RNA-protein organization of U1, U5 and U4-U6 small nuclear ribonucleoproteins in HeLa cells

Small nuclear ribonucleoproteins (snRNPs) containing U1 and U5 snRNAs from HeLa cells have been fractionated using a combination of isopycnic centrifugation in cesium chloride and ion-exchange chromatography on DEAE-Sepharose. The procedure is based on the extreme stability conferred upon snRNPs by Mg2+ enabling them to withstand the very high ionic strength that prevails in cesium chloride. U1 snRNP prepared by this method contains all nine major proteins (68K, A, B, B', C, D, E, F, G) corresponding to those previously identified by immunoprecipitation and is therefore precipitable by anti-RNP and anti-Sm antibodies. U5 snRNP purified in this way contains the common D to G proteins and is also enriched in a 25 X 10(3) Mr protein that may be U5 snRNP-specific. The core-resistant U5 snRNA sequence (nucleotide 84 to 3' OH) covered by D to G proteins is extended by only six nucleotides. A similar situation is seen in U4-U6 snRNP, which we have obtained in a sufficiently pure form to examine protected sequences. However, the core-resistant sequence of U4 (nucleotide 116 to 3' OH) in U4-U6 snRNP is extended by 37 nucleotides, suggesting that the protein composition of this particle could be more complex than that of U5 snRNP. The ribonucleoprotein organization of snRNPs is summarized and discussed in view of our current knowledge on snRNA sequences protected by proteins.     

Molecular comparison of monocot and dicot U1 and U2 snRNAs

To elucidate differences between the pre-mRNA splicing components in monocots and dicots, we have cloned and characterized several U1 and U2 snRNA sequence variants expressed in wheat seedling nuclei. Primer extension sequencing on wheat and pea snRNA populations has demonstrated that two 5'-terminal nucleotides found in most other U1 snRNAs are missing/modified in many plant U1 snRNAs. Comparison of the wheat U1 and U2 snRNA variants with their counterparts expressed in pea nuclei has defined regions of structural divergence between monocot and dicot U1 and U2 snRNAs. The U1 and U2 snRNA sequences involved in RNA:RNA interaction with pre-mRNAs are absolutely conserved. Significant differences occur between wheat and pea U1 snRNAs in stem I and II structures implicated in the binding of U1-specific proteins suggesting that the monocot and dicot U1-specific snRNP proteins differ in their binding specificities. Stem III structures, which are required in mammalian systems for splicing complex formation but not for U1-specific protein binding, differ more extensively than stems I, II, or IV. In U2 snRNAs, the sequence differences between these two species are primarily localized in stem III and in stem IV which has been implicated in snRNP protein binding. These differences suggest that monocot and dicot U1 and U2 snRNPs represent distinct entities that may have monocot- and dicot-specific snRNP protein variants associated with each snRNA.     

Interaction of snRNAs with rapidly sedimenting nuclear sub-structures (hnRNPs) from HeLa cells.

We have shown previously (Liautard et al., 1982, J. Mol. Biol., 162, 623-643) that digestion with micrococcal nuclease under drastic conditions of a pure U1 snRNP, as well as a mixture containing U2, U1, U4, U5 and U6 snRNPs, gives rise to resistant RNA fragments derived from all but U6 snRNAs. As an attempt to elucidate the way in which snRNPs are attached to their native structure, the same approach was applied to hnRNP which are known to contain snRNP (Guimont-Ducamp et al., 1977, Biochimie, 59, 755-758). Micrococcal nuclease digestion of hnRNPs yielded a population of 15-50 nucleotides long resistant fragments of snRNAs. Sequence analyses showed that all fragments previously identified in core snRNPs were also present. Only U2 and U5 snRNAs were further protected as a result of their association with the hnRNP complex (from the cap to nucleotide 32 for U2 and from nucleotide 22 to nucleotide 70 for U5). No additional protected fragment derived from U1, U4 and U6 snRNAs was found. This finding confirms that the 5' terminal region of U1 snRNP remains available for base-pairing interaction with the premessenger RNA, as predicted by the model of Lerner et al. (Nature, 1980, 283, 220-224).     

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.     

U1-U2 snRNPs interaction induced by an RNA complementary to the 5'' end sequence of U1 snRNA.

Several lines of evidences indicate that U1 and U2 snRNPs become interacting during pre-mRNA splicing. Here we present data showing that an U1-U2 snRNPs interaction can be mediated by an RNA only containing the consensus 5' splice site of all of the sequences characteristic of pre-mRNAs. Using monospecific antibodies (anti-(U1) RNP and anti-(U2) RNP), we have found that a tripartite complex comprising U1 and U2 snRNPs is immunoprecipitated in the presence of a consensus 5' splice site containing RNA, either from a crude extract or from an artificial mixture enriched in U1 and U2 snRNPs. This complex does not appear in the presence of an RNA lacking the sequence complementary to the 5' terminus of U1 snRNA. Moreover, RNAse T1 protection coupled to immunoprecipitation experiments have demonstrated that only the 5' end sequence of U1 snRNA contacts the consensus 5' splice site containing RNA, arguing that U2 snRNP binding in the tripartite complex is mediated by U1 snRNP.     

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.     

Monospecific antibodies reveal details of U2 snRNP structure and interaction between U1 and U2 snRNPs.

Monospecific antibodies directed against several U small nuclear ribonucleoprotein (U snRNP) particle proteins were affinity purified from a patient's anti-(U1,U2)RNP serum. These were used to demonstrate that: (i) proteins equivalent to the mammalian U2 snRNP-specific A' and B" proteins are present in Xenopus laevis oocytes; (ii) both proteins A' and B" have the same structural requirements for binding to U2 snRNA; (iii) proteins B, B' and D have the same structural requirement for binding to U2 snRNA; (iv) using very high specific activity RNA probes it is possible to detect a fraction of either U1 or U2 snRNA precipitable by antibodies directed against proteins specific for the other U snRNP, indicating an interaction between U1 and U2 snRNPs. The structural requirements of this interaction were studied for the U2 snRNP. All changes made to U2 snRNA or snRNP structure resulted in loss of the interaction with U1 snRNP.     

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.     

5'-terminal caps of snRNAs are accessible for reaction with 2,2,7-trimethylguanosine-specific antibody in intact snRNPs

Immune precipitation assays with antibodies specific for 2,2,7-trimethylguanosine (m2,2,7(3)G) have been used to study the accessibility of the 5'-terminal m2,2,7(3)G-containing caps of eucaryotic small nuclear RNAs (snRNAs) either as naked RNAs or in intact small nuclear ribonucleoprotein (snRNPs). The antibody selectively precipitates snRNA species U1a, U1b, U2, U4, and U5 from total deproteinized RNA isolated from Ehrlich ascites cells. Binding by the antibody occurs via the m2,2,7(3)G moiety of the snRNAs' caps, since complex formation with the antibody can be completely abolished by excess nucleoside m2,2,7(3)G. The specificity of the antibody is further demonstrated by the complete absence of reaction with deproteinized snRNA species U6, the 5' terminus of which does not contain m2,2,7(3)G. Most importantly, the cap structures of the snRNAs U1a, U1b, U2, U4, and U5 are also accessible for anti-m2,2,7(3)G IgGs when intact snRNPs are reacted with the antibody. In this case, snRNP species U6 is coprecipitated, suggesting that there are intermolecular interactions between this and other snRNPs. Our data demonstrate that the 5'-terminal regions of the above snRNAs are not protected by the snRNP proteins. This finding is of special interest for snRNP species U1, and is discussed in terms of a model which proposes that the 5'-terminal region of U1 participates in the proper alignment of splice junctions in eucaryotic pre-mRNAs (Lerner, M. R., Boyle, J.A., Mount, S.M., Wolin, S.L., and Steitz, J. A. (1980) Nature (Lond.) 283, 220-224).     

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.     

Direct binding of small nuclear ribonucleoprotein G to the Sm site of small nuclear RNA. Ultraviolet light cross-linking of protein G to the AAU stretch within the Sm site (AAUUUGUGG) of U1 small nuclear ribonucleoprotein reconstituted in vitro.

The major small nuclear ribonucleoproteins (snRNPs) U1, U2, U5 and U4/U6 participate in the splicing of pre-mRNA. U1, U2, U4 and U5 RNAs share a highly conserved sequence motif PuA(U)nGPu, termed the Sm site, which is normally flanked by two hairpin loops. The Sm site provides the major binding site for the group of common proteins, B', B, D1, D2, D3, E, F and G, which are shared by the spliceosomal snRNPs. We have investigated the ability of common snRNP proteins to recognize the Sm site of snRNA by using ultraviolet light-induced RNA-protein cross-linking within U1 snRNP particles. The U1 snRNP particles, reconstituted in vitro, contained U1 snRNA labelled with 32P. Cross-linking of protein to this U1 snRNA occurred only in the presence of the single-stranded stretch of snRNA that makes up the conserved Sm site. Characterization of the cross-linked protein by one and two-dimensional gel electrophoresis indicated that snRNP protein G had become cross-linked to the U1 snRNA. This was confirmed by specific immunoprecipitation of the cross-linked RNA-protein complex with an anti-G antiserum. The cross-link was located on the U1 snRNA by fingerprint analysis with RNases T1 and A; this demonstrated that the protein G has been cross-linked to the AAU stretch within the 5'-terminal half of the Sm site (AAUUUGUGG). These results suggest that the snRNP protein G may be involved in the direct recognition of the Sm site.     

Modified nucleotides at the 5' end of human U2 snRNA are required for spliceosomal E-complex formation

U2 snRNA, a key player in nuclear pre-mRNA splicing, contains a 5'-terminal m3G cap and many internal modifications. The latter were shown in vertebrates to be generally required for U2 function in splicing, but precisely which residues are essential and their role in snRNP and/or spliceosome assembly is presently not clear. Here, we investigated the roles of individual modified nucleotides of HeLa U2 snRNA in pre-mRNA splicing, using a two-step in vitro reconstitution/complementation assay. We show that the three pseudouridines and five 2'O-methyl groups within the first 20 nucleotides of U2 snRNA, but not the m3G cap, are required for efficient pre-mRNA splicing. Individual pseudouridines were not essential, but had cumulative effects on U2 function. In contrast, four of five 2'O-methylations (at positions 1, 2, 12, and 19) were individually required for splicing. The in vitro assembly of 17S U2 snRNPs was not dependent on the presence of modified U2 residues. However, individual internal modifications were required for the formation of the ATP-independent early spliceosomal E complex. Our data strongly suggest that modifications within the first 20 nucleotides of U2 play an important role in facilitating the interaction of U2 with U1 snRNP and/or other factors within the E complex.     

U2 small nuclear RNA is a substrate for the CCA-adding enzyme (tRNA nucleotidyltransferase).

The CCA-adding enzyme builds and repairs the 3' terminus of tRNA. Approximately 65% of mature human U2 small nuclear RNA (snRNA) ends in 3'-terminal CCA, as do all mature tRNAs; the other 35% ends in 3' CC or possibly 3' C. The 3'-terminal A of U2 snRNA cannot be encoded because the 3' end of the U2 snRNA coding region is CC/CC, where the slash indicates the last encoded nucleotide. The first detectable U2 snRNA precursor contains 10-16 extra 3' nucleotides that are removed by one or more 3' exonucleases. Thus, if 3' exonuclease activity removes the encoded 3' CC during U2 snRNA maturation, as appears to be the case in vitro, the cell may need to build or rebuild the 3'-terminal A, CA, or CCA of U2 snRNA. We asked whether homologous and heterologous class I and class II CCA-adding enzymes could add 3'-terminal A, CA, or CCA to human U2 snRNA lacking 3'-terminal A, CA, or CCA. The naked U2 snRNAs were good substrates for the human CCA-adding enzyme but were inactive with the Escherichia coli enzyme; activity was also observed on native U2 snRNPs. We suggest that the 3' stem/loop of U2 snRNA resembles a tRNA minihelix, the smallest efficient substrate for class I and II CCA-adding enzymes, and that CCA addition to U2 snRNA may take place in vivo after snRNP assembly has begun.     

Purification of snRNPs U1, U2, U4, U5 and U6 with 2,2,7-trimethylguanosine-specific antibody and definition of their constituent proteins reacting with anti-Sm and anti-(U1)RNP antisera

Small nuclear ribonucleoprotein particles (snRNPs) of the U-snRNP class from Ehrlich ascites tumor cells were purified in a one-step procedure by affinity chromatography with antibodies specific for 2,2,7-trimethylguanosine (m23.2.7G), which is part of the 5'-terminal cap structure of snRNAs U1-U5. Antibody-bound snRNPs are desorbed from the affinity column by elution with excess nucleoside m23.2.7G; this guarantees maintenance of their native structure. The snRNPs U1, U2, U4, U5 and U6 can be recovered quantitatively from nuclear extracts by this procedure. Co-isolation of U6 snRNP must be due to interactions between this and other snRNPs, as anti-m23.2.7G antibodies do not react with deproteinized U6 snRNA. We have so far defined nine proteins of approximate mol. wts. 10 000, 12 000, 13 000, 16 000, 21 000, 28 000, 32 000, 34 000 and 75 000. Purified snRNPs react with anti-(U1)RNP and with anti-Sm antisera from patients with mixed connective tissue disease and from MRL/l mice. As determined by the protein blotting technique, six of the snRNP polypeptides, characterized by apparent mol. wts. 13 000, 16 000, 21 000, 28 000, 34 000 and 75 000, bear antigenic determinants for one or the other of the above autoantibody classes. This suggests strongly that the U-snRNPs produced by the procedure described here are indeed representative of the snRNPs in the cell. With highly purified snRNPs available, investigation of possible enzymic functions of the particles may now be undertaken.     

A new U6 small nuclear ribonucleoprotein-specific protein conserved between cis- and trans-splicing systems.

Spliceosomal U6 small nuclear RNA (snRNA) plays a central role in the pre-mRNA splicing mechanism and is highly conserved throughout evolution. Previously, a sequence element essential for both capping and cytoplasmic-nuclear transport of U6 snRNA was mapped in the 5'-terminal domain of U6 snRNA. We have identified a protein in cytoplasmic extracts of mammalian and Trypanosoma brucei cells that binds specifically to this U6 snRNA element. Competition studies with mutant and heterologous RNAs demonstrated the conserved binding specificity of the mammalian and trypanosomal proteins. The in vitro capping analysis of mutant U6 snRNAs indicated that protein binding is required but not sufficient for capping of U6 snRNA by a gamma-monomethyl phosphate. Through RNA affinity purification of mammalian small nuclear ribonucleoproteins (snRNPs), we detected this protein also in nuclear extract as a new specific component of the U6 snRNP but surprisingly not of the U4/U6 or the U4/U5/U6 multi-snRNP. These results suggest that the U6-specific protein is involved in U6 snRNA maturation and transport and may therefore be functionally related to the Sm proteins of the other spliceosomal snRNPs.     

Primary and secondary structure of U2 snRNA

With the improved rapid sequencing techniques, the earlier sequence of U2 RNA of Novikoff hepatoma (Shibata et al, J. Biol. Chem. 250, 3909-3920, 1975) was reanalyzed and modified. The improved sequence of U2 RNA is 188 (or 189) nucleotides long and is in register with a characterized U2 RNA pseudogene (Denison et al, PNAS 78, 810-814, 1981) except for an 11 nucleotide sequence (nucleotides 147-157) which is absent from the pseudogene. From these results, a secondary structure of U2 RNA is proposed which is supported by the preferred cleavage sites with T1-RNase, RNase A and S1 nuclease. Isolated U2 RNA was cleaved by T1-RNase preferentially at positions 64 and 164, whereas U2 RNA in U2-snRNP was cleaved only at position 64, indicating that position 164 is protected in U2-snRNP. As with U1 RNA (Epstein et al, PNAS 78, 1562-1566, 1981) the 5'-end of isolated U2 RNA was not preferentially cleaved by T1-RNase.     

Antisense probing of the human U4/U6 snRNP with biotinylated 2'-OMe RNA oligonucleotides

We have used antisense 2'-OMe RNA oligonucleotides carrying four 5'-terminal biotin residues to probe the structure and function of the human U4/U6 snRNP. Nine oligonucleotides, complementary to multiple regions of U4 and U6 snRNAs, bound stably and specifically to U4/U6 snRNP. This allowed for efficient and selective removal of U4/U6 from HeLa cell nuclear extracts. Binding of oligonucleotides to certain snRNA domains inhibited splicing and affected the U4-U6 interaction. Pre-mRNA and splicing products could also be affinity-selected through binding of the oligonucleotides to U4/U6 snRNPs in splicing complexes. The results suggest that U4 snRNP is not released during spliceosome assembly.     

RNA structure and RNA-protein interactions in purified yeast U6 snRNPs

The U6 small nuclear RNA (snRNA) undergoes major conformational changes during the assembly of the spliceosome and catalysis of splicing. It associates with the specific protein Prp24p, and a set of seven LSm2p-8p proteins, to form the U6 small nuclear ribonucleoprotein (snRNP). These proteins have been proposed to act as RNA chaperones that stimulate pairing of U6 with U4 snRNA to form the intermolecular stem I and stem II of the U4/U6 duplex, whose formation is essential for spliceosomal function. However, the mechanism whereby Prp24p and the LSm complex facilitate U4/U6 base-pairing, as well as the exact binding site(s) of Prp24p in the native U6 snRNP, are not well understood. Here, we have investigated the secondary structure of the U6 snRNA in purified U6 snRNPs and compared it with its naked form. Using RNA structure-probing techniques, we demonstrate that within the U6 snRNP a large internal region of the U6 snRNA is unpaired and protected from chemical modification by bound Prp24p. Several of these U6 nucleotides are available for base-pairing interaction, as only their sugar backbone is contacted by Prp24p. Thus, Prp24p can present them to the U4 snRNA and facilitate formation of U4/U6 stem I. We show that the 3' stem-loop is not bound strongly by U6 proteins in native particles. However, when compared to the 3' stem-loop in the naked U6 snRNA, it has a more open conformation, which would facilitate formation of stem II with the U4 snRNA. Our data suggest that the combined association of Prp24p and the LSm complex confers upon U6 nucleotides a conformation favourable for U4/U6 base-pairing. Interestingly, we find that the open structure of the yeast U6 snRNA in native snRNPs can also be adopted by human U6 and U6atac snRNAs.     

U5 small nuclear ribonucleoprotein: RNA structure analysis and ATP-dependent interaction with U4/U6.

To understand how the U5 small nuclear ribonucleoprotein (snRNP) interacts with other spliceosome components, its structure and binding to the U4/U6 snRNP were analyzed. The interaction of the U5 snRNP with the U4/U6 snRNP was studied by separating the snRNPs in HeLa cell nuclear extracts on glycerol gradients. A complex running at 25S and containing U4, U5, and U6 but not U1 or U2 snRNAs was identified. In contrast to results with native gel electrophoresis to separate snRNPs, this U4/U5/U6 snRNP complex requires ATP to assemble from the individual snRNPs. The structure of the U5 RNA within the U5 snRNP and the U4/5/6 snRNP complexes was then compared. Oligonucleotide-targeted RNase H digestion identified one RNA sequence in the U5 snRNP capable of base pairing to other nucleic acid sequences. Chemical modification experiments identified this sequence as well as two other U5 RNA sequences as accessible to modification within the U5 RNP. One of these regions is a large loop in the U5 RNA secondary structure whose sequence is conserved from Saccharomyces cerevisiae to humans. Interestingly, no differences in modification of free U5 snRNP as compared to U5 in the U4/U5/U6 snRNP complex were observed, suggesting that recognition of specific RNA sequences in the U5 snRNP is not required for U4/U5/U6 snRNP assembly.