Bibekananda Sahoo

Abstract Receptor binding is the first step in viral cell entry. In enveloped virus cell entry, viral and host membrane fusion follows receptor binding. Viral surface receptor-binding protein associates with membrane fusion protein and masks its structure, to prevent pre-mature fusion activity. Dissociation of receptor-binding protein from fusion protein is an essential step before membrane fusion. Mechanism of receptor binding leading to dissociation of receptor binding and fusion protein is poorly understood in alphaviruses. Chikungunya virus (CHIKV), an alphavirus, re-emerged as a global pathogen in recent past. CHIKV surface envelope proteins, E2 and E1, function as receptor binding and fusion protein, respectively. Site of heparan sulfate (HS) receptor binding on E2–E1 heterodimer and its effect on E2–E1 heterodimer conformation is not known. Using molecular docking, we mapped HS binding to a positively charged pocket on E2 that is structurally conserved in alphaviruses. Based on our results from docking and sequence analysis, we identified a novel HS-binding sequence motif in E2. Purified E2 binds to heparin and HS specifically through charge interactions. Binding affinity of E2 to HS is comparable with other known HS–protein interactions (Kd ∼ 1.8 μM). Mutation of charged residues in the predicted HS-binding motif of E2 to alanine resulted in reduction of HS binding. Molecular dynamics (MD) simulations on E2, after docking HS, predicted allosteric domain movements. Fluorescence spectroscopy, far-UV circular dichroism spectroscopy, fluorescence resonance energy transfer experiments on HS-bound E2 corroborate our findings from MD simulations. We propose a mechanism where receptor-binding results in allosteric domain movements in E2, explaining E2–E1 dissociation.

Aedes mosquito-transmitted viruses such as the Zika, dengue, and chikungunya viruses have spread globally. CHIKV, similar to many other enveloped viruses, enters cells in sequential steps: step 1 involves receptor binding followed by endocytosis, and step 2 involves viral-cell membrane fusion in the endocytic vesicle. The viral envelope surface protein, E1, performs membrane fusion. E1 is triggered to undergo conformational changes by acidic pH of the maturing endosome. Different domains of E1 rearrange during the pre- to postfusion conformation change. Using in silico analysis of the E1 structure and different biochemical experiments, we explained a structural mechanism of key conformational changes in E1 triggered by acidic pH. We noted two important structural changes in E1 at acidic pH. In the first, a spring-twisted region in a loop connecting two domains (I and III) untwists, bringing a swiveling motion of domains on each other. In the second, breaking of interactions between domains I and III and domain separation are required for membrane fusion. This knowledge will help devise new therapeutic strategies to block conformation changes in E1 and thus viral entry.

FRG1 is the primary candidate gene for Fascioscapulohumeral Muscular Dystrophy. So far, its role has been reported in muscle development, vasculogenesis, angiogenesis, and tumorigenesis. Mechanistically studies suggest FRG1's role in RNA biogenesis which may have implications in multiple physiological processes and diseases, including tumorigenesis. Its probable role as hnRNP and association with NMD-related genes prompted us to look into FRG1's effect on NMD gene expression and the mechanism. Using microarray profiling in cell lines, we found that FRG1 altered the mRNA surveillance pathway and associated pathways, such as RNA transport and spliceosome machinery molecules. Multiple sequence alignment of core factors, namely, UPF1, UPF3B, and SMG1, showed conserved stretches of nucleotide sequence 'CTGGG'. Structural modeling followed by EMSA, ChIP-qPCR, and luciferase reporter assays showed 'CTGGG' as a FRG1 binding site. Analysis of the publicly available datasets showed that the expression of FRG1 correlates with NMD genes in different tissue types. We validated the effect of FRG1 on NMD gene transcription by qRT-PCR. Overall, FRG1 might be a transcriptional regulator of NMD genes.

Summary NINJ1 is a recently identified active executioner of plasma membrane rupture (PMR), a process previously thought to be a passive osmotic lysis event in lytic cell death. NINJ2 is a close paralog of NINJ1 but it failed to mediate PMR. By cryoEM, we found that both NINJ1 and NINJ2 were able to assemble into linear filament that binds strongly to lipids on one side but is water-soluble on the other side. The more-or-less straight NINJ1 filament was able to wrap around a membrane bleb and solubilize it from the plasma membrane to induce PMR; however, the intrinsically curved NINJ2 filament failed to do so, explaining its incapability of mediating PMR. We further demonstrated that binding to cholesterol at the inner leaflet of the lipid bilayer was responsible for the curving of the NINJ2 filament, while strong lipid binding at the outer leaflet was contributing to NINJ1’s capability of mediating PMR.