Human Claudin-Derived Peptides Block the Membrane Fusion Process of Zika Virus and Are Broad Flavivirus Inhibitors

Exploring therapeutic potential of claudin in Flavivirus infection: A review on current advances and future perspectives

Flavivirus such as Dengue, Zika, West Nile, Japanese encephalitis, and yellow fever virus, composed of single-stranded positive-sense RNA, predominantly contaminated through arthropods. Flavivirus infection characterises from asymptomatic signs to severe hemorrhagic fever and encephalitis. The host's immune system detects these viruses and provides a defence mechanism to sustain their life and growth. However, flaviviruses through different mechanisms compromise the host's immune defence. The current pharmacotherapeutic strategies against Flavivirus infection target different stages of the Flavivirus life cycle and its proteins. On the contrary, the host's immune defence mechanism is equally important to restrict their growth. It has been suggested that flaviviruses compromise claudins to sustain their life and growth inside the mammalian cells. This review primarily focuses on the effect of Flavivirus on claudins (CLDNs), transmembrane proteins that form tight junctions in mammalian cells. CLDNs are crucial in viral entry and pathogenesis by regulating paracellular permeability, particularly in tissues and the blood-brain barrier. Recent studies indicate that the Dengue and Zika viruses can potentially be treated by targeting specific CLDNs-specifically CLDN 1, CLDN 5, and CLDN 7 to inhibit viral entry and fusion. Additionally, it highlights the current challenges and future prospects in developing claudin-based antiviral agents against Flavivirus infections.

Antimicrobial Peptides Against Arboviruses: Mechanisms, Challenges, and Future Directions

This review delves into the potential of antimicrobial peptides (AMPs) as promising candidates for combating arboviruses, focusing on their mechanisms of antiviral activity, challenges, and future directions. AMPs have shown promise in preventing arbovirus attachment to host cells, inducing interferon production, and targeting multiple viral stages, illustrating their multifaceted impact on arbovirus infections. Structural elucidation of AMP-viral complexes is explored to deepen the understanding of molecular determinants governing viral neutralization, paving the way for structure-guided design. Furthermore, this review highlights the potential of AMP-based combination therapies to create synergistic effects that enhance overall treatment outcomes while minimizing the likelihood of resistance development. Challenges such as susceptibility to proteases, toxicity, and scalable production are discussed alongside strategies to address these limitations. Additionally, the expanding applications of AMPs as vaccine adjuvants and antiviral delivery systems are emphasized, underscoring their versatility beyond direct antiviral functions.

Advances in Zika virus vaccines and therapeutics: A systematic review

Zika virus (ZIKV) is the causative agent of a viral infection that causes neurological complications in newborns and adults worldwide. Its wide transmission route and alarming spread rates are of great concern to the scientific community. Numerous trials have been conducted to develop treatment options for ZIKV infection. This review highlights the latest developments in the fields of vaccinology and pharmaceuticals developments for ZIKV infection. A systematic and comprehensive approach was used to gather relevant and up-to-date data so that inferences could be made about the gaps in therapeutic development. The results indicate that several therapeutic interventions are being tested against ZIKV infection, such as DNA vaccines, subunit vaccines, live-attenuated vaccines, virus-vector-based vaccines, inactivated vaccines, virus-like particles, and mRNA-based vaccines. In addition, approved anti-ZIKV drugs that can reduce the global burden are discussed. Although many vaccine candidates for ZIKV are at different stages of development, none of them have received Food and Drug Authority approval for use up to now. The issue of side effects associated with these drugs in vulnerable newborns and pregnant women is a major obstacle in the therapeutic pathway.

Role of endoplasmic reticulum stress-related unfolded protein response and its implications in dengue virus infection for biomarker development

Dengue virus (DENV) causes debilitating disease in humans, which varies at different rates in host cells, such as monocytes, macrophages, dendritic cells, Langerhans cells, and other cell types. Such heterogeneity in DENV infection in cells could be attributed to a range of factors, including host cell immune response, anti-viral cellular proteins, and virus mediated cellular autophagy. This review delineates an important feature of every cell, the unfolded protein response (UPR) that is attributed to the accumulation of several viral and unfolded/misfolded proteins, such as in DENV infection. UPR is a normal process to counteract endoplasmic reticulum (ER) stress that leads to cell autophagy; though the phenomenon is markedly upregulated during DENV infection. This could be attributed to the uncontrolled activation of the key UPR signaling pathways: inositol-requiring transmembrane kinase/endoribonuclease 1 (IRE1), protein kinase R (PKR)-like endoplasmic reticulum kinase (PERK), and activating transcription factor-6 (ATF6), which promote cell autophagy under normal and diseased conditions through the downstream regulation of apoptosis promoting factors such as X-box binding protein (XBP1), GADD34, and ATF-6. Because DENV can modulate these signaling cascades, by promoting dysregulated cell autophagy, the ER stress mediated UPR pathways and the inherent agents could play an important role in delineating the severity of dengue infection with a potential for developing DENV targeted therapeutics.

The Anti-Dengue Virus Peptide DV2 Inhibits Zika Virus Both In Vitro and In Vivo

The C-terminal portion of the E protein, known as stem, is conserved among flaviviruses and is an important target to peptide-based antiviral strategies. Since the dengue (DENV) and Zika (ZIKV) viruses share sequences in the stem region, in this study we evaluated the cross-inhibition of ZIKV by the stem-based DV2 peptide (419–447), which was previously described to inhibit all DENV serotypes. Thus, the anti-ZIKV effects induced by treatments with the DV2 peptide were tested in both in vitro and in vivo conditions. Molecular modeling approaches have demonstrated that the DV2 peptide interacts with amino acid residues exposed on the surface of pre- and postfusion forms of the ZIKA envelope (E) protein. The peptide did not have any significant cytotoxic effects on eukaryotic cells but efficiently inhibited ZIKV infectivity in cultivated Vero cells. In addition, the DV2 peptide reduced morbidity and mortality in mice subjected to lethal challenges with a ZIKV strain isolated in Brazil. Taken together, the present results support the therapeutic potential of the DV2 peptide against ZIKV infections and open perspectives for the development and clinical testing of anti-flavivirus treatments based on synthetic stem-based peptides.