Type 2 diabetes mellitus is a metabolic disorder resulting from impaired insulin secretion and resistance. Dipeptidyl peptidase (DPP)-IV is an enzyme known to trigger the catalysis of insulinotropic hormones, further abating the endogenous insulin levels and elevating the glucose levels in blood plasma. In the field of drug development, DPP-IV inhibitors have opened up numerous opportunities for leveraging this target to generate compounds as hypoglycemic agents by regulating incretin activity and subsequently decreasing blood glucose levels. However, the practice of synthetic drugs is an apparent choice but poses a great pharmacovigilance issue due to their incessant undesirable effects. The ideology was set to inventively look upon different ethnomedicinal plants for their anti-diabetic properties to address these issues. To date, myriads of phytochemicals are characterized, eliciting an anti-diabetic response by targeting various enzymes and augmenting glucose homeostasis. Antioxidants have played a crucial role in alleviating the symptoms of diabetes by scavenging free radicals or treating the underlying causes of metabolic disorders and reducing free radical formation. Plant-based DPP-IV inhibitors, including alkaloids, phenolic acid, flavonoids, quercetin, and coumarin, also possess antioxidant capabilities, providing anti-diabetic and antioxidative protection. This review article provides a new gateway for exploring the ability of plant-based DPP-IV inhibitors to withstand oxidative stress under pathological conditions related to diabetes and for reforming the strategic role of ethnomedicinal plants as potent DPP-IV inhibitors through the development of polyherbal formulations and nanophytomedicines to regulate incretin activity.
Plant growth-promoting fungi play an important role in development of sustainable agriculture. In the current study, 13 fungal strains were isolated from the rhizosphere of healthy (wheat) plant and screened for their indolic auxin production potential. strain PGFW, strain BFW and strain DGFW were amongst the most efficient indolic auxin-producing strains. Indolic auxins such as indole 3 acetate (IAA), indole 3 butyrate (IBA) and indole 3 propionate (IPA) are produced by fungi. The conventional method to assess the IAA production is through a spectrophotometric assay using Salkowski's reagent, which quantifies all indolic auxins and not individual auxins. Moreover, it was also observed that the absorption maxima () of the samples, when compared to that of standard indole-3-acetic acid, showed deviation from the latter, indicative of production of a mixture of indolic derivatives by the fungi. Hence, for further profiling of these indolic compounds, high-performance thin layer chromatography (HPTLC) based protocol was standardized to precisely detect and quantify individual indolic auxins like IAA, IBA and IPA in the range of 100-1000 ng per spot. HPTLC analysis also showed that the fungal strains produce different indolic auxins in media with and without fortification of tryptophan, with the production of indolic auxins being enhanced in presence of tryptophan. Thus, this standardized HPTLC protocol is an efficient and sensitive methodology to separate and quantify the indolic derivatives.
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