The role of U2AF35 and U2AF65 in enhancer-dependent splicing

U2 small nuclear ribonucleoprotein particle (snRNP) auxiliary factor of 65 kDa, U2AF65, can promote U1 snRNP recruitment to 5' splice sites

The splicing factor U2AF(65), U2 small nuclear ribonucleoprotein particle (snRNP) auxillary factor of 65 kDa, binds to pyrimidine-rich sequences at 3' splice sites to recruit U2 snRNP to pre-mRNAs. We report that U2AF(65) can also promote the recruitment of U1 snRNP to weak 5' splice sites that are followed by uridine-rich sequences. The arginine- and serine-rich domain of U2AF(65) is critical for U1 recruitment, and we discuss the role of its RNA-RNA annealing activity in this novel function of U2AF(65).

Bifunctional antisense oligonucleotides provide a trans-acting splicing enhancer that stimulates SMN2 gene expression in patient fibroblasts

The multiplicity of proteins compared with genes in mammals owes much to alternative splicing. Splicing signals are so subtle and complex that small perturbations may allow the production of new mRNA variants. However, the flexibility of splicing can also be a liability, and several genetic diseases result from single-base changes that cause exons to be skipped during splicing. Conventional oligonucleotide strategies can block reactions but cannot restore splicing. We describe here a method by which the use of a defective exon was restored. Spinal muscular atrophy (SMA) results from mutations of the Survival Motor Neuron (SMN) gene. Mutations of SMN1 cause SMA, whereas SMN2 acts as a modifying gene. The two genes undergo alternative splicing with SMN1, producing an abundance of full-length mRNA transcripts, whereas SMN2 predominantly produces exon 7-deleted transcripts. This discrepancy is because of a single nucleotide difference in SMN2 exon 7, which disrupts an exonic splicing enhancer containing an SF2ASF binding site. We have designed oligoribonucleotides that are complementary to exon 7 and contain exonic splicing enhancer motifs to provide trans-acting enhancers. These tailed oligoribonucleotides increased SMN2 exon 7 splicing in vitro and rescued the incorporation of SMN2 exon 7 in SMA patient fibroblasts. This treatment also resulted in the partial restoration of gems, intranuclear structures containing SMN protein that are severely reduced in patients with SMA. The use of tailed antisense oligonucleotides to recruit positively acting factors to stimulate a splicing reaction may have therapeutic applications for genetic disorders, such as SMA, in which splicing patterns are altered.

Potential protein partners for the N-terminal domain of human topoisomerase I revealed by phage display

Phage display procedure was applied to the N-terminal domain of human topoisomerase I. The consensus sequence identified for clones binding to the N-terminal domain was found in 35 human proteins that are either permanently or temporarily located in the nucleus. They are in majority involved in the DNA repair, transcription, RNA metabolism or cell cycle control. Four of identified proteins: Bub3 protein, Cockayne syndrome protein A, damaged DNA binding protein 2 and GRWD protein belong to WD-repeat proteins and their sequences recognized by the N-terminal domain are identically localized.

A general role for splicing enhancers in exon definition

Exonic splicing enhancers (ESEs) facilitate exon definition by assisting in the recruitment of splicing factors to the adjacent intron. Here we demonstrate that suboptimal 5' and 3' splice sites are activated independently by ESEs when they are located on different exons. However, when they are situated within a single exon, the same weak 5' and 3' splice sites are activated simultaneously by a single ESE. These findings demonstrate that a single ESE promotes the recognition of both exon/intron junctions within the same step during exon definition. Our results suggest that ESEs recruit a multicomponent complex that minimally contains components of the splicing machinery required for 5' and 3' splice site selection.

Multiple roles for SR proteins in trans splicing

The trans-splicing reaction involves the association of 5' and 3' splice sites contained on separate transcripts. The mechanism by which these splice sites are juxtaposed during trans-spliceosome assembly and the role of SR proteins at each stage in this process have not been determined. Utilizing a system that allows for the separation of the RNA binding and RS domains of SR proteins, we have found that SR proteins are required for at least two stages of the trans-splicing reaction. They are important both prior to and subsequent to the addition of U2 snRNP to the 3' acceptor. In addition, we have demonstrated a role for RS domain phosphorylation in both of these activities. Dephosphorylation of the RS domain led to a block in U2 snRNP binding to the substrate. In a separate experiment, RS domain phosphorylation was also determined to be necessary for trans splicing to proceed on a substrate that had U2 snRNP already bound. This newly identified role for phosphorylated SR proteins post-U2-snRNP addition coincides with the recruitment of the 5' splice site contained on the SL RNP, suggesting a role for SR proteins in splice site communication in trans splicing.

Listening to silence and understanding nonsense: exonic mutations that affect splicing

Point mutations in the coding regions of genes are commonly assumed to exert their effects by altering single amino acids in the encoded proteins. However, there is increasing evidence that many human disease genes harbour exonic mutations that affect pre-mRNA splicing. Nonsense, missense and even translationally silent mutations can inactivate genes by inducing the splicing machinery to skip the mutant exons. Similarly, coding-region single-nucleotide polymorphisms might cause phenotypic variability by influencing splicing accuracy or efficiency. As the splicing mechanisms that depend on exonic signals are elucidated, new therapeutic approaches to treating certain genetic diseases can begin to be explored.

Characterization of U2AF(6), a splicing factor related to U2AF(35)

The essential splicing factor U2AF (U2 auxiliary factor) is a heterodimer composed of 65-kDa (U2AF(65)) and 35-kDa (U2AF(35)) subunits. U2AF(35) has multiple functions in pre-mRNA splicing. First, U2AF(35) has been shown to function by directly interacting with the AG at the 3' splice site. Second, U2AF(35) is thought to play a role in the recruitment of U2AF(65) by serine-arginine-rich (SR) proteins in enhancer-dependent splicing. It has been proposed that the physical interaction between the arginine-serine-rich (RS) domain of U2AF(35) and SR proteins is important for this activity. However, other data suggest that this may not be the case. Here, we report the identification of a mammalian gene that encodes a 26-kDa protein bearing strong sequence similarity to U2AF(35), designated U2AF(26). The N-terminal 187 amino acids of U2AF(35) and U2AF(26) are nearly identical. However, the C-terminal domain of U2AF(26) lacks many characteristics of the U2AF(35) RS domain and, therefore, might be incapable of interacting with SR proteins. We show that U2AF(26) can associate with U2AF(65) and can functionally substitute for U2AF(35) in both constitutive and enhancer-dependent splicing, demonstrating that the RS domain of the small U2AF subunit is not required for splicing enhancer function. Finally, we show that U2AF(26) functions by enhancing the binding of U2AF(65) to weak 3' splice sites. These studies identify U2AF(26) as a mammalian splicing factor and demonstrate that distinct U2AF complexes can participate in pre-mRNA splicing. Based on its sequence and functional similarity to U2AF(35), U2AF(26) may play a role in regulating alternative splicing.

Exon identity established through differential antagonism between exonic splicing silencer-bound hnRNP A1 and enhancer-bound SR proteins

SR proteins recognize exonic splicing enhancer (ESE) elements and promote exon use, whereas certain hnRNP proteins bind to exonic splicing silencer (ESS) elements and block exon recognition. We investigated how ESS3 in HIV-1 tat exon 3 blocks splicing promoted by one SR protein (SC35) but not another (SF2/ASF). hnRNP A1 mediates silencing by binding initially to a required high-affinity site in ESS3, which then promotes further hnRNP A1 association with the upstream region of the exon. Both SC35 and SF2/ASF recognize upstream ESE motifs, but only SF2/ASF prevents secondary hnRNP A1 binding, presumably by blocking its cooperative propagation along the exon. The differential antagonism between a negative and two positive regulators exemplifies how inclusion of an alternative exon can be modulated.

Modulation of survival motor neuron pre-mRNA splicing by inhibition of alternative 3' splice site pairing

Spinal muscular atrophy is caused by the loss of functional survival motor neuron (SMN1) alleles. A translationally silent nucleotide transition in the duplicated copy of the gene (SMN2) leads to exon 7 skipping and expression of a nonfunctional gene product. It has been suggested that differential SMN2 splicing is caused by the disruption of an exonic splicing enhancer. Here we show that the single nucleotide difference reduces the intrinsic strength of the 3' splice site of exon 7 2-fold, whereas the strength of the 5' splice site of the exon 7 is not affected. Thus, a decrease in splice site strength is magnified in the context of competing exons. These data suggest that lower levels of exon 7 definition not only reduce intron 6 removal but, more importantly, increase the efficiency of the competing exon 7 skipping pathway. Antisense oligonucleotides were tested to modulate exon 7 inclusion, which contains the authentic translation stop codon. Oligonucleotides directed toward the 3' splice site of exon 8 were shown to alter SMN2 splicing in favor of exon 7 inclusion. These results suggest that antisense oligonucleotides could be used as a therapeutic strategy to counteract the progression of SMA.

Dual function for U2AF(35) in AG-dependent pre-mRNA splicing

The splicing factor U2AF is required for the recruitment of U2 small nuclear RNP to pre-mRNAs in higher eukaryotes. The 65-kDa subunit of U2AF (U2AF(65)) binds to the polypyrimidine (Py) tract preceding the 3' splice site, while the 35-kDa subunit (U2AF(35)) contacts the conserved AG dinucleotide at the 3' end of the intron. It has been shown that the interaction between U2AF(35) and the 3' splice site AG can stabilize U2AF(65) binding to weak Py tracts characteristic of so-called AG-dependent pre-mRNAs. U2AF(35) has also been implicated in arginine-serine (RS) domain-mediated bridging interactions with splicing factors of the SR protein family bound to exonic splicing enhancers (ESE), and these interactions can also stabilize U2AF(65) binding. Complementation of the splicing activity of nuclear extracts depleted of U2AF by chromatography in oligo(dT)-cellulose requires, for some pre-mRNAs, only the presence of U2AF(65). In contrast, splicing of a mouse immunoglobulin M (IgM) M1-M2 pre-mRNA requires both U2AF subunits. In this report we have investigated the sequence elements (e.g., Py tract strength, 3' splice site AG, ESE) responsible for the U2AF(35) dependence of IgM. The results indicate that (i) the IgM substrate is an AG-dependent pre-mRNA, (ii) U2AF(35) dependence correlates with AG dependence, and (iii) the identity of the first nucleotide of exon 2 is important for U2AF(35) function. In contrast, RS domain-mediated interactions with SR proteins bound to the ESE appear to be dispensable, because the purine-rich ESE present in exon M2 is not essential for U2AF(35) activity and because a truncation mutant of U2AF(35) consisting only of the pseudo-RNA recognition motif domain and lacking the RS domain is active in our complementation assays. While some of the effects of U2AF(35) can be explained in terms of enhanced U2AF(65) binding, other activities of U2AF(35) do not correlate with increased cross-linking of U2AF(65) to the Py tract. Collectively, the results argue that interaction of U2AF(35) with a consensus 3' splice site triggers events in spliceosome assembly in addition to stabilizing U2AF(65) binding, thus revealing a dual function for U2AF(35) in pre-mRNA splicing.