For long, natural products have played an essential alternative source of therapeutic agents due to having least or no side effect and toxicity. The present study is an attempt to promote natural anticancer drug development focusing on the updated structural information of PDGFR, EGFR, FGFR, and VEGFR inhibitors isolated from the plant sources. The data used in this review has been collected from internet resources, viz. GOOGLE Web, GOOGLE SCHOLAR, and PubMed Central. The citation of each report was first checked, after which the articles were selected as an authentic reference for the present study. Around 200 journal articles were initially selected, of which around 142 were finally chosen for presenting the study on the natural sourced inhibitors of EGFR, PDGFR, FGFR, and VEGFR-mediated signaling pathways which may help to enhance the potential cancer treatment.

"Pelargonidin mediated selective activation of p53 and parp proteins in preventing food additive induced genotoxicity: an in vivo coupled in silico molecular docking study".

Food-additive toxicity has become a major health hazard issue globally. Alloxan (ALX), a food-additive, intaken daily through flour causes diabetes and genotoxicity by inducing chromosomal-aberration and DNA-damage. The use of phytochemicals as a protective measure of health hazards has become quite evident because of their least side effects. Pelargonidin (PG), one such phyto-product, have an anti-genotoxic and anti-diabetic effect. In this study, the possibility of PG to inhibit alloxan-induced chromosomal-aberration and DNA-damage was assessed in mice model in vivo and the experimental outcome was validated theoretically through in silico structure-based molecular docking study. Results of the mitotic-index observed from the PG-pre-treated-alloxan-administered (PG+ALX) mice group revealed a significant reduction in chromosomal-anomaly, DNA-damage, and an upregulation of the p53 and PARP protein expression when compared to the ALX-treated mice group. Additionally, the in silico molecular docking study predicted the biochemical mechanism of actions of pelargonidin by identifying the two important amino acid residues p53 and PARP as the active bio-targets of pelargonidin. Therefore, results of our present in vivo and silico studies implicate that pelargonidin could effectively restrict DNA-damage and chromosomal-aberration by modulating PARP and p53 repair proteins showing its ability for possible protein-drug interaction, an effective therapeutic tool in future drug discovery.

Exploring the Potential Inhibition of Candidate Drug Molecules for Clinical Investigation Based on their Docking or Crystallographic Analyses against M. tuberculosis Enzyme Targets.

Tuberculosis (TB) is a devastating disease responsible for millions of humans' deaths worldwide. It is caused by a mycobacterial organism, the tubercle bacillus or Mycobacterium tuberculosis. Although TB can be treated, cured and can be prevented if patients take prescribed medicines, scientists have never come close to wiping it out due to a sharp rise in the incidence of multidrug-resistant (MDR) and extensively drug-resistant (XDR) mycobacterium strains. Due to long regimen treatment and emergence of MDR and XDR-TB, it is urgent to re-engineer and reposition old drugs for developing new antimycobacterial entities with novel mechanisms of action to achieve effective TB control even against the resistant forms of TB. To combat the dreadful MDR and XDR-TB, potential targets are being extensively searched for the last couple of years for the design and discovery of active potential antitubercular chemotherapeutics. To explore the disease virulence, potential new tubercular target enzymes such as InhA, MmpL3, ATP synthase, DprE1, QcrB and MenA have been taken into consideration in the present study and the structure-based design of the corresponding target inhibitors which are under clinical investigation has been attempted to identify structural features for the discovery of new chemical entities (NCEs) having specificity towards MDR and XDR Mycobacterium tuberculosis (M. tuberculosis).