Polypeptide components of human small nuclear ribonucleoproteins

Proline-rich sequence recognition: I. Marking GYF and WW domain assembly sites in early spliceosomal complexes

Proline-rich sequences (PRS) and their recognition domains have emerged as transposable protein interaction modules during eukaryotic evolution. They are especially abundant in proteins associated with pre-mRNA splicing and likely assist in the formation of the spliceosome by binding to GYF and WW domains. Here we profile PRS-mediated interactions of the CD2BP2/52K GYF domain by a site-specific peptide inhibitor and stable isotope labeling/mass spectrometry analysis. Several PRS hubs with multiple proline-rich motifs exist that can recruit GYF and/or WW domains. Saturating the PRS sites by an isolated GYF domain inhibited splicing at the level of A complex formation. The interactions mediated by PRS are therefore important to the early phases of spliceosomal assembly.

The appearance of U1 RNP antibody specificities in sequential autoimmune human antisera follows a characteristic order that implicates the U1-70 kd and B'/B proteins as predominant U1 RNP immunogens

OBJECTIVE

To observe the order of development of anti-U1 RNP peptide antibodies in humans.

METHODS

Immunoblots against Jurkat cell lysates were performed on 5,882 serum samples from 3,668 patients referred on clinical grounds for RNP antibody testing to a reference laboratory between 1989 and 1999. In patients from whom multiple samples were drawn, we determined the order in which IgG antibodies to the U1 RNP peptides A, B'/B, C, D, and 70 kd appeared.

RESULTS

One hundred sixty-three patients with serial samples were identified in whom antibodies to at least one U1 RNP peptide initially were not present but later appeared. The first RNP antibodies to appear were most often directed against the 70 kd and B'/B peptides (P < 0.01). Antibodies to the A and C peptides usually developed after other RNP peptide antibodies, and antibodies to D often emerged only after immunity to multiple other U1 RNP proteins had appeared. B'/B, but not 70 kd, was a frequent early target of spreading after initial immunity to other RNP peptides.

CONCLUSION

Orderly patterns of emergence of U1 RNP peptide antibodies appear to exist in humans. Two peptides, 70 kd and B'/B, show characteristics of early immunogens in the development of human RNP immunity.

Overexpression of the arginine-rich carboxy-terminal region of U1 snRNP 70K inhibits both splicing and nucleocytoplasmic transport of mRNA

Transient transfection of the U1 snRNP 70K protein into COS cells induced nuclear reorganization and redistribution of the splicing factor SC-35, whereas hnRNP proteins were not affected. Correspondingly, splicing and nucleocytoplasmic transport of a coexpressed mRNA substrate was reduced by overexpression of U1-70K. The carboxy-terminal portion of U1-70K-encompassing repeats of Arg/Ser, Arg/Glu, and Arg/Asp localizes to the nucleus independently of U1 RNA and was responsible for these inhibitory effects. This region of U1-70K contains amino acid residues similar to those found in splicing factors SC-35, U2AF, su(wa), and in other SR proteins suggesting that U1-70K protein may serve as a focus of assembly for functional components of the splicing/transport machinery. These findings are compatible with models that propose that direct interaction between U1-70K and SR proteins play a regulatory role in early events of spliceosome assembly.

Thiophosphorylation of U1-70K protein inhibits pre-mRNA splicing

The U1 small nuclear ribonucleoprotein (snRNP) particle is one of the Sm class of snRNPs essential for splicing of precursor messenger RNA. Mammalian U1 snRNP contains a 165-nucleotide long RNA molecule and at least 11 proteins: the U1-specific 70K proteins A and C, and the common U snRNP proteins (B', B, D1, D2, D3, E, F and G). One of the functions of U1 snRNP is recognition of the 5' splice site, an event that requires both U1 RNA and U1 proteins. The 70K protein is the only heavily phosphorylated U1 protein in the cell. Isolated U1 snRNPs are associated with a kinase activity that selectively phosphorylates the 70K protein in vitro in a reaction requiring ATP. Here we investigate the role of phosphorylation of the 70K protein in the splicing of pre-mRNA. The 70K protein on U1 snRNPs was phosphorylated in vitro with either ATP, or with ATP-gamma S, which gave a thiophosphorylated product that was resistant to dephosphorylation by phosphatases. When HeLa nuclear splicing extracts that had been depleted of endogenous U1 snRNPs were complemented with U1 snRNPs possessing normal phosphorylated 70K protein, mature spliceosomes were generated and the splicing activity of the extracts was fully restored. By contrast, if thiophosphorylated U1 snRNPs were used instead, splicing was completely inhibited, although formation of the mature spliceosome was unaffected. Our data show that the state of phosphorylation of the U1-specific 70K protein is critical for its participation in a pre-catalytic step of the splicing reaction.

Ser/Thr-specific protein phosphatases are required for both catalytic steps of pre-mRNA splicing

We have used a combination of highly specific protein phosphatase inhibitors and purified mammalian protein phosphatases to show that at least two separate Ser/Thr protein phosphatase activities are required for pre-mRNA splicing, but not for spliceosome assembly. Okadaic acid, tautomycin, and microcystin-LR, which are potent and specific inhibitors of PP1 and PP2A, two of the four major types of Ser/Thr-specific phosphatase catalytic subunits, block both catalytic steps of the pre-mRNA splicing mechanism in HeLa nuclear extracts. Inhibition of PP2A inhibits the second step of splicing predominantly while inhibition of both PP1 and PP2A blocks both steps, indicating a differential contribution of PP1 and PP2A activities to the two separate catalytic steps of splicing. Splicing activity is restored to toxin-inhibited extracts by the addition of highly purified mammalian PP1 or PP2A. Protein phosphatase activity was not required for efficient assembly of splicing complexes containing each of the U1, U2, U4/U6 and U5 snRNPs. The data indicate that reversible protein phosphorylation may play an important role in regulating the pre-mRNA splicing mechanism.

Assembly and intracellular transport of snRNP particles

The assembly of the major small nuclear ribonucleoprotein (snRNP) particles begins in the cytoplasm where large pools of common core proteins are preassembled in several RNA-free intermediate particles. Newly synthesized snRNAs transiently enter the cytoplasm and complex with core particles to form pre-snRNP particles. Subsequently, the cap structure at the 5' end of the snRNA is hypermethylated. The resulting trimethylguanosine (TMG) cap is an integral part of the nuclear localization signal for snRNP particles and the pre-snRNP particles are rapidly transported into the nucleus. SnRNP particles mature when snRNA-specific proteins complex with the particles, in some cases, just before or during nuclear transport, but in most instances after the particles are in the nucleus. In addition, U6 snRNA hybridizes with U4 snRNA to form a U4/U6 snRNP in the nucleus. The transport signals are retained on the snRNP particles and proteins since existing particles and proteins enter the reformed nucleus after mitosis.

Characterisation of human and murine snRNP proteins by two-dimensional gel electrophoresis and phosphopeptide analysis of U1-specific 70K protein variants

The proteins of the major human snRNPs U1, U2, U4/U6 and U5 were characterised by two-dimensional electrophoresis, with isoelectric focussing in the first dimension and SDS-polyacrylamide gel electrophoresis in the second. With the exception of protein F, which exhibits an acidic pl value (pl = 3.3), the snRNP proteins are basic. Post-translational modification was found among the proteins associated specifically with the U1 and U2 particles. The most complex modification pattern was observed for the U1-specific 70K protein. This was found in at least 13 isoelectric variants, with pl values ranging from 6.7 to 8.7; these variants differed also in molecular weight. All of the 70K variants are phosphorylated in the cell. Thin-layer analysis of their tryptic phosphopeptides revealed that the 70K variants have four major phosphopeptides in common, in addition to which at least four additional serine residues are phosphorylated to different extents. The comparative phosphopeptide analysis shows that differential phosphorylation alone is not sufficient to explain the occurrence of the many isoelectric variants of 70K, so that the final charge of the 70K variants is determined both by phosphorylation and by other, as yet unidentified posttranslational modifications. By two-dimensional separation of snRNP proteins obtained from mouse Ehrlich ascites tumour cells, it was shown that the pattern of pl values of the mouse proteins was almost identical with the corresponding pattern for human proteins. Even the complex modification patterns of the 70K protein are identical in mouse and man, indicating that the presence in the cell of so many variants of this protein may have functional importance. The major difference between murine and human snRNP proteins is the absence of protein B' from mouse snRNPs. This suggests that the homologous protein B may be able to carry out the task of protein B'.

Nuclear exchange of the U1 and U2 snRNP-specific proteins

The snRNP particles include a set of common core snRNP proteins and snRNP specific proteins. In rodent cells the common core proteins are the B, D, D', E, F and G proteins in a suggested stoichiometry of B2D'2D2EFG. The additional U1- and U2-specific proteins are the 70-kD, A and C proteins and the A' and B" proteins, respectively. Previous cell fractionation and kinetic analysis demonstrated the snRNP core proteins are stored in the cytoplasm in large partially assembled snRNA-free intermediates that assemble with newly synthesized snRNAs during their transient appearance in the cytoplasm (Sauterer, R. A., R. J. Feeney, and G. W. Zieve. 1988. Exp. Cell Res. 176:344-359). This report investigates the assembly and intracellular distribution of the U1 and U2 snRNP-specific proteins. Cell enucleation and aqueous cell fractionation are used to prepare nuclear and cytoplasmic fractions and the U1- and U2-specific proteins are identified by isotopic labeling and immunoprecipitation or by immunoblotting with specific autoimmune antisera. The A, C, and A' proteins are found both assembled into mature nuclear snRNP particles and in unassembled pools in the nucleus that exchange with the assembled snRNP particles. The unassembled proteins leak from isolated nuclei prepared by detergent extraction. The unassembled A' protein sediments at 4S-6S in structures that may be multimers. The 70-kD and B" proteins are fully assembled with snRNP particles which do not leak from isolated nuclei. The kinetic studies suggest that the B" protein assembles with the U2 particle in the cytoplasm before it enters the nucleus.

Direct, sequence-specific binding of the human U1-70K ribonucleoprotein antigen protein to loop I of U1 small nuclear RNA

We have studied the interaction of two of the U1 small nuclear ribonucleoprotein (snRNP)-specific proteins, U1-70K and U1-A, with U1 small nuclear RNA (snRNA). The U1-70K protein is a U1-specific RNA-binding protein. Deletion and mutation analyses of a beta-galactosidase/U1-70K partial fusion protein indicated that the central portion of the protein, including the RNP sequence domain, is both necessary and sufficient for specific U1 snRNA binding in vitro. The highly conserved eight-amino-acid RNP consensus sequence was found to be essential for binding. Deletion and mutation analyses of U1 snRNA showed that both the U1-70K fusion protein and the native HeLa U1-70K protein bound directly to loop I of U1 snRNA. Binding was sequence specific, requiring 8 of the 10 bases in the loop. The U1-A snRNP protein also interacted specifically with U1 snRNA, principally with stem-loop II.

Direct, sequence-specific binding of the human U1-70K ribonucleoprotein antigen protein to loop I of U1 small nuclear RNA

We have studied the interaction of two of the U1 small nuclear ribonucleoprotein (snRNP)-specific proteins, U1-70K and U1-A, with U1 small nuclear RNA (snRNA). The U1-70K protein is a U1-specific RNA-binding protein. Deletion and mutation analyses of a beta-galactosidase/U1-70K partial fusion protein indicated that the central portion of the protein, including the RNP sequence domain, is both necessary and sufficient for specific U1 snRNA binding in vitro. The highly conserved eight-amino-acid RNP consensus sequence was found to be essential for binding. Deletion and mutation analyses of U1 snRNA showed that both the U1-70K fusion protein and the native HeLa U1-70K protein bound directly to loop I of U1 snRNA. Binding was sequence specific, requiring 8 of the 10 bases in the loop. The U1-A snRNP protein also interacted specifically with U1 snRNA, principally with stem-loop II.

Direct cross-linking of snRNP proteins F and 70K to snRNAs by ultra-violet radiation in situ

Protein-RNA interactions in small nuclear ribonucleoproteins (UsnRNPs) from HeLa cells were investigated by irradiation of purified nucleoplasmic snRNPs U1 to U6 with UV light at 254 nm. The cross-linked proteins were analyzed on one- and two-dimensional gel electrophoresis systems, and the existence of a stable cross-linkage was demonstrated by isolating protein-oligonucleotide complexes from snRNPs containing 32P-labelled snRNAs after exhaustive digestion with a mixture of RNases of different specificities. The primary target of the UV-light induced cross-linking reaction between protein and RNA was protein F. It was also found to be cross-linked to U1 snRNA in purified U1 snRNPs. Protein F is known to be one of the common snRNP proteins, which together with D, E and G protect a 15-25 nucleotide long stretch of snRNAs U1, U2, U4 and U5, the so-called domain A or Sm binding site against nuclease digestion (Liautard et al., 1982). It is therefore likely that the core-protein may bind directly and specifically to the common snRNA domain A, or else to a sub-region of this. The second protein which was demonstrated to be cross-linked to snRNA was the U1 specific protein 70K. Since it has been shown that binding of protein 70K to U1 RNP requires the presence of the 5' stem and loop of U1 RNA (Hamm et al., 1987) it is likely that the 70K protein directly interacts with a sub-region of the first stem loop structure.

Pre-mRNA splicing by complementation with purified human U1, U2, U4/U6 and U5 snRNPs

The four major nucleoplasmic small nuclear ribonucleoprotein particles U1, U2, U4/U6 and U5 can be extensively purified from HeLa cells by immunoaffinity chromatography using a monoclonal anti-trimethylguanosine antibody. The snRNP particles in active splicing extracts are selectively bound to the immunoaffinity matrix, and are then gently eluted by competition with an excess of free nucleoside. Biochemical complementation studies show that the purified snRNPs are active in pre-mRNA splicing, but only in the presence of additional non-snRNP protein factors. All the RNPs that are necessary for splicing can be purified in this manner. The active snRNPs are characterized with respect to their polypeptide composition, and shown to be distinct from several other activities implicated in splicing.

The U2 small nuclear ribonucleoprotein particle as an autoantigen. Analysis with sera from patients with overlap syndromes

We identified eight patients whose sera contained autoantibodies to the U2 small nuclear ribonucleoprotein (snRNP), an RNA protein particle involved in the splicing of newly transcribed messenger RNA. Each of these patients had an overlap syndrome that included features of either systemic lupus erythematosus (SLE), scleroderma, and/or polymyositis. We then used these sera to characterize the autoantigenic polypeptides of the U1 and U2 snRNP particles. In immunoblots, all sera contained antibodies to the B" polypeptide of the U2 snRNP. A subset of these sera that more effectively immunoprecipitated the native U2 particle contained an additional antibody system that recognized the A' polypeptide of this snRNP. Antibodies eluted from the B" protein bound the A polypeptide of the U1 snRNP and vice versa. Moreover, antibodies to the B" polypeptide were accompanied by antibodies to the 68K and C polypeptides of the U1 snRNP. Finally, the A' and B" polypeptides remained physically associated after the U2 particle was cleaved with RNase. Thus these sera contain multiple autoantibody systems that, at one level, target two physically associated antigenic polypeptides of the U2 particle and, at another, target two snRNP particles which are associated during the splicing of premessenger RNA. These linked autoantibody sets provide further evidence that intact macromolecular structures are targeted by the immune response in SLE and related diseases.

The human U1-70K snRNP protein: cDNA cloning, chromosomal localization, expression, alternative splicing and RNA-binding

We have isolated and sequenced cDNA clones encoding the human U1-70K snRNP protein, and have mapped this locus (U1AP1) to human chromosome 19. The gene produces two size classes of RNA, a major 1.7-kb RNA and a minor 3.9-kb RNA. The 1.7-kb species appears to be the functional mRNA; the role of the 3.9-kb RNA, which extends further in the 5' direction, is unclear. The actual size of the hU1-70K protein is probably 52 kd, rather than 70 kd. The protein contains three regions similar to known nucleic acid-binding proteins, and it binds RNA in an in vitro assay. Comparison of the cDNA sequences indicates that there are multiple subclasses of mRNA that arise by alternative pre-mRNA splicing of at least four alternative exon segments. This suggests that multiple forms of the hU1-70K protein may exist, possibly with different functions in vivo.

Rapid inhibition of processing and assembly of small nuclear ribonucleoproteins after infection with vesicular stomatitis virus

After infection of baby hamster kidney cells with vesicular stomatitis virus (VSV), processing and assembly of small nuclear ribonucleoproteins (snRNP) were rapidly inhibited. The U1 and U2 snRNAs accumulated as precursor species approximately 3 and 10 nucleotides longer, respectively, than the mature RNAs. Alteration in snRNP assembly was noted because the precursor snRNAs were not associated with the U-series RNA-core protein complex in infected cells. However, antibodies specific for the U2 RNA-binding protein, A', were able to precipitate pre-U2 RNAs from VSV-infected cells. These results indicated that precursors to U2 RNA were bound to A' and remained bound during virus infection. Analysis of the synthesis of proteins normally associated with U1 and U2 RNAs indicated that synthesis was unaffected at times when snRNP assembly with core proteins was blocked by the VSV. These findings suggested that the core proteins associate with one another in the absence of the snRNAs in VSV-infected cells. They further suggest a correlation between the inability of the core complex to bind the U-series snRNPs and the failure to process the 3' ends of U1 and U2 RNAs in VSV-infected cells. These effects of VSV on snRNP assembly may be related to the shutoff of host-cell macromolecular synthesis.

Rapid inhibition of processing and assembly of small nuclear ribonucleoproteins after infection with vesicular stomatitis virus

After infection of baby hamster kidney cells with vesicular stomatitis virus (VSV), processing and assembly of small nuclear ribonucleoproteins (snRNP) were rapidly inhibited. The U1 and U2 snRNAs accumulated as precursor species approximately 3 and 10 nucleotides longer, respectively, than the mature RNAs. Alteration in snRNP assembly was noted because the precursor snRNAs were not associated with the U-series RNA-core protein complex in infected cells. However, antibodies specific for the U2 RNA-binding protein, A', were able to precipitate pre-U2 RNAs from VSV-infected cells. These results indicated that precursors to U2 RNA were bound to A' and remained bound during virus infection. Analysis of the synthesis of proteins normally associated with U1 and U2 RNAs indicated that synthesis was unaffected at times when snRNP assembly with core proteins was blocked by the VSV. These findings suggested that the core proteins associate with one another in the absence of the snRNAs in VSV-infected cells. They further suggest a correlation between the inability of the core complex to bind the U-series snRNPs and the failure to process the 3' ends of U1 and U2 RNAs in VSV-infected cells. These effects of VSV on snRNP assembly may be related to the shutoff of host-cell macromolecular synthesis.

U1, U2, and U6 small nuclear ribonucleoproteins (snRNPs) are associated with large nuclear RNP particles containing transcripts of an amplified gene in vivo

Nuclear ribonucleoprotein (RNP) complexes that contain intact transcripts of the amplified gene for CAD, the multifunctional protein that initiates UMP synthesis in Syrian hamster cells, have been released from nuclei of Syrian hamster cells as large particulate structures that sediment at the 200S region in a sucrose gradient. By the technique of RNA hybridization, we have shown that U1, U2, and U6 small nuclear RNAs (snRNAs) cosediment with the large RNP particles in the sucrose gradients. Autoimmune sera from systemic lupus erythematosus and mixed connective tissue disease patients, characterized as anti-(U1)RNP, have further been shown to immunoprecipitate CAD RNA along with U1 and U2 snRNAs from the fractionated nuclear 200S RNP particles. We conclude that U1, U2, and U6 snRNPs are integral constituents of the 200S RNP particles. The requirement of snRNPs for RNA processing that evidently occurs on RNP particles has been recently demonstrated. Our results thus suggest that the 200S RNPs are structurally and functionally close to the native particles on which RNA processing occurs.

Further characterization and subcellular localization of Sm and U1 ribonucleoprotein antigens

Sera from patients with systemic autoimmune diseases often contain antibodies against small nuclear ribonucleoprotein (snRNP) particles. Anti-Sm antibodies react with the entire set of U1, U2, U4, U5 and U6 (U1-U6) RNP particles whereas anti-(U1)RNP sera specifically recognize particles containing U1 RNA. Here we performed semi-quantitative immunoblotting using 16 human anti-Sm, 15 human anti-(U1)RNP sera and two mouse monoclonal antibodies to establish which snRNA-associated proteins carry antigenic determinants. Almost every (15/16) human anti-Sm sera recognized epitopes present on a 28-kDa (B/B') protein doublet and on a 16-kDa (D) polypeptide. Nine anti-(U1)RNP sera also recognized the B/B' doublet, but in all cases a much stronger reaction was observed with one or more of the specifically U1 RNA-associated 70 kDa, A or C antigens. With affinity-purified antibody fractions eluted from individual antigen bands on nitrocellulose blots it is shown that the anti-Sm-reactive polypeptides B/B' and D contain common epitopes. We also report the finding of one human anti-Sm serum with exclusive specificity for the B/B' doublet and a mouse monoclonal anti-Sm antibody recognizing only the D protein, indicating that these antigens also carry unique epitopes. In immunoprecipitation assays, purified anti-B/B' and -D antibodies react with (U1-U6) RNP while purified anti-70 kDa, anti-A and anti-C antibodies precipitate exclusively U1 RNP particles. Finally, we established the subcellular localization of Sm and U1 RNP antigens using a biochemical cell fractionation procedure. Part of the 70 kDa and B/B' antigens were found in a nuclease and high salt-resistant nuclear substructure, usually referred to as nuclear matrix, while the A and D antigens could be extracted completely from HeLa nuclei by ribonuclease treatment and subsequent high salt extraction.

Quantitation of anti-RNP and anti-Sm antibodies in MCTD and SLE patients by immunoblotting

A quantitative immunoblotting assay (QIBA) for the determination of specific antibody titres in human autoimmune sera is described. In this assay, a total HeLa nuclear protein fraction, immobilized on nitrocellulose blot strips, was used as source of antigens and immunoreactive species of autoantibodies were quantitated by an enzyme linked second antibody procedure. Besides being more discriminative, QIBA appeared to be up to 500 times more sensitive than immunodiffusion or immunoelectrophoresis. In this study we used 21 sera from patients with SLE or MCTD for a quantitative analysis of their specific autoantibody content. Within this group, a very diverse spectrum of antibody populations was observed; anti-RNP sera appeared to contain, among others, high tired antibody versus 70K and 31K polypeptides while all (n = 6) anti-Sm sera recognized a 25kD protein doublet. In a follow-up study of two MCTD patients significant flares in specific antibody content could be observed.

Antinuclear antibody determination: the present state of diagnostic and clinical relevance

Determination of antinuclear antibodies (ANA) will gain in diagnostic significance if a specific type of ANA can be related to a defined clinical disorder. The past decade has brought us quite a lot of papers dedicated to this subject. Yet, with exception of the DNA/anti-DNA system, observed correlations have remained scarce or contradictory. Also, still little is known about the pathogenic role of ANA. Perhaps more recent approaches using biochemical technologies will provide us with highly purified nuclear antigens necessary to study possible correlations at a more sophisticated level.