ETR-3 and CELF4 protein domains required for RNA binding and splicing activity in vivo

Members of the CUG-BP and ETR-3 like factor (CELF) protein family bind within conserved intronic elements (called MSEs) flanking the cardiac troponin T (cTNT) alternative exon 5 and promote exon inclusion in vivo and in vitro. Here we use a comparative deletion analysis of two family members (ETR-3 and CELF4) to identify separate domains required for RNA binding and splicing activity in vivo. CELF proteins contain two adjacent RNA binding domains (RRM1 and RRM2) near the N-terminus and one RRM (RRM3) near the C-terminus, which are separated by a 160–230 residue divergent domain of unknown function. Either RRM1 or RRM2 of CELF4 are necessary and sufficient for binding MSE RNA and RRM2 plus an additional 66 amino acids of the divergent domain are as effective as full-length protein in activating MSE-dependent splicing in vivo. Non-overlapping N- and C-terminal regions of ETR-3 containing either RRM1 and RRM2 or RRM3 plus segments of the adjacent divergent domain activate MSE-dependent exon inclusion demonstrating an unusual functional redundancy of the N- and C-termini of the protein. These results identify specific regions of ETR-3 and CELF4 that are likely targets of protein–protein interactions required for splicing activation.     

MBNL and CELF proteins regulate alternative splicing of the skeletal muscle chloride channel CLCN1

The expression and function of the skeletal muscle chloride channel CLCN1/ClC-1 is regulated by alternative splicing. Inclusion of the CLCN1 exon 7A is aberrantly elevated in myotonic dystrophy (DM), a genetic disorder caused by the expansion of a CTG or CCTG repeat. Increased exon 7A inclusion leads to a reduction in CLCN1 function, which can be causative of myotonia. Two RNA-binding protein families—muscleblind-like (MBNL) and CUG-BP and ETR-3-like factor (CELF) proteins—are thought to mediate the splicing misregulation in DM. Here, we have identified multiple factors that regulate the alternative splicing of a mouse Clcn1 minigene. The inclusion of exon 7A was repressed by MBNL proteins while promoted by an expanded CUG repeat or CELF4, but not by CUG-BP. Mutation analyses suggested that exon 7A and its flanking region mediate the effect of MBNL1, whereas another distinct region in intron 6 mediates that of CELF4. An exonic splicing enhancer essential for the inclusion of exon 7A was identified at the 5′ end of this exon, which might be inhibited by MBNL1. Collectively, these results provide a mechanistic model for the regulation of Clcn1 splicing, and reveal novel regulatory properties of MBNL and CELF proteins.     

CELF6, a member of the CELF family of RNA-binding proteins, regulates muscle-specific splicing enhancer-dependent alternative splicing

We previously described a family of five RNA-binding proteins: CUG-binding protein, embryonic lethal abnormal vision-type RNA-binding protein 3, and the CUG-binding protein and embryonic lethal abnormal vision-type RNA-binding protein 3-like factors (CELFs) 3, 4, and 5. We demonstrated that all five of these proteins specifically activate exon inclusion of cardiac troponin T minigenes in vivo via muscle-specific splicing enhancer (MSE) sequences. We also predicted that a sixth family member, CELF6, was located on chromosome 15. Here, we describe the isolation and characterization of CELF6. Like the previously described CELF proteins, CELF6 shares a domain structure containing three RNA-binding domains and a divergent domain of unknown function. CELF6 is strongly expressed in kidney, brain, and testis and is expressed at very low levels in most other tissues. In the brain, expression is widespread and maintained from the fetus to the adult. CELF6 activates exon inclusion of a cardiac troponin T minigene in transient transfection assays in an MSE-dependent manner and can activate inclusion via multiple copies of a single element, MSE2. These results place CELF6 in a functional subfamily of CELF proteins that includes CELFs 3, 4, and 5. CELF6 also promotes skipping of exon 11 of insulin receptor, a known target of CELF activity that is expressed in kidney.     

Plant serine/arginine-rich proteins and their role in pre-mRNA splicing

Pre-messenger RNA (pre-mRNA) splicing, a process by which mature mRNAs are generated by excision of introns and ligation of exons, is an important step in the regulation of gene expression in all eukaryotes. Selection of alternative splice sites in a pre-mRNA generates multiple mRNAs from a single gene that encode structurally and functionally distinct proteins. Alternative splicing of pre-mRNAs contributes greatly to the proteomic complexity of plants and animals and increases the coding potential of a genome. However, the mechanisms that regulate constitutive and alternative splicing of pre-mRNA are not understood in plants. A serine/arginine-rich (SR) family of proteins is implicated in constitutive and alternative splicing of pre-mRNAs. Here I review recent progress in elucidating the roles of serine/arginine-rich proteins in pre-mRNA splicing.     

The neurofibromatosis type I pre-mRNA is a novel target of CELF protein-mediated splicing regulation

The CUG-BP and ETR-3 like factors (CELF) are a family of six highly conserved RNA-binding proteins that preferentially bind to UG-rich sequences. One of the key functions of these proteins is to mediate alternative splicing in a number of tissues, including brain, heart and muscle. To fully understand the function of CELF proteins, it is important to identify downstream targets of CELF proteins. In this communication, we report that neurofibromatosis type I (NF1) exon 23a is a novel target of CELF protein-mediated splicing regulation in neuron-like cells. NF1 regulates Ras signaling, and the isoform that excludes exon 23a shows 10 times greater ability to down-regulate Ras signaling than the isoform that includes exon 23a. Five of the six CELF proteins strongly suppress the inclusion of NF1 exon 23a. Over-expression or siRNA knockdown of these proteins in cell transfection experiments altered the levels of NF1 exon 23a inclusion. In vitro binding and splicing analyses demonstrate that CELF proteins block splicing through interfering with binding of U2AF⁶⁵. These studies, combined with our previous investigations demonstrating a role for Hu proteins and TIA-1/TIAR in controlling NF1 exon 23a inclusion, highlight the complex nature of regulation of this important alternative splicing event.     

Lsm proteins promote regeneration of pre-mRNA splicing activity

Lsm proteins are ubiquitous, multifunctional proteins that affect the processing of most RNAs in eukaryotic cells, but their function is unknown. A complex of seven Lsm proteins, Lsm2-8, associates with the U6 small nuclear RNA (snRNA) that is a component of spliceosome complexes in which pre-mRNA splicing occurs. Spliceosomes contain five snRNAs, U1, U2, U4, U5, and U6, that are packaged as ribonucleoprotein particles (snRNPs). U4 and U6 snRNAs contain extensive sequence complementarity and interact to form U4/U6 di-snRNPs. U4/U6 di-snRNPs associate with U5 snRNPs to form U4/U6.U5 tri-snRNPs prior to spliceosome assembly. Within spliceosomes, disruption of base-paired U4/U6 heterodimer allows U6 snRNA to form part of the catalytic center. Following completion of the splicing reaction, snRNPs must be recycled for subsequent rounds of splicing, although little is known about this process. Here we present evidence that regeneration of splicing activity in vitro is dependent on Lsm proteins. RNP reconstitution experiments with exogenous U6 RNA show that Lsm proteins promote the formation of U6-containing complexes and suggest that Lsm proteins have a chaperone-like function, supporting the assembly or remodeling of RNP complexes involved in splicing. Such a function could explain the involvement of Lsm proteins in a wide variety of RNA processing pathways.     

Ubiquitin binding by a variant Jab1/MPN domain in the essential pre-mRNA splicing factor Prp8p

The U1, U2, U4/U6, and U5 small nuclear ribonucleoproteins (snRNPs) are components of the spliceosome, which catalyzes pre-mRNA splicing. One of the largest and the most highly conserved proteins in the spliceosome is Prp8p, a component of the U5 snRNP. Despite its size and conservation, very few motifs have been identified that suggest specific biochemical functions. A variant of the Jab1/MPN domain found in a class of deubiquitinating enzymes is present near the C terminus of Prp8p. Ubiquitination regulates a broad range of cellular pathways, and its functions generally require ubiquitin recognition by one or more ubiquitin-binding domains (UBDs). No precise role for ubiquitin has been defined in the pre-mRNA splicing pathway, and no known UBDs have been found within splicing proteins. Here we show that a Prp8p fragment containing the Jab1/MPN domain binds directly to ubiquitin with an affinity comparable to other known UBDs. Several mutations within this domain that compromise splicing also reduce interaction of the fragment with ubiquitin-Sepharose. Our results define a new UBD and suggest functional links between ubiquitin and the pre-mRNA splicing machinery.     

Human splicing factor SF3a, but not SF1, is essential for pre-mRNA splicing in vivo

The three subunits of human splicing factor SF3a are essential for the formation of the functional 17S U2 snRNP and prespliceosome assembly in vitro. RNAi-mediated depletion indicates that each subunit is essential for viability of human cells. Knockdown of single subunits results in a general block in splicing strongly suggesting that SF3a is a constitutive splicing factor in vivo. In contrast, splicing of several endogenous and reporter pre-mRNAs is not affected after knockdown of SF1, which functions at the onset of spliceosome assembly in vitro and is essential for cell viability. Thus, SF1 may only be required for the splicing of a subset of pre-mRNAs. We also observe a reorganization of U2 snRNP components in SF3a-depleted cells, where U2 snRNA and U2-B' are significantly reduced in nuclear speckles and the nucleoplasm, but still present in Cajal bodies. Together with the observation that the 17S U2 snRNP cannot be detected in extracts from SF3a-depleted cells, our results provide further evidence for a function of Cajal bodies in U2 snRNP biogenesis.     

A novel set of spliceosome-associated proteins and the essential splicing factor PSF bind stably to pre-mRNA prior to catalytic step II of the splicing reaction.

We have isolated and determined the protein composition of the spliceosomal complex C. The pre-mRNA in this complex has undergone catalytic step I, but not step II, of the splicing reaction. We show that a novel set of 14 spliceosome-associated proteins (SAPs) and the essential splicing factor PSF are specifically associated with the C complex, implicating these proteins in catalytic step II. Significantly, immunodepletion and biochemical complementation studies demonstrate directly that PSF is essential for catalytic step II. Purified PSF is known to UV crosslink to pyrimidine tracts, and our data show that PSF UV crosslinks to pre-mRNA in purified C complex. Thus, PSF may replace the 3' splice site binding factor U2AF65 which is destabilized during spliceosome assembly. Finally, we show that SAPs 60 and 90, which are present in both the B and C complexes, are specifically associated with U4 and U6 snRNPs, and thus may have important roles in the functioning of these snRNPs during the splicing reaction.     

Structural and functional analysis of essential pre-mRNA splicing factor Prp19p

U-box-containing Prp19p is an integral component of the Prp19p-associated complex (the nineteen complex, or NTC) that is essential for activation of the spliceosome. Prp19p makes numerous protein-protein contacts with other NTC components and is required for NTC stability. Here we show that Prp19p forms a tetramer in vitro and in vivo and we map the domain required for its oligomerization to a central tetrameric coiled-coil. Biochemical and in vivo analyses are consistent with Prp19p tetramerization providing an interaction surface for a single copy of its binding partner, Cef1p. Electron microscopy showed that the isolated Prp19p tetramer is an elongated particle consisting of four globular WD40 domains held together by a central stalk consisting of four N-terminal U-boxes and four coiled-coils. These structural and functional data provide a basis for understanding the role of Prp19p as a key architectural component of the NTC.     

Antagonistic regulation of alpha-actinin alternative splicing by CELF proteins and polypyrimidine tract binding protein

The alpha-actinin gene has a pair of alternatively spliced exons. The smooth muscle (SM) exon is repressed in most cell types by polypyrimidine tract binding protein (PTB). CELF (CUG-BP and ETR3-like factors) family proteins, splicing regulators whose activities are altered in myotonic dystrophy, were found to coordinately regulate selection of the two alpha-actinin exons. CUG-BP and ETR3 activated the SM exon, and along with CELF4 they were also able to repress splicing of the NM (nonmuscle) exon both in vivo and in vitro. Activation of SM exon splicing was associated with displacement of PTB from the polypyrimidine tract by binding of CUG-BP at adjacent sites. Our data provides direct evidence for the activity of CELF proteins as both activators and repressors of splicing within a single-model system of alternative splicing, and suggests a model whereby alpha-actinin alternative splicing is regulated by synergistic and antagonistic interactions between members of the CELF and PTB families.     

The role of U5 snRNP in pre-mRNA splicing.

The current model for the function of the U5 small nuclear ribonucleoprotein particle (snRNP) in the spliceosome proposes that U5 carries binding sites for the 5' and 3' exons, allowing the spliceosome to 'tether' the 5' exon intermediate produced by the first catalytic step and align it with the 3' exon for the second step. Functional analysis of U5 snRNA in cis-spliceosomes has provided support for this model, and data from nematode and trypanosome splicing systems suggest that U5 or a U5-like snRNA performs a similar role in trans-splicing.