Characterization and functional implications of the RNA binding properties of nuclear factor TDP-43, a novel splicing regulator of CFTR exon 9

Variations in a polymorphic (TG)m sequence near exon 9 of the human CFTR gene have been associated with variable proportions of exon skipping and occurrence of disease. We have recently identified nuclear factor TDP-43 as a novel splicing regulator capable of binding to this element in the CFTR pre-mRNA and inhibiting recognition of the neighboring exon. In this study we report the dissection of the RNA binding properties of TDP-43 and their functional implications in relationship with the splicing process. Our results show that this protein contains two fully functional RNA recognition motif (RRM) domains with distinct RNA/DNA binding characteristics. Interestingly, TDP-43 can bind a minimum number of six UG (or TG) single-stranded dinucleotide stretches, and binding affinity increases with the number of repeats. In particular, the highly conserved Phe residues in the first RRM region play a key role in nucleic acid recognition.     

U1 small nuclear RNA-promoted exon selection requires a minimal distance between the position of U1 binding and the 3' splice site across the exon.

Both experimental work and surveys of the lengths of internal exons in nature have suggested that vertebrate internal exons require a minimum size of approximately 50 nucleotides for efficient inclusion in mature mRNA. This phenomenon has been ascribed to steric interference between complexes involved in recognition of the splicing signals at the two ends of short internal exons. To determine whether U1 small nuclear ribonucleoprotein, a multicomponent splicing factor that is involved in the first recognition of splice sites, contributes to the lower size limit of vertebrate internal exons, we have taken advantage of our previous observation that U1 small nuclear RNAs (snRNAs) which bind upstream or downstream of the 5' splice site (5'SS) stimulate splicing of the upstream intron. By varying the position of U1 binding relative to the 3'SS, we show that U1-dependent splicing of the upstream intron becomes inefficient when U1 is positioned 48 nucleotides or less downstream of the 3'SS, suggesting a minimal distance between U1 and the 3'SS of approximately 50 nucleotides. This distance corresponds well to the suggested minimum size of internal exons. The results of experiments in which the 3'SS region of the reporter was duplicated suggest an optimal distance of greater than 72 nucleotides. We have also found that inclusion of a 24-nucleotide miniexon is promoted by the binding of U1 to the downstream intron but not by binding to the 5'SS. Our results are discussed in the context of models to explain constitutive splicing of small exons in nature.     

TDP-43 binds heterogeneous nuclear ribonucleoprotein A/B through its C-terminal tail: an important region for the inhibition of cystic fibrosis transmembrane conductance regulator exon 9 splicing

TDP-43 is a highly conserved nuclear factor of yet unknown function that binds to ug-repeated sequences and is responsible for cystic fibrosis transmembrane conductance regulator exon 9 splicing inhibition. We have analyzed TDP-43 interactions with other splicing factors and identified the critical regions for the protein/protein recognition events that determine this biological function. We show here that the C-terminal region of TDP-43 is capable of binding directly to several proteins of the heterogeneous nuclear ribonucleoprotein (hnRNP) family with well known splicing inhibitory activity, in particular, hnRNP A2/B1 and hnRNP A1. Mutational analysis showed that TDP-43 proteins lacking the C-terminal region could not inhibit splicing probably because they were unable to form the hnRNP-rich complex involved in splicing inhibition. Finally, through splicing complex analysis, we show that splicing inhibition mediated by TDP-43 occurs at the earliest stages of spliceosomal assembly.     

Recognition of the 5' splice site by the spliceosome.

The splicing of nuclear pre-mRNAs is catalyzed by a large, multicomponent ribonucleoprotein complex termed the spliceosome. Elucidation of the molecular mechanism of splicing identified small nuclear RNAs (snRNAs) as important components of the spliceosome, which, by analogy to the self-splicing group II introns, are implicated in formation of the catalytic center. In particular, the 5' splice site (5'SS) and the branch site, which represent the two substrates for the first step of splicing, are first recognized by U1 and U2 snRNPs, respectively. This initial recognition of splice sites is responsible for the global definition of exons and introns, and represents the primary target for regulation of splicing. Subsequently, pairing interaction between the 5'SS and U1 snRNA is disrupted and replaced by a new interaction of the 5'SS with U6 snRNA. The 5'SS signal contains an invariant GU dinucleotide present at the 5' end of nearly all known introns, however, the mechanism by which the spliceosome recognizes this element is not known. We have identified and characterized a specific UV light-induced crosslink formed between the 5'SS RNA and hPrp8, a protein component of U5 snRNP in the spliceosome that is likely to reflect a specific recognition of the GU dinucleotide for splicing. Because recognition of the 5'SS must be linked to formation of the catalytic site, the identification of a specific and direct interaction between the 5'SS and Prp8 has significant implications for the role of this protein in the mechanism of mRNA splicing.     

Overlapping splicing regulatory motifs—combinatorial effects on splicing

Regulation of splicing in eukaryotes occurs through the coordinated action of multiple splicing factors. Exons and introns contain numerous putative binding sites for splicing regulatory proteins. Regulation of splicing is presumably achieved by the combinatorial output of the binding of splicing factors to the corresponding binding sites. Although putative regulatory sites often overlap, no extensive study has examined whether overlapping regulatory sequences provide yet another dimension to splicing regulation. Here we analyzed experimentally-identified splicing regulatory sequences using a computational method based on the natural distribution of nucleotides and splicing regulatory sequences. We uncovered positive and negative interplay between overlapping regulatory sequences. Examination of these overlapping motifs revealed a unique spatial distribution, especially near splice donor sites of exons with weak splice donor sites. The positively selected overlapping splicing regulatory motifs were highly conserved among different species, implying functionality. Overall, these results suggest that overlap of two splicing regulatory binding sites is an evolutionary conserved widespread mechanism of splicing regulation. Finally, over-abundant motif overlaps were experimentally tested in a reporting minigene revealing that overlaps may facilitate a mode of splicing that did not occur in the presence of only one of the two regulatory sequences that comprise it.     

Human, Drosophila, and C.elegans TDP43: nucleic acid binding properties and splicing regulatory function

TAR DNA binding protein (TDP43), a highly conserved heterogeneous nuclear ribonucleoprotein, was found to down-regulate splicing of the exon 9 cystic fibrosis transmembrane conductance regulator (CFTR) through specific binding to a UG-rich polymorphic region upstream of the 3' splice site. Despite the emergence of new information regarding the protein's nuclear localization and splicing regulatory activity, TDP43's role in cells remains elusive. To investigate the function of human TDP43 and its homologues, we cloned and characterized the proteins from Drosophila melanogaster and Caenorhabditis elegans. The proteins from human, fly, and worm show striking similarities in their nucleic acid binding specificity. We found that residues at two different positions, which show a strong conservation among TDP43 family members, are linked to the tight recognition of the target sequence. Our three-dimensional model of TDP43 in complex with a (UG)(m) sequence predicts that these residues make amino acid side-chain to base contacts. Moreover, our results suggest that Drosophila TDP43 is comparable to human TDP43 in regulating exon splicing. On the other hand, C.elegans TDP43 has no effect on exon recognition. TDP43 from C.elegans lacks the glycine-rich domain found at the carboxy terminus of the other two homologues. Mutants of human and fly TDP43 devoid of the C-terminal domain are likewise unable to affect splicing. Our studies suggest that the glycine-rich domain is essential for splicing regulation by human and fly TDP43.     

CELF proteins regulate CFTR pre-mRNA splicing: essential role of the divergent domain of ETR-3

Cystic fibrosis is a prominent genetic disease caused by mutations of the cystic fibrosis transmembrane conductance regulator (CFTR) gene. Among the many disease-causing alterations are pre-mRNA splicing defects that can hamper mandatory exon inclusion. CFTR exon 9 splicing depends in part on a polymorphic UG(m)U(n) sequence at the end of intron 8, which can be bound by TDP-43, leading to partial exon 9 skipping. CELF proteins, like CUG-BP1 and ETR-3, can also bind UG repeats and regulate splicing. We show here that ETR-3, but not CUG-BP1, strongly stimulates exon 9 skipping, although both proteins bind efficiently to the same RNA motif as TDP-43 and with higher affinity. We further show that the skipping of this exon may be due to the functional antagonism between U2AF⁶⁵ and ETR-3 binding onto the polymorphic U or UG stretch, respectively. Importantly, we demonstrate that the divergent domain of ETR-3 is critical for CFTR exon 9 skipping, as shown by deletion and domain-swapping experiments. We propose a model whereby several RNA-binding events account for the complex regulation of CFTR exon 9 inclusion, with strikingly distinct activities of ETR-3 and CUG-BP1, related to the structure of their divergent domain.     

Repositioning of the reaction intermediate within the catalytic center of the spliceosome

Conformational change within the spliceosome is required between the first catalytic step of pre-mRNA splicing, when the branch site attacks the 5' splice site (SS), and the second step, when the 5' exon attacks the 3'SS. Little is known, however, about repositioning of the reaction substrates during this transition. Whereas the 5'SS is positioned for the first step by pairing with the invariant U6 snRNA-ACAGAG site, we demonstrate that this pairing interaction must be disrupted to allow transition to the second step. We propose that removal of the branch structure from the catalytic center is in competition with binding of the 3'SS substrate for the second step. Changes in the relative occupancy of first and second step substrates at the catalytic center alter efficiency of the two steps of splicing, allowing use of suboptimal intron sequences and thereby altering substrate selectivity.     

The C-terminal region of hPrp8 interacts with the conserved GU dinucleotide at the 5' splice site

A U5 snRNP protein, hPrp8, forms a UV-induced crosslink with the 5' splice site (5'SS) RNA within splicing complex B assembled in trans- as well as in cis-splicing reactions. Both yeast and human Prp8 interact with the 5'SS, branch site, polypyrimidine tract, and 3'SS during splicing. To begin to define functional domains in Prp8 we have mapped the site of the 5'SS crosslink within the hPrp8 protein. Immunoprecipitation analysis limited the site of crosslink to the C-terminal 5060-kDa segment of hPrp8. In addition, size comparison of the crosslink-containing peptides generated with different proteolytic reagents with the pattern of fragments predicted from the hPrp8 sequence allowed for mapping of the crosslink to a stretch of five amino acids in the C-terminal portion of hPrp8 (positions 1894-1898). The site of the 5'SS:hPrp8 crosslink falls within a segment spanning the previously defined polypyrimidine tract recognition domain in yPrp8, suggesting that an overlapping region of Prp8 may be involved both in the 5'SS and polypyrimidine tract recognition events. In the context of other known interactions of Prp8, these results suggest that this protein may participate in formation of the catalytic center of the spliceosome.     

TDP-43 and FUS RNA-binding proteins bind distinct sets of cytoplasmic messenger RNAs and differently regulate their post-transcriptional fate in motoneuron-like cells

The RNA-binding proteins TDP-43 and FUS form abnormal cytoplasmic aggregates in affected tissues of patients with amyotrophic lateral sclerosis and frontotemporal lobar dementia. TDP-43 and FUS localize mainly in the nucleus where they regulate pre-mRNA splicing, but they are also involved in mRNA transport, stability, and translation. To better investigate their cytoplasmic activities, we applied an RNA immunoprecipitation and chip analysis to define the mRNAs associated to TDP-43 and FUS in the cytoplasmic ribonucleoprotein complexes from motoneuronal NSC-34 cells. We found that they bind different sets of mRNAs although converging on common cellular pathways. Bioinformatics analyses identified the (UG)(n) consensus motif in 80% of 3'-UTR sequences of TDP-43 targets, whereas for FUS the binding motif was less evident. By in vitro assays we validated binding to selected target 3'-UTRs, including Vegfa and Grn for TDP-43, and Vps54, Nvl, and Taf15 for FUS. We showed that TDP-43 has a destabilizing activity on Vegfa and Grn mRNAs and may ultimately affect progranulin protein content, whereas FUS does not affect mRNA stability/translation of its targets. We also demonstrated that three different point mutations in TDP-43 did not change the binding affinity for Vegfa and Grn mRNAs or their protein level. Our data indicate that TDP-43 and FUS recognize distinct sets of mRNAs and differently regulate their fate in the cytoplasm of motoneuron-like cells, therefore suggesting complementary roles in neuronal RNA metabolism and neurodegeneration.     

The canonical GU dinucleotide at the 5' splice site is recognized by p220 of the U5 snRNP within the spliceosome.

Specific recognition of the 5' splice site (5'SS) by the spliceosome components was studied using a simple in vitro system in which a short 5'SS RNA oligonucleotide specifically induces the assembly of snRNP particles into spliceosome-like complexes and actively participates in a trans-splicing reaction. Short-range cross-liking demonstrates that a U5 snRNP protein component, p220 (the human analogue of the yeast Prp8) specifically interacts with the invariant GU dinucleotide at the 5' end of the intron. The GU:p220 interaction can be detected in the functional splicing complex B. Although p220 has been known to contact several nucleotides around the 5' splice junction, the p220:GU dinucleotide interaction described here is remarkably specific. Consistent with the high conservation of the GU, even minor modifications of this element affect recognition of the 5'SS RNA by p220. Substitution of uridine at the GU with base analogues containing a large methyl or iodo group, but not a smaller flouro group at base position 5, interferes with association of 5'SS RNA with snRNP complexes and their functional participation in splicing.     

Systematic study of sequence motifs for RNA trans splicing in Trypanosoma brucei

mRNA maturation in Trypanosoma brucei depends upon trans splicing, and variations in trans-splicing efficiency could be an important step in controlling the levels of individual mRNAs. RNA splicing requires specific sequence elements, including conserved 5' splice sites, branch points, pyrimidine-rich regions [poly(Y) tracts], 3' splice sites (3'SS), and sometimes enhancer elements. To analyze sequence requirements for efficient trans splicing in the poly(Y) tract and around the 3'SS, we constructed a luciferase-beta-galactosidase double-reporter system. By testing approximately 90 sequences, we demonstrated that the optimum poly(Y) tract length is approximately 25 nucleotides. Interspersing a purely uridine-containing poly(Y) tract with cytidine resulted in increased trans-splicing efficiency, whereas purines led to a large decrease. The position of the poly(Y) tract relative to the 3'SS is important, and an AC dinucleotide at positions -3 and -4 can lead to a 20-fold decrease in trans splicing. However, efficient trans splicing can be restored by inserting a second AG dinucleotide downstream, which does not function as a splice site but may aid in recruitment of the splicing machinery. These findings should assist in the development of improved algorithms for computationally identifying a 3'SS and help to discriminate noncoding open reading frames from true genes in current efforts to annotate the T. brucei genome.     

Nuclear factor TDP-43 and SR proteins promote in vitro and in vivo CFTR exon 9 skipping

Alternative splicing of human cystic fibrosis transmembrane conductance regulator (CFTR) exon 9 is regulated by a combination of cis-acting elements distributed through the exon and both flanking introns (IVS8 and IVS9). Several studies have identified in the IVS8 intron 3' splice site a regulatory element that is composed of a polymorphic (TG)m(T)n repeated sequence. At present, no cellular factors have been identified that recognize this element. We have identified TDP-43, a nuclear protein not previously described to bind RNA, as the factor binding specifically to the (TG)m sequence. Transient TDP-43 overexpression in Hep3B cells results in an increase in exon 9 skipping. This effect is more pronounced with concomitant overexpression of SR proteins. Antisense inhibition of endogenous TDP-43 expression results in increased inclusion of exon 9, providing a new therapeutic target to correct aberrant splicing of exon 9 in CF patients. The clinical and biological relevance of this finding in vivo is demonstrated by our characterization of a CF patient carrying a TG10T9(DeltaF508)/TG13T3(wt) genotype leading to a disease-causing high proportion of exon 9 skipping.     

TDP-43 regulates global translational yield by splicing of exon junction complex component SKAR

TDP-43 is linked to neurodegenerative diseases including frontotemporal dementia and amyotrophic lateral sclerosis. Mostly localized in the nucleus, TDP-43 acts in conjunction with other ribonucleoproteins as a splicing co-factor. Several RNA targets of TDP-43 have been identified so far, but its role(s) in pathogenesis remains unclear. Using Affymetrix exon arrays, we have screened for the first time for splicing events upon TDP-43 knockdown. We found alternative splicing of the ribosomal S6 kinase 1 (S6K1) Aly/REF-like target (SKAR) upon TDP-43 knockdown in non-neuronal and neuronal cell lines. Alternative SKAR splicing depended on the first RNA recognition motif (RRM1) of TDP-43 and on 5'-GA-3' and 5'-UG-3' repeats within the SKAR pre-mRNA. SKAR is a component of the exon junction complex, which recruits S6K1, thereby facilitating the pioneer round of translation and promoting cell growth. Indeed, we found that expression of the alternatively spliced SKAR enhanced S6K1-dependent signaling pathways and the translational yield of a splice-dependent reporter. Consistent with this, TDP-43 knockdown also increased translational yield and significantly increased cell size. This indicates a novel mechanism of deregulated translational control upon TDP-43 deficiency, which might contribute to pathogenesis of the protein aggregation diseases frontotemporal dementia and amyotrophic lateral sclerosis.     

A short 5' splice site RNA oligo can participate in both steps of splicing in mammalian extracts.

A short 5' splice site RNA oligonucleotide (5'SS RNA oligo) undergoes both steps of splicing when a second RNA containing the 3' splice site region (3'SS RNA) is added in trans. This trans-splicing reaction displays the same 5' and 3' splice site sequence requirements as cis-splicing of full-length pre-mRNA. The analysis of RNA-snRNP complexes formed on each of the two splice site RNAs is consistent with the formation of partial complexes, which then associate to form the complete spliceosome. Specifically, U2 snRNP bound to the 3'SS RNA associates with U4/U5/U6 snRNP bound to the 5'SS RNA oligo. Thus, as expected, trans-splicing depends on the integrity of U2, U4, and U6 snRNAs. However, unlike cis-splicing, trans-splicing is enhanced when the 5' end of U1 snRNA is blocked or removed or when the U1 snRNP is depleted. Thus, the early regulatory requirement for U1 snRNP, which is essential in cis-splicing, is bypassed in this trans-splicing system. This simplified trans-splicing reaction offers a unique model system in which to study the mechanistic details of pre-mRNA splicing.     

TDP-43 regulates its mRNA levels through a negative feedback loop

TAR DNA-binding protein (TDP-43) is an evolutionarily conserved heterogeneous nuclear ribonucleoprotein (hnRNP) involved in RNA processing, whose abnormal cellular distribution and post-translational modification are key markers of certain neurodegenerative diseases, such as amyotrophic lateral sclerosis and frontotemporal lobar degeneration. We generated human cell lines expressing tagged forms of wild-type and mutant TDP-43 and observed that TDP-43 controls its own expression through a negative feedback loop. The RNA-binding properties of TDP-43 are essential for the autoregulatory activity through binding to 3' UTR sequences in its own mRNA. Our analysis indicated that the C-terminal region of TDP-43, which mediates TDP-43-hnRNP interactions, is also required for self-regulation. TDP-43 binding to its 3' UTR does not significantly change the pre-mRNA splicing pattern but promotes RNA instability. Moreover, blocking exosome-mediated degradation partially recovers TDP-43 levels. Our findings demonstrate that cellular TDP-43 levels are under tight control and it is likely that disease-associated TDP-43 aggregates disrupt TDP-43 self-regulation, thus contributing to pathogenesis.