Massimo Caputi

hnRNP A1: the Swiss army knife of gene expression.

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.

A Bidirectional SF2/ASF- and SRp40-Dependent Splicing Enhancer Regulates Human Immunodeficiency Virus Type 1 rev, env, vpu, and nef Gene Expression

ABSTRACT The integrated human immunodeficiency virus type 1 (HIV-1) genome is transcribed in a single pre-mRNA that is alternatively spliced into more than 40 mRNAs. We characterized a novel bidirectional exonic splicing enhancer (ESE) that regulates the expression of the HIV-1 env, vpu, rev, and nef mRNAs. The ESE is localized downstream of the vpu-, env-, and nef-specific 3′ splice site no. 5. SF2/ASF and SRp40 activate the ESE and are required for efficient 3′ splice site usage and binding of the U1 snRNP to the downstream 5′ splice site no. 4. U1 snRNP binding to the 5′ splice site no. 4 is required for splicing of the rev and nef mRNAs and to increase expression of the partially spliced env mRNA. Finally, our results indicate that this ESE is necessary for the recruitment of the U1 snRNP to the 5′ splice site no. 4, even when the 5′ splice site and the U1 snRNA have been mutated to obtain a perfect complementary match. The ESE characterized here is highly conserved in most viral subtypes.

Role of Cellular RNA Processing Factors in Human Immunodeficiency Virus Type 1 mRNA Metabolism, Replication, and Infectivity

ABSTRACT Expression of the human immunodeficiency virus type 1 genome requires several cellular factors regulating transcription, alternative splicing, RNA stability, and intracellular localization of the viral transcripts. In vitro and ex vivo approaches have identified SR proteins and hnRNPs of the A/B and H subfamilies as cellular factors that regulate different aspects of viral mRNA metabolism. To understand the role of these protein families within the context of the full replicating virus, we altered the expression levels of hnRNPs H, F, 2H9, GRSF1, A1, A2, and A3 and SR proteins SC35, SF2, and SRp40 in HEK 293 cells transfected with the proviral clone pNL4-3. Quantitative and semiquantitative PCR analyses showed that overexpression as well as downregulation of these proteins disrupted the balance of alternatively spliced viral mRNAs and may alter viral transcription. Furthermore, expression of hnRNPs H, F, 2H9, A1, and A2 and SR proteins SF2 and SRp40 increased nuclear localization of the unspliced Gag/Pol mRNA, while the same factors increased the cytoplasmic localization of the partially spliced Env mRNA. We also report that overexpression of hnRNPs A1 and A2 and SR proteins SF2, SC35, and SRp40 causes a dramatic decrease in virion production. Finally, utilizing a reporter TZM-bl cell line, we show that virion infectivity may be also impacted by deregulation of expression of most SR proteins and hnRNPs. This work demonstrates that cellular factors regulating mRNA processing have wide-ranging effects on human immunodeficiency virus type 1 replication and should be considered novel therapeutic targets.

The Secondary Structure of the Human Immunodeficiency Virus Type 1 Transcript Modulates Viral Splicing and Infectivity

ABSTRACT Splicing of human immunodeficiency virus type 1 (HIV-1) exon 6D is regulated by the presence of a complex splicing regulatory element (SRE) sequence that interacts with the splicing factors hnRNP H and SC35. In this work, we show that, in the context of the wild-type viral sequence, hnRNP H acts as a repressor of exon 6D inclusion independent of its binding to the SRE. However, hnRNP H binding to the SRE acts as an enhancer of exon 6D inclusion in the presence of a critical T-to-C mutation. These seemingly contrasting functional properties of hnRNP H appear to be caused by a change in the RNA secondary structure induced by the T-to-C mutation that affects the spatial location of bound hnRNP H with respect to the exon 6D splicing determinants. We propose a new regulatory mechanism mediated by RNA folding that may also explain the dual properties of hnRNP H in splicing regulation.

Chimeric peptide nucleic acid compounds modulate splicing of the bcl-x gene in vitro and in vivo

Alternative splicing of the bcl-x gene generates two transcripts: the anti-apoptotic bcl-xL isoform and the pro-apoptotic bcl-xS isoform. The ratio between the two isoforms is a key factor in development and in cancer progression. Here, we show that a short antisense chimeric peptide nucleic acid (PNA) oligonucleotide conjugated to a polypeptide containing eight Ser-Arg repeats (SR)8 can modulate splicing of bcl-x both in vitro and in vivo and induces apoptosis in HeLa cells. The PNA-SR oligo was targeted to a region of bcl-x that does not contain splicing regulatory sequences and was able to override the complex network of splicing enhancers and silencers that regulates the ratio between the two bcl-x isoforms. Thus, PNA-SR oligos are powerful tools that can potentially modulate splice site choice in endogenous genes independent of the presence of other splicing regulatory mechanisms on the target gene.

In vivo detection of RNA-binding protein interactions with cognate RNA sequences by fluorescence resonance energy transfer

Expression of the nascent RNA transcript is regulated by its interaction with a number of proteins. The misregulation of such interactions can often result in impaired cellular functions that can lead to cancer and a number of diseases. Thus, our understanding of RNA-protein interactions within the cellular context is essential for the development of novel diagnostic and therapeutic tools. While there are many in vitro methods that analyze RNA-protein interactions in vivo approaches are scarce. Here we established a method based on fluorescence resonance energy transfer (FRET), which we term RNA-binding mediated FRET (RB-FRET), which determines RNA-protein interaction inside cells and tested it on hnRNP H protein binding to its cognate RNA. Using two different approaches, we provide evidence that RB-FRET is sensitive enough to detect specific RNA-protein interactions in the cell, providing a powerful tool to study spatial and temporal localization of specific RNA-protein complexes.

HIV-1 transcription is regulated by splicing factor SRSF1

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.

Bipartite functions of the CREB co-activators selectively direct alternative splicing or transcriptional activation

The CREB regulated transcription co‐activators (CRTCs) regulate many biological processes by integrating and converting environmental inputs into transcriptional responses. Although the mechanisms by which CRTCs sense cellular signals are characterized, little is known regarding how CRTCs contribute to the regulation of cAMP inducible genes. Here we show that these dynamic regulators, unlike other co‐activators, independently direct either pre‐mRNA splice‐site selection or transcriptional activation depending on the cell type or promoter context. Moreover, in other scenarios, the CRTC co‐activators coordinately regulate transcription and splicing. Mutational analyses showed that CRTCs possess distinct functional domains responsible for regulating either pre‐mRNA splicing or transcriptional activation. Interestingly, the CRTC1–MAML2 oncoprotein lacks the splicing domain and is incapable of altering splice‐site selection despite robustly activating transcription. The differential usage of these distinct domains allows CRTCs to selectively mediate multiple facets of gene regulation, indicating that co‐activators are not solely restricted to coordinating alternative splicing with increase in transcriptional activity.

SRSF1 RNA Recognition Motifs Are Strong Inhibitors of HIV-1 Replication

ABSTRACT 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. IMPORTANCE Most 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.

Tat is a multifunctional viral protein that modulates cellular gene expression and functions

The human immunodeficiency virus type I (HIV-1) has developed several strategies to condition the host environment to promote viral replication and spread. Viral proteins have evolved to perform multiple functions, aiding in the replication of the viral genome and modulating the cellular response to the infection. Tat is a small, versatile, viral protein that controls transcription of the HIV genome, regulates cellular gene expression and generates a permissive environment for viral replication by altering the immune response and facilitating viral spread to multiple tissues. Studies carried out utilizing biochemical, cellular, and genomic approaches show that the expression and activity of hundreds of genes and multiple molecular networks are modulated by Tat via multiple mechanisms.