RNA polymerase III-mediated transcription of the trypanosome U2 small nuclear RNA gene is controlled by both intragenic and extragenic regulatory elements.

Transcription of U2 small nuclear RNA (snRNA) genes in eukaryotes is executed by RNA polymerase II and is dependent on extragenic cis-acting regulatory sequences which are not found in other genes. Here we have mapped promoter elements of the Trypanosoma brucei U2 snRNA gene by transient DNA expression of mutant constructs in insect form trypanosomes. Unlike other eukaryotic U2 snRNA genes, the T. brucei homolog is transcribed by an RNA polymerase III-like enzyme on the basis of its sensitivity to the inhibitors alpha-amanitin and tagetitoxin. Thus, the trypanosome U2 snRNA provides a unique example of an RNA polymerase III transcript carrying a trimethylated cap structure. The promoter of this gene consists of three distinct elements: an intragenic sequence close to the 5' end of the coding region, which is probably required to position the polymerase at the correct transcription start site; and two extragenic elements, located 110 and 160 nucleotides upstream, which are essential for U2 snRNA gene expression. These two elements closely resemble both in sequence and in distance from each other the A and B box consensus sequences of the internal control regions of tRNA genes.

Exonic sequences in the 5' untranslated region of alpha-tubulin mRNA modulate trans splicing in Trypanosoma brucei.

Previous studies have identified a conserved AG dinucleotide at the 3' splice site (3'SS) and a polypyrimidine (pPy) tract that are required for trans splicing of polycistronic pre-mRNAs in trypanosomatids. Furthermore, the pPy tract of the Trypanosoma brucei alpha-tubulin 3'SS region is required to specify accurate 3'-end formation of the upstream beta-tubulin gene and trans splicing of the downstream alpha-tubulin gene. Here, we employed an in vivo cis competition assay to determine whether sequences other than those of the AG dinucleotide and the pPy tract were required for 3'SS identification. Our results indicate that a minimal alpha-tubulin 3'SS, from the putative branch site region to the AG dinucleotide, is not sufficient for recognition by the trans-splicing machinery and that polyadenylation is strictly dependent on downstream trans splicing. We show that efficient use of the alpha-tubulin 3'SS is dependent upon the presence of exon sequences. Furthermore, beta-tubulin, but not actin exon sequences or unrelated plasmid sequences, can replace alpha-tubulin exon sequences for accurate trans-splice-site selection. Taken together, these results support a model in which the informational content required for efficient trans splicing of the alpha-tubulin pre-mRNA includes exon sequences which are involved in modulation of trans-splicing efficiency. Sequences that positively regulate trans splicing might be similar to cis-splicing enhancers described in other systems.

Temporal order of RNA-processing reactions in trypanosomes: rapid trans splicing precedes polyadenylation of newly synthesized tubulin transcripts.

Many trypanosome genes are expressed as part of large polycistronic transcription units. This finding suggests that regulation of mRNA biogenesis may emphasize RNA-processing reactions more so than in other organisms. This study was undertaken to understand the temporal order of two RNA-processing reactions, trans splicing and polyadenylation, in the maturation of trypanosome mRNAs in vivo. Kinetic studies revealed rapid trans splicing of alpha-tubulin, beta-tubulin, and actin pre-mRNAs within 1 to 2 min after synthesis of the 3' splice site. Furthermore, following blockage of pre-mRNA synthesis, newly synthesized spliced leader RNA cannot be used for trans splicing, suggesting that trypanosomes do not accumulate substantial amounts of pre-mRNA which can provide splice acceptor sites. Thus, trans splicing is cotranscriptional. In addition, we show that trans splicing precedes polyadenylation in the processing of trypanosome tubulin pre-mRNAs.

Trypanosome capping enzymes display a novel two-domain structure.

The ubiquitous m7G cap of eukaryotic mRNAs and of precursors to the spliceosomal small nuclear RNAs (snRNAs) is the result of an essential RNA modification acquired during transcript elongation. In trypanosomes, the m7G cap is restricted to the spliced leader (SL) RNA and the precursors of U2, U3, and U4 snRNAs. mRNA capping in these organisms occurs posttranscriptionally by trans splicing, which transfers the capped SL sequence to the 5' ends of all mRNAs. The SL cap is the most elaborate cap structure known in nature and has been shown to consist of an m7G residue followed by four methylated nucleotides. Using Crithidia fasciculata, we have characterized and purified the guanylyltransferase (capping enzyme), which transfers GMP from GTP to the diphosphate end of RNA. The corresponding gene codes for a protein of 697 amino acids, with the carboxy-terminal half of the C. fasciculata guanylyltransferase containing the six signature motifs previously identified in yeast capping enzymes. The amino-terminal half contains a domain that displays no resemblance to any other domain associated with capping enzymes. Intriguingly, this region harbors a consensus sequence for a phosphate-binding loop which is found in ATP- and GTP-binding proteins. This two-domain structure is also present in the Trypanosoma brucei capping enzyme, which shows 44% overall identity with the C. fasciculata capping enzyme. Thus, this structure appears to be common to all trypanosomatid protozoa and defines a novel class of capping enzymes.

Upstream tRNA genes are essential for expression of small nuclear and cytoplasmic RNA genes in trypanosomes.

An interesting feature of trypanosome genome organization involves genes transcribed by RNA polymerase III. The U6 small nuclear RNA (snRNA), U-snRNA B (the U3 snRNA homolog), and 7SL RNA genes are closely linked with different, divergently oriented tRNA genes. To test the hypothesis that this association is of functional significance, we generated deletion and block substitution mutants of all three small RNA genes and monitored their effects by transient expression in cultured insect-form cells of Trypanosoma brucei. In each case, two extragenic regulatory elements were mapped to the A and B boxes of the respective companion tRNA gene. In addition, the tRNA(Thr) gene, which is upstream of the U6 snRNA gene, was shown by two different tests to be expressed in T. brucei cells, thus confirming its identity as a gene. This association between tRNA and small RNA genes appears to be a general phenomenon in the family Trypanosomatidae, since it is also observed at the U6 snRNA loci in Leishmania pifanoi and Crithidia fasciculata and at the 7SL RNA locus in L. pifanoi. We propose that the A- and B-box elements of small RNA-associated tRNA genes serve a dual role as intragenic promoter elements for the respective tRNA genes and as extragenic regulatory elements for the linked small RNA genes. The possible role of tRNA genes in regulating small RNA gene transcription is discussed.

Determinants for cap trimethylation of the U2 small nuclear RNA are not conserved between Trypanosoma brucei and higher eukaryotic organisms.

In most eukaryotic organisms the U2 small nuclear RNA (snRNA) gene is transcribed by RNA polymerase II to generate a primary transcript with a 5' terminal 7-methylguanosine cap structure. Following nuclear export, the U2 snRNA is assembled into a core ribonucleoprotein particle (RNP). This involves binding a set of proteins that are shared by spliceosomal snRNPs to the highly conserved Sm site. Prior to nuclear import, the snRNA-(guanosine-N:2)-methyltransferase appears to interact with the core RNP and hypermethylates the cap structure to 2,2, 7-trimethylguanosine (m(3)G). In the protist parasite Trypanosoma brucei, U-snRNAs are complexed with a set of common proteins that are analogous to eukaryotic Sm antigens but do not have a highly conserved Sm sequence motif, and most U-snRNAs are synthesised by RNA polymerase III. Here, we examined the determinants for m(3)G cap formation in T.brucei by expressing mutant U2 snRNAs in vivo and assaying trimethylation and RNP assembly by immunoprecipitation. Surprisingly, these studies revealed that the Sm-analogous region is not required either for binding of the common proteins or for cap trimethylation. Furthermore, except for the first 24 nt which are part of the U2 promoter, the U2 coding region could be substituted or deleted without affecting cap trimethylation.

Conserved sequences in the U2 snRNA-encoding genes of Kinetoplastida do not include the putative branchpoint recognition region.

The U2 small nuclear RNA (snRNA) of Trypanosoma brucei gambiense, a flagellated protozoon of the order Kinetoplastida, is 148 nucleotides (nt) long, and thus the smallest U2 snRNA identified so far. To examine the evolutionary conservation of this RNA among Kinetoplastida, we have cloned and sequenced the U2 genes from Trypanosoma congolense and Leishmania mexicana amazonensis, which are 145 and 141 nt in length, respectively. The sequences of the Kinetoplastida U2 snRNAs are essentially identical in the 5' half of the molecule. Surprisingly, the putative branch site recognition sequence of L. m. amazonensis U2 snRNA shows two nt changes when compared with the other two U2 snRNAs. The sequence of the 3' half of the Kinetoplastida U2 snRNAs is less conserved with T. congolense and L. m. amazonensis RNAs showing 23 and 35 nt sequence variations, respectively, when compared with the corresponding sequence of the T. b. gambiense U2 snRNA. Alignment of the flanking regions of the U2 genes revealed several elements which are conserved both in sequence and in position relative to the U2 coding region and which may function in the biosynthesis of U2 snRNAs. One upstream element specifically binds protein factor(s) present in T. brucei nuclear extracts.

Structure of the Trypanosoma brucei U6 snRNA gene promoter.

Transcription in vivo of small nuclear and cytoplasmic RNA genes of Trypanosoma brucei was previously shown to require the A and B blocks of a divergently transcribed tRNA or tRNA-like gene located approximately 100 nucleotides (nt) upstream. To understand the functioning of these transcription units, we have used the U6 snRNA/tRNA(Thr) genes as a model system. Saturation mutagenesis revealed that for transcription in vivo three elements are essential and sufficient. In addition to the previously described A and B boxes, sequences in the U6 coding region close to the 5' end participate in positioning RNA polymerase III at the start site, and thus constitute a third promoter element. We further showed that the function of the upstream A box, but not the B box, is strictly dependent upon its distance to the U6 gene internal control region. Using our recently developed transcription extract we further demonstrated that in vitro U6 transcription requires only the intragenic sequences and the upstream A box of the tRNA(Thr) gene. This apparent discrepancy between the in vivo and in vitro requirements is highly reminiscent of U6 snRNA gene transcription in the yeast Saccharomyces cerevisiae, and suggests the possibility that similar to the yeast system the B block of the trypanosome U6 snRNA gene promoter might be involved in chromatin organization.

Unusual diversity in alpha-amanitin sensitivity of RNA polymerases in trichomonads.

Previous studies in the parasitic protist Trichomonas vaginalis have revealed that protein coding genes are transcribed by an alpha-amanitin-resistant RNA polymerase (RNAP) II. To investigate whether this unusual property is a general characteristic of trichomonads, we addressed the physiology of RNA synthesis in lysolecithin-permeabilized cells. Unlike in T. vaginalis, RNAP II in Tritrichomonas foetus was highly sensitive to the inhibitor alpha-amanitin. On the other hand, RNAP III, identified by its sensitivity to the specific inhibitor tagetitoxin, was found to be resistant to alpha-amanitin in Tritrichomonas foetus, but showed a typical intermediate sensitivity in T. vaginalis. Extension of this study to an additional seven trichomonad species confirmed this genera specific pattern of alpha-amanitin sensitivity and highlighted an unusual diversity in RNAPs among trichomonads, a closely related group of unicellular eukaryotes.

Characterization of a candidate Trypanosoma brucei U1 small nuclear RNA gene.

We have previously shown that the poly(A) polymerase (PAP) gene of Trypanosoma brucei is interrupted by an intervening sequence. It was postulated that removing this intron by cis-splicing requires a yet unidentified U1 small nuclear RNA (snRNA), which in other organisms engages in base-pair interactions across the 5' splice site during early spliceosome assembly. Here we present a characterization of a 75 nucleotide long candidate T. brucei U1 snRNA. Immunoprecipitation studies indicate that a trimethylguanosine cap structure is present at the 5' end and that the RNA is bound to core proteins common to spliceosomal ribonucleoprotein particles. The U1 snRNA has the potential for extensive intermolecular base pairing with the PAP 5' splice site. We used block replacement mutagenesis to identify sequences necessary for in vivo expression of U1 snRNA. We found that at least two cis-acting elements, tRNA-like A and B boxes, located in the 5'-flanking region are necessary for U1 snRNA synthesis; no internal sequences close to the transcription start site are essential, suggesting a promoter architecture distinct from other trypanosome U-snRNA genes.

Transcription of the Trypanosoma brucei spliced leader RNA gene is dependent only on the presence of upstream regulatory elements.

The spliced leader (SL) RNA plays a key role in mRNA maturation in trypanosomatid protozoa by providing the SL sequence, which is joined to the 5' end of every mRNA. As a first step towards a better understanding of the biogenesis and function of the SL RNA, we expressed a tagged SL RNA gene in a cell-free system of procyclic Trypanosoma brucei cells. Transcription initiates at + 1 can be detected as early as 1 min after addition of extract. Transcription of the SL RNA gene in vitro, as well as in permeable cells, is mediated by an alpha-amanitin/tagetitoxin resistant complex, suggesting a promoter that is intermediate between a classical RNA polymerase II and RNA polymerase III promoter. An analysis of the promoter architecture of the SL RNA gene revealed that regulatory elements are located upstream of the coding region and that the SL sequence, in contrast to the nematode SL sequence, is not required for T. brucei SL RNA gene transcription.

Sequence and heterogeneity in the 5S RNA gene cluster of Drosophila melanogaster.

The sequence of the entire 5S RNA gene of Drosophila melanogaster was determined by sequencing collectively 23 copies contained in a cloned fragment of Drosophila DNA and by sequencing individually four subcloned gene copies. A repetitive heptamer (GCTG CCT) present in variable numbers immediately following the coding sequence, is responsible for the length heterogeneity in the spacer region. Some of the gene copies contain a nucleotide change in the coding region which results in a new site for the restriction enzyme Mn1 I. The variant 5S RNA produced by these gene copies has not been detected in vivo. Two other single nucleotide variations were identified in the spacer region.

Trans splicing in trypanosomes requires methylation of the 5' end of the spliced leader RNA.

Trypanosoma brucei spliced leader (SL) RNA contains an unusual cap 4 structure consisting of 7-methylguanosine linked to four modified nucleosides. During RNA maturation, trans splicing transfers the first 39 nucleotides of the SL RNA including the cap structure to the 5' end of all mRNAs. Here we show that exposure of permeable trypanosome cells to S-adenosyl-L-homocysteine inhibits methylation of the nucleosides adjacent to 7-methylguanosine of newly synthesized SL RNA and prevents utilization of the SL RNA in trans splicing. However, trans splicing of the SL RNA preexisting in the cells is not inhibited by S-adenosyl-L-homocysteine as shown by the observation that newly synthesized alpha-tubulin RNA is trans spliced at the same level as in control cells. Therefore, it appears that the newly synthesized SL RNA is the only known component of the trans-splicing machinery that is impaired in its function by inhibition of methylation. Undermethylation does not alter either the stability of the SL RNA or the electrophoretic mobility and chromatographic behavior of the core SL ribonucleoprotein particle. Taken together, our data suggest that the cap 4 structure of the SL RNA plays an essential role in the trans-splicing process.

Polygene transcripts are precursors to calmodulin mRNAs in trypanosomes.

In African trypanosomes, calmodulin is encoded by a small family of tandemly repeated genes consisting of three to four units. We show that all the members of the calmodulin cluster of Trypanosoma brucei gambiense are expressed. In addition to mature mRNAs, steady-state RNA contains a small percentage of polygene transcripts which comprise at least two and probably all calmodulin genes. The 5' ends of a portion of these molecules appear to be indistinguishable from those of mature calmodulin mRNAs. Polygene transcripts are not polyadenylated and have discrete ends which map in the intergenic regions downstream from the polyadenylation sites. Using biotinylated hybridization probes and selection of the hybrids on streptavidin-agarose, we further show that calmodulin polygene transcripts are the most abundant RNA species detected in pulse-labelled RNA of cultured procyclic trypanosomes. Our data strongly imply that polygene transcripts are authentic precursors to mature calmodulin mRNAs.

Permeable trypanosome cells as a model system for transcription and trans-splicing.

We have established conditions for Trypanosoma brucei permeable cells to study transcription and trans-splicing. We found that the concentration of monovalent and, to a lesser extent, divalent ions plays a critical role for the expression of a number of different genes. Most remarkably, the synthesis of the spliced leader (SL) RNA was optimal at 20 mM KCl, whereas higher potassium concentrations were inhibitory. In addition, MgCl2 concentrations above 3 mM led to the accumulation of a 3' end shortened SL RNA species, which has been previously reported not to participate in trans-splicing. Using conditions optimal for the synthesis of the SL RNA, we observed accurate trans-splicing of newly-synthesized alpha-tubulin RNA. Moreover, we detected the SL intron both joined to high molecular weight RNAs in the form of branched Y-structures and as a free linear molecule, which rapidly turned over. Furthermore, ionic concentrations that inhibit the synthesis of the SL RNA produced exclusively unspliced alpha-tubulin RNA, thus demonstrating that transcription and trans-splicing can be uncoupled.

Trypanosomatid protozoa provide paradigms of eukaryotic biology.

Over the last 10 years, trypanosomatid protozoa have been the subject of intense investigation particularly focusing on their parasitic lifestyle and their intriguing and novel cell properties. These studies have furthered our understanding of the physiology and functioning of these cells and have identified a large number of biochemical and metabolic peculiarities, including mitochondrial function, enzymatic compartmentalization, and gene expression. This review focuses on the mode of gene expression and highlights areas of trypanosome research that have provided paradigms of eukaryotic biology.

Destruction of U2, U4, or U6 small nuclear RNA blocks trans splicing in trypanosome cells.

We have used permeable cells of Trypanosoma brucei to analyze the role of snRNAs in the trans splicing process. Degradation of U2, U4, or U6 snRNA by site-directed cleavage with complementary deoxyoligonucleotides and RNAase H inhibits trans splicing of the spliced leader (SL) RNA and newly synthesized alpha-tubulin pre-mRNAs. Cleavage of U snRNAs abolishes the appearance of putative trans splicing reaction intermediates and products, namely, linear branched molecules consisting of the SL intron joined to high molecular weight RNA (Y structures) and free SL intron. This indicates that U snRNAs are required for an early step in trans splicing. alpha-tubulin transcripts synthesized in the absence of trans splicing are unstable, suggesting that the addition of the SL sequence stabilizes pre-mRNAs against degradation. Our results provide direct evidence for the participation of U2 and U4/U6 snRNPs in trans splicing.

Accurate modification of the trypanosome spliced leader cap structure in a homologous cell-free system.

During RNA maturation in trypanosomatid protozoa, trans-splicing transfers the spliced leader (SL) sequence and its cap from the SL RNA to the 5' end of all mRNAs. In Trypanosoma brucei and Crithidia fasciculata the SL RNA has an unusual cap structure with four methylated nucleotides following the 7-methylguanosine residue (cap 4). Since modification of the 5' end of the SL RNA is a pre-requisite for trans-splicing activity in T. brucei, we have begun to characterize the enzyme(s) involved in this process. Here we report the development of a T. brucei cell-free system for modification of the cap of the SL RNA. Analysis of the nucleotide composition of the in vitro generated cap structure by two-dimensional thin layer chromatography established that the in vitro reaction is accurate. Cap 4 formation requires the SL RNA to be in a ribonucleoprotein particle and can be inhibited by annealing a complementary 2'-O-methyl RNA oligonucleotide to nucleotides 7-18 of the SL RNA. Methylation of the 5' end of the SL RNA is also required for trans-splicing in T. cruzi and Leishmania amazonensis and cell-free extracts from C. fasciculata and L. amazonensis are capable of modifying the cap structure on the T. brucei SL ribonucleoprotein particle.