Interaction of the U1 snRNP with nonconserved intronic sequences affects 5' splice site selection

Intron definition and splice site selection occur at an early stage during assembly of the spliceosome, the complex mediating pre-mRNA splicing. Association of U1 snRNP with the pre-mRNA is required for these early steps. We report here that the yeast U1 snRNP-specific protein Nam8p is a component of the commitment complexes, the first stable complexes assembled on pre-mRNA. In vitro and in vivo, Nam8p becomes indispensable for efficient 5' splice site recognition when this process is impaired as a result of the presence of noncanonical 5' splice sites or the absence of a cap structure. Nam8p stabilizes commitment complexes in the latter conditions. Consistent with this, Nam8p interacts with the pre-mRNA downstream of the 5' splice site, in a region of nonconserved sequence. Substitutions in this region affect splicing efficiency and alternative splice site choice in a Nam8p-dependent manner. Therefore, Nam8p is involved in a novel mechanism by which a snRNP component can affect splice site choice and regulate intron removal through its interaction with a nonconserved sequence. This supports a model where early 5' splice recognition results from a network of interactions established by the splicing machinery with various regions of the pre-mRNA.     

Mammalian pre-mRNA branch site selection by U2 snRNP involves base pairing

SV40 early pre-mRNA is alternatively spliced to produce large T and small t mRNAs by use of different 5'-splice sites and a shared 3'-splice site. The large T splicing pathway uses multiple lariat branch sites, whereas small t splicing, constrained by its small intron size, can use only one. We exploited this situation to test the hypothesis that RNA-RNA base pairing between U2 snRNA and the branch site sequence is important in mammalian pre-mRNA splicing by constructing and analyzing several mutations in the small t pre-mRNA branch site (UUCUAAU). All of the mutations resulted in substantial decreases in small t splicing relative to large T. To test whether these effects resulted from decreased base pairing with U2 snRNA, compensatory mutations were introduced at the appropriate positions (nucleotides 34-36) in a cloned human U2 gene. All branch site mutations tested (four separate single base substitutions and two triple mutations) were suppressed (i.e., small t splicing was increased) by the appropriate U2 mutations. These results establish that recognition of the poorly conserved mammalian pre-mRNA branch site sequence by U2 snRNP can involve base-pairing.     

Association of U6 snRNA with the 5'-splice site region of pre-mRNA in the spliceosome.

U6 snRNA is one of the five RNA species required for splicing of nuclear pre-mRNAs. High conservation of its sequence has led to the hypothesis that U6 snRNA plays a catalytic role in splicing. If this is the case, U6 snRNA should be localized close to sites where the splicing reaction occurs. However, this has never been demonstrated. Here, we have shown that U6 snRNA is cross-linked to the 5'-splice site region of pre-mRNA by UV irradiation during the in vitro splicing reaction. We have also detected the cross-link of U6 snRNA and the region around the branchpoint of the intron lariat. The results show that U6 snRNA is present near the splice sites in the splicing reaction and support the idea that U6 snRNA is a catalytic element in the spliceosome.     

U5 snRNP在前体mRNA剪接加工中的作用

前体mRNA的剪接是基因表达过程中的关键一步,发生在基因的转录之后与蛋白合成之前。在由前体mRNA剪接加工而形成成熟mRNA时,需要将转录本中的内含子切除,因为它会干扰基因的表达。前体mRNA的剪接发生在细胞核中,是在一个大的RNA与蛋白质的复合体即剪接体的催化下完成的。复合体中含有U1、U2、U5,二聚体形式的U4/U6小核RNA(snRNA)和一些小核核糖核蛋白(snRNP)。U5snRNP特异蛋白包括hPrp8,hSnu114(aGTPase),hBrr2(aDExH/Dboxhelicase)和Prp28等。Prp8构成剪接体的催化核心,hSnu114可避免剪接复合体过早的活化。因此,U5snRNP在剪接体聚集过程和前体mRNA的剪接反应中发挥重要作用。     

Mechanism for Aar2p function as a U5 snRNP assembly factor

Little is known about how particle-specific proteins are assembled on spliceosomal small nuclear ribonucleoproteins (snRNPs). Brr2p is a U5 snRNP-specific RNA helicase required for spliceosome catalytic activation and disassembly. In yeast, the Aar2 protein is part of a cytoplasmic precursor U5 snRNP that lacks Brr2p and is replaced by Brr2p in the nucleus. Here we show that Aar2p and Brr2p bind to different domains in the C-terminal region of Prp8p; Aar2p interacts with the RNaseH domain, whereas Brr2p interacts with the Jab1/MPN domain. These domains are connected by a long, flexible linker, but the Aar2p–RNaseH complex sequesters the Jab1/MPN domain, thereby preventing binding by Brr2p. Aar2p is phosphorylated in vivo, and a phospho-mimetic S253E mutation in Aar2p leads to disruption of the Aar2p–Prp8p complex in favor of the Brr2p–Prp8p complex. We propose a model in which Aar2p acts as a phosphorylation-controlled U5 snRNP assembly factor that regulates the incorporation of the particle-specific Brr2p. The purpose of this regulation may be to safeguard against nonspecific RNA binding to Prp8p and/or premature activation of Brr2p activity.     

Regulation of doublesex pre-mRNA processing occurs by 3'-splice site activation

Sex-specific alternative processing of the doublesex (dsx) pre-mRNA controls somatic sexual differentiation in Drosophila melanogaster. Processing in the female-specific pattern results from the utilization of an upstream 3'-terminal exon and requires the activities of both the transformer (tra) and transformer-2 (tra-2) genes. Use of the more downstream male-specific terminal exons does not require the activities of these genes and is thus considered the default dsx-processing pattern. Here, we used transient expression of dsx pre-mRNAs in the presence or absence of tra and tra-2 gene products in Drosophila tissue culture cells to investigate the molecular mechanism controlling this alternative RNA-processing decision. These studies reveal that female-specific processing of dsx pre-mRNA is controlled by tra and tra-2 through the positive regulation of female-specific alternative 3'-terminal exon use. Delineation of cis-acting sequences necessary for regulation shows that a 540-nucleotide region from within the female exon is both necessary and sufficient for regulation. In addition, utilization of the female-specific 3'-splice site (3'SS) is regulated independently of female-specific polyadenylation. Regulated polyadenylation was obtained only in the presence of splicing, suggesting that activation of female-specific exon use occurs by 3'SS activation.     

Luc7p, a novel yeast U1 snRNP protein with a role in 5′ splice site recognition

The characterization of a novel yeast-splicing factor, Luc7p, is presented. The LUC7 gene was identified by a mutation that causes lethality in a yeast strain lacking the nuclear cap-binding complex (CBC). Luc7p is similar in sequence to metazoan proteins that have arginine-serine and arginine-glutamic acid repeat sequences characteristic of a family of splicing factors. We show that Luc7p is a component of yeast U1 snRNP and is essential for vegetative growth. The composition of yeast U1 snRNP is altered in luc7 mutant strains. Extracts of these strains are unable to support any of the defined steps of splicing unless recombinant Luc7p is added. Although the in vivo defect in splicing wild-type reporter introns in a luc7 mutant strain is comparatively mild, splicing of introns with nonconsensus 5' splice site or branchpoint sequences is more defective in the mutant strain than in wild-type strains. By use of reporters that have two competing 5' splice sites, a loss of efficient splicing to the cap proximal splice site is observed in luc7 cells, analogous to the defect seen in strains lacking CBC. CBC can be coprecipitated with U1 snRNP from wild-type, but not from luc7, yeast strains. These data suggest that the loss of Luc7p disrupts U1 snRNP-CBC interaction, and that this interaction contributes to normal 5' splice site recognition.     

5' splice site selection in yeast: genetic alterations in base-pairing with U1 reveal additional requirements

Using a strategy of compensatory nucleotide changes between yeast U1 and a 5' splice site, we have analyzed the contribution of base-pairing to the efficiency and fidelity of pre-mRNA splicing in vivo. Watson-Crick base-pairing interactions with U1 can be demonstrated at intron positions 1 and 5 but not at position 4. Moreover, restoration of the ability to pair with U1 is not sufficient to restore activity in the second step of splicing to intron position 1 mutants. Finally, in contrast to recent observations in mammalian systems, we find that the precise position of 5' splice site cleavage is not determined solely by the base-pairing interaction with U1. Rather, the presence of a G residue at position 5 is required for the correct localization of the nucleolytic event. Taken together, these results indicate that the demands for 5' splice site selection and utilization are more complex than a simple maximization of Watson-Crick interactions with U1.     

Apoptotic modifications affect the autoreactivity of the U1 snRNP autoantigen

A hallmark of systemic autoimmune diseases is the presence of high titers of serum autoantibodies targeting a diversity of autoantigens. Most components of the U1 snRNP complex are autoantigenic in systemic lupus erythematosus (SLE) and SLE overlap syndrome, which is also called mixed connective tissue disease (MCTD). It is hypothesized that posttranslational modifications, in particular cell death-associated modifications, play an important role in breaking tolerance to self-antigens. Recently, it became clear that the U1 snRNP particle, more specifically its U1-70K protein component, displays a new epitope during apoptosis. This review intends to give an overview of the modifications that occur on the U1 snRNP autoantigens, especially those arising during cell death, to summarize recent data describing autoantibody reactivities with apoptosis-specific epitopes on the U1 snRNP complex, and to provide some insight into the mechanisms that might underlie the immune response to self-antigens.     

Universally conserved and yeast-specific U1 snRNA sequences are important but not essential for U1 snRNP function

To study the contribution of the large, 568-nucleotide yeast (Saccharomyces cerevisiae) U1 snRNA to pre-mRNA splicing, we generated mutations in two regions of the molecule and introduced each mutant gene back into yeast as the sole copy of the U1 snRNA gene. We mutagenized the "A loop," a subregion highly conserved in primary sequence in all U1 snRNA molecules analyzed to date. We also mutagenized a portion of the yeast core subdomain, a region conserved in primary and secondary structure among several yeast species but absent from the much smaller metazoan U1 molecule. Surprisingly, mutations in these two regions had little or no effect on growth rate, yet several of them affected an inefficiently spliced reporter gene construct. In addition, combinations of mutants in both regions gave rise to reduced growth rates. Using the latter assay, we confirmed some of the proposed secondary structure of the yeast core domain. The experiments indicate that both regions contribute to U1 snRNP activity but that mutations in a single region do not have a substantial effect on growth rate because U1 snRNP activity is not rate-limiting for growth.     

Mapping of epitopes on U1 snRNP polypeptide A with synthetic peptides and autoimmune sera.

The ability of synthetic peptides encompassing almost the entire sequence of snRNP U1A polypeptide to be recognized in ELISA by sera of autoimmune patients was investigated. Sera from 18 patients with mixed connective tissue disease (MCTD), 145 with systemic lupus erythematosus (SLE) and 120 with other rheumatic autoimmune diseases were tested with 13 overlapping peptides. Among them, peptide 257-282 and, to a lower extent, peptide 1-11 were recognized by MCTD, SLE and Sjögren''s syndrome sera. In contrast, peptide 35-58 was recognized by 94% of MCTD and only 19% of SLE sera. It did not react with any of the other patient sera. The ELISA results were compared with the pattern of reactivity observed in immunoblotting. The results indicate that peptide 35-58 probably contains a major epitope recognized by MCTD autoantibodies. It is noteworthy that in snRNP particles, this region of U1A interacts with RNA and presents only limited homology with the corresponding sequence 32-50 of U2B''''.     

Structural basis for dual roles of Aar2p in U5 snRNP assembly

Yeast U5 small nuclear ribonucleoprotein particle (snRNP) is assembled via a cytoplasmic precursor that contains the U5-specific Prp8 protein but lacks the U5-specific Brr2 helicase. Instead, pre-U5 snRNP includes the Aar2 protein not found in mature U5 snRNP or spliceosomes. Aar2p and Brr2p bind competitively to a C-terminal region of Prp8p that comprises consecutive RNase H-like and Jab1/MPN-like domains. To elucidate the molecular basis for this competition, we determined the crystal structure of Aar2p in complex with the Prp8p RNase H and Jab1/MPN domains. Aar2p binds on one side of the RNase H domain and extends its C terminus to the other side, where the Jab1/MPN domain is docked onto a composite Aar2p–RNase H platform. Known Brr2p interaction sites of the Jab1/MPN domain remain available, suggesting that Aar2p-mediated compaction of the Prp8p domains sterically interferes with Brr2p binding. Moreover, Aar2p occupies known RNA-binding sites of the RNase H domain, and Aar2p interferes with binding of U4/U6 di-snRNA to the Prp8p C-terminal region. Structural and functional analyses of phospho-mimetic mutations reveal how phosphorylation reduces affinity of Aar2p for Prp8p and allows Brr2p and U4/U6 binding. Our results show how Aar2p regulates both protein and RNA binding to Prp8p during U5 snRNP assembly.     

T cell lines recognizing the 70-kD protein of U1 small nuclear ribonucleoprotein (U1snRNP).

In sera of patients with mixed connective tissue disease (MCTD) high titres of IgG autoantibodies to U1snRNP-specific proteins (70 kD, A, C) are found, suggesting an antigen-driven and T-cell-dependent process. In order to establish U1snRNP-specific T cell lines we cultured under various culture conditions mononuclear cells from MCTD patients and healthy donors with a highly purified UsnRNP preparation from HeLa cells. Nine T cell lines were established by limiting dilution cloning from two MCTD patients and five T cell lines from a healthy individual. All T cell lines expressed the TCR alpha beta/CD3 complex. Surprisingly, most of the T cells lines exhibited the CD8 phenotype. Irrespective of this phenotype, all T cell lines showed a proliferative response to an N-terminal part (aa 51-195) of recombinant U1-specific 70-kD protein. One CD8+ T cell clone exhibited cytotoxic activity against an autologous B cell line pulsed with snRNP or recombinant fragments (aa 51-95 and aa 51-88). Interestingly, two T cell lines proliferated in response to four recombinant polypeptides representing different parts of the U1snRNP 70-kD protein. Since regions of sequence homology are distributed over the 70-kD molecule, it is suggested that conserved motifs may be recognized by the T cell lines.     

Self-inactivating lentiviral vectors with U3 and U5 modifications.

Lentiviral vectors have gained much attention in recent years mainly because they integrate into nondividing host-cell genomes. For clinical applications, a safe and efficient lentiviral vector system is required. Previously, we have established a human immunodeficiency virus type 1 (HIV-1)-derived three-plasmid lentiviral vector system for viral vector production which includes a packaging vector pHP, a transducing vector pTV, and an envelope-encoding plasmid pHEF-VSVG. Cotransfection of these three plasmids into TE671 human rhabdomyosarcoma cells routinely yields 10(5)-10(6) infectious units per milliliter in 24 h. Here we have extensively modified long terminal repeats (LTRs) of pTV to generate a safer lentiviral vector system. The 5' U3 was replaced with a truncated cytomegalovirus (CMV) immediate early (IE) enhancer/TATA promoter and the 3' U3 (except for the integration attachment site) was also deleted. These modifications resulted in a vector with 80% wild-type vector efficiency. Further deletion of 3' U5 impaired vector function; however, this problem was solved by replacing the 3' U5 with bovine growth hormone polyadenylation (bGHpA) sequence. The pTV vector containing all these modifications including the 5' promoter substitution, the 3' U3 deletion, and the substitution of 3' U5 with bGHpA exhibited a self-inactivating (SIN) phenotype after transduction, transduced both dividing and nondividing cells at similar efficiencies, and produced vector titers twice as high as that of the wild-type construct. Thus, both safety and efficacy of the HP/TV vector have been improved by these LTR modifications. Further deletion of 5' U5 impaired vector efficiency, suggesting that the 5' U5 has critical roles in vector function.     

A recombinant 70K protein ELISA. Screening for antibodies against U1snRNP proteins in human sera.

Antibodies to uridylic acid rich small nuclear ribonucleoprotein particles (UsnRNP) are mainly detected in patients with systemic lupus erythematosus (SLE) or mixed connective tissue disease (MCTD). Particularly those directed against epitopes of the 70K protein of U1snRNP serve as important markers for the diagnosis of MCTD. To establish an ELISA for determination of anti-70K protein antibodies in patients' sera a 1239 bp long cDNA insert coding for the epitopes of the 70K protein was ligated into a fusion expression vector. The bacterially expressed fusion protein was purified by chromatography on DEAE cellulose. Microtiter plates were coated with the fusion protein as well as with partially purified calf thymus extract (CTE) containing all natural UsnRNP antigens and RNase digested calf thymus extract (CTERNase) in which the natural 70K antigen was destroyed by the nuclease treatment. 10,888 sera of patients with suspected or overt rheumatic disease were analyzed for antibodies against these antigens simultaneously. Antibodies against CTE or CTERNase were not detected in 9123 sera, none of these showed reactivity with the 70K protein indicating a high degree of specificity of the assay. Positive results in each the 70K protein, CTE as well as the CTERNase ELISAs were obtained with 474 sera. 319 sera were only positive with CTE and 70K protein. Of these 793 anti-70K protein ELISA positive sera, 79% could be confirmed by immunoblot. Of 967 sera reacting with CTE and CTERNase but not with the recombinant 70K protein, 31% contained antibodies against various other UsnRNP proteins as shown by immunoblotting. 2.4% of these sera revealed also antibodies against the 70K protein. The use of the recombinant 70K protein as antigen meets the criterion for a simple and specific assay to detect anti-U1snRNP antibodies. Nevertheless, the sole use of this recombinant protein for anti-U1snRNP antibody screening may not be appropriate, because antibodies against other frequently occurring U1snRNP proteins (A, C) cannot be detected with this test. Therefore it should be used together with a natural UsnRNP antigen until further studies in patients with well established diagnoses will show whether natural antigens may be omitted.     

Alternative splicing in the neural cell adhesion molecule pre-mRNA: regulation of exon 18 skipping depends on the 5'-splice site

Two isoforms of the neural cell adhesion molecule (NCAM), termed NCAM-180 and NCAM-140, derive from a single gene via inclusion or exclusion of the penultimate exon 18 (E18). This alternative splicing event is tissue-specific and regulated during differentiation. To explore its structural basis, we have analyzed the pattern of spliced mRNA generated from transiently transfected minigenes construct containing this exon and portions of the adjacent introns and exons faithfully reproduces the differentiation state-dependent alternative splicing of the endogenous pre-mRNA. By systematic deletion and replacement analysis, we scanned the minigene for the presence of functionally important cis-elements. We identified two sequences that affected differentiation state-dependent regulation. One, the central part of E18, does not seem to contain a specific cis-element essential for proper splice site choice, because extending the deletion restored correctly regulated expression of the splicing products. In contrast, the 5'-splice site is an important element for regulation. Replacing it with a corresponding sequence from the alpha-globin gene resulted in constitutive use of the optional exon. When placed in the alpha-globin gene it did not promote alternative splicing. Instead, we observed a strongly decreased efficiency of splicing of the downstream intron in undifferentiated cells. This block of splicing was partially relieved after differentiation. The results are consistent with a model in which skipping of E18 is controlled in part at the associated 5'-splice site by trans-acting factors that undergo quantitative or qualitative changes during differentiation of N2a cells.     

Mutation in the splicing factor Hprp3p linked to retinitis pigmentosa impairs interactions within the U4/U6 snRNP complex

Mutations in PRPF3, a gene encoding the essential pre-mRNA splicing factor Hprp3p, have been identified in patients with autosomal dominant retinitis pigmentosa type 18 (RP18). Patients with RP18 have one of two single amino acid substitutions, Pro493Ser or Thr494Met, at the highly conserved Hprp3p C-terminal region. Pro493Ser occurs sporadically, whereas Thr494Met is observed in several unlinked RP families worldwide. The latter mutation also alters a potential recognition motif for phosphorylation by casein kinase II (CKII). To understand the molecular basis of RP18, we examined the consequences of Thr494Met mutation on Hprp3p molecular interactions with components of the U4/U6.U5 small nuclear ribonucleoprotein particles (snRNPs) complex. Since numerous mutations causing human diseases change pre-mRNA splice sites, we investigated whether Thr494Met substitution affects the processing of PRPF3 mRNA. We found that Thr494Met does not affect PRPF3 mRNA processing, indicating that the mutation may exert its effect primarily at the protein level. We used small hairpin RNAs to specifically silence the endogenous PRPF3 while simultaneously expressing HA-tagged Thr494Met. We demonstrated that the C- but not N-terminal region of Hprp3p is indeed phosphorylated by CKII in vitro and in cells. CKII-mediated Hprp3p phosphorylation was significantly reduced by Thr494Met mutation. Consequently, the Hprp3p C-terminal region is rendered partially defective in its association with itself, Hprp4p, and U4/U6 snRNA. Our findings provide new insights into the biology of Hprp3p and suggest that the loss of Hprp3p phosphorylation at Thr494 is a key step for initiating Thr494Met aberrant interactions within U4/U6 snRNP complex and that these are likely linked to the RP18 phenotype.     

FISH Mapping of Bovine U21, U1 and U7 Molecular Markers to River Buffalo Chromosomes 3p, 5q and 5p

Three bovine cosmid-derived microsatellites (IDV-GA49, IDVGA7 and IDVGA47), previously assigned to cattle syntenic groups U1, U7 and U21, respectively, were fluorescence in situ hybridization (FISH) mapped to river buffalo (Bubalus bubalis, L., 2n= 50) chromosomes (BBU) 3p22 (IDVGA47, U21), BBU 5q21 (IDVGA49, U1) and BBU 5p19 (IDVGA7, U7) using sequential FISH and R-banding techniques. These localizations allowed the assignment, for the first time, of the bovine syntenic groups U21, U1 and U7 to specific river buffalo chromosomes. FISH mapping of IDVGA7 (U7) to cattle rob(1;29) p-arms confirms the banding homologies between BTA 29 and BBU 5p and further supports the idea that cattle standard karyotypes need adjustments.This revised version was published online in November 2005 with corrections to the Cover Date.