ABSTRACT
Zika Virus (ZIKV) belongs to the class of flavivirus that can be transmitted by Aedes mosquitoes. The number of Zika virus caused cases of acute infections, neurological disorders and congenital microcephaly are rapidly growing and therefore, in 2016, the World Health Organization declared a global "Public Health Emergency of International Concern". Anti-ZIKV therapeutic and vaccine development strategies are growing worldwide in recent years, however, no specific and safe treatment is available till date to save the human life. Currently, development of peptide therapeutics against ZIKV has attracted rising attention on account of their high safety concern and low development cost, in comparison to small therapeutic molecules and antibody-based anti-viral drugs. In present review, an overview of ZIKV inhibition by peptide-based inhibitors including E-protein derived peptides, antimicrobial peptides, frog skin peptides and probiotic peptides has been discussed. Peptides inhibitors have also been reported to act against NS5, NS2B-NS3 protease and proteasome in order to inhibit ZIKV infection. Recent advances in peptide-based therapeutics and vaccine have been reviewed and their future promise against ZIKV infections has been explored.
Subject(s)
Aedes , Zika Virus Infection , Zika Virus , Animals , Antiviral Agents , Humans , PeptidesABSTRACT
Bacterial alternative sigma factors are mostly regulated by a partner-switching mechanism. Regulation of the virulence-associated alternative sigma factor SigF of Mycobacterium tuberculosis has been an area of intrigue, with SigF having more predicted regulators than other sigma factors in this organism. Rv1364c is one such predicted regulator, the mechanism of which is confounded by the presence of both anti-sigma factor and anti-sigma factor antagonist functions in a single polypeptide. Using protein binding and phosphorylation assays, we demonstrate that the anti-sigma factor domain of Rv1364c mediates autophosphorylation of its antagonist domain and binds efficiently to SigF. Furthermore, we identified a direct role for the osmosensor serine/threonine kinase PknD in regulating the SigF-Rv1364c interaction, adding to the current understanding about the intersection of these discrete signaling networks. Phosphorylation of SigF also showed functional implications in its DNA binding ability, which may help in activation of the regulon. In M. tuberculosis, osmotic stress-dependent induction of espA, a SigF target involved in maintaining cell wall integrity, is curtailed upon overexpression of Rv1364c, showing its role as an anti-SigF factor. Overexpression of Rv1364c led to induction of another target, pks6, involved in lipid metabolism. This induction was, however, curtailed in the presence of osmotic stress conditions, suggesting modulation of SigF target gene expression via Rv1364c. These data provide evidence that Rv1364c acts an independent SigF regulator that is sensitive to the osmosensory signal, mediating the cross talk of PknD with the SigF regulon.IMPORTANCEMycobacterium tuberculosis, capable of latently infecting the host and causing aggressive tissue damage during active tuberculosis, is endowed with a complex regulatory capacity built of several sigma factors, protein kinases, and phosphatases. These proteins regulate expression of genes that allow the bacteria to adapt to various host-derived stresses, like nutrient starvation, acidic pH, and hypoxia. The cross talk between these systems is not well understood. SigF is one such regulator of gene expression that helps M. tuberculosis to adapt to stresses and imparts virulence. This work provides evidence for its inhibition by the multidomain regulator Rv1364c and activation by the kinase PknD. The coexistence of negative and positive regulators of SigF in pathogenic bacteria reveals an underlying requirement for tight control of virulence factor expression.