Neuroprotective Drug Discovery From Phytochemicals and Metabolites for CNS Viral Infection: A Systems Biology Approach With Clinical and Imaging Validation

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dc.contributor.author Bhattacharjee, Anindita
dc.contributor.author Purohit, Pratik
dc.contributor.author Roy, Prasun K.
dc.date.accessioned 2023-04-20T06:51:30Z
dc.date.available 2023-04-20T06:51:30Z
dc.date.issued 2022-07-25
dc.identifier.issn 16624548
dc.identifier.uri http://localhost:8080/xmlui/handle/123456789/2129
dc.description This paper is submitted by the author of IIT (BHU), Varanasi en_US
dc.description.abstract Background: Recent studies have reported that pulmo-neurotropic viruses can cause systemic invasion leading to acute respiratory failure and neuroinfection. The tetracycline class of secondary metabolites of microorganisms is effective against several migrating neurotropic viral disorders, as Japanese-Encephalitis (JE), Severe-Acute-Respiratory-Syndrome Coronavirus-2 (SARS-COV2), Human-Immunodeficiency-Virus (HIV), and Simian-Immunodeficiency-Virus (SIV). Another microbial secondary metabolite, cephalosporin, can be used for anti-viral combination therapy. However, a substantial public health debacle is viral resistance to such antibiotics, and, thus, one needs to explore the antiviral efficiency of other secondary metabolites, as phytochemicals. Hence, here, we investigate phytochemicals like podophyllotoxin, chlorogenic acid, naringenin, and quercetin for therapeutic efficiency in neurotropic viral infections. Methods: To investigate the possibility of the afferent neural pathway of migrating virus in man, MRI scanning was performed on human subjects, whereby the connections between cranial nerves and the brain-stem/limbic-region were assessed by fiber-tractography. Moreover, human clinical-trial assessment (n = 140, p = 0.028) was done for formulating a quantitative model of antiviral pharmacological intervention. Furthermore, docking studies were performed to identify the binding affinity of phytochemicals toward antiviral targets as (i) host receptor [Angiotensin-converting Enzyme-2], (ii) main protease of SARS-COV2 virus (iii) NS3-Helicase/Nucleoside triphosphatase of Japanese-encephalitis-virus, and the affinities were compared to standard tetracycline and cephalosporin antibiotics. Then, network pharmacology analysis was utilized to identify the possible mechanism of action of those phytochemicals. Results: Human MRI-tractography analysis showed fiber connectivity, as: (a) Path-1: From the olfactory nerve to the limbic region (2) Path-2: From the peripheral glossopharyngeal nerve and vagus nerves to the midbrain-respiratory-center. Docking studies revealed comparable binding affinity of phytochemicals, tetracycline, and cephalosporin antibiotics toward both (a) virus receptors, (b) host cell receptors where virus-receptor binds. The phytochemicals effectively countered the cytokine storm-induced neuroinflammation, a critical pathogenic pathway. We also found that a systems-biology-based double-hit mathematical bi-exponential model accounts for patient survival-curve under antiviral treatment, thus furnishing a quantitative-clinical framework of secondary metabolite action on virus and host cells. Conclusion: Due to the current viral resistance to antibiotics, we identified novel phytochemicals that can have clinical therapeutic application to neurotropic virus infection. Based on human MRI scanning and clinical-trial analysis, we demarcated the anatomical pathway and systems-biology-based quantitative formulation of the mechanism of antiviral action. en_US
dc.language.iso en en_US
dc.publisher Frontiers Media S.A. en_US
dc.relation.ispartofseries Frontiers in Neuroscience;Article number 917867
dc.subject antiviral drug discovery en_US
dc.subject docking study en_US
dc.subject MRI fiber tractography en_US
dc.subject network pharmacology en_US
dc.subject neurotropic virus infection en_US
dc.subject phytochemicals en_US
dc.subject secondary metabolites en_US
dc.subject systems biology en_US
dc.subject angiotensin converting enzyme 2; antivirus agent; cephalosporin; chlorogenic acid; helicase; naringenin; nonstructural protein 3; nucleoside triphosphatase; phytochemical; podophyllotoxin; quercetin; tetracycline; virus receptor en_US
dc.subject antiviral activity; Article; brain stem; central nervous system infection; cranial nerve; cytokine storm; diffusion tensor imaging; drug development; drug efficacy; drug receptor binding; glossopharyngeal nerve; Japanese encephalitis virus; limbic system; mathematical model; mesencephalon; metabolite; molecular docking; nervous system inflammation; neuroprotection; neurotropic virus; nonhuman; nuclear magnetic resonance imaging; olfactory nerve; quantitative analysis; Severe acute respiratory syndrome coronavirus 2; survival; systems biology; systems pharmacology; vagus nerve; virus cell interaction; virus transmission en_US
dc.title Neuroprotective Drug Discovery From Phytochemicals and Metabolites for CNS Viral Infection: A Systems Biology Approach With Clinical and Imaging Validation en_US
dc.type Article en_US


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