Felix Filatov scite author profile

We describe a novel microarray-based approach for simultaneous identification and quantification of human immunodeficiency virus type 1 (HIV-1) and hepatitis B and C viruses (HBV and HCV) in donor plasma specimens. The method is based on multiplex real-time RT-PCR performed within the microarray hydrogel pads. Double-stranded amplification products are simultaneously detected using nonspecific SYBR Green I dye due to the reaction run in separate pads bearing 5'-immobilized specific primers. Both the sensitivity and specificity of the assay, based on 132 blood specimens analyzed, were 100% (56, 26, and 8 specimens were seropositive to HBV HCV and HIV-1, respectively; 22 were positive to both HIV-1 and HCV and 2 positive to all three viruses; 18 samples were pathogen-negative). The dynamic range of the quantitative analysis covered a six-order interval ranging from 100 to 106 genome equivalents per assay. The 95% detection limits were 14 gEq for HIV-1, 10 gEq (1.7 IU) for HBV, and 15 gEq (7.5 IU) for HCV per assay. The proposed approach is considered to be versatile and could be adapted for simultaneous identification and quantification of numerous genetic targets.

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Colocalization of the Herpes Simplex Virus 1 U _L 4 Protein with Infected Cell Protein 22 in Small, Dense Nuclear Structures Formed prior to Onset of DNA Synthesis

Jahedi

Markovitz

Filatov

et al. 1999

J Virol

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Herpes simplex virus 1 infected cell protein 22 (ICP22) localizes in small, dense nuclear bodies of primate cells early in infection and in the more diffuse replicative complexes after the onset of DNA synthesis. U L 4, a ␥ 2 protein, localizes in cytoplasm and in the small nuclear structures containing ICP22 but not in replicative complexes. In rabbit skin cells, both ICP22 and U L 4 localize in the dense nuclear bodies late in infection. The results suggest that the small nuclear structures perform a function involving both proteins late in infection.

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Viral component of the human genome

et al. 2017

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⎯Relationships between viruses and their human host are traditionally described from the point of view taking into consideration hosts as victims of viral aggression, which results in infectious diseases. However, these relations are in fact two-sided and involve modifications of both the virus and host genomes. Mutations that accumulate in the populations of viruses and hosts may provide them advantages such as the ability to overcome defense barriers of host cells or to create more efficient barriers to deal with the attack of the viral agent. One of the most common ways of reinforcing anti-viral barriers is the horizontal transfer of viral genes into the host genome. Within the host genome, these genes may be modified and extensively expressed to compete with viral copies and inhibit the synthesis of their products or modulate their functions in other ways. This review summarizes the available data on the horizontal gene transfer between viral and human genomes and discusses related problems.

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How many antiviral small interfering RNAs may be encoded by the mammalian genomes?

et al. 2010

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BackgroundThe discovery of RNA interference phenomenon (RNAi) and understanding of its mechanisms has revolutionized our views on many molecular processes in the living cell. Among the other, RNAi is involved in silencing of transposable elements and in inhibition of virus infection in various eukaryotic organisms. Recent experimental studies demonstrate few cases of viral replication suppression via complementary interactions between the mammalian small RNAs and viral transcripts.Presentation of the hypothesisIt was found that >50% of the human genome is transcribed in different cell types and that these transcripts are mainly not associated with known protein coding genes, but represent non-coding RNAs of unknown functions. We propose a hypothesis that mammalian DNAs encode thousands RNA motifs that may serve for antiviral protection. We also presume that the evolutional success of some groups of genomic repeats and, in particular, of transposable elements (TEs) may be due to their ability to provide antiviral RNA motifs to the host organism. Intense genomic repeat propagation into the genome would inevitably cause bidirectional transcription of these sequences, and the resulting double-stranded RNAs may be recognized and processed by the RNA interference enzymatic machinery. Provided that these processed target motifs may be complementary to viral transcripts, fixation of the repeats into the host genome may be of a considerable benefit to the host. It fits with our bioinformatical data revealing thousands of 21-28 bp long motifs identical between human DNA and human-pathogenic adenoviral and herpesviral genomes. Many of these motifs are transcribed in human cells, and the transcribed part grows proportionally to their lengths. Many such motifs are included in human TEs. For example, one 23 nt-long motif that is a part of human abundant Alu retrotransposon, shares sequence identity with eight human adenoviral genomes.Testing the hypothesisThis hypothesis could be tested on various mammalian species and viruses infecting mammalian cells.Implications of the hypothesisThis hypothesis proposes that mammalian organisms may use their own genomes as sources of thousands of putative interfering RNA motifs that can be recruited to repress intracellular pathogens like proliferating viruses.ReviewersThis article was reviewed by Eugene V. Koonin, Valerian V. Dolja and Yuri V. Shpakovski.

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Felix Filatov

An Oligonucleotide Microarray for Multiplex Real-Time PCR Identification of HIV-1, HBV, and HCV

Colocalization of the Herpes Simplex Virus 1 U _L 4 Protein with Infected Cell Protein 22 in Small, Dense Nuclear Structures Formed prior to Onset of DNA Synthesis

Viral component of the human genome

How many antiviral small interfering RNAs may be encoded by the mammalian genomes?

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Resources

About

Felix Filatov

An Oligonucleotide Microarray for Multiplex Real-Time PCR Identification of HIV-1, HBV, and HCV

Colocalization of the Herpes Simplex Virus 1 U L 4 Protein with Infected Cell Protein 22 in Small, Dense Nuclear Structures Formed prior to Onset of DNA Synthesis

Viral component of the human genome

How many antiviral small interfering RNAs may be encoded by the mammalian genomes?

Contact Info

Product

Resources

About

Colocalization of the Herpes Simplex Virus 1 U _L 4 Protein with Infected Cell Protein 22 in Small, Dense Nuclear Structures Formed prior to Onset of DNA Synthesis