RNA interference in Trypanosoma brucei: cloning of small interfering RNAs provides evidence for retroposon-derived 24-26-nucleotide RNAs.

In animals and protozoa, gene-specific double-stranded RNA (dsRNA) triggers degradation of homologous cellular RNAs, a phenomenon known as RNA interference (RNAi). In vitro and in vivo dsRNA is processed by a nuclease to produce 21-25-nt small interfering RNAs (siRNAs) that guide target RNA degradation. Here we show that activation of RNAi in Trypanosoma bruceiby expression or electroporation of actin dsRNA results in production of actin siRNAs and that 10% of these RNAs sediment as high-molecular-weight complexes at 100,000 x g. To characterize actin siRNAs, we established a cloning and enrichment strategy starting from 20-30 nt RNAs isolated from high-speed pellet and supernatant fractions. Sequence analysis revealed that actin siRNAs are 24-26 nt long and their distribution relative to actin dsRNA was similar in the two fractions. By sequencing over 1,300 fragments derived from the high-speed pellet fraction RNA, we found abundant 24-26-nt-long fragments homologous to the ubiquitous retroposon INGI and the site-specific retroposon SLACS. Northern hybridization with strand-specific probes confirmed that retroposon-derived 24-26-nt RNAs are present in both supernatant and high-speed pellet fractions and that they are constitutively expressed. We speculate that RNAi in trypanosomes serves a housekeeping function and is likely to be involved in silencing retroposon transcripts.

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.

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.

Genetic interference in Trypanosoma brucei by heritable and inducible double-stranded RNA.

The use of double-stranded RNA (dsRNA) to disrupt gene expression has become a powerful method of achieving RNA interference (RNAi) in a wide variety of organisms. However, in Trypanosoma brucei this tool is restricted to transient interference, because the dsRNA is not stably maintained and its effects are diminished and eventually lost during cellular division. Here, we show that genetic interference by dsRNA can be achieved in a heritable and inducible fashion. To show this, we established stable cell lines expressing dsRNA in the form of stem-loop structures under the control of a tetracycline-inducible promoter. Targeting a-tubulin and actin mRNA resulted in potent and specific mRNA degradation as previously observed in transient interference. Surprisingly, 10-fold down regulation of actin mRNA was not fatal to trypanosomes. This type of approach could be applied to study RNAi in other organisms that are difficult to microinject or electroporate. Furthermore, to quickly probe the consequences of RNAi for a given gene we established a highly efficient in vivo T7 RNA polymerase system for expression of dsRNA. Using the alpha-tubulin test system we obtained greater than 98% transfection efficiency and the RNAi response lasted at least two to three cell generations. These new developments make it possible to initiate the molecular dissection of RNAi both biochemically and genetically.

Cotranscriptional cap 4 formation on the Trypanosoma brucei spliced leader RNA.

mRNA cap formation in trypanosomatid protozoa is mediated through trans-splicing of the capped spliced leader (SL) sequence of the SL RNA onto the 5' end of all mRNAs. The SL RNA cap structure in Trypanosoma brucei is unique among eukaryotes and consists of 7-methylguanosine (m(7)G) followed by four methylated nucleotides (cap 4): m(7)Gpppm(2)(6)AmpAmpCmpm(3)Um. Using transcriptional arrest in permeable T. brucei cells, we have analyzed the temporal progression of cap 4 formation on the 140-nucleotide-long SL RNA. m(7)G capping of the SL RNA could be detected on prematurely terminated SL RNA transcripts of 56 nucleotides in length and longer. Subsequent modifications characteristic of the SL RNA cap 4 were added successively in a 5' to 3' direction and appeared to be independent of core ribonucleoprotein formation. Transcripts between 56 and 67 nucleotides in length were partially modified and carried methyl groups on the first two adenosine residues, whereas a fully modified cap 4 structure was present on transcripts arrested at position 117 and beyond. Taken together, our results are consistent with a cotranscriptional mechanism for generating the cap 4 structure on the SL RNA.

Import of proteins into the trypanosome nucleus and their distribution at karyokinesis.

In all eukaryotic organisms proteins are targeted to the nucleus via a receptor-mediated mechanism that requires a specific nuclear localization sequence (NLS) in the protein. Little is known about this process in trypanosomatid protozoa that are considered amongst the earliest divergent eukaryotes. We have used the green fluorescent protein (gfp) and beta-galactosidase reporters to identify the NLS of two trypanosomal proteins, namely the Trypanosoma brucei La protein homologue and histone H2B of T. cruzi. A monopartite NLS was demonstrated at the C terminus of the La protein, whereas a bipartite NLS was identified within the first 40 amino acids of histone H2B. Treatment of live trypanosomes with poisons of ATP synthesis resulted in exit of the La NLS-gfp fusion from the nucleus. Interestingly, this fusion protein accumulated at several discrete sites in the cytoplasm, rather than equilibrating between the nucleus and the cytoplasm. When ATP levels returned to normal, the protein reentered the nucleus, demonstrating that the process was energy dependent. Finally, using fusion proteins that localize to the nucleoplasm or the nucleolus, we identified a subpopulation of mitotic cells in which the chromosomes have segregated but the daughter nuclei remain connected by a thin thread-like structure. We propose that cells containing this structure represent a late stage in nuclear division that can be placed after chromosome segregation, but before completion of karyokinesis.

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.

Double-stranded RNA induces mRNA degradation in Trypanosoma brucei.

Double-stranded RNA (dsRNA) recently has been shown to give rise to genetic interference in Caenorhabditis elegans and also is likely to be the basis for phenotypic cosuppression in plants in certain instances. While constructing a plasmid vector for transfection of trypanosome cells, we serendipitously discovered that in vivo expression of dsRNA of the alpha-tubulin mRNA 5' untranslated region (5' UTR) led to multinucleated cells with striking morphological alterations and a specific block of cytokinesis. Transfection of synthetic alpha-tubulin 5' UTR dsRNA, but not of either strand individually, caused the same phenotype. On dsRNA transfection, tubulin mRNA, but not the corresponding pre-mRNA, was rapidly and specifically degraded, leading to a deficit of alpha-tubulin synthesis. The transfected cells were no longer capable of carrying out cytokinesis and eventually died. Analysis of cytoskeletal structures from these trypanosomes revealed defects in the microtubules of the flagellar axoneme and of the flagellar attachment zone, a complex cortical structure that we propose is essential for establishing the path of the cleavage furrow at cytokinesis. Last, dsRNA-mediated mRNA degradation is not restricted to alpha-tubulin mRNA but can be applied to other cellular mRNAs, thus establishing a powerful tool to genetically manipulate these important protozoan parasites.

MFR, a putative receptor mediating the fusion of macrophages.

We had previously identified a macrophage surface protein whose expression is highly induced, transient, and specific, as it is restricted to actively fusing macrophages in vitro and in vivo. This protein is recognized by monoclonal antibodies that block macrophage fusion. We have now purified this protein and cloned its corresponding cDNA. This protein belongs to the superfamily of immunoglobulins and is similar to immune antigen receptors such as the T-cell receptor, B-cell receptor, and viral receptors such as CD4. We have therefore named this protein macrophage fusion receptor (MFR). We show that the extracellular domain of MFR prevents fusion of macrophages in vitro and therefore propose that MFR belongs to the fusion machinery of macrophages. MFR is identical to SHPS-1 and BIT and is a homologue of P84, SIRPalpha, and MyD-1, all of which have been recently cloned and implicated in cell signaling and cell-cell interaction events.

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.

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.

Physical and transcriptional analysis of the Trypanosoma brucei genome reveals a typical eukaryotic arrangement with close interspersionof RNA polymerase II- and III-transcribed genes.

To further our understanding of the structural and functional organization of the Trypanosoma brucei genome, we have searched for and analyzed sites in the genome where Pol II transcription units meet Pol III genes. Physical and transcriptional maps of cosmid clones spanning the Pol III-transcribed U2 small nuclear RNA (snRNA) and U3 snRNA/7SL RNA gene loci demonstrated that single-copy Pol II genes are closely associated with Pol III-transcribed genes, being separated from each other by 0.6-3 kb. At the U3/7SL transcriptional domain, two Pol II transcription units converged from either side of the chromosome towards the Pol III genes, suggesting that at least for the chromosome containing the U3 snRNA and 7SL RNA genes, there exist two distinct initiation sites for Pol II. Furthermore, in all cases the Pol III genes hallmark the end of Pol II transcription units, suggesting perhaps a functional role for this genetic arrangement. Lastly, we asked whether the environment within a Pol III transcriptional domain allowed expression of pre-mRNA. To test this we inserted a CAT gene cassette, seemingly promoterless but endowed with pre-mRNA processing signals, in the chromosome between the U3 snRNA and 7SL RNA genes. Interestingly, abundant CAT mRNA was produced suggesting that the Pol III genes in the immediate vicinity did not prevent access of presumably Pol II to the CAT gene cassette. We propose that either CAT mRNA is synthesized by Pol II run-through transcription or by Pol II initiationupstream from the CAT gene.

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.

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.

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.

Accurate transcription of the Trypanosoma brucei U2 small nuclear RNA gene in a homologous extract.

In vitro transcription systems are a classic means to dissect mechanisms of gene expression at the molecular level. To begin an analysis of the biochemistry of gene expression in trypanosomes, we established an in vitro transcription system from cultured insect forms of Trypanosoma brucei. As a model we used the U2 snRNA gene which in vivo is transcribed by an RNA polymerase with characteristics of animal RNA polymerase III. To obtain maximum sensitivity in our assay, we adapted the so-called G-less cassette approach to the U2 snRNA gene promoter. Since an intragenic control region is required for accurate expression in vivo, we generated a series of mutations to substitute all guanosine residues in the intragenic control region. These mutants were shown to retain full transcriptional activity in vivo after transient expression in insect-form trypanosomes. In a cell-free extract, synthesis of the U2 G-less cassette RNA is correctly initiated, is mediated by RNA polymerase III as determined by RNA polymerase inhibitor studies, and is dependent on the integrity of the upstream B box element.

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.

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.