Navin Kumar

ANTIVIRAL POTENTIAL OF MEDICINAL PLANTS: AN OVERVIEW

The term ‘ A ntiviral agents’ has been defined in very broad terms as substances other than a virus or virus containing vaccine or specific antibody which can produce either a protective or therapeutic effect to the clear detectable advantage of the virus infected host. The herbal medicine has a long traditional use and the major advantage over other medicines i s their wide therapeutic window with rare side effects. There are some disadvantages of synthetic drugs like narrow therapeutic window and more importantly the various adverse side effects which occur quite frequently. Due to these disadvant ages and other limitations, there is an increasing trend in the field of research for discovering new and noble drugs based on various herbal formulations. This review attempts to address the importance of developing therapeutic herbal formulations from various medicinal plants using the knowledge based on traditional system of medicines, the Ayurveda. Although natural products have been used by civilization since ancient times, only in recent decades has there been growing r esearch into alternative therapies and the ther apeutic s use of natural products, especially those derived from plants. Plants synthesize and preserve a variety of biochemical products, many of which are extractable and used for various scientific investigations. Therefore, medicinal plants proved to be a major resort for the treatment

Prospects in the development of natural radioprotective therapeutics with anti-cancer properties from the plants of Uttarakhand region of India

Radioprotective agents are substances those reduce the effects of radiation in healthy tissues while maintaining the sensitivity to radiation damage in tumor cells. Due to increased awareness about radioactive substances and their fatal effects on human health, radioprotective agents are now the topic of vivid research. Scavenging of free radicals is the most common mechanism in oncogenesis that plays an important role in protecting tissues from lethal effect of radiation exposure therefore radioprotectors are also good anti-cancer agents. There are numerous studies indicating plant-based therapeutics against cancer and radioprotection. Such plants could be further explored for developing them as promising natural radioprotectors with anti-cancer properties. This review systematically presents information on plants having radioprotective and anti-cancer properties.

Homologous Recombination is Activated at Early Time Points Following Exposure to Cobalt Chloride Induced Hypoxic Conditions in Saccharomyces cerevisiae

DNA repair functions are essential for the maintenance of genetic integrity and are regulated in response to both environmental and chemical stressors in mammalian and yeast cells in culture. The inhibitory effect of limited O2 availability on DNA repair functions in general and on homologous recombination (HR) in particular, correlates with increased chromosomal abnormalities in hypoxic cancer cells. Given the above, we have investigated the effects of CoCl2,––a hypoxia mimetic agent on HR and genetic aberrations in Saccharomyces cerevisiae. Our studies demonstrate that both acute and chronic exposure to CoCl2 activated HR and increased genetic aberrations in S. cerevisiae D7 cells. At early time points following addition of CoCl2 to the growth media, cells were briefly arrested in the G1-S boundary concomitant with a transient increase in Rad52-GFP foci formation and induction of low levels of DNA damage. The mode of action of CoCl2 is thus similar to that of DNA synthesis inhibitors, the later are known to induce HR and cause G1-S arrest. We propose that the activation of HR in the presence of the hypoxia mimetic agent may be attributed to the replication stress and/or DNA damage induced by the stressor.

Comparative effects of hypoxia and hypoxia mimetic cobalt chloride on in vitro adhesion, biofilm formation and susceptibility to amphotericin B of Candida glabrata

OBJECTIVESnCandida glabrata has emerged as potent pathogen in nosocomial infections. The objective of this study is to investigate the effects of hypoxia (an important host factor) and hypoxia mimetic cobalt chloride upon growth, in vitro adhesion, biofilm formation and susceptibility to amphotericin B of Candida glabrata.nnnMATERIALS AND METHODSnGrowth was checked by spotting assays. Expression of TDH3, a gene of glycolytic pathway was analyzed as intracellular hypoxia marker by reverse transcription PCR. In vitro adhesion, biofilm development and susceptibility of biofilm to amphotericin B were performed on polystyrene plates and quantified by XTT assay in RPMI 1640 and YNB media. Experiments were performed in triplicates and Students t-test was used for statistical analysis.nnnRESULTSnHypoxia did not compromise the growth of C. glabrata unlike CoCl2. Hypoxia and CoCl2 upregulated TDH3 expression. Adhesion was reduced upon exposure to hypoxia and CoCl2. Biofilm activity remained unchanged in the presence of CoCl2 in both media. In comparison to normoxia control, hypoxia increased biofilm activity to 259.33 ± 22.05% in RPMI 1640, while hypoxia reduced it to 70.99 ± 2.99% in YNB. Biofilm susceptibility to amphotericin B was significantly decreased in RPMI 1640 and remained unaffected in YNB in hypoxia.nnnCONCLUSIONSnC. glabrata grows well even under hypoxia but not upon CoCl2 exposures. CoCl2 mimics hypoxia like expression of TDH3 but affects the virulence properties unlike hypoxia. Both, hypoxia and CoCl2 affects adhesion adversely. Hypoxia increases biofilm development and reduces the susceptibility of biofilm to amp B in RPMI 1640 but not in YNB.

Lingzhi or Reishi Medicinal Mushroom, Ganoderma lucidum (Agaricomycetes), Inhibits Candida Biofilms: A Metabolomic Approach

This article presents a comparative gas chromatography (GC)-mass spectrometry (MS)-based metabolomic analysis of mycelia and fruiting bodies of the medicinal mushroom Ganoderma lucidum. Three aqueous extracts-mycelia, fruiting bodies, and a mixture of them-and their sequential fractions (methanolic and ethyl acetate), prepared using an accelerated solvent extractor, were characterized by GC-MS to determine volatile organic compounds and by high-performance thin-layer chromatography to quantify ascorbic acid, a potent antioxidant. In addition, these extracts and fractions were assessed against Candida albicans and C. glabrata biofilms via the XTT reduction assay, and their antioxidant potential was evaluated. Application of chemometrics (hierarchical cluster analysis and principal component analysis) to GC data revealed variability in volatile organic compound profiles among G. lucidum extracts and fractions. The mycelial aqueous extract demonstrated higher anti-Candida activity and ascorbic acid content among all the extracts and fractions. Thus, this study illustrates the preventive effect of G. lucidum against C. albicans and C. glabrata biofilms along with its nutritional value.

Effectiveness of Phytoactive Molecules on Transcriptional Expression, Biofilm Matrix, and Cell Wall Components of Candida glabrata and Its Clinical Isolates

Toxicity challenges by antifungal arsenals and emergence of multidrug resistance scenario has posed a serious threat to global community. To cope up with this alarming situation, phytoactive molecules are richest, safest, and most effective source of broad spectrum antimicrobial compounds. In the present investigation, six phytoactive molecules [cinnamaldehyde (CIN), epigallocatechin, vanillin, eugenol (EUG), furanone, and epigallocatechin gallate] were studied against Candida glabrata and its clinical isolates. Among these, CIN and EUG which are active components of cinnamon and clove essential oils, respectively, exhibited maximum inhibition against planktonic growth of C. glabrata at a concentration of 64 and 128 μg mL–1, respectively. These two molecules effectively inhibited and eradicated approximately 80% biofilm of C. glabrata and its clinical isolates from biomaterials. CIN and EUG increased reactive oxygen species generation, cell lysis, and ergosterol content in plasma membrane and reduced virulence attributes (phospholipase and proteinase) as well as catalase activity of C. glabrata cells. Reduction of mitochondrial membrane potential with increased release of cytochrome c from mitochondria to cytosol indicated initiation of early apoptosis in CIN- and EUG-treated C. glabrata cells. Transcriptional analysis showed that multidrug transporter (CDR1) and ergosterol biosynthesis genes were downregulated in the presence of CIN, while getting upregulated in EUG-treated cells. Interestingly, genes such as 1,3-β-glucan synthase (FKS1), GPI-anchored protein (KRE1), and sterol importer (AUS1) were downregulated upon treatment of CIN/EUG. These results provided molecular-level insights about the antifungal mechanism of CIN and EUG against C. glabrata including its resistant clinical isolate. The current data established that CIN and EUG can be potentially formulated in new antifungal strategies.

Functional analysis of selected deletion mutants in Candida glabrata under hypoxia

Increased drug resistance in Candida glabrata (a model non-albicans Candida) calls for the identification of potential molecular targets for the development of effective drugs. Hypoxia (a state of low oxygen) is an important host factor, which affects the virulence of the pathogen and efficacy of drugs. In the present study, in vitro characterization of 13 null mutants of C. glabrata were done under hypoxic condition (1% O2). These mutants have a major role to play in cellular pathways, viability and pathogenesis (cell wall biosynthesis, ergosterol synthesis, calcium–calcineurin, etc.). The in vitro growth, biofilm formation and susceptibility of biofilm to antifungal drugs of these mutants were compared with the control. Hypoxia reduced the susceptibility of planktonic cells to fluconazole. The mutants ecm33Δ, kre1Δ, rox1Δ, and kre2Δ showed maximum reductions in their biofilm activities (>20%). The selected mutants (upc2BΔ, kre2 Δ, ecm7Δ, rox1 Δ, mid1Δ, ecm33Δ, cch1Δ, kre1Δ) showed reduced biofilm activities (>30%) in the presence of 16xa0μgxa0ml−1 fluconazole under hypoxia. Functional analysis revealed that Kre1, Ecm33, Upc2B, Kre2, Ecm7, Cch1, Mid1 and Rox1 can be explored as a potential drug target for developing novel antifungal drugs.