Despite an unprecedented global gain in knowledge since the emergence of SARS-CoV-2, almost all mechanistic knowledge related to the molecular and cellular details of viral replication, pathology and virulence has been generated using early prototypic isolates of SARS-CoV-2. Here, using atomic force microscopy and molecular dynamics, we investigated how these mutations quantitatively affected the kinetic, thermodynamic and structural properties of RBD—ACE2 complex formation. We observed for several variants of concern a significant increase in the RBD—ACE2 complex stability. While the N501Y and E484Q mutations are particularly important for the greater stability, the N501Y mutation is unlikely to significantly affect antibody neutralization. This work provides unprecedented atomistic detail on the binding of SARS-CoV-2 variants and provides insight into the impact of viral mutations on infection-induced immunity.
Light-induced oxidative damage of DNA by 1 O 2 generated from photoexcited C 60 was observed at the single-molecule level by atomic force microscopy (AFM) imaging. Two types of DNA origami with uniform morphologies were immobilized on a mica surface and used as DNA substrates. Upon visible light irradiation (528 nm) in the presence of a C 60 aqueous solution, the morphology changes of DNA origami substrates were observed by time-lapse AFM imaging at the single-molecule level by tracking a discrete DNA molecule. The origami showed nicked and flattened morphologies with relaxed features caused by the covalent cleavage of the DNA strands. The involvement of 1 O 2 in the on-surface DNA damage was clearly confirmed by AFM experiments in the presence of a 1 O 2 quencher and ESR measurements with a spintrapping agent for 1 O 2 . This study is the first example of single-molecule observation of oxidative damage of DNA by AFM with corresponding morphology changes in a photocontrolled and time-dependent manner by 1 O 2 generated catalytically from photoexcited C 60 .
Bacteriophages are being considered as a promising natural resource for the development of alternative strategies against mycobacterial diseases, especially in the context of the wide-spread occurrence of drug resistance among the clinical isolates of Mycobacterium tuberculosis. However, there is not much information documented on mycobacteriophages from India. Here, we report the isolation of 17 mycobacteriophages using Mycobacterium smegmatis as the bacterial host, where 9 phages also lyse M. tuberculosis H37Rv. We present detailed analysis of one of these mycobacteriophages - PDRPv. Transmission electron microscopy and polymerase chain reaction analysis (of a conserved region within the TMP gene) show PDRPv to belong to the Siphoviridae family and B1 subcluster, respectively. The genome (69 110 bp) of PDRPv is circularly permuted double-stranded DNA with ∼66% GC content and has 106 open reading frames (ORFs). On the basis of sequence similarity and conserved domains, we have assigned function to 28 ORFs and have broadly categorized them into 6 groups that are related to replication and genome maintenance, DNA packaging, virion release, structural proteins, lysogeny-related genes and endolysins. The present study reports the occurrence of novel antimycobacterial phages in India and highlights their potential to contribute to our understanding of these phages and their gene products as potential antimicrobial agents.
The low-density lipoprotein (LDL)-mimetic lipid nanoparticles (LNPs), decorated with MRI contrast agents, and fluorescent dyes, were prepared by the covalent attachment of apolipoprotin-mietic peptide (P), Gd(III)-chelate (Gd), and sulforhodamine B...
Despite intense scrutiny throughout the pandemic, development of efficacious drugs
against SARS-CoV-2 spread remains hindered. Understanding the underlying mechanisms of
viral infection is fundamental for developing novel treatments. While angiotensin
converting enzyme 2 (ACE2) is accepted as the key entry receptor of the virus, other
infection mechanisms exist. Dendritic cell-specific intercellular adhesion molecule-3
grabbing non-integrin (DC-SIGN) and its counterpart DC-SIGN-related (DC-SIGNR, also
known as L-SIGN) have been recognized as possessing functional roles in COVID-19 disease
and binding to SARS-CoV-2 has been demonstrated previously with ensemble and qualitative
techniques. Here we examine the thermodynamic and kinetic parameters of the
ligand–receptor interaction between these C-type lectins and the SARS-CoV-2 S1
protein using force–distance curve-based AFM and biolayer interferometry. We
evidence that the S1 receptor binding domain is likely involved in this bond formation.
Further, we employed deglycosidases and examined a nonglycosylated S1 variant to confirm
the significance of glycosylation in this interaction. We demonstrate that the high
affinity interactions observed occur through a mechanism distinct from that of ACE2.
Understanding biological interactions at a molecular-level grants valuable information relevant to improving medical treatments and outcomes. Among the suite of technologies available, Atomic Force Microscopy (AFM) is unique in its...
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