The SLA RNA gene of Trypanosoma brucei is organized in a tandem array which encodes several small RNAs.

We have recently identified the Spliced Leader Associated RNA (SLA RNA) which is implicated in pre-messenger RNA splicing in Trypanosoma brucei by virtue of its interaction with the 5' splice site of the trans spliced spliced leader RNA (SL RNA) in vivo. Southern analyses reveal that the SLA RNA gene is found in a tandem array of 10-11 copies per haploid genome in T. brucei. Each repeat unit in the array encodes three additional small RNAs of unknown function. RNA polymerase inhibition studies are consistent with transcription of all four genes by the same polymerase, but do not clearly differentiate between RNA polymerases II and III. The SLA RNA has homologs in other kinetoplastid protozoa and we have determined the sequence from two additional species. Trypanosoma cruzi and Crithidia fasciculata. Features of both secondary structure and sequence are conserved in these organisms. One conserved element, 5'-UGUAGUG-3', has the potential to base-pair to the SL RNA upstream of the 5' splice site. This potential interaction is consistent with the sites of SL RNA to SLA RNA psoralen cross-linking in vivo [1].

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 a small RNA that interacts with the 5' splice site of the Trypanosoma brucei spliced leader RNA in vivo.

In vivo psoralen cross-linking of the trypanosome spliced leader (SL) RNA has led to the discovery of a small RNA that we provisionally call the spliced leader-associated (SLA) RNA. The 72 nt SLA RNA is unlike any known small RNA except for a small region that resembles U5 snRNA. The SL/SLA RNA cross-links map to two regions, the predominant interactions occurring between the 5' splice site region of the SL RNA and a CUUUUA sequence in the SLA RNA. The resemblance between these cross-links and interactions of U5 snRNA with cis-spliced pre-mRNAs suggests that the SLA RNA may be the trans-splicing analog of U5 snRNA in trypanosomes.

In vivo UV cross-linking of U snRNAs that participate in trypanosome trans-splicing.

The maturation of mRNAs in Trypanosoma brucei involves a trans-splicing reaction whereby the 5' 39 nucleotides of a small RNA, called the spliced leader (SL) RNA, are joined with a pre-mRNA transcript. The trans-splicing reaction appears mechanistically similar to cis-splicing of nuclear pre-mRNAs, and homologs of the U2, U4, and U6 snRNAs are required for the process. In the work presented here, potential RNA-RNA interactions between the SL RNA and the U snRNAs of trypanosomes were examined by UV light induction of RNA-RNA cross-links in vivo. We detected cross-linkage between U2 and U6 RNAs and, as might be expected, between the trypanosome U4 and U6 RNAs. The latter contain extensive sequence complementarity and are thought to exist predominantly in a single RNP. We also detected an SL RNA species following in vivo UV treatment, which may represent either an intramolecular cross-link in the SL RNA or a cross-link formed between the SL RNA and an as yet unidentified small RNA. Mapping of the cross-link position between U2 and U6 RNAs is consistent with base-pairing between the 5' domain of U2 and the 3' end of U6 RNA. These results reveal the existence, in vivo, of cognate RNA-RNA interactions in the RNA homologs that participate in trans-splicing in trypanosomes and cis-splicing in other eukaryotes.

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.

Trypanosome mRNAs have unusual "cap 4" structures acquired by addition of a spliced leader.

A single capped oligonucleotide is released from Trypanosoma brucei poly(A)+ RNA upon digestion with RNase T2. This observation supports the hypothesis that all T. brucei mRNAs share a common leader sequence. Digestion of the T2-resistant species with nucleotide pyrophosphatase shows that the capping nucleotide is 7-methylguanosine 5'-monophosphate (pm7G). Additional characterization of the T2-resistant fragment indicates that modifications are present on the first four transcribed nucleotides; the 5' termini of T. brucei mRNAs can, therefore, be described as "cap 4" structures. Identical 5'-cap structures are found on the T. brucei spliced leader (SL) RNA; an observation compatible with the hypothesis that the small SL RNA acts as a donor of the SL for the mRNA. However, we find that within a population of purified SL RNAs are species that are capped but incompletely modified. The presence of these unmodified and partially modified species allowed us to analyze the 5' sequence of the SL RNA transcript. The results indicate that transcription begins four nucleotides upstream of the reported 5' end. Therefore, the T. brucei SL transcript is actually 39 rather than 35 nucleotides long. We have also analyzed the capped oligonucleotide of a distantly related Trypanosomatid, Leptomonas collosoma and find it to be identical to that of T. brucei. The potential significance of these results is discussed in light of observations of trypanosome gene expression.

Identification of a novel Y branch structure as an intermediate in trypanosome mRNA processing: evidence for trans splicing.

We present evidence that addition of the 35 nucleotide spliced leader (SL) to the 5' end of T. brucei mRNAs occurs via trans RNA splicing. A 100 nucleotide fragment of the 135 base SL RNA (100-mer) is revealed by S1 nuclease analysis of total and poly(A)+ RNA. This 100-mer is not detected by Northern hybridization analysis, indicating that it does not exist free in the cell. The 5' end of the 100-mer maps precisely to the conserved splice junction sequence of the SL RNA. Purified debranching enzyme releases this 100-mer RNA as a free, 100 nucleotide species. This indicates that the 100-mer is covalently linked to poly(A)+ RNA by a 2'-5' phosphodiester bond, that the branched intermediate has a discontinuous intron or Y structure (rather than a lariat), which is expected of a trans-spliced mRNA, and that the SL RNA is indeed the donor of the SL sequence to trypanosome mRNAs.

Trypanosome mRNAs share a common 5' spliced leader sequence.

A 5'-terminal leader sequence of 35 nucleotides was found to be present on multiple trypanosome RNAs. Based on its representation in cDNA libraries, we estimate that many, if not all, trypanosome mRNAs contain this leader. This same leader was originally identified on mRNAs encoding the molecules responsible for antigenic variation, variant surface glycoproteins. Studies of selected cDNAs containing this leader sequence revealed that leader-containing transcripts can be stage-specific, stage-regulated, or constitutive. They can be abundant or rare, and transcribed from single or multigene families. No linkage between the genomic leader sequences and the structural gene exons was observed. Possible mechanisms by which the leader sequences are added to trypanosome mRNAs are discussed.