Restriction of HIV-1 and other retroviruses by TRIM5.

Mammalian cells express a variety of innate immune proteins - known as restriction factors - which defend against invading retroviruses such as HIV-1. Two members of the tripartite motif protein family - TRIM5α and TRIMCyp - were identified in 2004 as restriction factors that recognize and inactivate the capsid shell that surrounds and protects the incoming retroviral core. Research on these TRIM5 proteins has uncovered a novel mode of non-self recognition that protects against cross-species transmission of retroviruses. Our developing understanding of the mechanism of TRIM5 restriction underscores the concept that core uncoating and reverse transcription of the viral genome are coordinated processes rather than discrete steps of the post-entry pathway of retrovirus replication. In this Review, we provide an overview of the current state of knowledge of the molecular mechanism of TRIM5-mediated restriction, highlight recent advances and discuss implications for the development of capsid-targeted antiviral therapeutics.

Somatic hypermutation in immunity and cancer: Critical analysis of strand-biased and codon-context mutation signatures.

For 30 years two general mechanisms have competed to explain somatic hypermutation of immunoglobulin (Ig) genes. The first, the DNA-based model, is focused only on DNA substrates. The modern form is the Neuberger "DNA Deamination Model" based on activation-induced cytidine deaminase (AID) and short-patch error-prone DNA repair by DNA Polymerase-η operating around AID C-to-U lesions. The other is an RNA-based mechanism or the "Reverse Transcriptase Model" of SHM which produces strand-biased mutations at A:T and G:C base pairs. This involves error-prone cDNA synthesis via an RNA-dependent DNA polymerase copying the Ig pre-mRNA template and integrating the now error-filled cDNA copy back into the normal chromosomal site. The modern form of this mechanism depends on AID dC-to-dU lesions and long tract error-prone cDNA synthesis of the transcribed strand by DNA Polymerase-η acting as a reverse transcriptase. The evidence for and against each mechanism is critically evaluated. The conclusion is that all the SHM molecular data gathered since 1980 supports directly or indirectly the RNA/RT-based mechanism. All the data and critical analyses are systematically laid out so the reader can evaluate this conclusion for themselves. Recently we have investigated whether similar RNA/RT-based mutator mechanisms explain how de novo mutations arise in somatic tissues (cancer genomes). The data analyses indeed suggest that cancers arise via dysregulated "Ig-like SHM responses" involving rogue DNA and RNA deaminations coupled to genome-wide RT events. Further, Robyn Lindley has recently shown that the strand-biased mutations in cancer genome genes are also in "codon-context." This has been termed Targeted Somatic Mutation (TSM) to highlight that mutations are far more targeted than previously thought in somatic tissues associated with disease. The TSM process implies an "in-frame DNA reader" whereby DNA and RNA deaminases at transcribed regions are guided in their mutagenic action, by the codon reading frame of the DNA.

Fusion of cyclophilin A to Fv1 enables cyclosporine-sensitive restriction of human and feline immunodeficiency viruses.

TRIM5alpha is a potent intracellular antiviral restriction factor governing species-specific retroviral replication. In the New World species owl monkey the coding region for the viral binding B30.2 domain of TRIM5alpha has been replaced by a cyclophilin A (CypA) pseudogene by retrotransposition. The resultant TRIM5-CypA fusion protein restricts human immunodeficiency virus type 1 (HIV-1), as well as feline immunodeficiency virus (FIV), by recruitment of the CypA domain to the incoming viral capsids. Infectivity is rescued by agents such as cyclosporine that disrupt CypA binding to its substrates. Mice encode an antiviral restriction factor called Fv1 (for Friend virus susceptibility gene 1), which is active against murine leukemia virus and related to endogenous gag sequences. Here we show that fusing CypA to Fv1 generates a restriction factor with the antiviral specificity of TRIMCyp but the antiviral properties of Fv1. Like TRIMCyp, Fv1-Cyp restricts HIV-1 and FIV and is sensitive to inhibition by cyclosporine. TRIM5alpha is known to have a short half-life and block infectivity before viral reverse transcription. We show that Fv1-Cyp has a long half-life and blocks after reverse transcription, suggesting that its longer half-life gives the restricted virus the opportunity to synthesize DNA, leading to a later block to infection. This notion is supported by the observation that infectivity of Fv1-Cyp restricted virus can be rescued by cyclosporine for several hours after infection, whereas virus restricted by TRIMCyp is terminally restricted after around 40 min. Intriguingly, the Fv1-Cyp-restricted HIV-1 generates closed circular viral DNA, suggesting that the restricted virus complex enters the nucleus.

[Changes in cellular transcription on terms of the type of proliferative stimulus in immune-reactive lymphocyte cultures]. / Modificari ale transcriptiei celulare în functie de tipul stimulului proliferativ în culturi de limfocite imunreactive.

Transcriptase activities were investigated in cell extracts of human circulating lymphocyte cultures stimulated for proliferation with polyclonal mitogens like PHA, PPD, and endotoxin from Salm. typhimurium S, and also with two polynucleotides. Enzymic activity of the cell extracts was tested differentiatelly for direct (DNA/RNA) and reverse (RNA/DNA) transcription, using appropriate template-primers: activated DAN and poly (dA). r(pU)10 for direct transcription, and poly (rA.rC. rU), poly (dA) x d(pT)10, and poly (rA). d(pT)12-18 for reverse transcription. All lymphoproliferative stimulators are able to enhance simultaneously the cellular mitosis and the direct transcriptase activity in the cell. There is a good correlation between the two effects. Enzyme affinity to natural DNA is higher than to synthetic poly (dA) r(pU)10 PHA, a mitogen for T lymphocyte, enhances the eukaryote type of reverse transcriptase, while among the mitogens for B lymphocyte the PPD enhances an intermediate (viral-eukaryotic) type of reverse transcriptase, and ENDO is not stimulatory for reverse transcription. Duplex polyribonucleotides have an adjuvant activity: they intensify the action of stimulators but they have not a direct enhancing activity. The different transcriptases involved in the lymphocyte differentiation and proliferation may be targets for clinically useful immunosuppressive drugs differentiated for T and B cells.