Evidence for the presence of a small U5-like RNA in active trans-spliceosomes of Trypanosoma brucei.

The existence of the Trypanosoma brucei 5' splice site on a small RNA of uniform sequence (the spliced leader or SL RNA) has allowed us to characterize the RNAs with which it interacts in vivo by psoralen crosslinking treatment. Analysis of the most abundant crosslinks formed by the SL RNA allowed us previously to identify the spliced leader-associated (SLA) RNA. The role of this RNA in trans-splicing, as well as the possible existence of an analogous RNA interaction in cis-splicing, is unknown. We show here that the 5' splice site region of the SL RNA is also crosslinked in vivo to a second small RNA. Although it is very small and lacks a 5' trimethylguanosine (TMG) cap, the SLA2RNA possesses counterparts of the conserved U5 snRNA stem-loop 1 and internal loop 1 sequence elements, as well as a potential trypanosome snRNA core protein binding site; these combined features meet the phylogenetic definition of U5 snRNA. Like U5, the SLA2 RNA forms an RNP complex with the U4 and U6 RNAs, and interacts with the 5' splice site region via its putative loop 1 sequence. In a final analogy with U5, the SLA2 RNA is found crosslinked to a molecule identical to the free 5' exon splicing intermediate. These data present a compelling case for the SLA2 RNA not only as an active trans-spliceosomal component, but also for its identification as the trypanosome U5 structural homolog. The presence of a U5-like RNA in this ancient eukaryote establishes the universality of the spliceosomal RNA core components.     

Identification of the major spliceosomal RNAs in Dictyostelium discoideum reveals developmentally regulated U2 variants and polyadenylated snRNAs

Most eukaryotic mRNAs depend upon precise removal of introns by the spliceosome, a complex of RNAs and proteins. Splicing of pre-mRNA is known to take place in Dictyostelium discoideum, and we previously isolated the U2 spliceosomal RNA experimentally. In this study, we identified the remaining major spliceosomal RNAs in Dictyostelium by a bioinformatical approach. Expression was verified from 17 small nuclear RNA (snRNA) genes. All these genes are preceded by a putative noncoding RNA gene promoter. Immunoprecipitation showed that snRNAs U1, U2, U4, and U5, but not U6, carry the conserved trimethylated 5' cap structure. A number of divergent U2 species are expressed in Dictyostelium. These RNAs carry the U2 RNA hallmark sequence and structure motifs but have an additional predicted stem-loop structure at the 5' end. Surprisingly, and in contrast to the other spliceosomal RNAs in this study, the new U2 variants were enriched in the cytoplasm and were developmentally regulated. Furthermore, all of the snRNAs could also be detected as polyadenylated species, and polyadenylated U1 RNA was demonstrated to be located in the cytoplasm.     

Plant small nuclear RNAs. V. U4 RNA is present in broad bean plants in the form of sequence variants and is base-paired with U6 RNA.

U4 RNA, which is known to play an indispensable role in pre-mRNA splicing, is present in plant nuclei, has a canonical m3 2,2,7 G cap at its 5' end and is associated with U6 RNA in snRNP particles. It occurs in broad bean in the form of a number of sequence variants. Two of these were sequenced: U4A RNA is 154 and U4B RNA is 152 nucleotides long. Sequence similarity of broad bean U4B RNA is 94 per cent to broad bean U4A RNA, 65 per cent to rat U4A RNA, 61 per cent to Drosophila U4A RNA and 50 per cent to snR14, the U4 RNA equivalent of the yeast Saccharomyces cerevisiae. Sequence conservation is much more pronounced in the 5' half of the molecule than in its 3' half. The secondary structure of both variants of broad bean U4 RNA perfectly fits with that of all other U4 RNAs sequenced so far. Nucleotide changes between broad bean U4A and U4B RNAs are restricted to molecular regions that affect the thermodynamic stability of these molecules. A model is proposed for the base pairing interaction of broad bean U4 RNA with broad bean U6 RNA. This is the first report on the structure of a plant U4 RNA.     

Isolation and sequence of four small nuclear U RNA genes of Trypanosoma brucei subsp. brucei: identification of the U2, U4, and U6 RNA analogs.

Trypanosomes use trans splicing to place a common 39-nucleotide spliced-leader sequence on the 5' ends of all of their mRNAs. To identify likely participants in this reaction, we used antiserum directed against the characteristic U RNA 2,2,7-trimethylguanosine (TMG) cap to immunoprecipitate six candidate U RNAs from total trypanosome RNA. Genomic Southern analysis using oligonucleotide probes constructed from partial RNA sequence indicated that the four largest RNAs (A through D) are encoded by single-copy genes that are not closely linked to one another. We have cloned and sequenced these genes, mapped the 5' ends of the encoded RNAs, and identified three of the RNAs as the trypanosome U2, U4, and U6 analogs by virtue of their sequences and structural homologies with the corresponding metazoan U RNAs. The fourth RNA, RNA B (144 nucleotides), was not sufficiently similar to known U RNAs to allow us to propose an identify. Surprisingly, none of these U RNAs contained the consensus Sm antigen-binding site, a feature totally conserved among several classes of U RNAs, including U2 and U4. Similarly, the sequence of the U2 RNA region shown to be involved in pre-mRNA branchpoint recognition in yeast, and exactly conserved in metazoan U2 RNAs, was totally divergent in trypanosomes. Like all other U6 RNAs, trypanosome U6 did not contain a TMG cap and was immunoprecipitated from deproteinized RNA by anti-TMG antibody because of its association with the TMG-capped U4 RNA. These two RNAs contained extensive regions of sequence complementarity which phylogenetically support the secondary-structure model proposed by D. A. Brow and C. Guthrie (Nature [London] 334:213-218, 1988) for the organization of the analogous yeast U4-U6 complex.     

Methylphosphate cap structure increases the stability of 7SK, B2 and U6 small RNAs in Xenopus oocytes.

We studied the role of the methylphosphate cap structure in the stability and nucleocytoplasmic transport by microinjecting U6, 7SK and B2 RNAs into the Xenopus oocytes. In every case, the methylphosphate capped RNAs were 3 to 9 times more stable than the uncapped RNAs. When a methylphosphate cap structure was placed on human H1 RNA which is normally not capped, its stability was improved 2-7 fold. These data show that the methylphosphate cap enhances the stability of 7SK, B2, H1 and U6 RNAs. The methylphosphate-capped 7SK RNA was transported into the nucleus from cytoplasm, but remained in the nucleus when injected into the nucleus; in this respect, 7SK RNA exhibited properties previously shown for U6 RNA. Both U6 and 7SK RNAs with ppp on their 5' ends were transported from cytoplasm to the nucleus suggesting that the methylphosphate cap structure is not required for transport of these RNAs across the nuclear membrane.     

A candidate U1 small nuclear RNA for trypanosomatid protozoa.

In trypanosomatid protozoa, all mRNAs obtain identical 5'-ends by trans-splicing of the 5'-terminal 39 nucleotides of a small spliced leader RNA to appropriate acceptor sites in pre-mRNA. Although this process involves spliceosomal small nuclear (sn) RNAs, it is thought that trypanosomatids do not contain a homolog of the cis-spliceosomal U1 snRNA. We show here that a trypanosomatid protozoon, Crithidia fasciculata, contains a novel small RNA that displays several features characteristic of a U1 snRNA, including (i) a methylguanosine cap and additional 5'-terminal modifications, (ii) a potential binding site for common core proteins that are present in other trans-spliceosomal ribonucleoproteins, (iii) a U1-like 5'-terminal sequence, and (iv) a U1-like stem/loop I structure. Because trypanosomatid pre-mRNAs do not appear to contain cis-spliced introns, we argue that this previously unrecognized RNA species is a good candidate to be a trans-spliceosomal U1 snRNA.     

Complete cap 4 formation is not required for viability in Trypanosoma brucei

In kinetoplastids spliced leader (SL) RNA is trans-spliced onto the 5' ends of all nuclear mRNAs, providing a universal exon with a unique cap. Mature SL contains an m(7)G cap, ribose 2'-O methylations on the first four nucleotides, and base methylations on nucleotides 1 and 4 (AACU). This structure is referred to as cap 4. Mutagenized SL RNAs that exhibit reduced cap 4 are trans-spliced, but these mRNAs do not associate with polysomes, suggesting a direct role in translation for cap 4, the primary SL sequence, or both. To separate SL RNA sequence alterations from cap 4 maturation, we have examined two ribose 2'-O-methyltransferases in Trypanosoma brucei. Both enzymes fall into the Rossmann fold class of methyltransferases and model into a conserved structure based on vaccinia virus homolog VP39. Knockdown of the methyltransferases individually or in combination did not affect growth rates and suggests a temporal placement in the cap 4 formation cascade: TbMT417 modifies A(2) and is not required for subsequent steps; TbMT511 methylates C(3), without which U(4) methylations are reduced. Incomplete cap 4 maturation was reflected in substrate SL and mRNA populations. Recombinant methyltransferases bind to a methyl donor and show preference for m(7)G-capped RNAs in vitro. Both enzymes reside in the nucleoplasm. Based on the cap phenotype of substrate SL stranded in the cytosol, A(2), C(3), and U(4) methylations are added after nuclear reimport of Sm protein-complexed substrate SL RNA. As mature cap 4 is dispensable for translation, cap 1 modifications and/or SL sequences are implicated in ribosomal interaction.     

High evolutionary conservation of the secondary structure and of certain nucleotide sequences of U5 RNA.

The nucleotide sequence of chicken, pheasant, duck and Tetrahymena pyriformis U5 RNAs as well as that of new mammalian variant U5 RNAs was determined and compared to that of rat and HeLa cells U5 RNAs. Primary structure conservation is about 95% between rat and human cells, 82% between mammals and birds and 57% between the Protozoan and mammals. The same model of secondary structure, a free single-stranded region flanked by two hairpins can be constructed from all RNAs and is identical to the model previously proposed for mammalian U5 RNA on an experimental basis (1). Thus, this model is confirmed and is likely to be that of an ancestor U5 RNA. The 3' region of the U5 RNA molecule constitutes domain A, and is common to U1, U2, U4 and U5 RNAs (2). The characteristic nucleotide sequences of domain A are highly conserved throughout the phylogenetic evolution of U5 RNA suggesting that they are important elements in the function of the four small RNAs. Another region of high evolutionary conservation is the top part of the 5' side hairpin whose conserved sequence is specific to U5 RNA. It might participate in the particular function of U5 RNA.     

A small nuclear ribonucleoprotein associates with the AAUAAA polyadenylation signal in vitro

RNAs containing the polyadenylation sites for adenovirus L3 or E2a mRNA or for SV40 early or late mRNA are substrates for cleavage and poly(A) addition in an extract of HeLa cell nuclei. When polyadenylation reactions are probed with ribonuclease T1 and antibodies directed against either the Sm protein determinant or the trimethylguanosine cap structure at the 5' end of U RNAs in small nuclear ribonucleoproteins, RNA fragments containing the AAUAAA polyadenylation signal are immunoprecipitated. The RNA cleavage step that occurs prior to poly(A) addition is inhibited by micrococcal nuclease digestion of the nuclear extract. The immunoprecipitation of fragments containing the AAUAAA sequence can be altered, but not always abolished, by pretreatment with micrococcal nuclease. We discuss the involvement of small nuclear ribonucleoproteins in the cleavage and poly(A) addition reactions that form the 3' ends of most eukaryotic mRNAs.     

Synthesis of 5' cap-0 and cap-1 RNAs using solid-phase chemistry coupled with enzymatic methylation by human (guanine-N⁷)-methyl transferase

The 5' end of eukaryotic mRNA carries a N(7)-methylguanosine residue linked by a 5'-5' triphosphate bond. This cap moiety ((7m)GpppN) is an essential RNA structural modification allowing its efficient translation, limiting its degradation by cellular 5' exonucleases and avoiding its recognition as "nonself" by the innate immunity machinery. In vitro synthesis of capped RNA is an important bottleneck for many biological studies. Moreover, the lack of methods allowing the synthesis of large amounts of RNA starting with a specific 5'-end sequence have hampered biological and structural studies of proteins recognizing the cap structure or involved in the capping pathway. Due to the chemical nature of N(7)-methylguanosine, the synthesis of RNAs possessing a cap structure at the 5' end is still a significant challenge. In the present work, we combined a chemical synthesis method and an enzymatic methylation assay in order to produce large amounts of RNA oligonucleotides carrying a cap-0 or cap-1. Short RNAs were synthesized on solid support by the phosphoramidite 2'-O-pivaloyloxymethyl chemistry. The cap structure was then coupled by the addition of GDP after phosphorylation of the terminal 5'-OH and activation by imidazole. After deprotection and release from the support, GpppN-RNAs or GpppN(2'-Om)-RNAs were purified before the N(7)-methyl group was added by enzymatic means using the human (guanine-N(7))-methyl transferase to yield (7m)GpppN-RNAs (cap-0) or (7m)GpppN(2'-Om)-RNAs (cap-1). The RNAs carrying different cap structures (cap, cap-0 or, cap-1) act as bona fide substrates mimicking cellular capped RNAs and can be used for biochemical and structural studies.     

U2 RNA shares a structural domain with U1, U4, and U5 RNAs.

We previously reported common structural features within the 3'-terminal regions of U1, U4, and U5 RNAs. To check whether these features also exist in U2 RNA, the primary and secondary structures of the 3'-terminal regions of chicken, pheasant, and rat U2 RNAs were examined. Whereas no difference was observed between pheasant and chicken, the chicken and rat sequences were only 82.5% homologous. Such divergence allowed us to propose a unique model of secondary structure based on maximum base-pairing and secondary structure conservation. The same model was obtained from the results of limited digestion of U2 RNA with various nucleases. Comparison of this structure with those of U1, U4, and U5 RNAs shows that the four RNAs share a common structure designated as domain A, and consisting of a free single-stranded region with the sequence Pu-A-(U)n-G-Pup flanked by two hairpins. The hairpin on the 3' side is very stable and has the sequence Py-N-Py-Gp in the loop. The presence of this common domain is discussed in connection with relationships among U RNAs and common protein binding sites.     

3' processing of human pre-U2 small nuclear RNA: a base-pairing interaction between the 3' extension of the precursor and an internal region.

The spliceosomal small nuclear RNAs U1, U2, U4, and U5 are transcribed by RNA polymerase II as precursors with extensions at their 3' ends. The 3' processing of these pre-snRNAs is not understood in detail. Two pathways of pre-U2 RNA 3' processing in vitro were revealed in the present investigation by using a series of human wild-type and mutant pre-U2 RNAs. Substrates with wild-type 3' ends were initially shortened by three or four nucleotides (which is the first step in vivo), and the correct mature 3' end was then rapidly generated. In contrast, certain mutant pre-U2 RNAs displayed an aberrant 3' processing pathway typified by the persistence of intermediates representing cleavage at each internucleoside bond in the precursor 3' extension. Comparison of the wild-type and mutant pre-U2 RNAs revealed a potential base-pairing interaction between nucleotides in the precursor 3' extension and a sequence located between the Sm domain and stem-loop III of U2 RNA. Substrate processing competition experiments using a highly purified pre-U2 RNA 3' processing activity suggested that only RNAs capable of this base-pairing interaction had high affinity for the pre-U2 RNA 3' processing enzyme. The importance of this postulated base-pairing interaction between the precursor 3' extension and the internal region between the Sm domain and stem-loop III was confirmed by the results obtained with a compensatory substitution that restores the base pairing, which displayed the normal 3' processing reaction. These results implicate a precursor-specific base-paired structure involving sequences on both sides of the mature cleavage site in the 3' processing of human U2 RNA.