Jesudass Joseph Sahayarayan scite author profile

Background The current health concern to the entire world is the chronic respiratory disease caused by coronavirus 2 (COVID-19). A specific treatment or proper therapy is still lacking, and the investigations from across the world for proper drug/vaccine development towards disease control are in progress. The Coronavirus replication takes place by the conversion of the polypeptide into functional protein and this occurs due to the key enzyme Main protease (M pro ). Therefore, identification of natural and effective M pro inhibitors could be a safe and promising approach for COVID-19 control. Methods The present in silico study evaluates the effect of bioactive compounds found in Eucalyptus and Corymbia species essential oil on M pro by docking. Molecular docking of the major seven compounds of essential oil (citronellol, alpha-terpineol, eucalyptol, d -limonene, 3-carene, o -cymene, and alpha-pinene) with M pro was studied by AutoDock 4.2, and the properties were analysed by PreADMET and Biovia Discovery Studio visualizer. Results The calculated parameters such as binding energy, hydrophobic interactions, and hydrogen bond interactions of 6LU7 (M pro ) with Eucalyptus and Corymbia volatile secondary metabolites represented its scope as an effective therapy option against covid-19. Among the docked compounds, eucalyptol shows the least binding energy without toxicity. Conclusions The outcome of this study reported that the essential oil of Eucalyptus and Corymbia species, mainly eucalyptol can be utilized as a potential inhibitor against COVID-19 and also it can be used in its treatment. Hence, further analysis was required to explore its potential application in medicine.

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In-silico protein-ligand docking studies against the estrogen protein of breast cancer using pharmacophore based virtual screening approaches

Sahayarayan

Rajan

Ramasamy

et al. 2021

Saudi Journal of Biological Sciences

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Microbial Volatile Organic Compounds: An Alternative for Chemical Fertilizers in Sustainable Agriculture Development

2022

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Microorganisms are exceptional at producing several volatile substances called microbial volatile organic compounds (mVOCs). The mVOCs allow the microorganism to communicate with other organisms via both inter and intracellular signaling pathways. Recent investigation has revealed that mVOCs are chemically very diverse and play vital roles in plant interactions and microbial communication. The mVOCs can also modify the plant’s physiological and hormonal pathways to augment plant growth and production. Moreover, mVOCs have been affirmed for effective alleviation of stresses, and also act as an elicitor of plant immunity. Thus, mVOCs act as an effective alternative to various chemical fertilizers and pesticides. The present review summarizes the recent findings about mVOCs and their roles in inter and intra-kingdoms interactions. Prospects for improving soil fertility, food safety, and security are affirmed for mVOCs application for sustainable agriculture.

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Effect of different Agrobacterium rhizogenes strains for in-vitro hairy root induction, total phenolic, flavonoids contents, antibacterial and antioxidant activity of (Cucumis anguria L.)

Sahayarayan

Udayakumar²,

Arun

et al. 2020

Saudi Journal of Biological Sciences

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The present study aimed to investigate the effect of different Agrobacterium rhizogenes on the induction of hairy root of Cucumis anguria and determine its total phenolic, flavonoids contents, antibacterial and antioxidant activity. In this investigation A. rhizogenes strains such as, 15834, 13333, A4, R1200, R1000, LBA9402, R1301 and R1601 are all investigated, were developing hairy root conception in cotyledon and leaf tissue explants. Polymerase chain response (PCR) and the converse transcription-PCR are transgenic clones of hairy roots has been utilized rol A and rol B particular primers. In the middle of the different attention of better regulators the extreme transformation frequency was achieved in (IBA + NAA) cotyledon explant. Transgenic hairy roots increase in MS liquid medium added to with IBA + NAA (2.46 + 1.07) displayed the maximum accumulation of biomass 0.68 g/l dry weight (DW) and 6.52 ± 0.49 g/l fresh weight (FW) were obtained at the 21 days of cotyledon explant. The flavonoid and total phenolic contents were estimated using aluminium chloride method and Folin-Ciocalteu method. The amount of phenolic compounds in Cucumis anguria L non transformed root (124.46 ± 6.13 mg GA/g) was lower than that in the methanol extracts of Cucumis anguria L. hairy roots (160.38 ± 5.0 mg GA/g), being was Cucumis anguria L non transformed root lower (42.93 ± 1.58 mg rutin/g) than that in the concentration of total flavonoids in Cucumis anguria L. hairy root (16.26 ± 1.84 mg rutin/g). Additionally, transgenic hairy roots professionally produced various phenolic and flavonoid composites. The total antimicrobial activity, phenolics, flavonoids content and antioxidant were more in the hairy roots related to non-transformed roots. In our discovery, the A. rhizogenes R1000 is promising candidate for hairy root initiation of C. anguria from cotyledone explants were realized large number of hairy roots compared with leaf explants. The antioxidant potential of methanol extracts of flavonoid and phenolic compounds from the hairy roots have great potential to treat various diseases.

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Identification of potential drug target in malarial disease using molecular docking analysis

Sahayarayan

Rajan

Nachiappan

et al. 2020

Saudi Journal of Biological Sciences

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Malaria caused by genus Plasmodium, is a parasite which is the main health issue for humans and about half of the population were suffered. An every year, approximately 1.2–2.7 million people died due to malaria globally. Therefore to prevent the spreading of malaria from the glob novel active drugs with specific activities are necessary. The present study aimed to identify novel drug molecule together with the bioinformatic tools for the development of active malarial drugs. As the search for latest anti malarial compound was developed, this work determined six active blends from various drug databases which possess drug-like characteristics and presents a significant anti malarial actions in in-silico level. Compound ID 300238, 889, 76569, 87324, 45678, and Z185397112are a few of the ligands were got from the Toss lab, Maybridge, Cambridge, Life chem, Bitter, and Examine drug databases and docked against hexokinase 1 protein (PDB: 1CZA) with high throughput practical screening (HTVS) using Glide v6.6. Amid the 6 compounds, compound no: 300238 from Toss lab has the greatest docking score of −9.889 kcal/mol targeting 1CZA protein. The active sites of Hexokinase I of protein were determine by using superimposition of the destination and template structure showed similar structural folds and active sites which were decidedly conserved. The quality of hexokinase I protein was considered to be sterically stable where the protein was prepared by utilizing the software protein preparation execute in the Schrodinger suite. Prepared proteins were evaluated using SAVES and the studies of molecular dynamics of the hexokinase, and the GROMACS were performed for protein–ligand complex. The low HOMO-LUMO energy gaps of the compound verified the greater stability of the molecule. Here, the tested drug candidates have good absorption, distribution, metabolism, and excretion (ADME) properties which were established by using QikProp, version 3.4 of Schrodinger.

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