U small nuclear ribonucleoprotein requirements for nematode cis- and trans-splicing in vitro.

In nematodes, a fraction of mRNAs acquires a common 22-nucleotide 5'-terminal spliced leader sequence via a trans-splicing reaction. The same premessenger RNAs which receive the spliced leader are also processed by conventional cis-splicing. Whole cell extracts prepared from synchronous embryos of the parasitic nematode Ascaris lumbricoides catalyze both cis- and trans-splicing. We have used this cell-free system and oligodeoxynucleotide directed RNase H digestion to assess the U small nuclear RNA requirements for nematode cis- and trans-splicing. These experiments indicated that both cis- and trans-splicing require intact U2 and U4/U6 small nuclear ribonucleoproteins (snRNPs). However, whereas cis-splicing displays the expected requirement for an intact U1 snRNP, trans-splicing is unaffected when approximately 90% of U1 snRNP is degraded. These results suggest that 5' splice site identification differs in nematode cis- and trans-splicing.     

A new twist in trypanosome RNA metabolism: cis-splicing of pre-mRNA

It has been known for almost a decade and a half that in trypanosomes all mRNAs are trans-spliced by addition to the 5' end of the spliced leader (SL) sequence. During the same time period the conviction developed that classical cis-splicing introns are not present in the trypanosome genome and that the trypanosome gene arrangement is highly compact with small intergenic regions separating one gene from the next. We have now discovered that these tenets are no longer true. Poly(A) polymerase (PAP) genes in Trypanosoma brucei and Trypanosoma cruzi are split by intervening sequences of 653 and 302 nt, respectively. The intervening sequences occur at identical positions in both organisms and obey the GT/AG rule of cis-splicing introns. PAP mRNAs are trans-spliced at the very 5' end as well as internally at the 3' splice site of the intervening sequence. Interestingly, 11 nucleotide positions past the actual 5' splice site are conserved between the T. bruceiand T. cruzi introns. Point mutations in these conserved positions, as well as in the AG dinucleotide of the 3' splice site, abolish intron removal in vivo. Our results, together with the recent discovery of cis-splicing introns in Euglena gracilis, suggest that both trans- and cis-splicing are ancient acquisitions of the eukaryotic cell.     

In Euglena, spliced-leader RNA (SL-RNA) and 5S rRNA genes are tandemly repeated.

In Euglena gracilis, a 26 nucleotide leader sequence (spliced leader sequence = SL) is transferred by trans-splicing to the 5' end of a vast majority of cytoplasmic mRNAs (8). The SL originates from the 5' extremity of a family of closely related snRNAs (SL-RNAs) which are about 100 nucleotide long. In this paper we present the nucleotide sequences of two SL-RNA genes, confirming the sequences previously established by sequencing purified SL-RNAs. Although some SL-RNA genes are dispersed throughout the genome, we show that the majority of SL-RNA genes are located on 0.6 kb repeated units which also encode the cytoplasmic 5S rRNA. We estimate that the copy number of these repeated units is about 300 per haploid genome. The association of SL-RNA and 5S rRNA genes in tandemly repeated units is also found in nematodes but paradoxically does not exist in trypanosomes which are phylogenically much closer to Euglena. We also show that a high number of sequences analogous to the 26 nucleotide SL are dispersed throughout the genome and are not associated with SL-RNAs.     

Spliced leader trans-splicing in the nematode Trichinella spiralis uses highly polymorphic, noncanonical spliced leaders

The trans-splicing of short spliced leader (SL) RNAs onto the 5' ends of mRNAs occurs in a diverse range of taxa. In nematodes, all species so far characterized utilize a characteristic, conserved spliced leader, SL1, as well as variants that are employed in the resolution of operons. Here we report the identification of spliced leader trans-splicing in the basal nematode Trichinella spiralis, and show that this nematode does not possess a canonical SL1, but rather has at least 15 distinct spliced leaders, encoded by at least 19 SL RNA genes. The individual spliced leaders vary in both size and primary sequence, showing a much higher degree of diversity compared to other known trans-spliced leaders. In a survey of T. spiralis mRNAs, individual mRNAs were found to be trans-spliced to a number of different spliced leader sequences. These data provide the first indication that the last common ancestor of the phylum Nematoda utilized spliced leader trans-splicing and that the canonical spliced leader, SL1, found in Caenorhabditis elegans, evolved after the divergence of the major nematode clades. This discovery sheds important light on the nature and evolution of mRNA processing in the Nematoda.     

mRNAs that mature through trans-splicing in Caenorhabditis elegans have a trimethylguanosine cap at their 5'' termini.

Approximately 10% of the mRNAs in the nematode Caenorhabditis elegans mature through a trans-splicing mechanism that involves the transfer of a 22-nucleotide spliced leader to the 5' end of the pre-mRNA. The spliced leader RNA exists as a small nuclear ribonucleoprotein particle and has the trimethylguanosine cap that is characteristic of eucaryotic small nuclear RNAs. We found that the trimethylguanosine cap present on the spliced leader RNA was transferred to the pre-mRNA during the trans-splicing reaction. Thereafter, the trimethylguanosine cap was maintained on the mature mRNA. This is the first example of eucaryotic cellular mRNAs possessing a trimethylguanosine cap structure.     

Mapping of branch sites in trans-spliced pre-mRNAs of Trypanosoma brucei.

The process of trans splicing is essential to the maturation of all mRNAs in the Trypanosomatidae, a family of protozoan parasites, and to specific mRNAs in several species of nematode. In Trypanosoma brucei, a 39-nucleotide (nt) leader sequence originating from a small, 139-nt donor RNA (the spliced leader [SL] RNA) is spliced to the 5' end of mRNAs. An intermediate in this trans-splicing process is a Y structure which contains the 3' 100 nt of the SL RNA covalently linked to the pre-mRNA via a 2'-5' phosphodiester bond at the branch point residue. We mapped the branch points in T. brucei alpha- and beta-tubulin pre-mRNAs. The primary branch acceptors for the alpha- and beta-tubulins are 44 and 56 nt upstream of the 3' splice sites, respectively, and are A residues. Minor branch acceptors were detected 42 and 49 nt upstream of the alpha-tubulin splice site and 58 nt upstream of the splice site in beta-tubulin. The regions surrounding these branch points lack homology to the consensus sequences determined for mammalian cells and yeasts; there is also no conservation among the sequences themselves. Thus, the identified sequences suggest that the mechanism of branch point recognition in T. brucei differs from the mechanism of recognition by U2 RNA that has been proposed for other eucaryotes.     

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.     

Direct analysis of nematode cis- and trans-spliceosomes: a functional role for U5 snRNA in spliced leader addition trans-splicing and the identification of novel Sm snRNPs.

Most nuclear pre-mRNAs in nematodes are processed by both cis- and trans-splicing. In trans-splicing, the 5' terminal exon, the spliced leader sequence (SL), is derived from a trans-splicing specific Sm snRNP, the SL RNP. Because U snRNPs are required cofactors for trans-splicing, and because this processing reaction proceeds via a two-step reaction pathway identical to that of cis-splicing, it has long been assumed that trans-splicing is catalyzed in a complex analogous to the cis-spliceosome. However, similarities or differences between cis- and trans-spliceosomes have not been established. In particular, the role of U5 snRNP in trans-splicing has been unclear. Here, we have used affinity selection to analyze the U snRNA constituents of nematode cis- and trans-spliceosomes. We find that U5 snRNP is an integral component of the trans-spliceosome and, using site-specific crosslinking, we show that U5 snRNP establishes specific Interactions with the SL RNA exon. We also identify two novel Sm snRNPs that are enriched in both cis- and trans-spliceosomes. Finally, we provide evidence that a SL RNP-containing multi-snRNP (SL, U4, U5, and U6 RNPs) may be a functional precursor in trans-spliceosome assembly.     

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.     

Isolation of distinct small ribonucleoprotein particles containing the spliced leader and U2 RNAs of Trypanosoma brucei

Messenger RNA maturation in trypanosomes involves an RNA trans-splicing reaction in which a 39 nucleotide 5'-spliced leader (SL), derived from an independently transcribed 139 nucleotide SL RNA, is joined to pre-mRNAs. Trans-splicing intermediates are structurally consistent with a mechanism of SL addition which is similar to that of cis-splicing of nuclear pre-mRNAs; homologous components (e.g. the U small nuclear RNAs) exist in both cis- and trans-splicing systems, suggesting that these also participate in the two types of splicing reactions. In this study, ribonucleoprotein (RNP) complexes containing the trypanosome SL and U2 RNAs were purified and characterized. Although present at low levels in cellular extracts, the SL and U2 RNPs are the two most abundant of the several non-ribosomal small RNP complexes in these cells. The purification scheme utilizes ion-exchange chromatography, equilibrium density centrifugation, and gel filtration chromatography and reveals that the SL RNP shares biophysical properties with U RNPs of trypanosomes and other eukaryotes; its sedimentation coefficient in sucrose gradients is approximately 10 S, and it is resistant to dissociation during Cs2SO4 equilibrium density centrifugation. Complete separation of the SL and U2 RNPs was achieved by non-denaturing polyacrylamide gel electrophoresis. Proteins purifying with the SL and U2 RNPs were identified by 125I-labeling of tyrosine residues. Four SL RNP proteins with approximate molecular masses of 36, 32, 30, and 27 kDa and one U2 RNP protein of 31 kDa were identified, suggesting that different polypeptides are associated with these two RNAs. These particles are not immunoprecipitated by anti-Sm sera which recognizes U snRNP proteins of other eukaryotes including humans plants and yeast.     

trans-spliced Caenorhabditis elegans mRNAs retain trimethylguanosine caps.

The nematode Caenorhabditis elegans has an unusual small nuclear RNA, containing a 100-nucleotide RNA molecule, spliced leader RNA, which donates its 5' 22 nucleotides to a variety of recipient RNAs by a trans-splicing reaction. The spliced leader RNA has a 5' trimethylguanosine (TMG) cap, which becomes the 5' end of trans-spliced mRNAs. We found that mature trans-spliced mRNAs were immunoprecipitable with anti-TMG cap antibodies and that TMG-containing dinucleotides specifically competed with the trans-spliced mRNAs for antibody binding. We also found that these mRNAs retained their TMG caps throughout development and that the TMG-capped mRNAs were polysome associated. Since the large majority of C. elegans mRNAs are not trans-spliced, the addition of the spliced leader and its TMG cap to a limited group of recipient RNAs may create a functionally distinct subset of mRNAs.     

On the role of exon and intron sequences in trans-splicing utilization and cap 4 modification of the trypanosomatid Leptomonas collosoma SL RNA

In trypanosomatid protozoa the biogenesis of mature mRNA involves addition of the spliced leader (SL) sequence from the SL RNA to polycistronic pre-mRNA via trans-splicing. Here we present a mutational analysis of the trypanosomatid Leptomonas collosoma SL RNA to further our understanding of its functional domains important for trans-splicing utilization. Mutant SL RNAs were analyzed for defects in modification of the hypermethylated cap structure (cap 4) characteristic of trypanosomatid SL RNAs, for defects in the first step of the reaction and overall utilization in trans-splicing. Single substitution of the cap 4 nucleotides led to undermethylation of the cap 4 structure, and these mutants were all impaired in their utilization in trans-splicing. Abrogation of the sequence of the Sm-like site and sequences downstream to it also showed cap modification and trans-splicing defects, thus providing further support for a functional linkage between cap modifications and trans-splicing. Further, we report that in L. collosoma both the exon and intron of the SL RNA contribute information for efficient function of the SL RNA in trans-splicing. This study, however, did not provide support for the putative SL RNA-U6 small nuclear RNA (snRNA) interaction at the Sm site like in the nematodes, suggesting differences in the bridging role of U6 in the two trans-splicing systems.     

A short 5' splice site RNA oligo can participate in both steps of splicing in mammalian extracts.

A short 5' splice site RNA oligonucleotide (5'SS RNA oligo) undergoes both steps of splicing when a second RNA containing the 3' splice site region (3'SS RNA) is added in trans. This trans-splicing reaction displays the same 5' and 3' splice site sequence requirements as cis-splicing of full-length pre-mRNA. The analysis of RNA-snRNP complexes formed on each of the two splice site RNAs is consistent with the formation of partial complexes, which then associate to form the complete spliceosome. Specifically, U2 snRNP bound to the 3'SS RNA associates with U4/U5/U6 snRNP bound to the 5'SS RNA oligo. Thus, as expected, trans-splicing depends on the integrity of U2, U4, and U6 snRNAs. However, unlike cis-splicing, trans-splicing is enhanced when the 5' end of U1 snRNA is blocked or removed or when the U1 snRNP is depleted. Thus, the early regulatory requirement for U1 snRNP, which is essential in cis-splicing, is bypassed in this trans-splicing system. This simplified trans-splicing reaction offers a unique model system in which to study the mechanistic details of pre-mRNA splicing.     

The spliceosomal snRNAs of Caenorhabditis elegans.

Nematodes are the only group of organisms in which both cis- and trans-splicing of nuclear mRNAs are known to occur. Most Caenorhabditis elegans introns are exceptionally short, often only 50 bases long. The consensus donor and acceptor splice site sequences found in other animals are used for both cis- and trans-splicing. In order to identify the machinery required for these splicing events, we have characterized the C. elegans snRNAs. They are similar in sequence and structure to those characterized in other organisms, and several sequence variations discovered in the nematode snRNAs provide support for previously proposed structure models. The C. elegans snRNAs are encoded by gene families. We report here the sequences of many of these genes. We find a highly conserved sequence, the proximal sequence element (PSE), about 65 bp upstream of all 21 snRNA genes thus far sequenced, including the SL RNA genes, which specify the snRNAs that provide the 5' exons in trans-splicing. The sequence of the C. elegans PSE is distinct from PSE's from other organisms.     

Most mRNAs in the nematode Ascaris lumbricoides are trans-spliced: a role for spliced leader addition in translational efficiency.

Some pre-mRNAs in nematodes are processed by trans-splicing. In this reaction, a 22-nt 5' terminal exon (the spliced leader, SL) and its associated 2,2,7-trimethylguanosine cap are acquired from a specialized Sm snRNP, the SL RNP. Although it has been evident for many years that not all nematode mRNAs contain the SL sequence, the prevalence of trans-spliced mRNAs has, with the exception of Caenorhabditis elegans, not been determined. To address this question in an organism amenable to biochemical analysis, we have prepared a message-dependent protein synthesis system from developing embryos of the parasitic nematode, Ascaris lumbricoides. Using this system, we have used both hybrid-arrest and hybrid-selection approaches to show that the vast majority (80-90%) of A. lumbricoides mRNAs contain the SL sequence and therefore are processed by trans-splicing. Furthermore, to examine the effect of SL addition on translation, we have measured levels of protein synthesis in extracts programmed with a variety of synthetic mRNAs. We find that the SL sequence itself and its associated hypermethylated cap functionally collaborate to enhance translational efficiency, presumably at the level of initiation of protein synthesis. These results indicate that trans-splicing plays a larger role in nematode gene expression than previously suspected.