Distinct sets of adjacent heterogeneous nuclear ribonucleoprotein (hnRNP) A1/A2 binding sites control 5' splice site selection in the hnRNP A1 mRNA precursor

In the heterogeneous nuclear ribonucleoprotein (hnRNP) A1 pre-mRNA, different regions in the introns flanking alternative exon 7B have been implicated in the production of the A1 and A1B mRNA splice isoforms. Among these, the CE1a and CE4 elements, located downstream of common exon 7 and alternative exon 7B, respectively, are bound by hnRNP A1 to promote skipping of exon 7B in vivo and distal 5' splice site selection in vitro. Here, we report that CE1a is flanked by an additional high affinity A1 binding site (CE1d). In a manner similar to CE1a, CE1d affects 5' splice site selection in vitro. Consistent with a role for hnRNP A1 in the activity of CE1d, a mutation that abrogates A1 binding abolishes distal 5' splice site activation. Moreover, the ability of CE1d to stimulate distal 5' splice site usage is lost in an HeLa extract depleted of hnRNP A/B proteins, and the addition of recombinant A1 restores the activity of CE1d. Notably, distal 5' splice site selection mediated by A1 binding sites is not compromised in an extract prepared from mouse cells that are severely deficient in hnRNP A1 proteins. In this case, we show that hnRNP A2 compensates for the A1 deficiency. Further studies with the CE4 element reveal that it also consists of two distinct portions (CE4m and CE4p), each one capable of promoting distal 5' splice site use in an hnRNP A1-dependent manner. The presence of multiple A1/A2 binding sites downstream of common exon 7 and alternative exon 7B probably plays an important role in maximizing the activity of hnRNP A1/A2 proteins.     

An intron element modulating 5' splice site selection in the hnRNP A1 pre-mRNA interacts with hnRNP A1.

The hnRNP A1 pre-mRNA is alternatively spliced to yield the A1 and A1b mRNAs, which encode proteins differing in their ability to modulate 5' splice site selection. Sequencing a genomic portion of the murine A1 gene revealed that the intron separating exon 7 and the alternative exon 7B is highly conserved between mouse and human. In vitro splicing assays indicate that a conserved element (CE1) from the central portion of the intron shifts selection toward the distal donor site when positioned in between the 5' splice sites of exon 7 and 7B. In vivo, the CE1 element promotes exon 7B skipping. A 17-nucleotide sequence within CE1 (CE1a) is sufficient to activate the distal 5' splice site. RNase T1 protection/immunoprecipitation assays indicate that hnRNP A1 binds to CE1a, which contains the sequence UAGAGU, a close match to the reported optimal A1 binding site, UAGGGU. Replacing CE1a by different oligonucleotides carrying the sequence UAGAGU or UAGGGU maintains the preference for the distal 5' splice site. In contrast, mutations in the AUGAGU sequence activate the proximal 5' splice site. In support of a direct role of the A1-CE1 interaction in 5'-splice-site selection, we observed that the amplitude of the shift correlates with the efficiency of A1 binding. Whereas addition of SR proteins abrogates the effect of CE1, the presence of CE1 does not modify U1 snRNP binding to competing 5' splice sites, as judged by oligonucleotide-targeted RNase H protection assays. Our results suggest that hnRNP A1 modulates splice site selection on its own pre-mRNA without changing the binding of U1 snRNP to competing 5' splice sites.     

Function of conserved domains of hnRNP A1 and other hnRNP A/B proteins.

hnRNP A1 is a pre-mRNA binding protein that antagonizes the alternative splicing activity of splicing factors SF2/ASF or SC35, causing activation of distal 5' splice sites. The structural requirements for hnRNP A1 function were determined by mutagenesis of recombinant human hnRNP A1. Two conserved Phe residues in the RNP-1 submotif of each of two RNA recognition motifs appear to be involved in specific RNA-protein interactions and are essential for modulating alternative splicing. These residues are not required for general pre-mRNA binding or RNA annealing activity. The C-terminal Gly-rich domain is necessary for alternative splicing activity, for stable RNA binding and for optimal RNA annealing activity. hnRNP A1B, which is an alternatively spliced isoform of hnRNP A1 with a longer Gly-rich domain, binds more strongly to pre-mRNA but has only limited alternative splicing activity. In contrast, hnRNP A2 and B1, which have 68% amino acid identity with hnRNP A1, bind more weakly to pre-mRNA and have stronger splice site switching activities than hnRNP A1. We propose that specific combinations of antagonistic hnRNP A/B and SR proteins are involved in regulating alternative splicing of distinct subsets of cellular premRNAs.     

High-affinity hnRNP A1 binding sites and duplex-forming inverted repeats have similar effects on 5' splice site selection in support of a common looping out and repression mechanism

High-affinity binding sites for the hnRNP A1 protein stimulate the use of a distal 5' splice site in mammalian pre-mRNAs. Notably, strong A1-mediated shifts in splice site selection are not accompanied by equivalent changes in the assembly of U1 snRNP-containing complexes on competing 5' splice sites. To explain the above results, we have proposed that an interaction between hnRNP A1 molecules bound to high-affinity sites loops out the internal 5' splice site. Here, we present additional evidence in support of the looping out model. First, replacing A1 binding sites with sequences that can generate a loop through RNA duplex formation activates distal 5' splice site usage in an equivalent manner. Second, increasing the distance between the internal 5' splice site and flanking A1 binding sites does not compromise activation of the distal 5' splice site. Similar results were obtained with pre-mRNAs carrying inverted repeats. Using a pre-mRNA containing only one 5' splice site, we show that splicing is repressed when flanked by two high-affinity A1 binding sites or by inverted repeats, and that inactivation of the internal 5' splice site is sufficient to elicit a strong increase in the use of the distal donor site. Our results are consistent with the view that the binding of A1 to high-affinity sites promotes loop formation, an event that would repress the internal 5' splice site and lead to distal 5' splice site activation.     

RNA binding specificity of hnRNP proteins: a subset bind to the 3'' end of introns.

The binding of hnRNP proteins to pre-mRNAs in nuclear extracts, and as isolated proteins, was studied by using monoclonal antibody immunopurification of hnRNP proteins bound to RNase T1-generated fragments. Several major hnRNP proteins, A1, C and D, bind specifically to the 3' end of introns within a region containing the conserved polypyrimidine stretch between the branch site and the 3' splice site. Mutations which alter the conserved 3' splice site dinucleotide AG strongly impair or abolish the binding of the A1 protein as well as of an anti-Sm reactive component(s) to this region. The A1, C and D proteins do not bind efficiently to fragments of either bacterial RNA or the intronless spliced product (mRNA). The binding of these proteins at the 3' end of the intron does not require addition to the extract of exogenous ATP, but remains after ATP addition. These findings demonstrate that several hnRNP proteins have RNA binding specificities on pre-mRNA, and suggest a model for hnRNP particle structure and assembly.     

A nuclear localization domain in the hnRNP A1 protein

The heterogeneous nuclear RNP (hnRNP) A1 protein is one of the major pre-mRNA/mRNA binding proteins in eukaryotic cells and one of the most abundant proteins in the nucleus. It is localized to the nucleoplasm and it also shuttles between the nucleus and the cytoplasm. The amino acid sequence of A1 contains two RNP motif RNA-binding domains (RBDs) at the amino terminus and a glycine-rich domain at the carboxyl terminus. This configuration, designated 2x RBD-Gly, is representative of perhaps the largest family of hnRNP proteins. Unlike most nuclear proteins characterized so far, A1 (and most 2x RBD-Gly proteins) does not contain a recognizable nuclear localization signal (NLS). We have found that a segment of ca. 40 amino acids near the carboxyl end of the protein (designated M9) is necessary and sufficient for nuclear localization; attaching this segment to the bacterial protein beta- galactosidase or to pyruvate kinase completely localized these otherwise cytoplasmic proteins to the nucleus. The RBDs and another RNA binding motif found in the glycine-rich domain, the RGG box, are not required for A1 nuclear localization. M9 is a novel type of nuclear localization domain as it does not contain sequences similar to classical basic-type NLS. Interestingly, sequences similar to M9 are found in other nuclear RNA-binding proteins including hnRNP A2.     

Human immunodeficiency virus type 1 hnRNP A/B-dependent exonic splicing silencer ESSV antagonizes binding of U2AF65 to viral polypyrimidine tracts

Human immunodeficiency virus type 1 (HIV-1) exonic splicing silencers (ESSs) inhibit production of certain spliced viral RNAs by repressing alternative splicing of the viral precursor RNA. Several HIV-1 ESSs interfere with spliceosome assembly by binding cellular hnRNP A/B proteins. Here, we have further characterized the mechanism of splicing repression using a representative HIV-1 hnRNP A/B-dependent ESS, ESSV, which regulates splicing at the vpr 3' splice site. We show that hnRNP A/B proteins bound to ESSV are necessary to inhibit E complex assembly by competing with the binding of U2AF65 to the polypyrimidine tracts of repressed 3' splice sites. We further show evidence suggesting that U1 snRNP binds the 5' splice site despite an almost complete block of splicing by ESSV. Possible splicing-independent functions of U1 snRNP-5' splice site interactions during virus replication are discussed.     

hnRNP A1 contacts exon 5 to promote exon 6 inclusion of apoptotic Fas gene

Fas is a transmembrane cell surface protein recognized by Fas ligand (FasL). When FasL binds to Fas, the target cells undergo apoptosis. A soluble Fas molecule that lacks the transmembrane domain is produced from skipping of exon 6 encoding this region in alternative splicing procedure. The soluble Fas molecule has the opposite function of intact Fas molecule, protecting cells from apoptosis. Here we show that knockdown of hnRNP A1 promotes exon 6 skipping of Fas pre-mRNA, whereas overexpression of hnRNP A1 reduces exon 6 skipping. Based on the bioinformatics approach, we have hypothesized that hnRNP A1 functions through interrupting 5′ splice site selection of exon 5 by interacting with its potential binding site close to 5′ splice site of exon 5. Consistent with our hypothesis, we demonstrate that mutations of the hnRNP A1 binding site on exon 5 disrupted the effects of hnRNP A1 on exon 6 inclusion. RNA pull-down assay and then western blot analysis with hnRNP A1 antibody prove that hnRNP A1 contacts the potential binding site RNA sequence on exon 5 but not the mutant sequence. In addition, we show that the mutation of 5′ splice site on exon 5 to a less conserved sequence destructed the effects of hnRNP A1 on exon 6 inclusion. Therefore we conclude that hnRNP A1 interacts with exon 5 to promote distal exon 6 inclusion of Fas pre-mRNA. Our study reveals a novel alternative splicing mechanism of Fas pre-mRNA.     

hnRNP A1 controls HIV-1 mRNA splicing through cooperative binding to intron and exon splicing silencers in the context of a conserved secondary structure

The removal of the second intron in the HIV-1 rev/tat pre-mRNAs, which involves the joining of splice site SD4 to SA7, is inhibited by hnRNP A1 by a mechanism that requires the intronic splicing silencer (ISS) and the exon splicing silencer (ESS3). In this study, we have determined the RNA secondary structure and the hnRNP A1 binding sites within the 3' splice site region by phylogenetic comparison and chemical/enzymatic probing. A biochemical characterization of the RNA/protein complexes demonstrates that hnRNP A1 binds specifically to primarily three sites, the ISS, a novel UAG motif in the exon splicing enhancer (ESE) and the ESS3 element, which are all situated in experimentally supported stem loop structures. A mutational analysis of the ISS region revealed that the core hnRNP A1 binding site directly overlaps with a major branchpoint used in splicing to SA7, thereby providing a direct explanation for the inhibition of U2 snRNP association with the pre-mRNA by hnRNP A1. Binding of hnRNP A1 to the ISS core site is inhibited by RNA structure but strongly stimulated by the exonic silencer, ESS3. Moreover, the ISS also stimulate binding of hnRNP A1 to the exonic splicing regulators ESS3 and the ESE. Our results suggest a model where a network is formed between hnRNP A1 molecules situated at discrete sites in the intron and exon and that these interactions preclude the recognition of essential splicing signals including the branch point.     

Selection of alternative 5' splice sites: role of U1 snRNP and models for the antagonistic effects of SF2/ASF and hnRNP A1

The first component known to recognize and discriminate among potential 5' splice sites (5'SSs) in pre-mRNA is the U1 snRNP. However, the relative levels of U1 snRNP binding to alternative 5'SSs do not necessarily determine the splicing outcome. Strikingly, SF2/ASF, one of the essential SR protein-splicing factors, causes a dose-dependent shift in splicing to a downstream (intron-proximal) site, and yet it increases U1 snRNP binding at upstream and downstream sites simultaneously. We show here that hnRNP A1, which shifts splicing towards an upstream 5'SS, causes reduced U1 snRNP binding at both sites. Nonetheless, the importance of U1 snRNP binding is shown by proportionality between the level of U1 snRNP binding to the downstream site and its use in splicing. With purified components, hnRNP A1 reduces U1 snRNP binding to 5'SSs by binding cooperatively and indiscriminately to the pre-mRNA. Mutations in hnRNP A1 and SF2/ASF show that the opposite effects of the proteins on 5'SS choice are correlated with their effects on U1 snRNP binding. Cross-linking experiments show that SF2/ASF and hnRNP A1 compete to bind pre-mRNA, and we conclude that this competition is the basis of their functional antagonism; SF2/ASF enhances U1 snRNP binding at all 5'SSs, the rise in simultaneous occupancy causing a shift in splicing towards the downstream site, whereas hnRNP A1 interferes with U1 snRNP binding such that 5'SS occupancy is lower and the affinities of U1 snRNP for the individual sites determine the site of splicing.     

Mechanistic control of carcinoembryonic antigen-related cell adhesion molecule-1 (CEACAM1) splice isoforms by the heterogeneous nuclear ribonuclear proteins hnRNP L, hnRNP A1, and hnRNP M

Carcinoembryonic antigen-related cell adhesion molecule-1 (CEACAM1) is expressed in a variety of cell types and is implicated in carcinogenesis. Alternative splicing of CEACAM1 pre-mRNA generates two cytoplasmic domain splice variants characterized by the inclusion (L-isoform) or exclusion (S-isoform) of exon 7. Here we show that the alternative splicing of CEACAM1 pre-mRNA is regulated by novel cis elements residing in exon 7. We report the presence of three exon regulatory elements that lead to the inclusion or exclusion of exon 7 CEACAM1 mRNA in ZR75 breast cancer cells. Heterologous splicing reporter assays demonstrated that the maintenance of authentic alternative splicing mechanisms were independent of the CEACAM1 intron sequence context. We show that forced expression of these exon regulatory elements could alter CEACAM1 splicing in HEK-293 cells. Using RNA affinity chromatography, three members of the heterogeneous nuclear ribonucleoprotein family (hnRNP L, hnRNP A1, and hnRNP M) were identified. RNA immunoprecipitation of hnRNP L and hnRNP A1 revealed a binding motif located central and 3' to exon 7, respectively. Depletion of hnRNP A1 or L by RNAi in HEK-293 cells promoted exon 7 inclusion, whereas overexpression led to exclusion of the variable exon. By contrast, overexpression of hnRNP M showed exon 7 inclusion and production of CEACAM1-L mRNA. Finally, stress-induced cytoplasmic accumulation of hnRNP A1 in MDA-MB-468 cells dynamically alters the CEACAM1-S:CEACAM1:L ratio in favor of the l-isoform. Thus, we have elucidated the molecular factors that control the mechanism of splice-site recognition in the alternative splicing regulation of CEACAM1.     

Modulation of exon skipping by high-affinity hnRNP A1-binding sites and by intron elements that repress splice site utilization

The RNA-binding protein hnRNP A1 is a splicing regulator produced by exclusion of alternative exon 7B from the A1 pre-mRNA. Each intron flanking exon 7B contains a high-affinity A1-binding site. The A1-binding elements promote exon skipping in vivo, activate distal 5' splice site selection in vitro and improve the responsiveness of pre-mRNAs to increases in the concentration of A1. Whereas the glycine-rich C-terminal domain of A1 is not required for binding, it is essential to activate the distal 5' splice site. Because A1 complexes can interact simultaneously with two A1-binding sites, we propose that an interaction between bound A1 proteins facilitates the pairing of distant splice sites. Based on the distribution of putative A1-binding sites in various pre-mRNAs, an A1-mediated change in pre-mRNA conformation may help define the borders of mammalian introns. We also identify an intron element which represses the 3' splice site of exon 7B. The activity of this element is mediated by a factor distinct from A1. Our results suggest that exon 7B skipping results from the concerted action of several intron elements that modulate splice site recognition and pairing.     

Modeling by homology of RNA binding domain in A1 hnRNP protein

Eukaryotic nuclear RNA binding proteins share a common sequence motif thought to be implicated in RNA binding. One of the two domains present in A1 hnRNP protein, has been modelled by homology in order to make a prediction of the main features of the RNA binding site. Acylphosphatase (EC 3.6.1.7) was selected as template for the modeling experiment. The predicted RNA binding site is a beta-sheet containing the two RNP consensus sequences as well as lysines and arginines conserved among the family.     

Purification and RNA binding properties of a C-type hnRNP protein from HeLa cells

A protein of the C group, most likely C3 (Mr approximately 42,000, pI approximately 6, corresponding to IEF 48m,n of the HeLa protein catalogue (Celis, J. E., Bravo, R., Arenstorf, H. P., and LeStourgeon, W. M. (1986) FEBS Lett. 194, 101-109)), a minor hnRNP protein was purified to near homogeneity under nondenaturing conditions from 40 S heterogeneous nuclear ribonucleoprotein particles. Type C protein stoichiometrically disrupts the residual secondary structure of natural and synthetic RNAs, e.g. HeLa hnRNA, coliphage MS2 RNA, and poly(rU)-spermine, and decreases the Tm of duplex structures, e.g. poly[r(A + U)], by about 30 degrees C. Binding of the protein to polynucleotides is not highly cooperative and has a stoichiometry of one protein per about 10 nucleotides. Binding experiments with a variety of synthetic and natural poly- and oligonucleotides, including those containing consensus splice site sequences, indicate that the protein has a high affinity for G-rich and U-rich regions, G-rich regions being preferred. Base analogs I and T have affinities for the protein that are similar to G and U. There is little or no affinity for A- and C-rich regions. The presence of A residues in a G- or U-rich sequence does not interfere with binding while C-rich regions decrease or prevent the binding of the protein. The nucleotide specificity of type C protein, e.g. selective binding to an oligonucleotide from the 3' end of an intron, is discussed in relationship to the abundance of G and U and the relative scarcity of C residues in the processing signals in pre-mRNA.     

hnRNP A1 binds promiscuously to oligoribonucleotides: utilization of random and homo-oligonucleotides to discriminate sequence from base-specific binding.

To understand the range of possible and probable A1 functions in pre-mRNA biogenesis, it is important that we quantify the relative ability (or inability) of A1 to bind high affinity RNA target sequences and/or structures. Using a fluorescence competition assay we have determined apparent binding affinities for a wide range of 20mer oligos containing putative and possible A1 targets including the high affinity 'winner' sequence identified by selection/amplification [Burd,C.G and Dreyfuss,G. (1994) EMBO J. 13, 1197-1204], AUUUA sequences found in 3'-UTRs of labile mRNAs, 5'- and 3'-splice sites and telomeric sequences. With the exception of a 20mer 'winner' sequence, all other 20mers examined bind A1 with a narrow, approximately 10-fold range of affinities extending from 3.2 x 10(6) to 4.2 x 10(7) M(-1). Studies with homo-oligomers suggest this range reflects nucleotide base rather than sequence specificity and hence, it was possible to predict reasonably accurate affinities for all other 20mers examined except for the 'winner', whose unusually high affinity of 4.0 x 10(8) M(-1) results from a unique higher order structure and sequence. Since there is no known physiological role for the 'winner' 20mer sequence, these data suggest A1 generally binds indiscriminately to all available pre-mRNA sequences. Both the large abundance of A1 in vivo and its binding properties are thus consistent with it playing a structural role in pre-mRNA biogenesis.     

Interaction of the sex-lethal RNA binding domains with RNA.

Sex determination and X chromosome dosage compensation in Drosophila melanogaster are directed by the Sex-lethal (Sxl) protein. In part, Sxl functions by regulating the splicing of the transformer pre-mRNA by binding to a 3' splice site polypyrimidine tract. Polypyrimidine tracts are essential for splicing of metazoan pre-mRNAs. To unravel the mechanism of splicing regulation at polypyrimidine tracts we analyzed the interaction of Sxl with RNA. The RNA binding activity of Sxl was mapped to the two ribonucleoprotein consensus sequence domains of the protein. Quantitation of binding showed that both RNA binding domains (RBDs) were required in cis for site-specific RNA binding. Individual RBDs interacted with RNA more weakly and had lost the ability to discriminate between wild-type and mutant transformer polypyrimidine tracts. Structural elements in one of the RBDs that are likely to interact with a polypyrimidine tract were identified using nuclear magnetic resonance techniques. In addition, our data suggest that multiple imino protons of the transformer polypyrimidine tract were involved in hydrogen bonding. Interestingly, in vitro Sxl bound with equal affinity to polypyrimidine tracts of pre-mRNAs that it does not regulate in vivo. We discuss the implications of this finding for the mechanism through which Sxl may gain selectivity for particular polypyrimidine tracts in vivo.     

hnRNP A1 and hnRNP F modulate the alternative splicing of exon 11 of the insulin receptor gene

Exon 11 of the insulin receptor gene (INSR) is alternatively spliced in a developmentally and tissue-specific manner. Linker scanning mutations in a 5' GA-rich enhancer in intron 10 identified AGGGA sequences that are important for enhancer function. Using RNA-affinity purification and mass spectrometry, we identified hnRNP F and hnRNP A1 binding to these AGGGA sites and also to similar motifs at the 3' end of the intron. The hnRNPs have opposite functional effects with hnRNP F promoting and hnRNP A1 inhibiting exon 11 inclusion, and deletion of the GA-rich elements eliminates both effects. We also observed specific binding of hnRNP A1 to the 5' splice site of intron 11. The SR protein SRSF1 (SF2/ASF) co-purified on the GA-rich enhancer and, interestingly, also competes with hnRNP A1 for binding to the splice site. A point mutation -3U→C decreases hnRNP A1 binding, increases SRSF1 binding and renders the exon constitutive. Lastly, our data point to a functional interaction between hnRNP F and SRSF1 as a mutant that eliminates SRSF1 binding to exon 11, or a SRSF1 knockdown, which prevents the stimulatory effect of hnRNP F over expression.