Prp40 pre-mRNA processing factor 40 homolog B (PRPF40B) associates with SF1 and U2AF65 and modulates alternative pre-mRNA splicing in vivo

The first stable complex formed during the assembly of spliceosomes onto pre-mRNA substrates in mammals includes U1 snRNP, which recognizes the 5′ splice site, and the splicing factors SF1 and U2AF, which bind the branch point sequence, polypyrimidine tract, and 3′ splice site. The 5′ and 3′ splice site complexes are thought to be joined together by protein–protein interactions mediated by factors that ensure the fidelity of the initial splice site recognition. In this study, we identified and characterized PRPF40B, a putative mammalian ortholog of the U1 snRNP-associated yeast splicing factor Prp40. PRPF40B is highly enriched in speckles with a behavior similar to splicing factors. We demonstrated that PRPF40B interacts directly with SF1 and associates with U2AF⁶⁵. Accordingly, PRPF40B colocalizes with these splicing factors in the cell nucleus. Splicing assays with reporter minigenes revealed that PRPF40B modulates alternative splice site selection. In the case of Fas regulation of alternative splicing, weak 5′ and 3′ splice sites and exonic sequences are required for PRPF40B function. Placing our data in a functional context, we also show that PRPF40B depletion increased Fas/CD95 receptor number and cell apoptosis, which suggests the ability of PRPF40B to alter the alternative splicing of key apoptotic genes to regulate cell survival.     

A novel function for the U2AF 65 splicing factor in promoting pre-mRNA 3'-end processing

Splicing and 3′-end processing (including cleavage and polyadenylation) of vertebrate pre-mRNAs are tightly coupled events that contribute to the extensive molecular network that coordinates gene expression. Sequences within the terminal intron of genes are essential to stimulate pre-mRNA 3′-end processing, although the factors mediating this effect are unknown. Here, we show that the pyrimidine tract of the last splice acceptor site of the human β-globin gene is necessary to stimulate mRNA 3′-end formation in vivo and binds the U2AF 65 splicing factor. Naturally occurring β-thalassaemia-causing mutations within the pyrimidine tract reduces both U2AF 65 binding and 3′-end cleavage efficiency. Significantly, a fusion protein containing U2AF 65, when tethered upstream of a cleavage/polyadenylation site, increases 3′-end cleavage efficiency in vitro and in vivo. Therefore, we propose that U2AF 65 promotes 3′-end processing, which contributes to 3′-terminal exon definition.     

Analysis of Spliceosomal Proteins in Trypanosomatids Reveals Novel Functions in mRNA Processing

In trypanosomatids, all mRNAs are processed via trans-splicing, although cis-splicing also occurs. In trans-splicing, a common small exon, the spliced leader (SL), which is derived from a small SL RNA species, is added to all mRNAs. Sm and Lsm proteins are core proteins that bind to U snRNAs and are essential for both these splicing processes. In this study, SmD3- and Lsm3-associated complexes were purified to homogeneity from Leishmania tarentolae. The purified complexes were analyzed by mass spectrometry, and 54 and 39 proteins were purified from SmD3 and Lsm complexes, respectively. Interestingly, among the proteins purified from Lsm3, no mRNA degradation factors were detected, as in Lsm complexes from other eukaryotes. The U1A complex was purified and mass spectrometry analysis identified, in addition to U1 small nuclear ribonucleoprotein (snRNP) proteins, additional co-purified proteins, including the polyadenylation factor CPSF73. Defects observed in cells silenced for U1 snRNP proteins suggest that the U1 snRNP functions exclusively in cis-splicing, although U1A also participates in polyadenylation and affects trans-splicing. The study characterized several trypanosome-specific nuclear factors involved in snRNP biogenesis, whose function was elucidated in Trypanosoma brucei. Conserved factors, such as PRP19, which functions at the heart of every cis-spliceosome, also affect SL RNA modification; GEMIN2, a protein associated with SMN (survival of motor neurons) and implicated in selective association of U snRNA with core Sm proteins in trypanosomes, is a master regulator of snRNP assembly. This study demonstrates the existence of trypanosomatid-specific splicing factors but also that conserved snRNP proteins possess trypanosome-specific functions.     

A physical and functional link between splicing factors promotes pre-mRNA 3′ end processing

Polypyrimidine tract-binding protein (PTB) is a splicing regulator that also plays a positive role in pre-mRNA 3′ end processing when bound upstream of the polyadenylation signal (pA signal). Here, we address the mechanism of PTB stimulatory function in mRNA 3′ end formation. We identify PTB as the protein factor whose binding to the human β-globin (HBB) 3′ UTR is abrogated by a 3′ end processing-inactivating mutation. We show that PTB promotes both in vitro 3′ end cleavage and polyadenylation and recruits directly the splicing factor hnRNP H to G-rich sequences associated with several pA signals. Increased binding of hnRNP H results in stimulation of polyadenylation through a direct interaction with poly(A) polymerase. Therefore, our results provide evidence of a concerted regulation of pA signal recognition by splicing factors bound to auxiliary polyadenylation sequence elements.     

ElrA binding to the 3'UTR of cyclin E1 mRNA requires polyadenylation elements

The early cell divisions of Xenopus laevis and other metazoan embryos occur in the presence of constitutively high levels of the cell cycle regulator cyclin E1. Upon completion of the 12th cell division, a time at which many maternal proteins are downregulated by deadenylation and destabilization of their encoding mRNAs, maternal cyclin E1 protein is downregulated while its mRNA is polyadenylated and stable. We report here that stable polyadenylation of cyclin E1 mRNA requires three cis-acting elements in the 3′ untranslated region; the nuclear polyadenylation sequence, a contiguous cytoplasmic polyadenylation element and an upstream AU-rich element. ElrA, the Xenopus homolog of HuR and a member of the ELAV gene family binds the cyclin E1 3′UTR with high affinity. Deletion of these elements dramatically reduces the affinity of ElrA for the cyclin E1 3′UTR, abolishes polyadenylation and destabilizes the mRNA. Together, these findings provide compelling evidence that ElrA functions in polyadenylation and stabilization of cyclin E1 mRNA via binding these elements.     

A Role for SRp54 during Intron Bridging of Small Introns with Pyrimidine Tracts Upstream of the Branch Point

One of the earliest steps in pre-mRNA recognition involves binding of the splicing factor U2 snRNP auxiliary factor (U2AF or MUD2 in Saccharomyces cerevisiae) to the 3′ splice site region. U2AF interacts with a number of other proteins, including members of the serine/arginine (SR) family of splicing factors as well as splicing factor 1 (SF1 or branch point bridging protein in S. cerevisiae), thereby participating in bridging either exons or introns. In vertebrates, the binding site for U2AF is the pyrimidine tract located between the branch point and 3′ splice site. Many small introns, especially those in nonvertebrates, lack a classical 3′ pyrimidine tract. Here we show that a 59-nucleotide Drosophila melanogaster intron contains C-rich pyrimidine tracts between the 5′ splice site and branch point that are needed for maximal binding of both U1 snRNPs and U2 snRNPs to the 5′ and 3′ splice site, respectively, suggesting that the tracts are the binding site for an intron bridging factor. The tracts are shown to bind both U2AF and the SR protein SRp54 but not SF1. Addition of a strong 3′ pyrimidine tract downstream of the branch point increases binding of SF1, but in this context, the upstream pyrimidine tracts are inhibitory. We suggest that U2AF- and/or SRp54-mediated intron bridging may be an alternative early recognition mode to SF1-directed bridging for small introns, suggesting gene-specific early spliceosome assembly.Pre-mRNA splicing is a conserved process occurring in a wide variety of eucaryotes with differing exon/intron architectures (reviewed in references 4, 6, 9, 15, 20, and 26). Vertebrates typically have small exons and large introns. Nonmetazoans frequently have the opposite genetic organization, with introns smaller than the minimum permissible for splicing of a vertebrate intron. Drosophila melanogaster possesses a mixture of these two classes of intron sizes (16, 23). In addition, more than half of the small introns in Drosophila are missing a prominent vertebrate splicing signal, the 3′ polypyrimidine tract (23). For these reasons, Drosophila provides a model system in which to study potential mechanistic variations operating during recognition of splicing signals.In the general model of early vertebrate spliceosome complex assembly, U1 snRNP binds to the 5′ splice site and U2 snRNP auxiliary factor (U2AF) binds to the 3′ polypyrimidine tract, thereby facilitating U2 snRNP interaction with the branch point. Various members of the serine/arginine (SR) family of proteins may participate by promoting or stabilizing these interactions (reviewed in references 13, 22, and 31). This family of proteins may also act as exon or intron bridging factors via their SR-mediated interaction with SR domains on the small subunit of U2AF (U2AF³⁵) and the U1 70K protein (32, 33, 38). SF1, originally discovered as an essential splicing factor in reconstitution assays (19), has also been observed to bind to the branch point (7, 8). In yeast, BBP (branch point bridging protein), the ortholog to SF1, functions as an intron bridging factor via interactions with U1 snRNP-associated proteins and the large subunit of U2AF (U2AF⁶⁵) (1, 2). It is assumed that vertebrate SF1 can play a similar role, although the mammalian equivalents to the yeast U1 snRNP proteins that interact with BBP have not yet been identified. Furthermore, the relationship between bridging by SR proteins and that afforded by SF1 is unclear.We have previously examined the cis-acting sequences required for efficient splicing of a constitutively spliced small (59-nucleotide [nt]) intron from the D. melanogaster mle gene that lacks a well-defined pyrimidine tract between the branch point and 3′ splice site (18, 29). Assembly of initial ATP-dependent spliceosomes (complex A) on the mle intron requires both the 5′ and 3′ splice sites, suggesting concerted recognition of the entire intron (29). Instead of a classic pyrimidine tract, the mle intron contains two C-rich tracts located between the 5′ splice site and branch point that are necessary for efficient splicing of this intron (18). In addition to a requirement for maximal splicing efficiency, the pyrimidine stretches are also necessary for binding of U2AF, interaction of factors with the 5′ splice site, and proper assembly of the active spliceosome, suggesting that these sequences affect early assembly events at both ends of this small intron. Interestingly, the upstream C-rich tracts are inhibitory if a classical 3′ pyrimidine tract is introduced between the branch point and 3′ splice site (18). This observation suggests competing pathways of factor binding to this substrate and also raises the possibility of alternative gene-specific modes of association of constitutive factors with introns.Here we demonstrate that both U2AF and an SR protein, SRp54, interact with the C-rich tracts in the mle intron. The central location of the pyrimidine tracts, their importance for maximal splicing, and the ability of human SRp54 to interact with U2AF⁶⁵ instead of U2AF³⁵ (37) suggested that the binding of SRp54 to the tracts could replace SF1 in bridging this intron. Immunoprecipitation studies using an antibody specific for SF1 indicated that SF1 did not contact mle precursor RNA unless a pyrimidine tract was introduced downstream of the branch point. Furthermore, antibodies against either SRp54 or U2AF immunoprecipitated both halves of a precleaved mle splicing substrate, suggesting that these factors either directly or indirectly interact with both the 5′ and 3′ splice sites. We suggest that SRp54 participates in bridging the small mle intron via its ability to bind both the C-rich tracts and the large subunit of U2AF.     

Cancer-relevant Splicing Factor CAPERα Engages the Essential Splicing Factor SF3b155 in a Specific Ternary Complex

U2AF homology motifs (UHMs) mediate protein-protein interactions with U2AF ligand motifs (ULMs) of pre-mRNA splicing factors. The UHM-containing alternative splicing factor CAPERα regulates splicing of tumor-promoting VEGF isoforms, yet the molecular target of the CAPERα UHM is unknown. Here we present structures of the CAPERα UHM bound to a representative SF3b155 ULM at 1.7 Å resolution and, for comparison, in the absence of ligand at 2.2 Å resolution. The prototypical UHM/ULM interactions authenticate CAPERα as a bona fide member of the UHM family of proteins. We identify SF3b155 as the relevant ULM-containing partner of full-length CAPERα in human cell extracts. Isothermal titration calorimetry comparisons of the purified CAPERα UHM binding known ULM-containing proteins demonstrate that high affinity interactions depend on the presence of an intact, intrinsically unstructured SF3b155 domain containing seven ULM-like motifs. The interplay among bound CAPERα molecules gives rise to the appearance of two high affinity sites in the SF3b155 ULM-containing domain. In conjunction with the previously identified, UHM/ULM-mediated complexes of U2AF⁶⁵ and SPF45 with SF3b155, this work demonstrates the capacity of SF3b155 to offer a platform for coordinated recruitment of UHM-containing splicing factors.     

Splicing factors stimulate polyadenylation via USEs at non-canonical 3' end formation signals

The prothrombin (F2) 3' end formation signal is highly susceptible to thrombophilia-associated gain-of-function mutations. In its unusual architecture, the F2 3' UTR contains an upstream sequence element (USE) that compensates for weak activities of the non-canonical cleavage site and the downstream U-rich element. Here, we address the mechanism of USE function. We show that the F2 USE contains a highly conserved nonameric core sequence, which promotes 3' end formation in a position- and sequence-dependent manner. We identify proteins that specifically interact with the USE, and demonstrate their function as trans-acting factors that promote 3' end formation. Interestingly, these include the splicing factors U2AF35, U2AF65 and hnRNPI. We show that these splicing factors not only modulate 3' end formation via the USEs contained in the F2 and the complement C2 mRNAs, but also in the biocomputationally identified BCL2L2, IVNS and ACTR mRNAs, suggesting a broader functional role. These data uncover a novel mechanism that functionally links the splicing and 3' end formation machineries of multiple cellular mRNAs in an USE-dependent manner.     

A high-fat diet increases l-carnitine synthesis through a differential maturation of the Bbox1 mRNAs

l-carnitine is a key molecule in both mitochondrial and peroxisomal lipid metabolisms. l-carnitine is biosynthesized from gamma-butyrobetaine by a reaction catalyzed by the gamma-butyrobetaine hydroxylase (Bbox1). The aim of this work was to identify molecular mechanisms involved in the regulation of l-carnitine biosynthesis and availability. Using 3′ RACE, we identified four alternatively polyadenylated Bbox1 mRNAs in rat liver. We utilized a combination of in vitro experiments using hybrid constructs containing the Bbox1 3′ UTR and in vivo experiments on rat liver mRNAs to reveal specificities in the different Bbox1 mRNA isoforms, especially in terms of polyadenylation efficiency, mRNA stability and translation efficiency. This complex maturation process of the Bbox1 mRNAs in the liver was studied on rats fed a high-fat diet. High-fat diet selectively increased the level of three Bbox1 mRNA isoforms in rat liver and the alternative use of polyadenylation sites contributed to the global increase in Bbox1 enzymatic activity and l-carnitine levels. Our results show that the maturation of Bbox1 mRNAs is nutritionally regulated in the liver through a selective polyadenylation process to adjust l-carnitine biosynthesis to the energy supply.