In vitro reconstitution of snRNPs: a reconstituted U4/U6 snRNP participates in splicing complex formation

RNAi knockdown of hPrp31 leads to an accumulation of U4/U6 di-snRNPs in Cajal bodies

Cajal bodies (CBs) are subnuclear organelles of animal and plant cells. A role of CBs in the assembly and maturation of small nuclear ribonucleoproteins (snRNP) has been proposed but is poorly understood. Here we have addressed the question where U4/U6.U5 tri-snRNP assembly occurs in the nucleus. The U4/U6.U5 tri-snRNP is a central unit of the spliceosome and must be re-formed from its components after each round of splicing. By combining RNAi and biochemical methods, we demonstrate that, after knockdown of the U4/U6-specific hPrp31 (61 K) or the U5-specific hPrp6 (102 K) protein in HeLa cells, tri-snRNP formation is inhibited and stable U5 mono-snRNPs and U4/U6 di-snRNPs containing U4/U6 proteins and the U4/U6 recycling factor p110 accumulate. Thus, hPrp31 and hPrp6 form an essential connection between the U4/U6 and U5 snRNPs in vivo. Using fluorescence microscopy, we show that, in the absence of either hPrp31 or hPrp6, U4/U6 di-snRNPs as well as p110 accumulate in Cajal bodies. In contrast, U5 snRNPs largely remain in nucleoplasmic speckles. Our data support the idea that CBs may play a role in tri-snRNP recycling.

The 65 and 110 kDa SR-related proteins of the U4/U6.U5 tri-snRNP are essential for the assembly of mature spliceosomes

The association of the U4/U6.U5 tri-snRNP with pre-spliceosomes is a poorly understood step in the spliceosome assembly pathway. We have identified two human tri-snRNP proteins (of 65 and 110 kDa) that play an essential role in this process. Characterization by cDNA cloning of the 65 and 110 kDa proteins revealed that they are likely orthologues of the yeast spliceosomal proteins Sad1p and Snu66p, respectively. Immunodepletion of either protein from the HeLa cell nuclear extracts inhibited pre-mRNA splicing due to a block in the formation of mature spliceosomes, but had no effect on the integrity of the U4/U6.U5 tri-snRNP. Spliceosome assembly and splicing catalysis could be restored to the respective depleted extract by the addition of recombinant 65 or 110 kDa protein. Our data demonstrate that both proteins are essential for the recruitment of the tri-snRNP to the pre-spliceosome but not for the maintenance of the tri-snRNP stability. Moreover, since both proteins contain an N-terminal RS domain, they could mediate the association of the tri-snRNP with pre-spliceosomes by interaction with members of the SR protein family.

Alternate exon usage is a commonly used mechanism for increasing coding diversity within genes coding for extracellular matrix proteins

Extracellular matrix proteins are a diverse family of secreted proteins and glycoproteins that are responsible for a variety of critical functions in different tissues. A large number of multiexon genes encode these proteins of the extracellular matrix. Over the last few years, it has become evident that the processing of the pre-mRNA from several of these genes involves alternative splicing. This review summarizes the known examples of alternative splicing in genes coding for the extracellular matrix and attempts to relate the increase in coding diversity generated by alternate exon usage to the function(s) of individual extracellular matrix proteins.

In vitro reconstitution of U1 and U2 snRNPs from isolated proteins and snRNA

In this paper we describe a method for preparing native, RNA-free, proteins from anti-m3G purified snRNPs (U1, U2, U4/U6 and U5) and the subsequent quantitative reconstitution of U1 and U2 snRNPs from purified proteins and snRNA. Reconstituted U1 and U2 snRNPs contained the full complement of core proteins, B, B', D1, D2, D3, E, F and G. Both the U1 and U2 reconstituted particles were stable in CsCl gradients and had the expected buoyant density of 1.4 g/cm3. Reconstituted RNP particle formation was not competited by a 50 fold molar excess of tRNA, as determined by gel retardation assays. However, U1 and U2 particle formation was reduced in the presence of an excess of cold U1 or U2 snRNA demonstrating a specific RNA-protein interaction. U1 and U2 snRNPs were also efficiently reconstituted in vitro, utilizing proteins prepared from mono Q purified U1 and U2 snRNPs. This suggests that for the assembly of snRNPs in vitro no auxiliary proteins other than bona fide snRNP proteins appear to be required. The potential of this reconstitution technique for investigating snRNP assembly and snRNA-protein interactions is discussed.

Mutational analysis of Schizosaccharomyces pombe U4 snRNA by plasmid exchange

We have developed a system for testing mutations by plasmid exchange in the fission yeast Schizosaccharomyces pombe. This system has been used to test the requirement for different regions of the small nuclear RNA U4 in S. pombe. Surprisingly, five of seven deletion and substitution mutations tested in different regions of U4 prevent the accumulation of the mutant RNA. Substitution of the U4 sequence in stem 1 of the U4/U6 interaction domain allows accumulation of the mutant U4, but does not support viability. Two sequences with homology to the Sm binding site are found in the 3' region of S. pombe U4; substitution of the 3' sequence of the two does not interfere with accumulation or function of U4, indicating that the 5' sequence is the functional Sm-binding site.

Assembly and nuclear transport of the U4 and U4/U6 snRNPs

We have analyzed the assembly of the spliceosomal U4/U6 snRNP by injecting synthetic wild-type and mutant U4 RNAs into the cytoplasm of Xenopus oocytes and determining the cytoplasmic-nuclear distribution of U4 and U4/U6 snRNPs by CsCl density gradient centrifugation. Whereas the U4 snRNP was localized in both the cytoplasmic and nuclear fractions, the U4/U6 snRNP was detected exclusively in the nuclear fraction. Cytoplasmic-nuclear migration of the U4 snRNP did not depend on the stem II nor on the 5' stem-loop region of U4 RNA. Our data provide strong evidence that, following the cytoplasmic assembly of the U4 snRNP, the interaction of the U4 snRNP with U6 RNA/RNP occurs in the nucleus; furthermore, cytoplasmic-nuclear transport of the U4 snRNP is independent of U4/U6 snRNP assembly.

Domain structure of U2 and U4/U6 small nuclear ribonucleoprotein particles from Trypanosoma brucei: identification of trans-spliceosomal specific RNA-protein interactions

Maturation of mRNAs in trypanosomes involves trans splicing of the 5' end of the spliced leader RNA and the exons of polycistronic pre-mRNAs, requiring small nuclear ribonucleoproteins (snRNPs) as cofactors. We have mapped protein-binding sites in the U2 and U4/U6 snRNPs by a combination of RNase H protection analysis, native gel electrophoresis, and CsCl density gradient centrifugation. In the U2 snRNP, protein binding occurs primarily in the 3'-terminal domain; through U2 snRNP reconstitution and chemical modification-interference assays, we have identified discrete positions within stem-loop IV of Trypanosoma brucei U2 RNA that are essential for protein binding; significantly, some of these positions differ from the consensus sequence derived from cis-spliceosomal U2 RNAs. In the U4/U6 snRNP, the major protein-binding region is contained within the 3'-terminal half of U4 RNA. In sum, while the overall domain structure of the U2 and U4/U6 snRNPs is conserved between cis- and trans-splicing systems, our data suggest that there are also trans-spliceosomal specific determinants of RNA-protein binding.

Domain structure of U2 and U4/U6 small nuclear ribonucleoprotein particles from Trypanosoma brucei: identification of trans-spliceosomal specific RNA-protein interactions

Maturation of mRNAs in trypanosomes involves trans splicing of the 5' end of the spliced leader RNA and the exons of polycistronic pre-mRNAs, requiring small nuclear ribonucleoproteins (snRNPs) as cofactors. We have mapped protein-binding sites in the U2 and U4/U6 snRNPs by a combination of RNase H protection analysis, native gel electrophoresis, and CsCl density gradient centrifugation. In the U2 snRNP, protein binding occurs primarily in the 3'-terminal domain; through U2 snRNP reconstitution and chemical modification-interference assays, we have identified discrete positions within stem-loop IV of Trypanosoma brucei U2 RNA that are essential for protein binding; significantly, some of these positions differ from the consensus sequence derived from cis-spliceosomal U2 RNAs. In the U4/U6 snRNP, the major protein-binding region is contained within the 3'-terminal half of U4 RNA. In sum, while the overall domain structure of the U2 and U4/U6 snRNPs is conserved between cis- and trans-splicing systems, our data suggest that there are also trans-spliceosomal specific determinants of RNA-protein binding.

Methylated cap structures in eukaryotic RNAs: structure, synthesis and functions

There are more than twenty capped small nuclear RNAs characterized in eukaryotic cells. All the capped RNAs appear to be involved in the processing of other nuclear premessenger or preribosomal RNAs. These RNAs contain either trimethylguanosine (TMG) cap structure or methylated gamma phosphate (Mppp) cap structure. The TMG capped RNAs are capped with M7G during transcription by RNA polymerase II and trimethylated further post-transcriptionally. The Mppp-capped RNAs are transcribed by RNA polymerase III and also capped post-transcriptionally. The cap structures improve the stability of the RNAs and in some cases TMG cap is required for transport of the ribonucleoproteins from cytoplasm to the nucleus. Where tested, the cap structures were not essential for their function in processing other RNAs.

Analysis of small nuclear ribonucleoproteins (RNPs) in Trypanosoma brucei: structural organization and protein components of the spliced leader RNP

trans splicing in Trypanosoma brucei involves the ligation of the 40-nucleotide spliced leader (SL) to each of the exons of large, polycistronic pre-mRNAs and requires the function of small nuclear ribonucleoproteins (snRNPs). We have identified and characterized snRNP complexes of SL, U2, U4, and U6 RNAs in T. brucei extracts by a combination of glycerol gradient sedimentation, CsCl density centrifugation, and anti-m3G immunoprecipitation. Both the SL RNP and the U4/U6 snRNP contain salt-stable cores; the U2 snRNP, in contrast to other eucaryotic snRNPs, is not stable under stringent ionic conditions. Two distinct complexes of U6 RNA were found, a U6 snRNP and a U4/U6 snRNP. The structure of the SL RNP was analyzed in detail by oligonucleotide-directed RNase H protection and by in vitro reconstitution. Our results indicate that the 3' half of SL RNA constitutes the core protein-binding domain and that protein components of the SL RNP also bind to the U2 and U4 RNAs. Using antisense RNA affinity chromatography, we identified a set of low-molecular-mass proteins (14.8, 14, 12.5, and 10 kDa) as components of the core SL RNP.

Analysis of small nuclear ribonucleoproteins (RNPs) in Trypanosoma brucei: structural organization and protein components of the spliced leader RNP

trans splicing in Trypanosoma brucei involves the ligation of the 40-nucleotide spliced leader (SL) to each of the exons of large, polycistronic pre-mRNAs and requires the function of small nuclear ribonucleoproteins (snRNPs). We have identified and characterized snRNP complexes of SL, U2, U4, and U6 RNAs in T. brucei extracts by a combination of glycerol gradient sedimentation, CsCl density centrifugation, and anti-m3G immunoprecipitation. Both the SL RNP and the U4/U6 snRNP contain salt-stable cores; the U2 snRNP, in contrast to other eucaryotic snRNPs, is not stable under stringent ionic conditions. Two distinct complexes of U6 RNA were found, a U6 snRNP and a U4/U6 snRNP. The structure of the SL RNP was analyzed in detail by oligonucleotide-directed RNase H protection and by in vitro reconstitution. Our results indicate that the 3' half of SL RNA constitutes the core protein-binding domain and that protein components of the SL RNP also bind to the U2 and U4 RNAs. Using antisense RNA affinity chromatography, we identified a set of low-molecular-mass proteins (14.8, 14, 12.5, and 10 kDa) as components of the core SL RNP.

Suppressors of a U4 snRNA mutation define a novel U6 snRNP protein with RNA-binding motifs

U4 and U6 small nuclear RNAs are associated by an extensive base-pairing interaction that must be disrupted and reformed with each round of splicing. U4 mutations within the U4/U6 interaction domain destabilize the complex in vitro and cause a cold-sensitive phenotype in vivo. Restabilization of the U4/U6 helix by dominant (gain-of-function), compensatory mutations in U6 results in wild-type growth. Cold-insensitive growth can also be restored by two classes of recessive (loss-of-function) suppressors: (1) mutations in PRP24, which we show to be a U6-specific binding protein of the RNP-consensus family; and (2) mutations in U6, which lie outside the interaction domain and identify putative PRP24-binding sites. Destabilization of the U4/U6 helix causes the accumulation of a PRP24/U4/U6 complex, which is undetectable in wild-type cells. The loss-of-function suppressor mutations inhibit the binding of PRP24 to U6, and thus presumably promote the release of PRP24 from the PRP24/U4/U6 complex and the reformation of the base-paired U4/U6 snRNP. We propose that the PRP24/U4/U6 complex is normally a highly transient intermediate in the spliceosome cycle and that PRP24 promotes the reannealing of U6 with U4.

Leucine periodicity of U2 small nuclear ribonucleoprotein particle (snRNP) A' protein is implicated in snRNP assembly via protein-protein interactions

Recombinant A' protein could be reconstituted into U2 small nuclear ribonucleoprotein particles (snRNPs) upon addition to HeLa cell extracts as determined by coimmunoprecipitation and particle density; however, direct binding to U2 RNA could not be demonstrated except in the presence of the U2 snRNP B" protein. Mutational analysis indicated that a central core region of A' was required for particle reconstitution. This region consists of five tandem repeats of approximately 24 amino acids each that exhibit a periodicity of leucine and asparagine residues that is distinct from the leucine zipper. Similar leucine-rich (Leu-Leu motif) repeats are characteristic of a diverse array of soluble and membrane-associated proteins from yeasts to humans but have not been reported previously to reside in nuclear proteins. Several of these proteins, including Toll, chaoptin, RNase/angiogenin inhibitors, lutropin-choriogonadotropin receptor, carboxypeptidase N, adenylyl cyclase, CD14, and human immunodeficiency virus type 1 Rev, may be involved in protein-protein interactions. Our findings suggest that in cell extracts the Leu-Leu motif of A' is required for reconstitution with U2 snRNPs and perhaps with other components involved in splicing through protein-protein interactions.

Leucine periodicity of U2 small nuclear ribonucleoprotein particle (snRNP) A' protein is implicated in snRNP assembly via protein-protein interactions

Recombinant A' protein could be reconstituted into U2 small nuclear ribonucleoprotein particles (snRNPs) upon addition to HeLa cell extracts as determined by coimmunoprecipitation and particle density; however, direct binding to U2 RNA could not be demonstrated except in the presence of the U2 snRNP B" protein. Mutational analysis indicated that a central core region of A' was required for particle reconstitution. This region consists of five tandem repeats of approximately 24 amino acids each that exhibit a periodicity of leucine and asparagine residues that is distinct from the leucine zipper. Similar leucine-rich (Leu-Leu motif) repeats are characteristic of a diverse array of soluble and membrane-associated proteins from yeasts to humans but have not been reported previously to reside in nuclear proteins. Several of these proteins, including Toll, chaoptin, RNase/angiogenin inhibitors, lutropin-choriogonadotropin receptor, carboxypeptidase N, adenylyl cyclase, CD14, and human immunodeficiency virus type 1 Rev, may be involved in protein-protein interactions. Our findings suggest that in cell extracts the Leu-Leu motif of A' is required for reconstitution with U2 snRNPs and perhaps with other components involved in splicing through protein-protein interactions.

Conserved domains of human U4 snRNA required for snRNP and spliceosome assembly

U4 snRNA is phylogenetically highly conserved and organized in several domains. To determine the function of each of the domains of human U4 snRNA in the multi-step process of snRNP and spliceosome assembly, we used reconstitution procedures in combination with snRNA mutagenesis. The highly conserved 5' terminal domain of U4 snRNA consists of the stem I and stem II regions that have been proposed to base pair with U6 snRNA, and the 5' stem-loop structure. We found that each of these structural elements is essential for spliceosome assembly. However, only the stem II region is required for U4-U6 interaction, and none of these elements for Sm protein binding. In contrast, the 3' terminal domain of U4 snRNA containing the Sm binding site is dispensable for both U4-U6 interaction and spliceosome assembly. Our results support an organization of the U4 snRNP into multiple functional domains, each of which acts at distinct stages of snRNP and spliceosome assembly.

Herpesvirus saimiri U RNAs are expressed and assembled into ribonucleoprotein particles in the absence of other viral genes

Marmoset T lymphocytes transformed by herpesvirus saimiri contain a set of five virally encoded U RNAs called HSUR1 through HSUR5. HSUR genes have been individually transfected into a nonlymphoid, nonsimian cell line (HeLa cells) in the absence of any other coding regions of the herpesvirus saimiri genome. The levels of HSUR1 through HSUR4 in HeLa transient-expression systems are comparable to those found in virally transformed T cells (23 to 91%). In contrast, HSUR5 is expressed at ninefold-higher levels in transfected HeLa cells. Immunoprecipitation experiments show that HSURs expressed in transfected cells bind proteins with Sm determinants and acquire a 5' trimethylguanosine cap structure, as they do in transformed T cells. HSUR1 or HSUR4 particles from transfected HeLa cells migrate between 10S and 15S in velocity gradients, identical to the sedimentation of "monoparticles" produced in virally transformed lymphocytes. We conclude from these transfection experiments that no other herpesvirus saimiri or host-cell-specific gene products appear to be required for efficient expression of the HSUR genes or for subsequent assembly of the viral U RNAs into small nuclear ribonucleoprotein particles. In lymphocytes transformed by herpesvirus saimiri, HSUR small nuclear ribonucleoprotein particles are involved in higher-order complexes that sediment between 20S and 25S. HSUR1, HSUR2, and HSUR5 dissociate from such complexes upon incubation at 30 degrees C, whereas the complex containing HSUR4 is stable to incubation.

Domains of yeast U4 spliceosomal RNA required for PRP4 protein binding, snRNP-snRNP interactions, and pre-mRNA splicing in vivo

U4 small nuclear RNA (snRNA) contains two intramolecular stem-loop structures, located near each end of the molecule. The 5' stem-loop is highly conserved in structure and separates two regions of U4 snRNA that base-pair with U6 snRNA in the U4/U6 small nuclear ribonucleoprotein particle (snRNP). The 3' stem-loop is highly divergent in structure among species and lies immediately upstream of the binding site for Sm proteins. To investigate the function of these two domains, mutants were constructed that delete the yeast U4 snRNA 5' stem-loop and that replace the yeast 3' stem-loop with that from trypanosome U4 snRNA. Both mutants fail to complement a null allele of the yeast U4 gene. The defects of the mutants have been examined in heterozygous strains by native gel electrophoresis, glycerol gradient centrifugation, and immunoprecipitation. The chimeric yeast-trypanosome RNA does not associate efficiently with U6 snRNA, suggesting that the 3' stem-loop of yeast U4 snRNA might be a binding site for a putative protein that facilitates assembly of the U4/U6 complex. In contrast, the 5' hairpin deletion mutant associates efficiently with U6 snRNA. However, it does not bind the U4/U6-specific protein PRP4 and does not assemble into a U4/U5/U6 snRNA. Thus, we propose that the role of the PRP4 protein is to promote interactions between the U4/U6 snRNP and the U5 snRNP.

The PRP4 (RNA4) protein of Saccharomyces cerevisiae is associated with the 5' portion of the U4 small nuclear RNA

We have combined oligonucleotide-directed RNase H degradation and immunoprecipitation in a study of the association of the Saccharomyces cerevisiae PRP4 protein with the U4-U6 complex. We have found that three oligonucleotides were able to direct nearly to completion the RNase H-specific cleavage of the target RNA molecules as they exist in splicing extracts. Immunoprecipitation of the degradation products with PRP4 antibody showed that the 5' portion of U4 small nuclear RNA (snRNA) and the 3' portion of U6 snRNA coimmunoprecipitated with the PRP4 protein. Micrococcal nuclease protection experiments confirmed further that the 5' portion and 3' end of U4 snRNA were very resistant to nuclease digestion, whereas the 3' portion of U6 snRNA was protected to only a very small extent. We conclude that the PRP4 protein of S. cerevisiae is associated primarily with the 5' portion of U4 snRNA in the U4-U6 small nuclear ribonucleoprotein (snRNP).

The PRP4 (RNA4) protein of Saccharomyces cerevisiae is associated with the 5' portion of the U4 small nuclear RNA

We have combined oligonucleotide-directed RNase H degradation and immunoprecipitation in a study of the association of the Saccharomyces cerevisiae PRP4 protein with the U4-U6 complex. We have found that three oligonucleotides were able to direct nearly to completion the RNase H-specific cleavage of the target RNA molecules as they exist in splicing extracts. Immunoprecipitation of the degradation products with PRP4 antibody showed that the 5' portion of U4 small nuclear RNA (snRNA) and the 3' portion of U6 snRNA coimmunoprecipitated with the PRP4 protein. Micrococcal nuclease protection experiments confirmed further that the 5' portion and 3' end of U4 snRNA were very resistant to nuclease digestion, whereas the 3' portion of U6 snRNA was protected to only a very small extent. We conclude that the PRP4 protein of S. cerevisiae is associated primarily with the 5' portion of U4 snRNA in the U4-U6 small nuclear ribonucleoprotein (snRNP).

U2 small nuclear RNP assembly in vitro

Incubation of a SP6-transcribed human U2 RNA precursor molecule in a HeLa cell S100 fraction resulted in the formation of ribonucleoprotein complexes. In the presence of ATP, the particles that assembled had several properties of native U2 snRNP, including resistance to dissociation in Cs2SO4 gradients, their buoyant density, and pattern of digestion by micrococcal nuclease. These particles also reacted with Sm monoclonal antibody and a human autoantibody with specificity for the U2 snRNP-specific proteins A' and B", but not with antibodies for U1 snRNP-specific proteins. In contrast, the particles that formed in the absence of ATP did not have these properties. ATP analogs with non-hydrolyzable beta-gamma bonds did not substitute for ATP in U2 snRNP assembly. Additional experiments with a mutant U2 RNA confirmed that nucleotides 154-167 of U2 RNA are required for binding of the U2 snRNP-specific proteins but not of the "Sm" core proteins. Pseudouridine formation, a major post-transcriptional modification of U2 RNA, was enhanced under assembly permissive conditions.