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.     

An ordered pathway of snRNP binding during mammalian pre-mRNA splicing complex assembly.

We have studied the assembly, composition and structure of splicing complexes using biotin-avidin affinity chromatography and RNase protection assays. We find that U1, U2, U4, U5 and U6 snRNPs associate with the pre-mRNA and are in the mature, functional complex. Association of U1 snRNP with the pre-mRNA is rapid and ATP independent; binding of all other snRNPs occurs subsequently and is ATP dependent. Efficient binding of U1 and U2 snRNPs requires a 5' splice site or a 3' splice site/branch point region, respectively. Both sequence elements are required for efficient U4, U5 and U6 snRNP binding. Mutant RNA substrates containing only a 5' splice site or a 3' splice site/branch point region are assembled into 'partial' splicing complexes, which contain a subset of these five snRNPs. RNase protection experiments indicate that in contrast to U1 and U2 snRNPs, U4, U5 and U6 snRNPs do not contact the pre-mRNA. Based upon the time course of snRNP binding and the composition of sucrose gradient fractionated splicing complexes we suggest an assembly pathway proceeding from a 20S (U1 snRNP only) through a 40S (U1 and U2 snRNPs) to the functional 60S splicing complex (U1, U2, U4, U5 and U6 snRNPs).     

Protein-RNA interactions in 20S U5 snRNPs.

The interaction of the U5-specific polypeptides with U5 snRNA was investigated by comparison of the differential accessibility towards nucleases and dimethylsulfate of defined regions of U5 snRNA in purified 20S and 10S U5 snRNPs. While 20S U5 snRNPs contain eight U5-specific proteins in addition to the common proteins, the 10S U5 snRNPs contain only the latter proteins. The results indicate that only the central part of stem/loop I of U5 snRNA including internal loops IL2 and IL2', contains binding sites for U5-specific proteins, suggesting that several U5-specific proteins may be bound to U5 snRNP via protein-protein interactions. Moreover, they show that the core polypeptides do not interact with stem/loop I.     

The low-abundance U11 and U12 small nuclear ribonucleoproteins (snRNPs) interact to form a two-snRNP complex.

A novel small nuclear ribonucleoprotein (snRNP) complex containing both U11 and U12 RNAs has been identified in HeLa cell extracts. This U11/U12 snRNP complex can be visualized on glycerol gradients, on native polyacrylamide gels, and by selection with antisense 2'-O-methyl oligoribonucleotides. RNase H-mediated degradation of the U12 snRNA confirmed a direct interaction between the U11 and U12 snRNPs. This snRNP complex is the first to be identified involving low-abundance snRNPs. Selection of the U11/U12 snRNP complex is sensitive to high salt, suggestive of a protein-mediated interaction. Secondary structure analyses revealed several regions of the U11 snRNP accessible for interaction with other RNAs or proteins but no detectable difference between the accessibility of these regions in the U11 monoparticle compared with the U11/U12 snRNP complex. There are also several accessible single-stranded regions in the U12 snRNP, and oligonucleotide-directed RNase H digestion identified nucleotides 28 to 36 of U12 as containing sequences required for the U11/U12 interaction. Both the U12 snRNP and the U11/U12 snRNP complex can be disrupted without altering the cleavage/polyadenylation activity of a nuclear extract.     

Polypeptide components of Drosophila small nuclear ribonucleoprotein particles.

In eukaryotes splicing of pre-mRNAs is mediated by the spliceosome, a dynamic complex of small nuclear ribonucleoprotein particles (snRNPs) that associate transiently during spliceosome assembly and the splicing reaction. We have purified snRNPs from nuclear extracts of Drosophila cells by affinity chromatography with an antibody specific for the trimethylguanosine (m3G) cap structure of snRNAs U1-U5. The polypeptide components of Drosophila snRNPs have been characterized and shown to consist of a number of proteins shared by all the snRNPs, and some proteins which appear to be specific to individual snRNP particles. On the basis of their apparent molecular weight and antigenicity many of these common and particle specific Drosophila snRNP proteins are remarkably conserved between Drosophila and human spliceosomes. By probing western blots of the Drosophila snRNP polypeptides with a number of antisera raised against human snRNP proteins, Drosophila polypeptides equivalent to many of the HeLa snRNP-common proteins have been identified, as well as candidates for a number of U1, U2 and U5-specific proteins.     

A 69-kD protein that associates reversibly with the Sm core domain of several spliceosomal snRNP species

The biogenesis of the spliceosomal small nuclear ribonucleoproteins (snRNPs) U1, U2, U4, and U5 involves: (a) migration of the snRNA molecules from the nucleus to the cytoplasm; (b) assembly of a group of common proteins (Sm proteins) and their binding to a region on the snRNAs called the Sm-binding site; and (c) translocation of the RNP back to the nucleus. A first prerequisite for understanding the assembly pathway and nuclear transport of the snRNPs in more detail is the knowledge of all the snRNP proteins that play essential roles in these processes. We have recently observed a previously undetected 69- kD protein in 12S U1 snRNPs isolated from HeLa nuclear extracts under non-denaturing conditions that is clearly distinct from the U1-70K protein. The following evidence indicates that the 69-kD protein is a common, rather than a U1-specific, protein, possibly associating with the snRNP core particles by protein-protein interaction. (a) Antibodies raised against the 69-kD protein, which did not cross-react with any of the Sm proteins B'-G, precipitated not only U1 snRNPs, but also the other spliceosomal snRNPs U2, U4/U6 and U5, albeit to a lower extent. (b) U1, U2, and U5 core RNP particles reconstituted in vitro contain the 69-kD protein. (c) Xenopus laevis oocytes contain an immunologically related homologue of the human 69-kD protein. When U1 snRNA as well as a mutant U1 snRNA, that can bind the Sm core proteins but lacks the capacity to bind the U1-specific proteins 70K, A, and C, were injected into Xenopus oocytes to allow assembly in vivo, they were recognized by antibodies specific against the 69-kD protein in the ooplasm and in the nucleus. The 69-kD protein is under-represented, if present at all, in purified 17S U2 and in 25S [U4/U6.U5] tri-snRNPs, isolated from HeLa nuclear extracts. Our results are consistent with the working hypothesis that this protein may either play a role in the cytoplasmic assembly of the core domain of the snRNPs and/or in the nuclear transport of the snRNPs. After transport of the snRNPs into the nucleus, it may dissociate from the particles as for example in the case of the 17S U2 or the 25S [U4/U6.U5] tri-snRNP, which bind more than 10 different snRNP specific proteins each in the nucleus.     

Purification of Drosophila snRNPs and characterization of two populations of functional U1 particles

U1 snRNP is required at an early stage during assembly of the spliceosome, the dynamic ribonucleoprotein (RNP) complex that performs nuclear pre-mRNA splicing. Here, we report the purification of U1 snRNP particles from Drosophila nuclear extracts and the characterization of their biochemical properties, polypeptide contents, and splicing activities. On the basis of their antigenicity, apparent molecular weight, and by peptide sequencing, the Drosophila 70K, SNF, B, U1-C, D1, D2, D3, E, F, and G proteins are shown to be integral components of these particles. Sequence database searches revealed that both the U1-specific and the Sm proteins are extensively conserved between human and Drosophila snRNPs. Furthermore, both species possess a conserved intrinsic U1-associated kinase activity with identical substrate specificity in vitro. Finally, our results demonstrate that a second type of functional U1 particle, completely lacking the U1/U2-specific protein SNF and the associated protein kinase activity, can be isolated from cultured Kc cell or Canton S embryonic nuclear extracts. This work describes the first characterization of a purified Drosophila snRNP particle and reinforces the view that their activity and composition, with the exception of the atypical bifunctional U1-A/U2-B" SNF protein, are highly conserved in metazoans.     

In vitro reconstitution of mammalian U2 and U5 snRNPs active in splicing: Sm proteins are functionally interchangeable and are essential for the formation of functional U2 and U5 snRNPs.

An in vitro reconstitution/splicing complementation system has been developed which has allowed the investigation of the role of mammalian U2 and U5 snRNP components in splicing. U2 or U5 snRNP cores are first reconstituted from purified native snRNP core proteins and snRNA in the absence of cellular extract and are subsequently added to splicing extracts depleted of either U2 or U5 snRNP. When snRNPs reconstituted with HeLa U2 or U5 snRNA were added to U2- or U5-depleted nuclear extract, splicing was complemented. Addition of naked snRNA, on the other hand, did not restore splicing, demonstrating that the core proteins are essential for both U2 and U5 snRNP functions in splicing. Hybrid U2 or U5 snRNPs, reconstituted with core proteins isolated from U1 or U2 snRNPs, were equally active in splicing complementation, indicating that the snRNP core proteins are functionally interchangeable. U5 snRNPs reconstituted from in vitro transcribed U5 snRNA restored splicing to a level identical to that observed with particles reconstituted from authentic HeLa U5 snRNA. In contrast, splicing could not be restored to U2-depleted extract by the addition of snRNPs reconstituted from synthetic U2 snRNA, suggesting that U2 snRNA base modifications are essential for U2 snRNP function.     

Conserved loop I of U5 small nuclear RNA is dispensable for both catalytic steps of pre-mRNA splicing in HeLa nuclear extracts

The function of conserved regions of the metazoan U5 snRNA was investigated by reconstituting U5 small nuclear ribonucleoprotein particles (snRNPs) from purified snRNP proteins and HeLa or Xenopus U5 snRNA mutants and testing their ability to restore splicing to U5-depleted nuclear extracts. Substitution of conserved nucleotides comprising internal loop 2 or deletion of internal loop 1 had no significant effect on the ability of reconstituted U5 snRNPs to complement splicing. However, deletion of internal loop 2 abolished U5 activity in splicing and spliceosome formation. Surprisingly, substitution of the invariant loop 1 nucleotides with a GAGA tetraloop had no effect on U5 activity. Furthermore, U5 snRNPs reconstituted from an RNA formed by annealing the 5' and 3' halves of the U5 snRNA, which lacked all loop 1 nucleotides, complemented both steps of splicing. Thus, in contrast to yeast, loop 1 of the human U5 snRNA is dispensable for both steps of splicing in HeLa nuclear extracts. This suggests that its function can be compensated for in vitro by other spliceosomal components: for example, by proteins associated with the U5 snRNP. Consistent with this idea, immunoprecipitation studies indicated that several functionally important U5 proteins associate stably with U5 snRNPs containing a GAGA loop 1 substitution.     

Ser/Arg-rich protein-mediated communication between U1 and U2 small nuclear ribonucleoprotein particles

Previous work demonstrated that U1 small nuclear ribonucleoprotein particle (snRNP), bound to a downstream 5' splice site, can positively influence utilization of an upstream 3' splice site via exon definition in both trans- and cis-splicing systems. Although exon definition results in the enhancement of splicing of an upstream intron, the nature of the factors involved has remained elusive. We assayed the interaction of U1 snRNP as well as the positive effect of a downstream 5' splice site on trans-splicing in nematode extracts containing either inactive (early in development) or active (later in development) serine/arginine-rich splicing factors (SR proteins). We have determined that U1 snRNP interacts with the 5' splice site in the downstream exon even in the absence of active SR proteins. In addition, we determined that U1 snRNP-directed loading of U2 snRNP onto the branch site as well as efficient trans-splicing in these inactive extracts could be rescued upon the addition of active SR proteins. Identical results were obtained when we examined the interaction of U1 snRNP as well as the requirement for SR proteins in communication across a cis-spliced intron. Weakening of the 3' splice site uncovered distinct differences, however, in the ability of U1 snRNP to promote U2 addition, dependent upon its position relative to the branch site. These results demonstrate that SR proteins are required for communication between U1 and U2 snRNPs whether this interaction is across introns or exons.     

Evidence from complementation assays in vitro that U5 snRNP is required for both steps of mRNA splicing.

We have established an in vitro complementation system that has allowed us to investigate the role of individual purified snRNPs in the splicing of pre-mRNA molecules. For the preparation of snRNP-depleted nuclear extracts we have first removed the majority of endogenous snRNPs from the nuclear extracts by one passage over an anti-m3G column and then degraded the remaining snRNPs with micrococcal nuclease. The mixture of snRNPs U1, U2, U4/U6 and U5, obtained by anti-m3G immuno-affinity chromatography, was functionally active and able to restore the splicing of snRNP-depleted nuclear extracts. Mono-Q chromatography was used for further fractionation of the snRNPs U1-U6. This produced three fractions that were highly enriched in snRNPs U1 and U2, U5 and U4/U6 respectively. Conditions were found where addition of the [U1, U2] and the U4/U6 snRNP fractions to the snRNP-depleted nuclear extracts gave rise to the formation of splice intermediates in the absence of any 3' cleavage/exon 1-exon 2 product formation. Only when purified 20S U5 snRNPs were added did both steps of the splicing reaction occur efficiently. Our data suggest that U5 snRNP is absolutely required for the second step of splicing and is needed further for efficient initiation of the splicing reaction. The requirement for U5 snRNPs for splicing was corroborated by glycerol gradient sedimentation analysis of the respective reconstituted pre-mRNP complexes. Stable and efficient formation of 50-60S spliceosomes was observed only in the presence of all snRNPs.     

Targeted snRNP depletion reveals an additional role for mammalian U1 snRNP in spliceosome assembly

HeLa cell nuclear splicing extracts have been prepared that are specifically and efficiently depleted of U1, U2, or U4/U6 snRNPs by antisense affinity chromatography using biotinylated 2'-OMe RNA oligonucleotides. Removal of each snRNP particle prevents pre-mRNA splicing but arrests spliceosome formation at different stages of assembly. Mixing extracts depleted for different snRNP particles restores formation of functional splicing complexes. Specific binding of factors to the 3' splice site region is still detected in snRNP-depleted extracts. Depletion of U1 snRNP impairs stable binding of U2 snRNP to the pre-mRNA branch site. This role of U1 snRNP in promoting stable preslicing complex formation is independent of the U1 snRNA-5' splice site interaction.     

Reassembly and protection of small nuclear ribonucleoprotein particles by heat shock proteins in yeast cells

The process of mRNA splicing is sensitive to in vivo thermal inactivation, but can be protected by pretreatment of cells under conditions that induce heat-shock proteins (Hsps). This latter phenomenon is known as "splicing thermotolerance". In this article we demonstrate that the small nuclear ribonucleoprotein particles (snRNPs) are in vivo targets of thermal damage within the splicing apparatus in heat-shocked yeast cells. Following a heat shock, levels of the tri-snRNP (U4/U6.U5), free U6 snRNP, and a pre-U6 snRNP complex are dramatically reduced. In addition, we observe multiple alterations in U1, U2, U5, and U4/U6 snRNP profiles and the accumulation of precursor forms of U4- and U6-containing snRNPs. Reassembly of snRNPs following a heat shock is correlated with the recovery of mRNA splicing and requires both Hsp104 and the Ssa Hsp70 family of proteins. Furthermore, we correlate splicing thermotolerance with the protection of a subset of snRNPs by Ssa proteins but not Hsp104, and show that Hsp70 directly associates with U4- and U6-containing snRNPs in splicing thermotolerant cells. In addition, our results show that Hsp70 plays a role in snRNP assembly under normal physiological conditions.     

U2 snRNA-protein contacts in purified human 17S U2 snRNPs and in spliceosomal A and B complexes

The 17S U2 snRNP plays an essential role in branch point selection and catalysis during pre-mRNA splicing. Much remains to be learned about the molecular architecture of the U2 snRNP, including which proteins contact the functionally important 5' end of the U2 snRNA. Here, RNA-protein interactions within immunoaffinity-purified human 17S U2 snRNPs were analyzed by lead(II)-induced RNA cleavage and UV cross-linking. Contacts between the U2 snRNA and SF3a60, SF3b49, SF3b14a/p14 and SmG and SmB were detected. SF3b49 appears to make multiple contacts, interacting with the 5' end of U2 and nucleotides in loops I and IIb. SF3a60 also contacted different regions of the U2 snRNA, including the base of stem-loop I and a bulge in stem-loop III. Consistent with it contacting the pre-mRNA branch point adenosine, SF3b14a/p14 interacted with the U2 snRNA near the region that base pairs with the branch point sequence. A comparison of U2 cross-linking patterns obtained with 17S U2 snRNP versus purified spliceosomal A and B complexes revealed that RNA-protein interactions with stem-loop I and the branch site-interacting region of U2 are dynamic. These studies provide important insights into the molecular architecture of 17S U2 snRNPs and reveal U2 snRNP remodeling events during spliceosome assembly.     

Interactions between small nuclear ribonucleoprotein particles in formation of spliceosomes

Electrophoretic separation of ribonucleoprotein particles in a nondenaturing gel was used to analyze the splicing of mRNA precursors. Early in the reaction, a complex formed consisting of the U2 small nuclear ribonucleoprotein particle (snRNP) bound to sequences upstream of the 3' splice site. This complex is modeled as a precursor of a larger complex, the spliceosome, which contains U2, U4/6, and U5 snRNPs. Conversion of the U2 snRNP-precursor RNA complex to the spliceosome probably involves binding of a single multi-snRNP particle containing U4/6 and U5 snRNPs. The excised intron was released in a complex containing U5, U6, and probably U2 snRNPs. Surprisingly, U4 snRNP was not part of the intron-containing complex, suggesting that U4/6 snRNP disassembles and assembles during splicing. Subsequently, the reassembled U4/6 snRNP would associate with U5 snRNP and participate in de novo spliceosome formation. U1 snRNP was not detected in any of the splicing complexes.     

The human 18S U11/U12 snRNP contains a set of novel proteins not found in the U2-dependent spliceosome

U11 and U12 snRNPs bind U12-type pre-mRNAs as a preformed di-snRNP complex, simultaneously recognizing the 5' splice site and branchpoint sequence. Thus, within the U12-type prespliceosome, U11/U12 components form a molecular bridge connecting both ends of the intron. We have affinity purified human 18S U11/U12 and 12S U11 snRNPs, and identified their protein components by using mass spectrometry. U11/U12 snRNPs lack all known U1 snRNP proteins but contain seven novel proteins (i.e., 65K, 59K, 48K, 35K, 31K, 25K, 20K) not found in the major spliceosome, four of which (59K, 48K, 35K, and 25K) are U11-associated. Thus, protein-protein and protein-RNA interactions contributing to 5' splice site recognition and/or intron bridging appear to differ significantly in the minor versus major prespliceosome. The majority of U11/U12 proteins are highly conserved in organisms known to contain U12-type introns. However, homologs of those associated with U11 were not detected in Drosophila melanogaster, consistent with the presence of a divergent U11 snRNP in flies. RNAi experiments revealed that several U11/U12 proteins are essential for cell viability, suggesting they play key roles in U12-type splicing. The presence of unique U11/U12 snRNP proteins in the U12-type spliceosome provides insight into potential evolutionary relationships between the major and minor spliceosome.     

The 5'' end domain of U2 snRNA is required to establish the interaction of U2 snRNP with U2 auxiliary factor(s) during mammalian spliceosome assembly.

Stable association of U2 snRNP with the branchpoint sequence of mammalian pre-mRNAs requires binding of a non-snRNP protein to the polypyrimidine tract. In order to determine how U2 snRNP contacts this protein, we have used an RNA containing the consensus 5' and the (Py)n-AG 3' splice sites but lacking the branchpoint sequence so as to prevent direct U2 snRNA base pairing to the branchpoint. Different approaches including electrophoretic separation of RNP complexes formed in nuclear extracts, RNase T1 protection immunoprecipitation assays with antibodies against snRNPs and UV cross-linking experiments coupled to immunoprecipitations allowed us to demonstrate that at least three splicing factors contact this RNA at 0 degree C without ATP. As expected, U1 snRNP interacts with the region comprising the 5' splice site. A protein of approximately 65,000 molecular weight recognizes the RNA specifically at the 5' boundary of the polypyrimidine tract. It could be either the U2 auxiliary factor (U2AF) (Zamore and Green (1989) PNAS 86, 9243-9247), the polypyrimidine tract binding protein (pPTB) (Garcia-Blanco et al. (1989) Genes and Dev. 3, 1874-1886) or a mixture of both. U2 snRNP also contacts the RNA in a way depending on p65 binding, thereby further arguing that the latter may correspond to the previously characterized U2AF and pPTB. Cleavage of U2 snRNA sequence by a complementary oligonucleotide and RNase H led us to conclude that the 5' terminus of U2 snRNA is required to ensure the contact between U2 snRNP and p65 bound to the RNA. More importantly, this conclusion can be extended to authentic pre-mRNAs. When we have used a human beta-globin pre-mRNA instead of the above artificial substrate, RNA bound p65 became precipitable by anti-(U2) RNP and anti-Sm antibodies except when the 5' end of U2 snRNA was selectively cleaved.     

In vitro reconstitution of mammalian U1 snRNPs active in splicing: the U1-C protein enhances the formation of early (E) spliceosomal complexes.

We have established an in vitro reconstitution/splicing complementation system which has allowed the investigation of the role of mammalian U1 snRNP components both in splicing and at the early stages of spliceosome formation. U1 snRNPs reconstituted from purified, native snRNP proteins and either authentic or in vitro transcribed U1 snRNA restored both early (E) splicing complex formation and splicing-activity to U1-depleted extracts. In vitro reconstituted U1 snRNPs possessing an m3G or ApppG cap were equally active in splicing, demonstrating that a physiological cap structure is not absolutely required for U1 function. However, the presence of an m7GpppG or GpppG cap was deleterious to splicing, most likely due to competition for the m7G cap binding proteins. No significant reduction in splicing or E complex formation was detected with U1 snRNPs reconstituted from U1 snRNA lacking the RNA binding sites of the U1-70K or U1-A protein (i.e., stem-loop I and II, respectively). Complementation studies with purified HeLa U1 snRNPs lacking subsets of the U1-specific proteins demonstrated a role for the U1-C, but not U1-A, protein in the formation and/or stabilization of early splicing complexes. Studies with recombinant U1-C protein mutants indicated that the N-terminal domain of U1-C is necessary and sufficient for the stimulation of E complex formation.