In vivo structural analysis of spliced leader RNAs in Trypanosoma brucei and Leptomonas collosoma: a flexible structure that is independent of cap4 methylations.

The formation of the mRNA 5' end in trypanosomatid protozoa is carried out by trans-splicing, which transfers a spliced leader (SL) sequence and its hypermethylated cap (cap4) from the SL RNA to the pre-mRNA. Previous in vitro studies with synthetic uncapped RNAs have shown that the SL sequence of Leptomonas collosoma can assume two alternate conformations, Form 1 and Form 2, with Form 1 being the dominant one. To gain information about the structure of the SL RNA in vivo, in its protein-rich environment, we have used permeable Trypanosoma brucei and L. collosoma cells for chemical modification experiments. We introduce the use in vivo of the water-soluble reagents CMCT and kethoxal. In contrast to the in vitro results, the Form 2 secondary structure predominates. However, there are chemically accessible regions that suggest conformational flexibility in SL RNPs and a chemically inaccessible region suggestive of protection by protein or involvement in tertiary interactions. Using complementary 2'-O-methyl RNA oligonucleotides, we show that T. brucei SL RNA can be induced to switch conformation in vivo. SL RNA stripped of proteins and probed in vitro does not display the same Form 2 bias, indicating that SL RNA structure is determined, at least in part, by its RNP context. Finally, the methyl groups of the cap4 do not seem to affect the secondary structure of T. brucei SL RNA, as shown by chemical modification of undermethylated SL RNA probed in vivo.     

Spectrin deficient inherited hemolytic anemias in the mouse: Characterization by spectrin synthesis and mRNA activity in reticulocytes

The 35 nucleotide spliced leader (SL) sequence is found on the 5' end of numerous trypanosome mRNAs, yet the tandemly organized reiteration units encoding this leader are not detectably linked to any of these structural genes. Here we report the presence of a class of discrete small SL RNA molecules that are derived from the genomic SL reiteration units of Trypanosoma brucei, Trypanosoma cruzi, and Leptomonas collosoma. These small SL RNAs are 135, 105, and 95 nucleotides, respectively, and contain a 5'-terminal SL or SL-like sequence. S1 nuclease analyses demonstrate that these small SL RNAs are transcribed from continuous sequence within the respective SL reiteration units. With the exception of the SL sequence and a concensus donor splice site immediately following it, these small RNAs are not well conserved. We suggest that the small SL RNAs may function as a donor of the SL sequence in an intermolecular process that places the SL at the 5' terminus of many trypanosomatid mRNAs.     

Spliced leader RNA of trypanosomes: in vivo mutational analysis reveals extensive and distinct requirements for trans splicing and cap4 formation.

In trypanosomes mRNAs are generated through trans splicing. The spliced leader (SL) RNA, which donates the 5'-terminal mini-exon to each of the protein coding exons, plays a central role in the trans splicing process. We have established in vivo assays to study in detail trans splicing, cap4 modification, and RNP assembly of the SL RNA in the trypanosomatid species Leptomonas seymouri. First, we found that extensive sequences within the mini-exon are required for SL RNA function in vivo, although a conserved length of 39 nt is not essential. In contrast, the intron sequence appears to be surprisingly tolerant to mutation; only the stem-loop II structure is indispensable. The asymmetry of the sequence requirements in the stem I region suggests that this domain may exist in different functional conformations. Second, distinct mini-exon sequences outside the modification site are important for efficient cap4 formation. Third, all SL RNA mutations tested allowed core RNP assembly, suggesting flexible requirements for core protein binding. In sum, the results of our mutational analysis provide evidence for a discrete domain structure of the SL RNA and help to explain the strong phylogenetic conservation of the mini-exon sequence and of the overall SL RNA secondary structure; they also suggest that there may be certain differences between trans splicing in nematodes and trypanosomes. This approach provides a basis for studying RNA-RNA interactions in the trans spliceosome.     

A protein related to the vaccinia virus cap-specific methyltransferase VP39 is involved in cap 4 modification in Trypanosoma brucei

The spliced-leader (SL) RNA plays a key role in the biogenesis of mRNA in trypanosomes by providing the m(7)G-capped SL sequence to the 5' end of every mRNA. The cap structure of the SL RNA is unique in eukaryotes with 4 nucleotides after the cap carrying a total of seven methyl groups and by convention is referred to as "cap 4". Although the enzymatic machinery for cap addition has been characterized in several organisms, including Trypanosoma brucei, the identification of methyltransferases dedicated to the generation of higher order cap structures has lagged behind, except in viruses. Here we describe T. brucei MT57 (TbMT57), a primarily nuclear polypeptide with structural and functional similarities to vaccinia virus VP39, a bifunctional protein acting at the mRNA 5' end as a cap-specific 2'-O-methyltransferase. Down-regulation by RNAi or genetic ablation of TbMT57 resulted in the accumulation of SL RNA missing 2'-O-methyl groups at positions +3 and +4 and thus bearing a cap 2 rather than a cap 4. Furthermore, competitive binding studies indicated that modifications at the +3 and +4 positions are important for binding to the nuclear cap-binding complex. Genetic ablation of MT57 resulted in viable cells with no apparent defect in SL RNA trans-splicing, suggesting that MT57 is not essential or that trypanosomes have developed alternate mechanisms to counteract the absence of this protein. Interestingly, MT57 homologs are only found in trypanosomatid protozoa that have a cap 4 structure and in poxviruses, of which vaccinia virus is a prototype.     

Structure-function analysis of the trypanosomatid spliced leader RNA.

In trypanosomes, all mRNAs possess a spliced leader (SL) at their 5' end. SL is added to pre-mRNA via trans -splicing from a small RNA, the SL RNA. To examine structure-function aspects of the trypanosomatid SL RNA, an in vivo system was developed in the monogenetic trypanosomatid Leptomonas collosoma to analyze the function of chimeric and site-directed SL RNA mutants in trans -splicing. Stable cell lines expressing chimeric and mutated SL RNA from the authentic SL RNA regulatory unit were obtained. The chimeric RNA was expressed and assembled into an SL RNP particle, but could not serve as a substrate in splicing. Mutations in loop II and III of L.collosoma SL RNA formed the Y structure intermediate. In addition, a double SL RNA mutant in loop II, and positions 7 and 8 of the intron, also formed the Y structure intermediate, suggesting that these intron positions, although proposed to participate in the interaction of SL RNA with U5, may not be crucial for the first step of the trans -splicing reaction. A mutation in the exon located in loop I was not utilized in splicing, suggesting the importance of exon sequences for trans -splicing in trypanosomes. However, a double SL RNA mutant in loop II and exon position 31 was utilized in both steps of splicing; the mutant thus provides a model molecule for further analysis of positions essential for the function of the SL RNA.     

Novel and essential subunits in the 300-kilodalton nuclear cap binding complex of Trypanosoma brucei

One of the unique aspects of RNA processing in trypanosomatid protozoa is the presence of a cap 4 structure (m7Gpppm2(6)AmpAmpCmpm3Um) at the 5' end of all mRNAs. The cap 4 becomes part of the mRNA through trans-splicing of a 39-nucleotide-long sequence donated by the spliced leader RNA. Although the cap 4 modifications are required for trans-splicing to occur, the underlying mechanism remains to be determined. We now describe an unconventional nuclear cap binding complex (CBC) in Trypanosoma brucei with an apparent molecular mass of 300 kDa and consisting of five protein components: the known CBC subunits CBP20 and importin-alpha and three novel proteins that are only present in organisms featuring a cap 4 structure and trans-splicing. Competitive binding studies are consistent with a specific interaction between the CBC and the cap 4 structure. Downregulation of several individual components of the T. brucei CBC by RNA interference demonstrated an essential function at an early step in trans-splicing. Thus, our studies are consistent with the CBC providing a mechanistic link between cap 4 modifications and trans-splicing.     

Elucidating the role of H/ACA-like RNAs in trans-splicing and rRNA processing via RNA interference silencing of the Trypanosoma brucei CBF5 pseudouridine synthase

Most pseudouridinylation in eukaryotic rRNA and small nuclear RNAs is guided by H/ACA small nucleolar RNAs. In this study, the Trypanosoma brucei pseudouridine synthase, Cbf5p, a snoRNP protein, was identified and silenced by RNAi. Depletion of this protein destabilized all small nucleolar RNAs of the H/ACA-like family. Following silencing, defects in rRNA processing, such as accumulation of precursors and inhibition of cleavages to generate the mature rRNA, were observed. snR30, an H/ACA RNA involved in rRNA maturation, was identified based on prototypical conserved domains characteristic of this RNA in other eukaryotes. The silencing of CBF5 also eliminated the spliced leader-associated (SLA1) RNA that directs pseudouridylation on the spliced leader RNA (SL RNA), which is the substrate for the trans-splicing reaction. Surprisingly, the depletion of Cbf5p not only eliminated the pseudouridine on the SL RNA but also abolished capping at the fourth cap-4 nucleotide. As a result of defects in the SL RNA and decreased modification on the U small nuclear RNA, trans-splicing was inhibited at the first step of the reaction, providing evidence for the essential role of H/ACA RNAs and the modifications they guide on trans-splicing.     

The spliced leader-associated RNA is a trypanosome-specific sn(o) RNA that has the potential to guide pseudouridine formation on the SL RNA

The spliced leader-associated (SLA1) RNA is a trypanosome-specific small RNA with unknown function. SLA1 carries a Sm-like site, and is associated with core Sm proteins. Here we found that SLA1 belongs to a family of hairpin-containing RNAs that are implicated in directing pseudouridylation. A potential for base-pair interaction between SLA1 and spliced leader (SL) RNA agrees with the canonical rules for guiding pseudouridylation on SL RNA. Direct RNA analysis showed that this uridine is indeed pseudouridylated in the SL RNA of Leptomonas collosoma, Leishmania major, and Trypanosoma brucei. This position is conserved in all trypanosomatid SL RNAs. Mutations introduced in the SL RNA to disrupt the interaction domain of SLA1/SL RNA abolished the formation of the pseudouridine. SLA1 is localized both to the nucleolus and nucleoplasm. This study solves a long-standing question regarding the function of this novel RNA and describes the first H/ACA RNA, which, unlike all other pseudouridine guides, is also a bona fide snRNA.     

Intramolecular base pairing between the nematode spliced leader and its 5'' splice site is not essential for trans-splicing in vitro.

The spliced leader RNAs of both trypanosomes and nematodes can form similar secondary structures where the trans-splice donor site is involved in intramolecular base pairing with the spliced leader sequence. It has been proposed that this base pairing could serve to activate autonomously the SL RNA splice donor site. Here, we have examined exon requirements for trans-splicing in a nematode cell free system. Complete disruption of secondary structure interactions at and around the trans-splice donor site did not affect the ability of the SL RNA to function in trans-splicing. In addition, the highly conserved 22 nt sequence could be productively replaced by artificial exons ranging in size from 2 to 246 nucleotides. These results reinforce the view that the 'intron' portion of the SL RNA functions as an independent Sm snRNP whose role is to deliver exon sequences to the trans-spliceosome.     

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.     

The role of intron structures in trans-splicing and cap 4 formation for the Leishmania spliced leader RNA.

A 39-nucleotide leader is trans-spliced onto all trypanosome nuclear mRNAs. The precursor spliced leader RNA was tested for trans-splicing function in vivo by mutating the intron. We report that in Leishmania tarentolae spliced leader RNA 5' modification is influenced by the primary sequence of stem-loop II, the Sm-binding site, and the secondary structure of stem-loop III. The sequence of stem-loop II was found to be important for cap 4 formation and splicing. As in Ascaris, mutagenesis of the bulge nucleotide in stem-loop II was detrimental to trans-splicing. Because restoration of the L. tarentolae stem-loop II structure was not sufficient to restore splicing, this result contrasts the findings in the kinetoplastid Leptomonas, where mutations that restored stem-loop II structure supported splicing. Methylation of the cap 4 structure and splicing was also dependent on both the Sm-binding site and the structure of stem-loop III and was inhibited by incomplete 3' end processing. The critical nature of the L. tarentolae Sm-binding site is consistent with its essential role in the Ascaris spliced leader RNA, whereas in Leptomonas mutation of the Sm-binding site and deletion of stem-loop III did not affect trans-splicing. A pathway for Leishmania spliced leader RNA processing and maturation is proposed.     

Mass spectrometry of mRNA cap 4 from trypanosomatids reveals two novel nucleosides.

Synthesis of mRNA in kinetoplastid protozoa involves the process of trans-splicing, in which an identical 39-41-nucleotide (depending on the species) mini-exon is placed at the 5' end of mature mRNAs. The mini-exon sequence is highly conserved among all members of the Kinetoplastida, nucleotides 1-6 being identical in the four genera so far examined. Prior to trans-splicing, the mini-exon donor RNA is capped by the addition of a (5'-5') triphosphate-linked 7-methylguanosine, followed by modification of the first four transcribed nucleotides. Partial structures have been previously deduced for this cap 4 moiety from Trypanosoma brucei and Leptomonas collosoma. We have purified enough cap 4 from T. brucei and Crithidia fasciculata to allow definitive structural analysis by combined liquid chromatography/mass spectrometry and gas chromatography/mass spectrometry. The results, together with the known mini-exon sequence, show that cap 4 in both species has the structure m7G(5')ppp(5')m6(2)AmpAmpCmpm3Ump. The presence of N6,N6,2'-O-trimethyladenosine and 3,2'-O-dimethyluridine, nucleosides previously unknown in nature, were confirmed by rigorous comparison with synthetic standards. The conservation of cap 4 between these divergent genera suggests that this structure may be common to most if not all Kinetoplastida.     

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.     

The trypanosomatid signal recognition particle consists of two RNA molecules,a 7SL RNA homologue and a novel tRNA-like molecule

Trypanosomatids are ancient eukaryotic parasites affecting humans and livestock. Here we report that the trypanosomatid signal recognition particle (SRP), unlike all other known SRPs in nature, contains, in addition to the 7SL RNA homologue, a short RNA molecule, termed sRNA-85. Using conventional chromatography, we discovered a small RNA molecule of 85 nucleotides co-migrating with the Leptomonas collosoma 7SL RNA. This RNA molecule was isolated, sequenced, and used to clone the corresponding gene. sRNA-85 was identified as a tRNA-like molecule that deviates from the canonical tRNA structure. The co-existence of these RNAs in a single complex was confirmed by affinity selection using an antisense oligonucleotide to sRNA-85. The two RNA molecules exist in a particle of approximately 14 S that binds transiently to ribosomes. Mutations were introduced in sRNA-85 that disrupted its putative potential to interact with 7SL RNA by base pairing; such mutants were unable to bind to 7SL RNA and to ribosomes and were aberrantly distributed within the cell. We postulate that sRNA-85 may functionally replace the truncated Alu domain of 7SL RNA. The discovery of sRNA-85 raises the intriguing possibility that sRNA-85 functional homologues may exist in other lower eukaryotes and eubacteria that lack the Alu domain.     

Multiple requirements for nematode spliced leader RNP function in trans-splicing.

The 5' exon donor in nematode trans-splicing, the SL RNA, is a small (approximately 100 nt) RNA that resembles cis-spliceosomal U snRNAs. Extensive analyses of the RNA sequence requirements for SL RNA function have revealed four essential elements, the core Sm binding site, three nucleotides immediately downstream of this site, a region of Stem-loop II, and a 5' splice site. Although these elements are necessary and sufficient for SL RNA function in vitro, their respective roles in promoting SL RNA activity have not been elucidated. Furthermore, although it has been shown that assembly of the SL RNA into an Sm RNP is a prerequisite for function, the protein composition of the SL RNP has not been determined. Here, we have used oligoribonucleotide affinity to purify the SL RNP and find that it contains core Sm proteins as well as four specific proteins (175, 40, 30, and 28 kDa). Using in vitro assembly assays; we show that association of the 175- and 30-kDa SL-specific proteins correlates with SL RNP function in trans-splicing. Binding of these proteins depends upon the sequence of the core Sm binding site; SL RNAs containing the U1 snRNA Sm binding site assemble into Sm RNPs that contain core, but not SL-specific proteins. Furthermore, mutational and thiophosphate interference approaches reveal that both the primary nucleotide sequence and a specific phosphate oxygen within a segment of Stemloop II of the SL RNA are required for function. Finally, mutational activation of an unusual cryptic 5' splice site within the SL sequence itself suggests that U5 snRNA may play a primary role in selecting and specifying the 5' splice site in SL addition trans-splicing.