Pan-India novel coronavirus SARS-CoV-2 genomics and global diversity analysis in spike protein.

The mortality rates due to COVID-19 have been found disproportionate globally and are currently being researched. India mortality rate with a population of 1.3 billion people is relatively lowest to other countries with high infection rates. Genetic composition of circulating isolates continues to be a key determinant of virulence and pathogenesis. This study aimed to analyse the extent of divergence between genomes of Indian isolates (n = 2525 as compared to reference Wuhan-1 strain and isolates from countries showing higher fatality rates including France, Italy, Belgium, and the USA. The study also analyses the impact of key mutations on interactions with angiotensin converting enzyme 2 (ACE2) and panel of neutralizing monoclonal antibodies. Using 1,44,605 spike protein sequences, global prevalence of mutations in spike protein was observed. The study suggests that SARS-CoV-2 genomes from India share consensus with global trends with respect to D614G as most prevalent mutational event (81.66% among 2525 Indian isolates). Indian isolates did not reported prevalence of N439K mutation in receptor binding motif (RBM) as compared to global isolates (0.54%). Computational docking and molecular dynamics simulation analysis of N439K mutation with respect to ACE 2 binding and reactivity with RBM targeted antibodies viz., B38, BD23, CB6, P2B-F26 and EY6A suggests that variant have relatively higher affinity with ACE 2 receptor which may support higher infectivity. The study warrants large scale monitoring of Indian isolates as SARS-CoV-2 virus is expected to evolve and mutations may appear in unpredictable way.

Molecular Characterization of the ß2-like Octopamine Receptor of Helicoverpa armigera.

Helicoverpa armigera is a devastating polyphagous and cosmopolitan crop pest. There are reports of this insect being resistant to a variety of pesticides raising concern worldwide. The Octopamine (OA) binding ß2-like receptor (OAR), a GPCR, is widely distributed in the nervous system of the insect and plays essential roles in the physiology and development and thus is an important target for insecticides. Yet, the molecular characterization of the H. armigera OAR (HarmOAR) and rational design of compounds based on this receptor is lacking. As a first step, we performed multiple sequence alignment of all insect OARs, which revealed that the sequences contained all conserved class A GPCR motifs. Phylogenetic studies showed clade-specific variations in the protein sequences primarily arising owing to differences in the ICL3 loop region. Further, a structural model of HarmOAR was built using the inactive human ß2AR as a template. 0.9 µs atomistic simulations revealed conserved inter helical contacts and water molecules of HarmOAR. The detailed binding of octopamine was studied using molecular docking and 0.3 µs atomistic simulations. Twenty-two insecticides active against octopamine receptors of other insects were compiled and docked to HarmOAR followed by rescoring with binding free energies to prioritize them for H. armigera. Our study suggests α-terpineol to be a good candidate as an insecticide or insect repellent for Helicoverpa armigera.

Evolutionary and structure-function analysis elucidates diversification of prokaryotic and eukaryotic trehalases.

Trehalase catalyses the breakdown of trehalose into two glucose moieties and is ubiquitous in all organisms. Here, we provide insights into the enigmatic origin and evolution of trehalase in major species. Study of taxonomic distribution, orthology, phylogeny and functional domains indicated that trehalase possibly originates from bacteria and was transmitted to other taxa through horizontal gene transfer. Domain analysis showed that glycosyl hydrolase family 37 is present in most of the sequences and represents dominant activity during evolution, and also, illustrating that cytosolic trehalase is primitive than its transmembrane form. Furthermore, it was observed that trehalase went through domain rearrangement to facilitate its activity in adverse environmental conditions like acidic pH. Gene context analysis depicts that trehalase neighbourhood consists of sugar transport and lipid metabolism genes. This highlights their relatedness in metabolic activity and similarity in gene regulation, respectively. Evolutionary and selection pressure analysis demonstrated that trehalase genes were duplicated and evolved under purifying selection, following horizontal gene transfer. Moreover, site-specific rate of evolution emphasized conservation of functionally important residues. In comparison with acid trehalase, neutral trehalase has an extra N-terminal extension. This study serves as an instigation to understand evolution and functionality of trehalase across diverse species. Communicated by Ramaswamy H. Sarma.