Your search keyword '"Senkevich TG"' showing total 5 results

1. Exaptation of Inactivated Host Enzymes for Structural Roles in Orthopoxviruses and Novel Folds of Virus Proteins Revealed by Protein Structure Modeling.

Author

Mutz P, Resch W, Faure G, Senkevich TG, Koonin EV, and Moss B

Subjects

Humans, Viral Proteins metabolism, Genes, Viral, Amino Acid Sequence, Orthopoxvirus genetics, Poxviridae genetics

Abstract

Viruses with large, double-stranded DNA genomes captured the majority of their genes from their hosts at different stages of evolution. The origins of many virus genes are readily detected through significant sequence similarity with cellular homologs. In particular, this is the case for virus enzymes, such as DNA and RNA polymerases or nucleotide kinases, that retain their catalytic activity after capture by an ancestral virus. However, a large fraction of virus genes have no readily detectable cellular homologs, meaning that their origins remain enigmatic. We explored the potential origins of such proteins that are encoded in the genomes of orthopoxviruses, a thoroughly studied virus genus that includes major human pathogens. To this end, we used AlphaFold2 to predict the structures of all 214 proteins that are encoded by orthopoxviruses. Among the proteins of unknown provenance, structure prediction yielded clear indications of origin for 14 of them and validated several inferences that were previously made via sequence analysis. A notable emerging trend is the exaptation of enzymes from cellular organisms for nonenzymatic, structural roles in virus reproduction that is accompanied by the disruption of catalytic sites and by an overall drastic divergence that precludes homology detection at the sequence level. Among the 16 orthopoxvirus proteins that were found to be inactivated enzyme derivatives are the poxvirus replication processivity factor A20, which is an inactivated NAD-dependent DNA ligase; the major core protein A3, which is an inactivated deubiquitinase; F11, which is an inactivated prolyl hydroxylase; and more similar cases. For nearly one-third of the orthopoxvirus virion proteins, no significantly similar structures were identified, suggesting exaptation with subsequent major structural rearrangement that yielded unique protein folds. IMPORTANCE Protein structures are more strongly conserved in evolution than are amino acid sequences. Comparative structural analysis is particularly important for inferring the origins of viral proteins that typically evolve at high rates. We used a powerful protein structure modeling method, namely, AlphaFold2, to model the structures of all orthopoxvirus proteins and compared them to all available protein structures. Multiple cases of recruitment of host enzymes for structural roles in viruses, accompanied by the disruption of catalytic sites, were discovered. However, many viral proteins appear to have evolved unique structural folds.

Published

2023

2. Poxvirus multiprotein entry-fusion complex.

Author

Senkevich TG, Ojeda S, Townsley A, Nelson GE, and Moss B

Subjects

Cell Line, Disulfides metabolism, Gene Expression Regulation, Viral, Multiprotein Complexes genetics, Poxviridae genetics, Protein Binding, Protein Subunits genetics, Protein Subunits metabolism, Viral Fusion Proteins genetics, Membrane Fusion, Multiprotein Complexes metabolism, Poxviridae metabolism, Viral Fusion Proteins metabolism

Abstract

Poxviruses have evolved elaborate mechanisms for cell entry, assembly, and exocytosis. Recently, four vaccinia virus membrane proteins, namely A21, A28, H2 and L5, were reported to be necessary for cell entry and virus-induced cell-cell fusion but not for virion morphogenesis or attachment of virus particles to cells. Using immunoaffinity purification followed by mass spectrometry, we now show that these four proteins as well as four additional previously uncharacterized putative membrane proteins (A16, G3, G9, and J5) form a stable complex. These proteins fall into two groups: A21, A28, G3, H2, and L5 have an N-terminal transmembrane domain, 0-2 intramolecular disulfide bonds, and no sequence similarity, whereas A16, G9, and J5 have a C-terminal transmembrane domain and 4-10 predicted disulfide bonds and are homologous. Studies with conditional-lethal null mutants indicated that the viral membrane was crucial for assembly of the complex and that the absence of individual polypeptide components profoundly decreased complex formation or stability, suggesting a complicated interaction network. Analysis of purified virions, however, demonstrated that the polypeptides of the complex trafficked independently to the viral membrane even under conditions in which the complex itself could not be isolated. All eight proteins comprising the entry-fusion complex are conserved in all poxviruses, suggesting that they have nonredundant functions and that the basic entry mechanism evolved before the division between vertebrate and invertebrate poxvirus species.

Published

2005

3. [Search for unique segments of the ectromelia virus genome by cross blot hybridization with DNA from other orthopoxviruses].

Author

Senkevich TG, Muravnik GL, and Chernos VI

Subjects

Ectromelia virus pathogenicity, Genome, Viral, Virulence genetics, DNA, Viral genetics, Ectromelia virus genetics, Nucleic Acid Hybridization methods, Poxviridae genetics

Abstract

In order to identify ectromelia virus (EMV) genome regions which may contain genes responsible for the specific pathogenicity of this virus, blot cross-hybridization of EMV DNA with those of other orthopoxviruses was performed. Two hybridization schemes were employed: one of them included hybridization of labelled cloned fragments of EMV with digests of other viral DNAs, the other, reciprocal, consisted in hybridization of labelled total DNAs of various orthopoxviruses with digests of the region of EMV DNA adjacent to the right-terminal inverted repeat. It was demonstrated that the counterpart to an approximately 8-kilobase pair portion of EMV genome flanking the inverted repeat could be detected only in the cowpox virus genome but not in the genomes of vaccinia and rabbitpox viruses. XhoI-O and XhoI-K fragments of EMV DNA contained, along with genes found in other poxviruses, certain genes which appeared to be unique for EMV. It is postulated that some of these genes may determine the specific biological properties of EMV, including its pathogenicity for mice.

Published

1992

4. A family of DNA virus genes that consists of fused portions of unrelated cellular genes.

Author

Koonin EV, Senkevich TG, and Chernos VI

Subjects

Amino Acid Sequence, Animals, DNA-Binding Proteins genetics, Drosophila melanogaster, Humans, Molecular Sequence Data, Sequence Homology, Nucleic Acid, Transcription Factors, Zinc Fingers, DNA, Viral genetics, Genes, Viral genetics, Poxviridae genetics

Published

1992

5. Biologic properties and genome structure of the recombinants between ectromelia and rabbitpox viruses.

Author

Chernos VI, Senkevich TG, Chelyapov NV, Antonova TP, Vovk TS, and Mitina IV

Subjects

Animals, Cells, Cultured, Chick Embryo, Cloning, Molecular, Culture Techniques, DNA Restriction Enzymes, DNA, Viral analysis, Ectromelia virus pathogenicity, Fibroblasts, Mice, Rabbits, Transfection, Vaccinia virus pathogenicity, DNA, Recombinant analysis, DNA, Viral genetics, Ectromelia virus genetics, Genes, Viral, Poxviridae genetics, Vaccinia virus genetics

Abstract

Administration of rabbitpox virus (RPV) DNA, cleaved into 2 fragments by SmaI restrictase, into ectromelia virus (EMV)-infected chick fibroblast cells yielded recombinants whose properties were characteristic of both parents. Some recombinants capable of producing RPV-type lesions upon intracutaneous (i.c.) infection of rabbits could also produce EMV-specific lesions upon footpad inoculation of mice. The analysis of some recombinants as well as vaccinia virus strains has shown that the ability of the virus to reproduce when injected into the mouse footpad is a necessary, but not a sufficient condition for production of EMV-type lesions. According to restrictase analysis of recombinant DNA, the genome of recombinants mainly consists of RPV DNA sequences with insertions of small EMV DNA fragments.

Published

1987