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

Evidence for the existence of the loop E motif of Potato spindle tuber viroid in vivo

RNA motifs comprising nucleotides that interact through non-Watson-Crick base pairing play critical roles in RNA functions, often by serving as the sites for RNA-RNA, RNA-protein, or RNA small ligand interactions. The structures of viral and viroid RNA motifs are studied commonly by in vitro, computational, and mutagenesis approaches. Demonstration of the in vivo existence of a motif will help establish its biological significance and promote mechanistic studies on its functions. By using UV cross-linking and primer extension, we have obtained direct evidence for the in vivo existence of the loop E motif of Potato spindle tuber viroid. We present our findings and discuss their biological implications.

A novel class of developmentally regulated noncoding RNAs in Leishmania

Leishmania is a protozoan parasite that causes serious morbidity and mortality in humans worldwide. The ability of these parasites to survive within the phagolysosomes of mammalian macrophages is dependent on the developmental regulation of a variety of genes. Identifying genomic sequences that are preferentially expressed during the parasite's intracellular growth would provide new insights about the mechanisms controlling stage-specific gene regulation for intracellular development of the parasite. Using a genomic library that differentially hybridized to probes made from total RNA from Leishmania infantum amastigote or promastigote life cycle stages, we identified a new class of noncoding RNAs (ncRNAs) ranging from approximately 300 to 600 nucleotides in size that are expressed specifically in the intracellular amastigote stage. These ncRNAs are transcribed by RNA polymerase II from genomic clusters of tandem head-to-tail repeats, which are mainly located within subtelomeric regions. Remarkably, both the sense and antisense orientations of these ncRNAs are transcribed and are processed by trans splicing and polyadenylation. The levels of antisense transcripts are at least 10-fold lower than those of the sense transcripts and are tightly regulated. The sense and antisense ncRNAs are cytosolic as shown by fluorescence in situ hybridization studies and cosediment with a small ribonucleoprotein complex. Amastigote-specific regulation of these ncRNAs possibly occurs at the level of RNA stability. Interestingly, overexpression of these ncRNAs in promastigotes, as part of an episomal expression vector, failed to produce any transcript, which further highlights the instability of these RNAs in the promastigote stage. This is the first report describing developmentally regulated ncRNAs in protozoan parasites.

Analysis of spliceosomal complexes in Trypanosoma brucei and silencing of two splicing factors Prp31 and Prp43

In trypanosomatids all mRNAs undergo trans-splicing, whereas cis-splicing is restricted to a few transcripts. Trans-splicing is mechanistically similar to cis-splicing, however, little is known about the trans-splicing machinery and its underlying mechanism. In this study, we examined the involvement of splicing factors in cis- and trans-splicing by RNA interference (RNAi). Two factors (Prp31 and Prp43) were found to be essential for both pathways, suggesting that splicing factors are shared by these two reactions. We identified a 45S complex carrying pre-mRNA and all the U-snRNAs, including U1 and the SL RNA, suggesting that a single spliceosomal complex may potentially conduct both trans- and cis-splicing.

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].

Human and fungal 3' splice sites are used by Trypanosoma brucei for trans splicing

In Trypanosoma brucei, pre-mRNAs are joined to a 5' 39 nt spliced leader sequence by trans splicing, a process that has not been well characterized. We have asked whether the 3' splice site regions of human and yeast introns are able to substitute in vivo for the 3' spliced leader acceptor regions of trypanosome pre-mRNA sequences. The ability of heterologous sequences to participate in trans splicing in trypanosomes was assayed by chloramphenicol acetyltransferase (CAT) enzyme activity and/or the detection of spliced CAT mRNA. Four out of the six heterologous 3' splice site regions (human beta-globin intervening sequence (IVS)2, human c-myc IVS2, human factor-VIII IVS1, and yeast actin IVS) functioned as 3' spliced leader acceptor regions in T. brucei, while two did not show significant or detectable levels of CAT activity (human beta-globin IVS1 and human c-myc IVS1). In the case of the human beta-globin IVS1 however, lengthening of the polypyrimidine tract as a result of single purine to pyrimidine transversions produced an active acceptor in which the spliced leader addition site coincides with the 3' splice site of the beta-globin exon 2. These studies indicate that some, but not all 3' acceptor regions in humans can function as spliced leader addition sites in trypansomes.

The SL1 trans-spliced leader RNA performs an essential embryonic function in Caenorhabditis elegans that can also be supplied by SL2 RNA

Covalent joining of leader RNA exons to pre-mRNAs by trans-splicing has been observed in protists and invertebrates, and can occur in cultured mammalian cells. In the nematode Caenorhabditis elegans, approximately 60% of mRNA species are trans-spliced to the 22-nucleotide SL1 leader, and another approximately 10% of mRNAs receive the 22-nucleotide SL2 leader. We have isolated deletions that remove the rrs-1 cluster, a gene complex that contains approximately 110 tandem copies of a repeat encoding both SL1 RNA and 5S rRNA. An SL1-encoding gene alone rescues the embryonic lethality caused by these deletions. Mutations within the Sm-binding site of SL1 RNA, which is required for trans-splicing, eliminate rescue, suggesting that the ability of the SL1 leader to be trans-spliced is required for its essential activity. We observe pleiotropic defects in embryos lacking SL1 RNA, suggesting that multiple mRNAs may be affected by the absence of an SL1 leader. We found, however, that SL1-receiving messages are expressed without an SL1 leader. Surprisingly, when overexpressed, SL2 RNA, which performs a distinct function from that of SL1 RNA in wild-type animals, can rescue the lethality of embryos lacking SL1 RNA. Moreover, in these mutant embryos, we detect SL2 instead of SL1 leaders on normally SL1-trans-spliced messages; this result suggests that the mechanism that discriminates between SL1 and SL2-trans-splicing may involve competition between SL1 and SL2-specific trans-splicing. Our findings demonstrate that SL1 RNA is essential for embryogenesis in C. elegans and that SL2 RNA can substitute for SL1 RNA in vivo.

Functionally redundant interactions between U2 and U6 spliceosomal snRNAs

Base-pairing between U2 and U6 snRNAs to form intermolecular helix II has been demonstrated previously as a requirement for pre-mRNA splicing in mammalian cells. In contrast, deletion and substitution mutation experiments in yeast have indicated that helix II is not essential; instead, other regions of U2 and U6 have been proposed to pair, forming a helix called Ib. To investigate the importance of U2/U6 helices in yeast, we have systematically mutagenized the regions proposed to form helices II and Ib. Allele-specific suppression of certain U6 mutations by complementary substitutions in U2 show that helix II indeed form in yeast but that it is essential only in the presence of additional mutations that disrupt U2 stem I and the proposed helix Ib. Similarly, the proposed helix Ib is essential only when helix II is disrupted. These observations provide an explanation for apparently conflicting data in yeast and mammalian experimental systems, and identify synergistic or functionally redundant interactions between U2 and U6 snRNAs.

trans-splicing: an update

5'-end maturation of messenger RNAs via acquisition of a trans-spliced leader sequence occurs in several primitive eukaryotes, some of which are parasitic. This type of trans-splicing proceeds though a two-step reaction pathway directly analogous to that of cis-splicing and like cis-splicing it requires multiple U snRNP cofactors. This minireview attempts to provide a brief synopsis of our current understanding of the evolution and biological significance of trans-splicing. Progress in deciphering the mechanism of trans-splicing, particularly as it relates to current models of cis-splicing, is also discussed.

The U6 snRNA-encoding gene of the monogenetic trypanosomatid Leptomonas collosoma

The U6 snRNA (U6) is the most conserved small nuclear RNA (snRNA) and apparently plays a central role in catalysis of the cis-splicing reaction. In trans-splicing, U6 may have an additional function. In the nematode trans-splicing system, a direct interaction between the U6 and spliced leader (SL) RNAs has been demonstrated, suggesting that U6 may serve as a bridge between the SL RNA and the acceptor pre-mRNA. To examine possible phylogenetic conservation of trypanosomatid U6 sequences that may interact with spliceosomal RNAs, we have cloned and sequenced the U6 gene from the monogenetic trypanosomatid Leptomonas collosoma (Lc). The Lc U6 deviates from the Trypanosoma brucei (Tb) RNA only in four positions located in the 5' stem-loop and the central domains. As in Tb, U6 is a single-copy gene and two tRNA genes, tRNAGln and tRNAIle, are found upstream to the gene. The tRNAs are differentially expressed; tRNAGln is transcribed in the opposite direction to U6, whereas tRNAIle is not transcribed. Possible base-pairing between U6 and the U2 and SL RNAs, similar to the interactions that take place in the nematode trans-splicing system, are proposed.

trans-spliceosomal U6 RNAs of Crithidia fasciculata and Leptomonas seymouri: deviation from the conserved ACAGAG sequence and potential base pairing with spliced leader RNA

U6 RNA genes from the trypanosomatids Crithidia fasciculata and Leptomonas seymouri have been isolated and sequenced. As in Trypanosoma brucei, the U6 RNA genes in both C. fasciculata and L. seymouri are arranged in close linkage with upstream tRNA genes. The U6 RNA sequences from C. fasciculata and L. seymouri deviate in five and three positions, respectively, from the published T. brucei sequence. Interestingly, both C. fasciculata U6 RNA genes carry a C-->T change at the second position of the ACAGAG hexanucleotide sequence, which is important for splicing function and has been considered phylogenetically invariable. A compensatory base change of the C. fasciculata spliced leader RNA at the highly conserved 5' splice site position +5, G-->A, suggests that an interaction between the 5' splice site region and U6 RNA recently proposed for the yeast cis-splicing system may also occur in trans splicing.

trans-spliceosomal U6 RNAs of Crithidia fasciculata and Leptomonas seymouri: deviation from the conserved ACAGAG sequence and potential base pairing with spliced leader RNA

U6 RNA genes from the trypanosomatids Crithidia fasciculata and Leptomonas seymouri have been isolated and sequenced. As in Trypanosoma brucei, the U6 RNA genes in both C. fasciculata and L. seymouri are arranged in close linkage with upstream tRNA genes. The U6 RNA sequences from C. fasciculata and L. seymouri deviate in five and three positions, respectively, from the published T. brucei sequence. Interestingly, both C. fasciculata U6 RNA genes carry a C-->T change at the second position of the ACAGAG hexanucleotide sequence, which is important for splicing function and has been considered phylogenetically invariable. A compensatory base change of the C. fasciculata spliced leader RNA at the highly conserved 5' splice site position +5, G-->A, suggests that an interaction between the 5' splice site region and U6 RNA recently proposed for the yeast cis-splicing system may also occur in trans splicing.

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.

The phylogenetically invariant ACAGAGA and AGC sequences of U6 small nuclear RNA are more tolerant of mutation in human cells than in Saccharomyces cerevisiae

U6 small nuclear RNA (snRNA) is the most highly conserved of the five spliceosomal snRNAs that participate in nuclear mRNA splicing. The proposal that U6 snRNA plays a key catalytic role in splicing [D. Brow and C. Guthrie, Nature (London) 337:14-15, 1989] is supported by the phylogenetic conservation of U6, the sensitivity of U6 to mutation, cross-linking of U6 to the vicinity of the 5' splice site, and genetic evidence for extensive base pairing between U2 and U6 snRNAs. We chose to mutate the phylogenetically invariant 41-ACAGAGA-47 and 53-AGC-55 sequences of human U6 because certain point mutations within the homologous regions of Saccharomyces cerevisiae U6 selectively block the first or second step of mRNA splicing. We found that both sequences are more tolerant to mutation in human cells (assayed by transient expression in vivo) than in S. cerevisiae (assayed by effects on growth or in vitro splicing). These differences may reflect different rate-limiting steps in the particular assays used or differential reliance on redundant RNA-RNA or RNA-protein interactions. The ability of mutations in U6 nucleotides A-45 and A-53 to selectively block step 2 of splicing in S. cerevisiae had previously been construed as evidence that these residues might participate directly in the second chemical step of splicing; an indirect, structural role seems more likely because the equivalent mutations have no obvious phenotype in the human transient expression assay.

The phylogenetically invariant ACAGAGA and AGC sequences of U6 small nuclear RNA are more tolerant of mutation in human cells than in Saccharomyces cerevisiae

U6 small nuclear RNA (snRNA) is the most highly conserved of the five spliceosomal snRNAs that participate in nuclear mRNA splicing. The proposal that U6 snRNA plays a key catalytic role in splicing [D. Brow and C. Guthrie, Nature (London) 337:14-15, 1989] is supported by the phylogenetic conservation of U6, the sensitivity of U6 to mutation, cross-linking of U6 to the vicinity of the 5' splice site, and genetic evidence for extensive base pairing between U2 and U6 snRNAs. We chose to mutate the phylogenetically invariant 41-ACAGAGA-47 and 53-AGC-55 sequences of human U6 because certain point mutations within the homologous regions of Saccharomyces cerevisiae U6 selectively block the first or second step of mRNA splicing. We found that both sequences are more tolerant to mutation in human cells (assayed by transient expression in vivo) than in S. cerevisiae (assayed by effects on growth or in vitro splicing). These differences may reflect different rate-limiting steps in the particular assays used or differential reliance on redundant RNA-RNA or RNA-protein interactions. The ability of mutations in U6 nucleotides A-45 and A-53 to selectively block step 2 of splicing in S. cerevisiae had previously been construed as evidence that these residues might participate directly in the second chemical step of splicing; an indirect, structural role seems more likely because the equivalent mutations have no obvious phenotype in the human transient expression assay.

Interaction of U6 snRNA with a sequence required for function of the nematode SL RNA in trans-splicing

Nematode trans-spliced leader (SL) RNAs are composed of two domains, an exon [the 22-nucleotide spliced leader] and a small nuclear RNA (snRNA)-like sequence. Participation in vitro of the spliced leader RNA in trans-splicing reactions is independent of the exon sequence or size and instead depends on features contained in the snRNA-like domain of the molecule. Chemical modification interference analysis has revealed that two short sequence elements in the snRNA-like domain are necessary for SL RNA activity. These elements are sufficient for such activity because when added to a 72-nucleotide fragment of a nematode U1 snRNA, this hybrid RNA could participate in trans-splicing reactions in vitro. One of the critical sequence elements may function by base-pairing with U6 snRNA, an essential U snRNA for both cis- and trans-splicing.

Evidence for a base-pairing interaction between U6 small nuclear RNA and 5' splice site during the splicing reaction in yeast

U6 small nuclear RNA (snRNA) is an essential factor in mRNA splicing. On the basis of the high conservation of its sequence, it has been proposed that U6 snRNA may function catalytically during the splicing reaction. If this is the case, it is likely that U6 snRNA interacts with the splice sites in the spliceosome to catalyze the reaction. We have used UV crosslinking to analyze the interactions of U6 snRNA with the splicing substrates during the yeast splicing reaction. Crosslinked products in which the central region of U6 snRNA was joined to the 5' splice site region of mRNA precursor and lariat intermediate were identified. The crosslinking sites were precisely located in one of these products. The results suggest a possible base-pairing interaction between U6 snRNA and the 5' splice site of the mRNA precursor.