7 research outputs found
Structural analysis and molecular dynamics simulation studies of HIV-1 antisense protein predict its potential role in HIV replication and pathogenesis
The functional significance of the HIV-1 Antisense Protein (ASP) has been a paradox since its discovery. The expression of this protein in HIV-1-infected cells and its involvement in autophagy, transcriptional regulation, and viral latency have sporadically been reported in various studies. Yet, the definite role of this protein in HIV-1 infection remains unclear. Deciphering the 3D structure of HIV-1 ASP would throw light on its potential role in HIV lifecycle and host-virus interaction. Hence, using extensive molecular modeling and dynamics simulation for 200 ns, we predicted the plausible 3D-structures of ASP from two reference strains of HIV-1 namely, Indie-C1 (subtype-C) and NL4-3 (subtype-B) so as to derive its functional implication through structural domain analysis. In spite of sequence and structural differences in subtype B and C ASP, both structures appear to share common domains like the Von Willebrand Factor Domain-A (VWFA), Integrin subunit alpha-X (ITGSX), and ETV6-Transcriptional repressor, thereby reiterating the potential role of HIV-1 ASP in transcriptional repression and autophagy, as reported in earlier studies. Gromos-based cluster analysis of the centroid structures also reassured the accuracy of the prediction. This is the first study to elucidate a highly plausible structure for HIV-1 ASP which could serve as a feeder for further experimental validation studies
Free-living, psychrotrophic bacteria of the genus Psychrobacter are descendents of pathobionts
Host-adapted microorganisms are generally assumed to have evolved
from free-living, environmental microorganisms, as examples of the reverse process
are rare. In the phylum Gammaproteobacteria, family Moraxellaceae, the genus
Psychrobacter includes strains from a broad ecological distribution including animal
bodies as well as sea ice and other nonhost environments. To elucidate the relationship
between these ecological niches and Psychrobacter’s evolutionary history, we
performed tandem genomic analyses with phenotyping of 85 Psychrobacter accessions.
Phylogenomic analysis of the family Moraxellaceae reveals that basal members of
the Psychrobacter clade are Moraxella spp., a group of often-pathogenic organisms.
Psychrobacter exhibited two broad growth patterns in our phenotypic screen: one group
that we called the “flexible ecotype” (FE) had the ability to grow between 4 and 37°C,
and the other, which we called the “restricted ecotype” (RE), could grow between 4 and
25°C. The FE group includes phylogenetically basal strains, and FE strains exhibit
increased transposon copy numbers, smaller genomes, and a higher likelihood to be
bile salt resistant. The RE group contains only phylogenetically derived strains and has
increased proportions of lipid metabolism and biofilm formation genes, functions that
are adaptive to cold stress. In a 16S rRNA gene survey of polar bear fecal samples, we
detect both FE and RE strains, but in in vivo colonizations of gnotobiotic mice, only FE
strains persist. Our results indicate the ability to grow at 37°C, seemingly necessary for
mammalian gut colonization, is an ancestral trait for Psychrobacter, which likely evolved
from a pathobiont
Data_Sheet_1_Structural analysis and molecular dynamics simulation studies of HIV-1 antisense protein predict its potential role in HIV replication and pathogenesis.docx
The functional significance of the HIV-1 Antisense Protein (ASP) has been a paradox since its discovery. The expression of this protein in HIV-1-infected cells and its involvement in autophagy, transcriptional regulation, and viral latency have sporadically been reported in various studies. Yet, the definite role of this protein in HIV-1 infection remains unclear. Deciphering the 3D structure of HIV-1 ASP would throw light on its potential role in HIV lifecycle and host-virus interaction. Hence, using extensive molecular modeling and dynamics simulation for 200 ns, we predicted the plausible 3D-structures of ASP from two reference strains of HIV-1 namely, Indie-C1 (subtype-C) and NL4-3 (subtype-B) so as to derive its functional implication through structural domain analysis. In spite of sequence and structural differences in subtype B and C ASP, both structures appear to share common domains like the Von Willebrand Factor Domain-A (VWFA), Integrin subunit alpha-X (ITGSX), and ETV6-Transcriptional repressor, thereby reiterating the potential role of HIV-1 ASP in transcriptional repression and autophagy, as reported in earlier studies. Gromos-based cluster analysis of the centroid structures also reassured the accuracy of the prediction. This is the first study to elucidate a highly plausible structure for HIV-1 ASP which could serve as a feeder for further experimental validation studies.</p
Statement in Support of: “Virology under the Microscope—a Call for Rational Discourse”
[Extract] We, members of the Australasian Virology Society, agree with and support the statement entitled “Virology under the Microscope—a Call for Rational Discourse” (1). Like virologists everywhere, we have worked with scientist and clinician colleagues worldwide to develop knowledge, tests, and interventions which collectively have reduced the number of deaths due to COVID-19 and curtailed its economic impact. Such work adds to the extraordinary achievements resulting from virology research that have delivered vaccines and/or antivirals against a long list of diseases and global scourges, including AIDS, smallpox, and polio (1).
We believe the question of the origin of SARS-CoV-2 should be approached with an open mind and in consideration of the best scientific evidence available. We concur with the view that the zoonosis hypothesis has the strongest supporting evidence (2–4), and this is a scenario that has been observed repeatedly in the past (5), including in Australia (6). Recent data strongly support the zoonosis hypothesis (7). We share the concern that emotive and fear-based dialogues in this area add to public confusion and can lead to ill-informed condemnation of virology research