A molecular code for splicing silencing: configurations of guanosine-rich motifs.

Alternative pre-mRNA splicing is frequently used to expand the protein-coding capacity of genomes, and to regulate gene expression at the post-transcriptional level. It is a significant challenge to decipher the molecular language of tissue-specific splicing because the inherent flexibility of these mechanisms is specified by numerous short sequence motifs distributed in introns and exons. In the present study, we employ the glutamate NMDA (N-methyl-D-aspartate) R1 receptor (GRIN1) transcript as a model system to identify the molecular determinants for a brain region-specific exon silencing mechanism. We identify a set of guanosine-rich motifs that function co-operatively to regulate the CI cassette exon in a manner consistent with its in vivo splicing pattern. Whereas hnRNP (heterogeneous nuclear ribonucleoprotein) A1 mediates silencing of the CI cassette exon in conjunction with the guanosine-rich motifs, hnRNP H functions as an antagonist to silencing. Genome-wide analysis shows that, while this motif pattern is rarely present in human and mouse exons, those exons for which the pattern is conserved are generally found to be skipped exons. The identification of a similar arrangement of guanosine-rich motifs in transcripts of the hnRNP H family of splicing factors has implications for their co-ordinate regulation at the level of splicing.

Alternative RNA splicing in the nervous system.

Tissue-specific alternative splicing profoundly effects animal physiology, development and disease, and this is nowhere more evident than in the nervous system. Alternative splicing is a versatile form of genetic control whereby a common pre-mRNA is processed into multiple mRNA isoforms differing in their precise combination of exon sequences. In the nervous system, thousands of alternatively spliced mRNAs are translated into their protein counterparts where specific isoforms play roles in learning and memory, neuronal cell recognition, neurotransmission, ion channel function, and receptor specificity. The essential nature of this process is underscored by the finding that its misregulation is a common characteristic of human disease. This review highlights the current views of the biological phenomenon of alternative splicing, and describes evidence for its intricate underlying biochemical mechanisms. The roles of RNA binding proteins and their tissue-specific properties are discussed. Why does alternative splicing occur in cosmic proportions in the nervous system? How does it affect integrated cellular functions? How are region-specific, cell-specific and developmental differences in splicing directed? How are the control mechanisms that operate in the nervous system distinct from those of other tissues? Although there are many unanswered questions, substantial progress has been made in showing that alternative splicing is of major importance in generating proteomic diversity, and in modulating protein activities in a temporal and spatial manner. The relevance of alternative splicing to diseases of the nervous system is also discussed.

Identification of a protein component of a mammalian tRNA(Sec) complex implicated in the decoding of UGA as selenocysteine.

This report describes a novel RNA-binding protein, SECp43, that associates specifically with mammalian selenocysteine tRNA (tRNA(Sec)). SECp43, identified from a degenerate PCR screen, is a highly conserved protein with two ribonucleoprotein-binding domains and a polar/acidic carboxy terminus. The protein and corresponding mRNA are generally expressed in rat tissues and mammalian cell lines. To gain insight into the biological role of SECp43, affinity-purified antibody was employed to identify its molecular partners. Surprisingly, the application of native HeLa cell extracts to a SECp43 antibody column results in the purification of a 90-nt RNA species identified by direct sequencing and Northern blot analysis as tRNA(Sec). The purification of tRNA(Sec) by the antibody column is striking, based on the low abundance of this tRNA species. Using recombinant SECp43 as a probe for interacting protein partners, we also identify a 48-kDa interacting protein, which is a possible component of the mammalian selenocysteine insertion (SECIS) pathway. To our knowledge, SECp43 is the first cloned protein demonstrated to associate specifically with eukaryotic tRNA(Sec).

Coordinate repression of a trio of neuron-specific splicing events by the splicing regulator PTB.

In this study, we demonstrate the ability of the polypyrimidine tract binding protein PTB to function as a coordinator of splicing regulation for a trio of neuron-specific exons that are subject to developmental splicing changes in the rat cerebellum. Three neuron-specific exons that show positive regulation are derived from the GABA(A) receptor gamma2 subunit 24 nucleotide exon, clathrin light chain B exon EN, and N-methyl-D-aspartate receptor NR1 subunit exon 5 pre-mRNAs. The functional activity of splicing repressor signals located in the 3' splice site regions adjacent to the neural exons is shown using an alternative splicing switch assay, in which these short RNA sequences function in trans to switch splicing to the neural pathway in HeLa splicing reactions. Parallel UV crosslinking/competition assays demonstrate selective binding of PTB in comparison to substantially lower binding at adjacent, nonneural 3' splice sites. Substantially lower PTB binding and splicing switch activity is also observed for the 3' splice site of NMDA exon 21, which is subject to negative regulation in cerebellum tissue in the same time frame. In splicing active neural extracts, the balance of control shifts to positive regulation, and this shift correlates with a PTB status that is predominantly the neural form. In this context, the addition of recombinant PTB is sufficient to switch splicing to the nonneural pathway. The neural extracts also reveal specific binding of the CUG triplet repeat binding protein to a subset of regulatory 3' splice site regions. These interactions may interfere with PTB function or modulate splicing levels in a substrate-specific manner within neural tissue. Together these results strengthen the evidence that PTB is a splicing regulator with multiple targets and demonstrate its ability to discriminate among neural and nonneural substrates. Thus, a variety of mechanisms that counterbalance the splicing repressor function of PTB in neural tissue are capable of mediating developmental splicing control. Altered expression of PTB isoforms during cerebellar development, as documented by Western blot analysis, is proposed to be a contributing mechanism.

A neuron-specific splicing switch mediated by an array of pre-mRNA repressor sites: evidence of a regulatory role for the polypyrimidine tract binding protein and a brain-specific PTB counterpart.

Tissue- and stage-specific alternative splicing events are widespread in mammals, yet the factors and mechanisms that direct these important posttranscriptional events are poorly understood. In this study, we focus on the 24-nt exon of the GABA(A) receptor gamma2 pre-mRNA, which is subject to neuron-specific and developmental splicing regulation in the rat cerebellum. Here we show biochemical evidence for a mechanism that directs the selective repression of the neuron-specific exon in non-neuronal splicing extracts derived from HeLa cells. Key evidence includes the discovery that the pathway of gamma2 pre-mRNA splicing switches from exon skipping to exon selection in splicing reactions with a short RNA competitor containing the 3' splice site region upstream of the 24-nt exon. In this assay, exon selection results from the coordinate activation of both flanking introns. A detailed dissection of this pre-mRNA region shows that it contains four repressor sites clustered around the branch site and extending into the 24-nt exon. These repressor sites are pyrimidine rich and bind avidly to the polypyrimidine tract binding protein (PTB) in HeLa nuclear extracts as determined by UV crosslinking/competition assays. Repression of the exon selection pathway is closely associated with the appearance of a specific RNA-protein complex, indicative of an inhibitor complex, that assembles on the repressor array. Upon the switch to the exon selection pathway, a substantial decrease in the inhibitor complex and a reciprocal increase in spliceosome complex A is observed. Excess recombinant PTB squelches the splicing switch and reestablishes exon skipping as the predominant splicing pathway. Extracts prepared from rat brain nuclei show reduced levels of conventional PTB compared to other splicing factors. Nonetheless, the rat brain nuclear extracts contain an activity that assembles an analogous inhibitor complex efficiently. We report a 59-kDa protein, p59, which has an electrophoretic mobility distinct from HeLa and rat kidney PTB, and which behaves in RNA binding assays as if it is the PTB counterpart in rat brain. Evidence that rat brain p59 is structurally related to PTB stems from western blot and immunoprecipitation analysis with a monoclonal antibody specific for the hnRNP I isoform of PTB. A model describing how the repressor array directs coordinate splicing regulation of flanking introns in the context of overlapping positive regulatory elements is discussed. The sequence, (5') UUCUCU (3'), in a pyrimidine context is associated with one class of intron splicing repressor sites that binds PTB in a variety of pre-mRNAs that are regulated by tissue-specific programs.

Cell- and stage-specific splicing events resolved in specialized neurons of the rat cerebellum.

Tissue and stage-specific pre-mRNA splicing events are important for posttranscriptional gene control, yet the diversity of such regulatory pathways has been largely unexplored at the single-cell level. Here we use a less conventional approach, which combines the whole-cell patch clamp method and the reverse transcriptase-polymerase chain reaction, to examine five neuron-specific splicing events in individual Purkinje neurons during postnatal development in live slices of rat cerebellum. Within the dimensions of the slice, the neurons sampled in this manner remain connected in their natural circuits and express multiple neuron-specific mRNAs, unlike established cell lines. In contrast to invariant splicing of control mRNAs, significant changes in splicing regulation during development are displayed by regulated exons of the GABA(A) receptor gamma2 subunit, clathrin light chain B, neural cell adhesion molecule, and N-methyl-D-aspartate receptor R1 mRNAs. Whereas two of the neuron-specific exons are regulated in parallel in Purkinje neurons, these same substrates are regulated differentially in cerebellar Granule neurons during the same course of development. These results illustrate how two types of specialized neurons contribute to splicing regulation in the natural environment of the complex tissue. In addition, these results provide a larger view of splicing regulation, favoring models in which cell-specific machineries operate in a more selective, rather than widespread manner, in these neuronal cell types.

Essential nucleotides direct neuron-specific splicing of gamma 2 pre-mRNA.

Tissue-and stage-specific pre-mRNA splicing events are prevalent in mammals, yet molecular details are lacking about these important mechanisms of posttranscriptional gene control. In this study, we investigate the regulated splicing of rat gamma 2 pre-mRNA, a subunit of the GABAA receptor, as a step toward understanding the molecular basis of a neuron-specific splicing event involving cassette exon selection. Cell-and substrate-specific regulation of gamma 2 pre-mRNA is recapitulated in a neuronal cell line derived from the cerebellum, which produces enhanced levels of the exon-selected mRNA. In contrast, a control cell line derived from non-neuronal cells of the pituitary produces prominent levels of the unregulated, exon-skipped mRNA. The cerebellar and pituitary cell lines are well matched in overall splicing efficiency and produce an invariant pattern of splicing for a control substrate, which is alternatively spliced but not regulated in this system. The appropriateness of the two cell lines is indicated by an extended mRNA mapping experiment, which documents the region-specific switch in exon selection throughout rat brain. Using this pair of cell lines, we show that large intron segments flanking the regulated exon are dispensable for regulation. These intron regions have been deleted to generate a minimal splicing substrate for the purpose of identifying essential RNA elements. In this context, we show that essential nucleotides are located at positions +7, +8, and +9 of the regulated exon and in a 9-nt adenosine-rich region of the adjacent 3' splice site. Due to the proximity and base complementarity of the required nucleotides, experiments were devised to test models involving the recognition of two single-stranded signals, or one duplex RNA signal. These results clearly disfavor the duplex RNA recognition model and indicate that the required regions are recognized as independent, single strands in neuronal cells. A weak 5' splice site adjacent to the regulated exon is required as a third essential element. Although the importance of a weak 5' splice site is common to other regulated systems such as NCAM, the essential nucleotides in the exon and 3' splice site region defined in this study for gamma 2 splicing regulation are novel.

Biochemical properties of a novel U2AF65 protein isoform generated by alternative RNA splicing.

A variety of RNA binding proteins with one or more RNA recognition (RNP-CS) motifs play essential roles in the pre-mRNA splicing process. One such factor, the U2 snRNP auxiliary factor large subunit (U2AF65), contains three RNP-CS motifs each of which is required for high affinity binding to polypyrimidine tracts. Here we report the isolation of a natural cDNA variant of human U2AF65, U2AF65 (S), which is shortened by a 12 nucleotide in frame deletion between RNP-CS2 and -CS3 motifs. A portion of the U2AF65 (S) cDNA was reported previously but was not characterized further. We observe that the U2AF65 (S) variant predominates in a variety of tissues and cell lines, and is generated together with the U2AF65 (L) form (2) by alternative 5' splice site selection from a single gene. The corresponding histidine-tagged recombinant proteins bind with similar affinities to model RNA substrates containing strong or weak polypyrimidine tracts. Both U2AF65 (S) and (L) protein isoforms reconstitute splicing activity with similar kinetic profiles in U2AF-depleted (splicing-deficient) HeLa nuclear extracts. Finally, the thermal stabilities of the protein isoforms are essentially equivalent. Thus, the presence or absence of the peptide segment, VSPP (residues 345-348), in the linker region between RNP-CS2 and -CS3 does not detract from the intrinsic RNA binding and splicing properties of the U2AF65 protein. The biological implications of alternative splicing for the function and evolution of RNA binding proteins are discussed.

Intrinsic U2AF binding is modulated by exon enhancer signals in parallel with changes in splicing activity.

A functional analysis of exon replacement mutations was performed in parallel with RNA-protein binding assays to gain insight into the role of the exon in alternative and simple splicing events. These results show that constitutive exons from unrelated genes contain strong signals that promote splicing in multiple sequence contexts by enhancing 3' splice site activity. A clue to the nature of the relationship between the exon and adjacent 3' splice site is indicated by the binding properties of exon variant RNAs when tested with different biochemical preparations of the essential splicing protein, U2AF. In the context of a complete nuclear extract, U2AF binding to the 3' splice site is stimulated by the presence of an adjacent constitutive exon. In contrast, highly purified HeLa U2AF binds equivalently to the exon variants under conditions in which differential polypyrimidine tract binding is evident. These results provide support for an assisted binding model in which positive-acting signals within exons, exon enhancers, direct the binding of accessory factors, which in turn increase the intrinsic affinity of U2AF for the adjacent 3' splice site. Further support for an assisted binding model is indicated by biochemical complementation of U2AF binding and by the localization of a novel exon enhancer, which, when introduced into a weak exon, stimulates splicing activity in parallel with U2AF binding. Immunoprecipitation analysis identifies the splicing factor, SC35, as a constituent of the exon enhancer binding complex. These results are discussed in the context of current models for functional exon-bridging interactions.

Regulated splicing of gamma2 pre-messenger RNA in neuronal cells.

The pre-mRNA encoding the gamma 2 subunit of the gamma-aminobutyric acid Type A receptor is spliced in a tissue-specific manner in mammalian brain resulting in mRNAs containing or lacking a 24 nucleotide exon, gamma 2L and gamma 2S, respectively. The gamma 2S mRNA predominates in pituitary, whereas the gamma 2L predominates in brainstem, spinal cord and cerebellum. In this study, a cell line derived from rat cerebellum that qualitatively reproduces regulated splicing of gamma 2 pre-mRNA was identified and used to dissect cis-regulatory elements. Sequence elements that alter the selection of the 24 nucleotide exon fall into two functional classes-activating elements and inhibitory elements. We identified several inhibitory elements that inhibit splicing of the 24 nucleotide exon in all cell types as well as specific inhibitory elements which repress splicing in non-neuronal cells. Activating elements are localized within conserved intron regions, as judged by a comparison of rat and human gene sequences, and appear to function generally in activating splicing of the 24 nucleotide exon in the cell types tested so far. These results are compatible with a hypothesis in which the mechanism of regulation involves a release from inhibition. Current experiments are aimed toward the development of tools to identify the trans-regulatory components.

Reconstitution of exon-bridging activity with purified U2AF and U1 snRNP components.

For pre-mRNAs containing multiple introns, the exon definition hypothesis has been proposed to account for the interactions that specify relatively short exons and prevent inappropriate exon-skipping [1]. Support for this hypothesis includes the finding that naturally occurring, or engineered mutations in 5' splice sites that weaken base complementary to U1 snRNA result in exon skipping due to a decrease in upstream 3' splice site activity. The reciprocal effect is also observed. For example, we found previously that the selection of the alternatively spliced rat preprotachykinin exon 4 is improved under conditions in which the adjacent 5' splice site is converted to a site with strengthened base pairing to U1 snRNA [2]. In the latter study, 3' splice site activity is improved in parallel with strengthened U1 snRNP binding to the downstream 5' splice site. Subsequent RNA-protein crosslinking experiments have provided evidence for exon bridging interactions between U2AF bound to the 3' splice site and U1 snRNP bound to the downstream 5' splice site in the preprotachykinin substrates [3]; see Figure 1. U2AF, a polypyrimidine tract binding protein composed of 65 and 35 kD subunits, is required for U2 snRNP binding to the adjacent branch site [4], [5]. In this work we have reconstituted exon bridging activity with purified components. These results show that U1 snRNP in addition to U2AF are the two components required to reconstitute full activity in vitro. The purified system has been used to test variants of U2AF and U1 snRNP. Our results show that the U1-A and U1-C proteins are dispensable for exon bridging activity. In addition, the 35 kD subunit of U2AF appears to be dispensable, at least under certain conditions.

U1 snRNP targets an essential splicing factor, U2AF65, to the 3' splice site by a network of interactions spanning the exon.

A description of cellular factors that govern alternative splicing of pre-mRNA is largely incomplete. In the case of the rat preprotachykinin gene, splicing of the alternative exon E4 occurs by a poorly understood mechanism in which exon selection is under the positive control of U1 snRNP. Because the binding of U1 snRNP to the 5' splice site of E4 is coincident with the selection of the 3' splice site of E4, this mechanism would appear to involve interactions that bridge across the exon. In this work, a UV cross-linking strategy was used to identify possible RNA-protein interactions involved in the proposed exon-bridging model. Of particular interest is a prominent 61-kD protein, p61, that binds to the 3' splice site of E4 in a manner that is clearly facilitated by a downstream 5' splice site and U1 snRNP particles. The identity of p61 is the essential splicing factor U2AF65, on the basis of copurification and selective binding to polypyrimidine tracts. These results indicate a model in which exon selection is positively regulated by the communication of U1 snRNP and U2AF65. That is, a natural deficiency in binding U2AF65 to the 3' splice site that leads to exon skipping might be overcome by a mechanism in which U1 snRNP facilitates the binding of U2AF65 through a network of template-directed and exon-bridging interactions.

Combinatorial splicing of exon pairs by two-site binding of U1 small nuclear ribonucleoprotein particle.

A two-site model for the binding of U1 small nuclear ribonucleoprotein particle (U1 snRNP) was tested in order to understand how exon partners are selected in complex pre-mRNAs containing alternative exons. In this model, it is proposed that two U1 snRNPs define a functional unit of splicing by base pairing to the 3' boundary of the downstream exon as well as the 5' boundary of the intron to be spliced. Three-exon substrates contained the alternatively spliced exon 4 (E4) region of the preprotachykinin gene. Combined 5' splice site mutations at neighboring exons demonstrate that weakened binding of U1 snRNP at the downstream site and improved U1 snRNP binding at the upstream site result in the failure to rescue splicing of the intron between the mutations. These results indicate the stringency of the requirement for binding a second U1 snRNP to the downstream 5' splice site for these substrates as opposed to an alternative model in which a certain threshold level of U1 snRNP can be provided at either site. Further support for the two-site model is provided by single-site mutations in the 5' splice site of the third exon, E5, that weaken base complementarity to U1 RNA. These mutations block E5 branchpoint formation and, surprisingly, generate novel branchpoints that are specified chiefly by their proximity to a cryptic 5' splice site located at the 3' terminus of the pre-mRNA. The experiments shown here demonstrate a true stimulation of 3' splice site activity by the downstream binding of U1 snRNP and suggest a possible mechanism by which combinatorial patterns of exon selection are achieved for alternatively spliced pre-mRNAs.

Control of alternative splicing by the differential binding of U1 small nuclear ribonucleoprotein particle.

Cellular factors controlling alternative splicing of precursor messenger RNA are largely unknown, even though this process plays a central role in specifying the diversity of proteins in the eukaryotic cell. For the identification of such factors, a segment of the rat preprotachykinin gene was used in which differential expression of neuropeptides gamma and K is dependent on alternative splicing of the fourth exon (E4). Sequence variants of the three-exon segment, (E3-E4-E5) were created, resulting in a sensitive assay for factors mediating the splicing switch between E4-skipping and E4-inclusion. A dinucleotide mutation in the 5' splice site of E4 that increase base-pairing of this site to U1 small nuclear RNA resulted in uniform selection of E4, whereas a control mutation that destroyed base-pairing resulted in uniform E4-skipping. Affinity selection of spliceosomes formed on these functionally distinct substrates revealed that the extreme difference in splicing was mediated by differential binding of the U1 small nuclear ribonucleoprotein particle (snRNP) to the 5' splice site of E4. These data show that, apart from its established role in selecting 5' splice sites, U1 snRNP plays a fundamental role in 3' exon selection and provides insight into possible mechanisms of alternative splicing.

A Sequential splicing mechanism promotes selection of an optimal exon by repositioning a downstream 5' splice site in preprotachykinin pre-mRNA.

To explore the structural basis of alternative splicing, we have analyzed the splicing of pre-mRNAs containing an optional exon, E4, from the preprotachykinin gene. This gene encodes substance P and related tachykinin peptides by alternative splicing of a common pre-mRNA. We have shown that alternative splicing of preprotachykinin pre-mRNA occurs by preferential skipping of optional E4. The competing mechanism that incorporates E4 into the final spliced RNA is constrained by an initial block to splicing of the immediate upstream intervening sequence (IVS), IVS3. This block is relieved by sequential splicing, in which the immediate downstream IVS4 is removed first. The structural change resulting from the first splicing event is directly responsible for activation of IVS3 splicing. This structural rearrangement replaces IVS4 sequences with E5 and its adjacent IVS5 sequences. To determine how this structural change promoted IVS3 splicing, we asked what structural change(s) would restore activity of IVS3 splicing-defective mutants. The most significant effect was observed by a 2-nucleotide substitution that converted the 5' splice site of E4 to an exact consensus match, GUAAGU. Exon 5 sequences alone were found not to promote splicing when present in one or multiple copies. However, when a 15-nucleotide segment of IVS5 containing GUAAGU was inserted into a splicing-defective mutant just downstream of the hybrid exon segment E4E5, splicing activity was recovered. Curiously, the 72-nucleotide L2 exon of adenovirus, without its associated 5' splice site, activates splicing when juxtaposed to E4. Models for the activation of splicing by an RNA structural change are discussed.

Spliceosome assembly involves the binding and release of U4 small nuclear ribonucleoprotein.

Splicing complexes that form a rabbit beta-globin precursor mRNA (pre-mRNA) have been analyzed for their small nuclear RNA (snRNA) content by both affinity chromatography and specific probe hybridization of replicas of native electrophoretic gels. A pathway of spliceosome assembly was deduced that has at least three stages. (i) U2 small nuclear ribonucleoprotein (snRNP) alone binds to sequences of mRNA upstream of the 3' splice site. (ii) U4, U5, and U6 snRNPs bind, apparently simultaneously. (iii) U4 snRNP is released to generate a spliceosome that contains U2, U5, and U6 snRNPs together with the RNA intermediates in splicing. U1 snRNP was not detected in association with any of these complexes. A parallel analysis of the spliceosome found with an adenovirus precursor mRNA substrate yielded an identical snRNP composition with one additional, unidentified RNA species, called X. This latter RNA species was not detected in the spliceosome bound to the beta-globin substrate.