The Sm domain is an ancient RNA-binding motif with oligo(U) specificity.

Sm and Sm-like proteins are members of a family of small proteins that is widespread throughout eukaryotic kingdoms. These proteins form heteromers with one another and bind, as heteromeric complexes, to various RNAs, recognizing primarily short U-rich stretches. Interestingly, completion of several genome projects revealed that archaea also contain genes that may encode Sm-like proteins. Herein, we studied the properties of one Sm-like protein derived from the archaebacterium Archaeoglobus fulgidus and overexpressed in Escherichia coli. This single small protein closely reflects the properties of an Sm or Sm-like protein heteromer. It binds to RNA with a high specificity for oligo(U), and assembles onto the RNA to form a complex that exhibits, as judged by electron microscopy, a ring-like structure similar to the ones observed with the Sm core ribonucleoprotein and the like Sm (LSm) protein heteromer. Importantly, multivariate statistical analysis of negative-stain electron-microscopic images revealed a sevenfold symmetry for the observed ring structure, indicating that the proteins form a homoheptamer. These results support the structural model of the Sm proteins derived from crystallographic studies on Sm heterodimers and demonstrate that the Sm protein family evolved from a single ancestor that was present before the eukaryotic and archaeal kingdoms separated.

Deficient brain snRNP70K in patients with Down syndrome.

The small nuclear ribonucleoprotein 70K (snRNP 70K; U1-70 kDa) is an integral part of the spliceosome, a large RNA-protein complex catalyzing the removal of introns from nuclear pre-mRNA. snRNP is one of the best-studied essential subunits of snRNPs, is highly conserved and its inactivation was shown to result in complete inhibition of splicing. Applying subtractive hybridization, we found a sequence with 100% identity to snRNP absent in fetal Down syndrome (DS) brain. This observation made us determine snRNP-mRNA steady-state levels and protein levels in brains of adult patients with DS. snRNP-mRNA and protein levels of five individual brain regions of DS and controls each, were determined by blotting techniques. snRNP-mRNA steady state levels were significantly decreased in DS brain. Performing Western blots with monoclonal and human antibodies, snRNP protein levels were decreased in several regions of DS brain, although one monoclonal antibody did not reveal different snRNP-immunoreactivity. Although decreased snRNP-protein could be explained by decreased mRNA-steady state levels, another underlying mechanism might be suggested: snRNP is one of the death substrates rapidly cleaved during apoptosis by interleukin-1-beta-converting enzyme-like (ICE) proteases, which was well-documented by several groups. As apoptosis is unrequivocally taking place in DS brain leading to permanent cell loses, decreased snRNP-protein levels may therefore reflect decreased synthesis and increased apoptosis-related proteolytic cleavage.

The human homologue of the yeast splicing factor prp6p contains multiple TPR elements and is stably associated with the U5 snRNP via protein-protein interactions.

An essential step of pre-mRNA spliceosome assembly is the interaction between the snRNPs U4/U6 and U5, to form the [U4/U6.U5] tri-snRNP. While the tri-snRNP protein Prp6p appears to play an important role for tri-snRNP formation in yeast, little is known about the interactions that connect the two snRNP particles in human tri-snRNPs. Here, we describe the molecular characterisation of a 102kD protein form HeLa tri-snRNPs. The 102kD protein exhibits a significant degree of overall homology with the yeast Prp6p, including the conservation of multiple tetratrico peptide repeats (TPR), making this the likely functional homologue of Prp6p. However, while the yeast Prp6p is considered to be a U4/U6-specific protein, the human 102kD protein was found to be tightly associated with purified 20 S U5 snRNPs. This association appears to be primarily due to protein-protein interactions. Interestingly, antibodies directed against the C-terminal TPR elements of the 102kD protein specifically and exclusively immunoprecipitate free U5 snRNPs, but not [U4/U6.U5] tri-snRNPs, from HeLa nuclear extract, suggesting that the C-terminal region of the 102kD protein is covered by U4/U6 or tri-snRNP-specific proteins. Since proteins containing TPR elements are typically involved in multiple protein-protein interactions, we suggest that the 102kD protein interacts within the tri-snRNP with both the U5 and U4/U6 snRNPs, thus bridging the two particles. Consistent with this idea, we show that in vitro translated U5-102kD protein binds to purified 13S U4/U6 snRNPs, which contain, in addition to the Sm proteins, all known U4/U6-specific proteins.

Crystal structure of the human U4/U6 small nuclear ribonucleoprotein particle-specific SnuCyp-20, a nuclear cyclophilin.

The cyclophilin SnuCyp-20 is a specific component of the human U4/U6 small nuclear ribonucleoprotein particle involved in the nuclear splicing of pre-mRNA. It stably associates with the U4/U6-60kD and -90kD proteins, the human orthologues of the Saccharomyces cerevisiae Prp4 and Prp3 splicing factors. We have determined the crystal structure of SnuCyp-20 at 2.0-A resolution by molecular replacement. The structure of SnuCyp-20 closely resembles that of human cyclophilin A (hCypA). In particular, the catalytic centers of SnuCyp-20 and hCypA superimpose perfectly, which is reflected by the observed peptidyl-prolyl-cis/trans-isomerase activity of SnuCyp-20. The surface properties of both proteins, however, differ significantly. Apart from seven additional amino-terminal residues, the insertion of five amino acids in the loop alpha1-beta3 and of one amino acid in the loop alpha2-beta8 changes the conformations of both loops. The enlarged loop alpha1-beta3 is involved in the formation of a wide cleft with predominantly hydrophobic character. We propose that this enlarged loop is required for the interaction with the U4/U6-60kD protein.

A doughnut-shaped heteromer of human Sm-like proteins binds to the 3'-end of U6 snRNA, thereby facilitating U4/U6 duplex formation in vitro.

We describe the isolation and molecular characterization of seven distinct proteins present in human [U4/U6.U5] tri-snRNPs. These proteins exhibit clear homology to the Sm proteins and are thus denoted LSm (like Sm) proteins. Purified LSm proteins form a heteromer that is stable even in the absence of RNA and exhibits a doughnut shape under the electron microscope, with striking similarity to the Sm core RNP structure. The purified LSm heteromer binds specifically to U6 snRNA, requiring the 3'-terminal U-tract for complex formation. The 3'-end of U6 snRNA was also co-precipitated with LSm proteins after digestion of isolated tri-snRNPs with RNaseT(1). Importantly, the LSm proteins did not bind to the U-rich Sm sites of intact U1, U2, U4 or U5 snRNAs, indicating that they can only interact with a 3'-terminal U-tract. Finally, we show that the LSm proteins facilitate the formation of U4/U6 RNA duplices in vitro, suggesting that the LSm proteins may play a role in U4/U6 snRNP formation.

The human U5-220kD protein (hPrp8) forms a stable RNA-free complex with several U5-specific proteins, including an RNA unwindase, a homologue of ribosomal elongation factor EF-2, and a novel WD-40 protein.

The human small nuclear ribonucleoprotein (snRNP) U5 is biochemically the most complex of the snRNP particles, containing not only the Sm core proteins but also 10 particle-specific proteins. Several of these proteins have sequence motifs which suggest that they participate in conformational changes of RNA and protein. Together, the specific proteins comprise 85% of the mass of the U5 snRNP particle. Therefore, protein-protein interactions should be highly important for both the architecture and the function of this particle. We investigated protein-protein interactions using both native and recombinant U5-specific proteins. Native U5 proteins were obtained by dissociation of U5 snRNP particles with the chaotropic salt sodium thiocyanate. A stable, RNA-free complex containing the 116-kDa EF-2 homologue (116kD), the 200kD RNA unwindase, the 220kD protein, which is the orthologue of the yeast Prp8p protein, and the U5-40kD protein was detected by sedimentation analysis of the dissociated proteins. By cDNA cloning, we show that the 40kD protein is a novel WD-40 repeat protein and is thus likely to mediate regulated protein-protein interactions. Additional biochemical analyses demonstrated that the 220kD protein binds simultaneously to the 40- and the 116kD proteins and probably also to the 200kD protein. Since the 220kD protein is also known to contact both the pre-mRNA and the U5 snRNA, it is in a position to relay the functional state of the spliceosome to the other proteins in the complex and thus modulate their activity.

The mammalian homologue of Prp16p is overexpressed in a cell line tolerant to Leflunomide, a new immunoregulatory drug effective against rheumatoid arthritis.

Prp2p, Prp16p, Prp22p, and Prp43p are members of the DEAH-box family of ATP-dependent putative RNA helicases required for pre-mRNA splicing in Saccharomyces cerevisiae. Recently, mammalian homologues of Prp43p and Prp22p have been described, supporting the idea that splicing in yeast and man is phylogenetically conserved. In this study, we show that a murine cell line resistant to the novel immunoregulatory drug Leflunomide (Arava) overexpresses a 135-kDa protein that is a putative DEAH-box RNA helicase. We have cloned the human counterpart of this protein and show that it shares pronounced sequence homology with Prp16p. Apart from its N-terminal domain, which is rich in RS, RD, and RE dipeptides, this human homologue of Prp16p (designated hPrp16p) is 41% identical to Prp16p. Significantly, homology is not only observed within the phylogenetically conserved helicase domain, but also in Prp16p-specific sequences. Immunofluorescence microscopy studies demonstrated that hPrp16p co-localizes with snRNPs in subnuclear structures referred to as speckles. Antibodies specific for hPrp16p inhibited pre-mRNA splicing in vitro prior to the second step. Thus, like its yeast counterpart, hPrp16p also appears to be required for the second catalytic step of splicing. Taken together, our data indicate that the human 135-kDa protein identified here is the structural and functional homologue of the yeast putative RNA helicase, Prp16p.

The human U5-200kD DEXH-box protein unwinds U4/U6 RNA duplices in vitro.

Splicing of nuclear precursors of mRNA (pre-mRNA) involves dynamic interactions between the RNA constituents of the spliceosome. The rearrangement of RNA-RNA interactions, such as the unwinding of the U4/U6 duplex, is believed to be driven by ATP-dependent RNA helicases. We recently have shown that spliceosomal U5 small nuclear ribonucleoproteins (snRNPs) from HeLa cells contain two proteins, U5-200kD and U5-100kD, which share homology with the DEAD/DEXH-box families of RNA helicases. Here we demonstrate that purified U5 snRNPs exhibit ATP-dependent unwinding of U4/U6 RNA duplices in vitro. To identify the protein responsible for this activity, U5 snRNPs were depleted of a subset of proteins under high salt concentrations and assayed for RNA unwinding. The activity was retained in U5 snRNPs that contain the U5-200kD protein but lack U5-100kD, suggesting that the U5-200kD protein could mediate U4/U6 duplex unwinding. Finally, U5-200kD was purified to homogeneity by glycerol gradient centrifugation of U5 snRNP proteins in the presence of sodium thiocyanate, followed by ion exchange chromatography. The RNA unwinding activity was found to reside exclusively with the U5-200kD DEXH-box protein. Our data raise the interesting possibility that this RNA helicase catalyzes unwinding of the U4/U6 RNA duplex in the spliceosome.

The 20kD protein of human [U4/U6.U5] tri-snRNPs is a novel cyclophilin that forms a complex with the U4/U6-specific 60kD and 90kD proteins.

Cyclophilins (Cyps) catalyze the cis/trans isomerization of peptidyl-prolyl bonds, a rate-limiting step in protein folding. In some cases, cyclophilins have also been shown to form stable complexes with specific proteins in vivo and may thus also act as chaperone-like molecules. We have characterized the 20kD protein of the spliceosomal 25S [U4/U6.U5] tri-snRNP complex from HeLa cells and show that it is a novel human cyclophilin (denoted SnuCyp-20). Purified [U4/U6.U5] tri-snRNPs, but not U1, U2, or U5 snRNPs, exhibit peptidyl-prolyl cis/trans isomerase activity in vitro, which is cyclosporin A-sensitive, suggesting that SnuCyp-20 is an active isomerase. Consistent with its specific association with tri-snRNPs in vitro, immunofluorescence microscopy studies showed that SnuCyp-20 is predominantly located in the nucleus, where it colocalizes in situ with typical snRNP-containing structures referred to as nuclear speckles. As a first step toward the identification of possible targets of SnuCyp-20, we have investigated the interaction of SnuCyp-20 with other proteins of the tri-snRNP. Fractionation of RNA-free protein complexes dissociated from isolated tri-snRNPs by treatment with high salt revealed that SnuCyp-20 is part of a biochemically stable heteromer containing additionally the U4/U6-specific 60kD and 90kD proteins. By coimmunoprecipitation experiments performed with in vitro-translated proteins, we could further demonstrate a direct interaction between SnuCyp-20 and the 60kD protein, but failed to detect a protein complex containing the 90kD protein. The formation of a stable SnuCyp-20/60kD/90kD heteromer may thus require additional factors not present in our in vitro reconstitution system. We discuss possible roles of SnuCyp-20 in the assembly of [U4/U6.U5] tri-snRNPs and/or in conformational changes occurring during the splicing process.

The human U5 snRNP-specific 100-kD protein is an RS domain-containing, putative RNA helicase with significant homology to the yeast splicing factor Prp28p.

Through UV-crosslinking experiments, we previously provided evidence suggesting that a U5 snRNP protein with a molecular weight in the 100-kDa range is an ATP-binding protein (Laggerbauer B, Lauber J, Lührmann R, 1996, Nucleic Acid Res 24:868-875). Separation of HeLa U5 snRNP proteins on 2D gels revealed multiple variants with apparent molecular masses of 100 kDa. Subsequent microsequencing of these variants led to the isolation of a cDNA encoding a protein with an N-terminal RS domain and a C-terminal domain that contains all of the conserved motifs characteristic of members of the DEAD-box family of RNA-stimulated ATPases and RNA helicases. Antibodies raised against cDNA-encoded 100-kDa protein specifically recognized native U5-100kD both on immunoblots and in purified HeLa U5 snRNPs or [U4/U6.U5] tri-snRNP complexes, confirming that the bona fide 100-kDa cDNA had been isolated. In vitro phosphorylation studies demonstrated that U5-100kD can serve as a substrate for both Clk/Sty and the U1 snRNP-associated kinase, and further suggested that the multiple U5-100kD variants observed on 2D gels represent differentially phosphorylated forms of the protein. A database homology search revealed a significant degree of homology (60% similarity, 37% identity) between the Saccharomyces cerevisiae splicing factor, Prp28p, which lacks an N-terminal RS domain, and the C-terminal domain of U5-100kD. Consistent with their designation as structural homologues, anti-Prp28 antibodies recognized specifically the human U5-100kD protein on immunoblots. Together with the DEXH-box U5-200kD protein (Lauber J et al., 1996, EMBO J 15:4001-4015), U5-100kD is the second example of a putative RNA helicase that is tightly associated with the U5 snRNP. Given the recent identification of the U5-116kD protein as a homologue of the ribosomal translocase EF-2 (Fabrizio P, Laggerbauer B, Lauber J, Lane WS, Lührmann R, 1997, EMBO J 16:4092-4106), at least three integral U5 snRNP proteins thus potentially facilitate conformational changes in the spliceosome during nuclear pre-mRNA splicing.

Factors involved in the activation of pre-mRNA splicing from downstream splicing enhancers.

The excision of introns with weak polypyrimidine tracts at their 3' splice sites can be enhanced by sequence elements in the downstream exon or by a downstream 5' splice site. The enhancers inside the exon do not conform to a strict consensus, but they are generally rich in purines. Here, we show that members of the family of SR proteins recognize these elements. Not only does SF2/ASF activate many different polypurine enhancers, but also at least one other SR protein, most likely SC35, is active as well. The degree of splicing activation varies with the polypurine enhancers and the SR proteins. Further, we show that the similar activation by downstream 5' splice sites requires U1 snRNP, which is not the case with purine-rich enhancers. These results are consistent with a model showing that U1 snRNP binds to the 5' splice site and SR proteins to exonic sequences upstream of the 5' splice site. Both interact with U2AF at the 3' splice site. This represents a molecular explanation for the exon recognition which is important for splice site selection in mammals.

Identity elements of human tRNA(Leu): structural requirements for converting human tRNA(Ser) into a leucine acceptor in vitro.

We have previously shown that the exchange of the discriminator base A73 of human tRNA(Leu) for G is alone sufficient to achieve complete loss of leucine acceptance and to create an efficient serine acceptor. The reverse identity switch, however, which was studied using T7 RNA polymerase transcripts of in vitro mutagenized tRNA genes, reveals a far more complex pattern of identity elements for tRNA(Leu). Introduction of the following tRNA(Leu)-specific structures is necessary to transform human tRNA(Ser) into an efficient leucine acceptor: the discriminator base A73, the base pairs C3:G70, A4:U69 and G5:C68 of the acceptor stem, C20a of the DHU loop and the long extra arm. In contrast to tRNA(Ser), human tRNA(Leu) identity requires both the sequence and the correct orientation of the long extra arm, whereas only its orientation is essential for serine identity.

Identity determinants of human tRNA(Ser): sequence elements necessary for serylation and maturation of a tRNA with a long extra arm.

Recently, there has been much progress in understanding tRNA identity, i.e. in elucidating the sets of nucleotides that are responsible for the specific aminoacylation of a tRNA with its cognate amino acid. Interest focused, however, on tRNAs from Escherichia coli and yeast. Here we have identified the major and minor determinants of human tRNA(Ser) which were revealed by an identity switch from human tRNA(Val) to tRNA(Ser). We used in vitro transcripts and subsequent aminoacylation by HeLa S100 extract to determine the kinetic parameter Vmax/Km. The two major identity elements which are absolutely required for aminoacylation by human seryl-tRNA synthetase are the discriminator base and the long extra arm. This is in contrast to E. coli tRNA(Ser) where the discriminator base is unimportant, whereas identity determinants in the acceptor stem are required. Other sequence elements have an influence not only on serylation, but also on tRNA maturation in vitro, i.e. on pre-tRNA processing and base modification. These nucleotides are located in the DHU and the T phi C arm and are probably necessary for the proper folding of tRNAs containing a long extra arm. A34 to inosine modification depends highly on the correct three-dimensional structure of the tRNA, whereas A58 to m1A methylation does not rely on the three-dimensional folding of the substrate. This is the first tRNA identity switch involving the exchange of a short versus a long extra arm.