Eukaryotic cells express a large variety of RNA binding proteins (RBPs), with diverse affinities and specificities towards target RNAs. These proteins play a crucial role in almost every aspect of RNA biogenesis, expression and function. The heterogeneous nuclear ribonucleoproteins (hnRNPs) are a complex and diverse family of RNA binding proteins. hnRNPs display multiple functions in the processing of heterogeneous nuclear RNAs into mature messenger RNAs. hnRNP A1 is one of the most abundant and ubiquitously expressed members of this protein family. hnRNP A1 plays multiple roles in gene expression by regulating major steps in the processing of nascent RNA transcripts. The transcription, splicing, stability, export through nuclear pores and translation of cellular and viral transcripts are all mechanisms modulated by this protein. The diverse functions played by hnRNP A1 are not limited to mRNA biogenesis, but extend to the processing of microRNAs, telomere maintenance and the regulation of transcription factor activity. Genomic approaches have recently uncovered the extent of hnRNP A1 roles in the development and differentiation of living organisms. The aim of this review is to highlight recent developments in the study of this protein and to describe its functions in cellular and viral gene expression and its role in human pathologies.
Efficient transcription of the HIV-1 genome is regulated by Tat, which recruits P-TEFb from the 7SK small nuclear ribonucleoprotein (snRNP) and other nucleoplasmic complexes to phosphorylate RNA polymerase II and other factors associated with the transcription complex. Although Tat activity is dependent on its binding to the viral TAR sequence, little is known about the cellular factors that might also assemble onto this region of the viral transcript. Here, we report that the splicing factor SRSF1 (SF2/ASF) and Tat recognize overlapping sequences within TAR and the 7SK RNA. SRSF1 expression can inhibit Tat transactivation by directly competing for its binding to TAR. Additionally, we provide evidence that SRSF1 can increase the basal level of viral transcription in the absence of Tat. We propose that SRSF1 activates transcription in the early stages of viral infection by recruiting P-TEFb to TAR from the 7SK snRNP. Whereas in the later stages, Tat substitutes for SRSF1 by promoting release of the stalled polymerase and more efficient transcriptional elongation.
Replication of the integrated HIV-1 genome is tightly regulated by a series of cellular factors. In previous work we showed that transactivation of the HIV-1 promoter is regulated by the cellular splicing factor SRSF1. Here we report that SRSF1 can downregulate the replication of B, C, and D subtype viruses by >200-fold in a cell culture system. We show that viral transcription and splicing are inhibited by SRSF1 expression. Furthermore, SRSF1 deletion mutants containing the protein RNA-binding domains but not the arginine serine-rich activator domain can downregulate viral replication by >2,000-fold with minimal impact on cell viability and apoptosis. These data suggest a therapeutic potential for SRSF1 and its RNA-binding domains. IMPORTANCEMost drugs utilized to treat the HIV-1 infection are based on compounds that directly target proteins encoded by the virus. However, given the high viral mutation rate, the appearance of novel drug-resistant viral strains is common. Thus, there is a need for novel therapeutics with diverse mechanisms of action. In this study, we show that the cellular protein SRSF1 is a strong inhibitor of viral replication. Furthermore, expression of the SRSF1 RNA-binding domains alone can inhibit viral replication by >2,000-fold in multiple viral strains without impacting cell viability. Given the strong antiviral properties of this protein, the RNA-binding domains, and the minimal effects observed on cell metabolism, further studies are warranted to assess the therapeutic potential of peptides derived from these sequences. Replication of the integrated HIV-1 genome is tightly regulated by a combination of host and viral factors. Interactions between viral sequences and cellular and viral proteins are required to express the viral genome, and alteration of the mechanisms regulating transcription, splicing, and export of the viral transcripts can dramatically affect HIV-1 infectivity and pathogenesis (1-3).The integrated provirus is transcribed into a single pre-mRNA from a promoter located within the 5= long terminal repeat (LTR) of the viral genome through RNA polymerase II (RNAP II) and a combination of basal and promoter specific factors (1). The viral protein, Tat, stimulates transcription elongation by binding to a structured RNA element (transactivation responsive region [TAR]), located at the 5= ends of all nascent HIV-1 transcripts (4, 5) and triggering the recruitment of the P-TEFb complex. The P-TEFb complex is composed of cellular cyclin T1 and the cyclindependent kinase 9. P-TEFb activates viral transcription by promoting the release of the NELF and DRB sensitivity-inducing factor transcriptional pausing complex (6, 7) and phosphorylation of the C-terminal domain of RNAP II to facilitate elongation of the viral transcript (8, 9).The single viral transcript undergoes a complex series of splicing events to generate over 40 mRNA isoforms; thus, the same viral protein is encoded by multiple mRNAs that vary for their 5= and 3= untranslated regions (10). Spliced viral mRNAs ...
Heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1) is one of the most abundant RNA binding proteins. hnRNP A1 is localized prevalently in the nucleus but it can relocate to the cytoplasm in response to specific stimuli shuttling between nuclear and cytoplasmic compartments. The cellular localization of this protein is regulated by a short C-terminus motif (M9) and other less defined sequences. The RNA binding specificity of this protein is dependent on multiple RNA binding domains (RBDs), which regulate its role in RNA processing and expression. hnRNP A1 plays multiple roles in gene expression by regulating the biogenesis and translation of messengers RNAs, the processing of miRNAs, affecting transcription and controlling telomere maintenance. The multiple functions of this protein correlate with diverse roles in genetic disease, cancer and the replication of viral pathogens. Utilizing a tagged hnRNP A1 deletion library we have shown that the three hnRNP A1 RBDs contribute to the prevalent nuclear distribution of the protein. Our data also indicate that a truncated form of the protein, lacking one of the RBDs, the RGG-box, can regulate splicing of a splicing reporter minigene and down-regulate replication of the HIV-1 virus with efficiency comparable to the wild type protein. This functional hnRNP A1 deletion mutant is similar to a predicted hnRNP A1 isoform, which had not been previously experimentally characterized.
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