The outbreak of pneumonia-like respiratory disorder at China and its rapid transmission world-wide resulted in public health emergency, which brought lineage B betacoronaviridae SARS-CoV-2 (severe acute respiratory syndrome coronavirus 2) into spotlight. The fairly high mutation rate, frequent recombination and interspecies transmission in betacoronaviridae are largely responsible for their temporal changes in infectivity and virulence. Investigation of global SARS-CoV-2 genotypes revealed considerable mutations in structural, non-structural, accessory proteins as well as untranslated regions. Among the various types of mutations, single-nucleotide substitutions are the predominant ones. In addition, insertion, deletion and frame-shift mutations are also reported, albeit at a lower frequency. Among the structural proteins, spike glycoprotein and nucleocapsid phosphoprotein accumulated a larger number of mutations whereas envelope and membrane proteins are mostly conserved. Spike protein and RNA-dependent RNA polymerase variants, D614G and P323L in combination became dominant world-wide. Divergent genetic variants created serious challenge towards the development of therapeutics and vaccines. This review will consolidate mutations in different SARS-CoV-2 proteins and their implications on viral fitness.
A balance between the synthesis and degradation of active proteins governs diverse cellular processes in plants, spanning from cell‐cycle progression and circadian rhythm to the outcome of several hormone signalling pathways. Ubiquitin‐mediated post‐translational modification determines the degradative fate of the target proteins, thereby altering the output of cellular processes. An equally important, and perhaps under‐appreciated, aspect of this pathway is the antagonistic process of de‐ubiquitination. De‐ubiquitinases (DUBs), a group of processing enzymes, play an important role in maintaining cellular ubiquitin homeostasis by hydrolyzing ubiquitin poly‐proteins and free poly‐ubiquitin chains into mono‐ubiquitin. Further, DUBs rescue the cellular proteins from 26S proteasome‐mediated degradation to their active form by cleaving the poly‐ubiquitin chain from the target protein. Any perturbation in DUB activity is likely to affect proteostasis and downstream cellular processes. This review illustrates recent findings on the biological significance and mechanisms of action of the DUBs in Arabidopsis thaliana, with an emphasis on ubiquitin‐specific proteases (UBPs), the largest family among the DUBs. We focus on the putative roles of various protein–protein interaction interfaces in DUBs and their generalized function in ubiquitin recycling, along with their pre‐eminent role in plant development.
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