The human Respiratory Syncytial Virus (hRSV) is the main responsible for occurrences of respiratory diseases as pneumonia and bronchiolitis in children and elderly. M2-1 protein from hRSV is an important antitermination factor for transcription process that prevents the premature dissociation of the polymerase complex, making it a potential target for developing of inhibitors of the viral replication. The present study reports the interaction of the M2-1 tetramer with pera (Q1) and tetracetylated (Q2) quercetin derivatives, which were synthesized with the objective of generating stronger bioactive compounds against oxidation process. Fluorescence experiments showed binding constants of the M2-1/compounds complexes on order of 10M with one ligand per monomeric unit, being the affinity of Q2 stronger than Q1. The thermodynamic analysis revealed values of ΔH>0 and ΔS>0, suggesting that hydrophobic interactions play a key role in the formation of the complexes. Molecular docking calculations indicated that binding sites for the compounds are in contact interfaces between globular and zinc finger domains of the monomers and that hydrogen bonds and stacking interactions are important contributions for stabilization of the complexes. Thus, the interaction of the acetylated quercetin derivatives in the RNA-binding sites of M2-1 makes these potential candidates for viral replication inhibitors.
The human Respiratory Syncytial Virus (hRSV) M2-1 protein functions as a processivity and antitermination factor of the viral polymerase complex. Here it is presented the first evidence that hRSV M2-1 core domain (cdM2-1) alone has an unfolding activity for long RNAs, as well as a biophysical and dynamic characterization of the cdM2-1/RNA complex. The main contact region of cdM2-1 with RNA was the α1–α2–α5–α6 helix bundle, which suffered local conformational changes and promoted the RNA unfolding activity. This activity may be triggered by base-pairing recognition. RNA molecules wrap around the whole cdM2-1, protruding their terminals over the domain. The α2–α3 and α3–α4 loops of cdM2-1 were marked by an increase in picosecond internal motions upon RNA binding even though they are not directly involved in the interaction. The results revealed that the cdM2-1/RNA complex originates from a fine-tuned binding, contributing to unraveling interaction aspects necessary to M2-1 activity.
IMPORTANCE The main outcome is the molecular description of a fine-tuned binding of the cdM2-1/RNA complex and the evidence that the domain alone has an unfolding activity for long RNAs. This binding mode is essential in the understanding of the function in the full-length protein. Orthopneumovirus, as the human Respiratory Syncytial Virus (hRSV), stands out for the unique role of M2-1 as a transcriptional antitermination factor able to increase the RNA polymerase processivity.
The eukaryotic translation initiation factor 3, subunit L (eIF3L) is one of the subunits of the eIF3 complex, an accessory protein of the Polymerase I enzyme and may have an important role in the Flavivirus replication by interaction with a viral non-structural 5 protein. Considering the importance of eIF3L in a diversity of cellular functions, we have produced the recombinant full-length eIF3L protein in Escherichia coli and performed spectroscopic and in silico analyses to gain insights into its hydrodynamic behavior and structure. Dynamic light scattering showed that eIF3L behaves as monomer when it is not interacting with other molecular partners. Circular dichroism experiments showed a typical spectrum of α-helical protein for eIF3L, which is supported by sequence-based predictions of secondary structure and the 3D in silico model. The molecular docking with the K subunit of the eIF3 complex revealed a strong interaction. It was also predicted several potential interaction sites in eIF3L, indicating that the protein is likely capable of interacting with other molecules as experimentally shown in other functional studies. Moreover, bioinformatics analyses showed approximately 8 putative phosphorylation sites and one possible N-glycosylation site, suggesting its regulation by post-translational modifications. The production of the eIF3L protein in E. coli and structural information gained in this study can be instrumental for target-based drug design and inhibitors against Flavivirus replication and to shed light on the molecular mechanisms involved in the eukaryotic translation initiation.
The human Respiratory Syncytial Virus (hRSV) M2-1 protein functions as a processivity and antitermination factor of the viral polymerase complex. Here it is presented the first evidence that hRSV M2-1 core domain (cdM2-1) alone has an unfolding activity for long RNAs, as well as a biophysical and dynamic characterization of the cdM2-1/RNA complex. The main contact region of cdM2-1 with RNA was the α1–α2–α5–α6 helix bundle, which suffered local conformational changes and promoted the RNA unfolding activity. This activity may be triggered by base-pairing recognition. RNA molecules wrap around the whole cdM2-1, protruding their terminals over the domain. The α2–α3 and α3–α4 loops of cdM2-1 were marked by an increase in picosecond internal motions upon RNA binding even though they are not directly involved in the interaction. The results revealed that the cdM2-1/RNA complex originates from a fine-tuned binding, contributing to unraveling interaction aspects necessary to M2-1 activity.IMPORTANCEThe main outcome is the molecular description of a fine-tuned binding of the cdM2-1/RNA complex and the evidence that the domain alone has an unfolding activity for long RNAs. This binding mode is essential in the understanding of the function in the full-length protein. Orthopneumovirus, as the human Respiratory Syncytial Virus (hRSV), stands out for the unique role of M2-1 as a transcriptional antitermination factor able to increase the RNA polymerase processivity.
Mayaro virus is a neglected virus that causes a mild, dengue-like febrile syndrome characterized by fever, headache, rash, retro-orbital pain, vomiting, diarrhea, articular edemas, myalgia, and severe arthralgia, symptoms which may persist for months and become very debilitating. Though the virus is limited to forest areas and is most frequently transmitted by Haemagogus mosquitoes, Aedes mosquitoes can also transmit this virus and, therefore, it has the potential to spread to urban areas. This study focuses on the metabolic foot-printing of Vero cells infected with the Mayaro virus. Nuclear magnetic resonance combined with multivariate analytical methods and pattern recognition tools found that metabolic changes can be attributed to the effects of Mayaro virus infection on cell culture. The results suggest that several metabolite levels vary in infection conditions at different time points. There were important differences between the metabolic profile of non-infected and Mayaro-infected cells. These organic compounds are metabolites involved in the glycolysis pathway, the tricarboxylic acid cycle, the pentose phosphate pathway, and the oxidation pathway of fatty acids (via β-oxidation). This exometabolomic study has generated a biochemical profile reflecting the progressive cytopathological metabolic alterations induced by Mayaro virus replication in the cells and can contribute to the knowledge of the molecular mechanisms involved in viral pathogenesis.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.