Transcription termination and 3'-End processing of the spliced leader RNA in kinetoplastids

A PCR-based method for the diagnosis of Enterobius vermicularis in stool samples, specifically designed for clinical application

BACKGROUND

Enterobius vermicularis (E. vermicularis) is a nematode that infects up to 200 million people worldwide, despite effective medications being available. Conventional diagnostic tests are hindered by low sensitivity and poor patient compliance. Furthermore, no biomolecular techniques are available for clinical application. The aim of this study was to develop a procedure specifically designed for clinical application to detect E. vermicularis by means of PCR.

MATERIALS AND METHODS

Two subject groups were taken into account: a group of 27 infected patients and a control group of 27 healthy subjects. A nested-PCR was performed on fecal samples to detect E. vermicularis. Due to the intrinsic difficulties of the fecal matrix, several countermeasures were adopted to ensure the efficient performance of the method: (a) a large amount of feces for the extraction process (20 g instead of 200 mg); (b) a combination of chemical and physical treatments to grind the fecal matrix; (c) an additional purification process for the negative samples after the first nested-PCR; and (d) the selection of a very specific target region for the PCR.

RESULTS

Due to the lack of overlap with other organisms, a sequence of the 5S ribosomal DNA (rDNA) spacer region including the tract SL1 was chosen to design appropriate external and internal primers. The first nested-PCR detected E.vermicularis in 19/27 samples from infected patients. After further purification, 5/8 of the negative samples resulted positive at the second PCR. Conversely, all the samples from healthy controls resulted negative to both PCRs. Sensitivity and specificity of the method were, respectively, 88.9% and 100%.

CONCLUSION

The results prove the high diagnostic accuracy of the proposed method, addressing and overcoming the challenges posed by both conventional tests and PCR-based approaches. Therefore, the method can be proposed for clinical application.

Regulation of gene expression in trypanosomatids: living with polycistronic transcription

In trypanosomes, RNA polymerase II transcription is polycistronic and individual mRNAs are excised by trans-splicing and polyadenylation. The lack of individual gene transcription control is compensated by control of mRNA processing, translation and degradation. Although the basic mechanisms of mRNA decay and translation are evolutionarily conserved, there are also unique aspects, such as the existence of six cap-binding translation initiation factor homologues, a novel decapping enzyme and an mRNA stabilizing complex that is recruited by RNA-binding proteins. High-throughput analyses have identified nearly a hundred regulatory mRNA-binding proteins, making trypanosomes valuable as a model system to investigate post-transcriptional regulation.

Characterization of spliced leader trans-splicing in a photosynthetic rhizarian amoeba, Paulinella micropora, and its possible role in functional gene transfer

Paulinella micropora is a rhizarian thecate amoeba, belonging to a photosynthetic Paulinella species group that has a unique organelle termed chromatophore, whose cyanobacterial origin is distinct from that of plant and algal chloroplasts. Because acquisition of the chromatophore was quite a recent event compared with that of the chloroplast ancestor, the Paulinella species are thought to be model organisms for studying the early process of primary endosymbiosis. To obtain insight into how endosymbiotically transferred genes acquire expression competence in the host nucleus, here we analyzed the 5′ end sequences of the mRNAs of P. micropora MYN1 strain with the aid of a cap-trapper cDNA library. As a result, we found that mRNAs of 27 genes, including endosymbiotically transferred genes, possessed the common 5′ end sequence of 28–33 bases that were posttranscriptionally added by spliced leader (SL) trans-splicing. We also found two subtypes of SL RNA genes encoded by the P. micropora MYN1 genome. Differing from the other SL trans-splicing organisms that usually possess poly(A)-less SL RNAs, this amoeba has polyadenylated SL RNAs. In this study, we characterize the SL trans-splicing of this unique organism and discuss the putative merits of SL trans-splicing in functional gene transfer and genome evolution.

Spliced leader RNA trans-splicing discovered in copepods

Copepods are one of the most abundant metazoans in the marine ecosystem, constituting a critical link in aquatic food webs and contributing significantly to the global carbon budget, yet molecular mechanisms of their gene expression are not well understood. Here we report the detection of spliced leader (SL) trans-splicing in calanoid copepods. We have examined nine species of wild-caught copepods from Jiaozhou Bay, China that represent the major families of the calanoids. All these species contained a common 46-nt SL (CopepodSL). We further determined the size of CopepodSL precursor RNA (slRNA; 108-158 nt) through genomic analysis and 3′-RACE technique, which was confirmed by RNA blot analysis. Structure modeling showed that the copepod slRNA folded into typical slRNA secondary structures. Using a CopepodSL-based primer set, we selectively enriched and sequenced copepod full-length cDNAs, which led to the characterization of copepod transcripts and the cataloging of the complete set of 79 eukaryotic cytoplasmic ribosomal proteins (cRPs) for a single copepod species. We uncovered the SL trans-splicing in copepod natural populations, and demonstrated that CopepodSL was a sensitive and specific tool for copepod transcriptomic studies at both the individual and population levels and that it would be useful for metatranscriptomic analysis of copepods.

Rediscovery of Trypanosoma (Pycnomonas) suis, a tsetse-transmitted trypanosome closely related to T. brucei

The African tsetse-transmitted trypanosomes are considered to be a well-known group of parasitic protozoa, but in 2008 a novel and distinctive trypanosome related to Trypanosoma brucei was discovered among tsetse isolates from Msubugwe in Tanzania. The host range, distribution and potential pathogenicity of this new trypanosome remain to be elucidated; such studies would be facilitated by a sensitive and specific identification method. Here, we identified two highly repetitive elements in the genome of the new trypanosome: a 177 bp repeat, which was located predominantly on the highly abundant minichromosomes, and a 138 bp repeat, which was widely dispersed in the genome. A PCR test based on each repeat was specific for the new trypanosome and sensitive to <0.1 trypanosome equivalent. These PCR tests were used to identify trypanosomes in archival pig blood smears from the 1950's, confirming the identity of the Msubugwe trypanosome as Trypanosoma (Pycnomonas) suis. We also present data on the molecular karyotype and spliced leader (SL, miniexon) repeat of the new trypanosome, both of which distinguish T. suis from other, better-known African tsetse-transmitted trypanosomes. The rediscovery of T. suis opens new lines of research into the evolution and biology of the African trypanosomes.

Signal recognition particle RNA in dinoflagellates and the Perkinsid Perkinsus marinus

In dinoflagellates and perkinsids, the molecular structure of the protein translocating machinery is unclear. Here, we identified several types of full-length signal recognition particle (SRP) RNA genes from Karenia brevis (dinoflagellate) and Perkinsus marinus (perkinsid). We also identified the four SRP S-domain proteins, but not the two Alu domain proteins, from P. marinus and several dinoflagellates. We mapped both ends of SRP RNA transcripts from K. brevis and P. marinus, and obtained the 3' end from four other dinoflagellates. The lengths of SRP RNA are predicted to be ∼260-300 nt in dinoflagellates and 280-285 nt in P. marinus. Although these SRP RNA sequences are substantially variable, the predicted structures are similar. The genomic organization of the SRP RNA gene differs among species. In K. brevis, this gene is located downstream of the spliced leader (SL) RNA, either as SL RNA-SRP RNA-tRNA gene tandem repeats, or within a SL RNA-SRP RNA-tRNA-U6-5S rRNA gene cluster. In other dinoflagellates, SRP RNA does not cluster with SL RNA or 5S rRNA genes. The majority of P. marinus SRP RNA genes array as tandem repeats without the above-mentioned small RNA genes. Our results capture a snapshot of a potentially complex evolutionary history of SRP RNA in alveolates.

Genomic analysis of sequence-dependent DNA curvature in Leishmania

Leishmania major is a flagellated protozoan parasite of medical importance. Like other members of the Trypanosomatidae family, it possesses unique mechanisms of gene expression such as constitutive polycistronic transcription of directional gene clusters, gene amplification, mRNA trans-splicing, and extensive editing of mitochondrial transcripts. The molecular signals underlying most of these processes remain under investigation. In order to investigate the role of DNA secondary structure signals in gene expression, we carried out a genome-wide in silico analysis of the intrinsic DNA curvature. The L. major genome revealed a lower frequency of high intrinsic curvature regions as well as inter- and intra- chromosomal distribution heterogeneity, when compared to prokaryotic and eukaryotic organisms. Using a novel method aimed at detecting region-integrated intrinsic curvature (RIIC), high DNA curvature was found to be associated with regions implicated in transcription initiation. Those include divergent strand-switch regions between directional gene clusters and regions linked to markers of active transcription initiation such as acetylated H3 histone, TRF4 and SNAP50. These findings suggest a role for DNA curvature in transcription initiation in Leishmania supporting the relevance of DNA secondary structures signals.

Trans-splicing in trypanosomes: machinery and its impact on the parasite transcriptome

In trypanosomes, all RNAs are processed by the concerted action of trans-splicing and polyadenylation. In trans-splicing, a common spliced leader (SL) is donated to all mRNAs from a small RNA molecule, the SL RNA. This article summarizes recent findings in the field focusing on SL RNA transcription, cap modifications and pseudouridylation. The role(s) of these modifications for splicing and gene expression are discussed. The recruitment of SL RNA to the spliceosome depends on splicing factors and recent progress in identifying such factors is described. A recent major advance in understanding the role of trans-splicing in the trypanosome transcriptome was obtained by whole-genome mapping of the SL and polyadenylation sites, revealing surprising heterogeneity and suggesting that gene regulation, especially during cycling between the two hosts of the parasite, involves alternative trans-splicing. Finally, the SL silencing mechanism, which is harnessed by the parasite to control gene expression under stress, is discussed.

Ab initio identification of novel regulatory elements in the genome of Trypanosoma brucei by Bayesian inference on sequence segmentation

BACKGROUND

The rapid increase in the availability of genome information has created considerable demand for both comparative and ab initio predictive bioinformatic analyses. The biology laid bare in the genomes of many organisms is often novel, presenting new challenges for bioinformatic interrogation. A paradigm for this is the collected genomes of the kinetoplastid parasites, a group which includes Trypanosoma brucei the causative agent of human African trypanosomiasis. These genomes, though outwardly simple in organisation and gene content, have historically challenged many theories for gene expression regulation in eukaryotes.

METHODOLOGY/PRINCIPLE FINDINGS

Here we utilise a Bayesian approach to identify local changes in nucleotide composition in the genome of T. brucei. We show that there are several elements which are found at the starts and ends of multicopy gene arrays and that there are compositional elements that are common to all intergenic regions. We also show that there is a composition-inversion element that occurs at the position of the trans-splice site.

CONCLUSIONS/SIGNIFICANCE

The nature of the elements discovered reinforces the hypothesis that context dependant RNA secondary structure has an important influence on gene expression regulation in Trypanosoma brucei.

Spliced leader RNAs, mitochondrial gene frameshifts and multi-protein phylogeny expand support for the genus Perkinsus as a unique group of alveolates

The genus Perkinsus occupies a precarious phylogenetic position. To gain a better understanding of the relationship between perkinsids, dinoflagellates and other alveolates, we analyzed the nuclear-encoded spliced-leader (SL) RNA and mitochondrial genes, intron prevalence, and multi-protein phylogenies. In contrast to the canonical 22-nt SL found in dinoflagellates (DinoSL), P. marinus has a shorter (21-nt) and a longer (22-nt) SL with slightly different sequences than DinoSL. The major SL RNA transcripts range in size between 80–83 nt in P. marinus, and ∼83 nt in P. chesapeaki, significantly larger than the typical ≤56-nt dinoflagellate SL RNA. In most of the phylogenetic trees based on 41 predicted protein sequences, P. marinus branched at the base of the dinoflagellate clade that included the ancient taxa Oxyrrhis and Amoebophrya, sister to the clade of apicomplexans, and in some cases clustered with apicomplexans as a sister to the dinoflagellate clade. Of 104 Perkinsus spp. genes examined 69.2% had introns, a higher intron prevalence than in dinoflagellates. Examination of Perkinsus spp. mitochondrial cytochrome B and cytochrome C oxidase subunit I genes and their cDNAs revealed no mRNA editing, but these transcripts can only be translated when frameshifts are introduced at every AGG and CCC codon as if AGGY codes for glycine and CCCCU for proline. These results, along with the presence of the numerous uncharacterized ‘marine alveolate group I' and Perkinsus-like lineages separating perkinsids from core dinoflagellates, expand support for the affiliation of the genus Perkinsus with an independent lineage (Perkinsozoa) positioned between the phyla of Apicomplexa and Dinoflagellata.

snRNA-specific role of SMN in trypanosome snRNP biogenesis in vivo

Pre-mRNA splicing in trypanosomes requires the SMN-mediated assembly of small nuclear ribonucleoproteins (snRNPs). In contrast to higher eukaryotes, the cellular localization of snRNP biogenesis and the involvement of nuclear-cytoplasmic trafficking in trypanosomes are controversial. By using RNAi knockdown of SMN in T. brucei to investigate its functional role in snRNP assembly, we found dramatic changes in the steady-state levels of snRNAs and snRNPs: The SL RNA accumulates, whereas U1, U4, and U5 snRNA levels decrease, and Sm core assembly in particular of the SL RNA is strongly reduced. In addition, SMN depletion blocks U4/U6 di-snRNP formation; the variant Sm core of the U2 snRNP, however, still forms efficiently after SMN knockdown. Concerning the longstanding question, whether nuclear-cytoplasmic trafficking is involved in trypanosomal snRNP biogenesis, fluorescence in situ hybridization (FISH) and immunofluorescence assays revealed that the SL RNA genes and transcripts colocalize with SMN. Remarkably, SMN silencing leads to a nucleoplasmic accumulation of both SL RNA and the Sm proteins. In sum, our data demonstrate an essential and snRNA-selective role of SMN in snRNP biogenesis in vivo and strongly argue for a nucleoplasmic Sm core assembly of the SL RNP.

Cell homeostasis in a Leishmania major mutant overexpressing the spliced leader RNA is maintained by an increased proteolytic activity

Although several stage-specific genes have been identified in Leishmania, the molecular mechanisms governing developmental gene regulation in this organism are still not well understood. We have previously reported an attenuation of virulence in Leishmania major and L. braziliensis carrying extra-copies of the spliced leader RNA gene. Here, we surveyed the major differences in proteome and transcript expression profiles between the spliced leader RNA overexpressor and control lines using two-dimensional gel electrophoresis and differential display reverse transcription PCR, respectively. Thirty-nine genes related to stress response, cytoskeleton, proteolysis, cell cycle control and proliferation, energy generation, gene transcription, RNA processing and post-transcriptional regulation have abnormal patterns of expression in the spliced leader RNA overexpressor line. The evaluation of proteolytic pathways in the mutant revealed a selective increase of cysteine protease activity and an exacerbated ubiquitin-labeled protein population. Polysome profile analysis and measurement of cellular protein aggregates showed that protein translation in the spliced leader RNA overexpressor line is increased when compared to the control line. We found that L. major promastigotes maintain homeostasis in culture when challenged with a metabolic imbalance generated by spliced leader RNA surplus through modulation of intracellular proteolysis. However, this might interfere with a fine-tuned gene expression control necessary for the amastigote multiplication in the mammalian host.

Gene expression in trypanosomatid parasites

The parasites Leishmania spp., Trypanosoma brucei, and Trypanosoma cruzi are the trypanosomatid protozoa that cause the deadly human diseases leishmaniasis, African sleeping sickness, and Chagas disease, respectively. These organisms possess unique mechanisms for gene expression such as constitutive polycistronic transcription of protein-coding genes and trans-splicing. Little is known about either the DNA sequences or the proteins that are involved in the initiation and termination of transcription in trypanosomatids. In silico analyses of the genome databases of these parasites led to the identification of a small number of proteins involved in gene expression. However, functional studies have revealed that trypanosomatids have more general transcription factors than originally estimated. Many posttranslational histone modifications, histone variants, and chromatin modifying enzymes have been identified in trypanosomatids, and recent genome-wide studies showed that epigenetic regulation might play a very important role in gene expression in this group of parasites. Here, we review and comment on the most recent findings related to transcription initiation and termination in trypanosomatid protozoa.

Dinoflagellate spliced leader RNA genes display a variety of sequences and genomic arrangements

Spliced leader (SL) trans-splicing is a common mRNA processing mechanism in dinoflagellates, in which a 22-nt sequence is transferred from the 5'-end of a small noncoding RNA, the SL RNA, to the 5'-end of mRNA molecules. Although the SL RNA gene was shown initially to be organized as tandem repeats with transcripts of 50-60 nt, shorter than most of their counterparts in other organisms, other gene organizations and transcript lengths were reported subsequently. To address the evolutionary gradient of gene organization complexity, we thoroughly examined transcript and gene organization of the SL RNA in a phylogenetically and ecologically diverse group of dinoflagellates representing four Orders. All these dinoflagellates possessed SL RNA transcripts of 50-60 nt, although in one species additional transcripts of up to 92 nt were also detected. At the genomic level, various combinations of SL RNA and 5S rRNA tandem gene arrays, including SL RNA-only, 5S rRNA-only, and mixed SL RNA-5S rRNA (SL-5S) clusters, were amplified by polymerase chain reaction for six dinoflagellates, containing intergenic spacers ranging from 88 bp to over 1.2 kb. Of these species, no SL-5S cluster was detected in Prorocentrum minimum, and only Karenia brevis showed the U6 small nuclear RNA gene associated with these mixed arrays. The 5S rRNA-only array was also found in three dinoflagellates, along with two SL-5S-adjacent arrangements found in two other species that could represent junctions. Two species contained multimeric SL exon repeats with no associated intron. These results suggest that 1) both the SL RNA tandem repeat and the SL-5S cluster genomic organizations are an "ancient" and widespread feature within the phylum of dinoflagellates and 2) rampant genomic duplication and recombination are ongoing independently in each dinoflagellate lineage, giving rise to the highly complex and diversified genomic arrangements of the SL RNA gene, while conserving the length and structure of the functional SL RNA.

Hypermethylated cap 4 maximizes Trypanosoma brucei translation

Through trans-splicing of a 39-nt spliced leader (SL) onto each protein-coding transcript, mature kinetoplastid mRNA acquire a hypermethylated 5'-cap structure, but its function has been unclear. Gene deletions for three Trypanosoma brucei cap 2'-O-ribose methyltransferases, TbMTr1, TbMTr2 and TbMTr3, reveal distinct roles for four 2'-O-methylated nucleotides. Elimination of individual gene pairs yields viable cells; however, attempts at double knock-outs resulted in the generation of a TbMTr2-/-/TbMTr3-/- cell line only. Absence of both kinetoplastid-specific enzymes in TbMTr2-/-/TbMTr3-/- lines yielded substrate SL RNA and mRNA with cap 1. TbMTr1-/- translation is comparable with wildtype, while cap 3 and cap 4 loss reduced translation rates, exacerbated by the additional loss of cap 2. TbMTr1-/- and TbMTr2-/-/TbMTr3-/- lines grow to lower densities under normal culture conditions relative to wildtype cells, with growth rate differences apparent under low serum conditions. Cell viability may not tolerate delays at both the nucleolar Sm-independent and nucleoplasmic Sm-dependent stages of SL RNA maturation combined with reduced rates of translation. A minimal level of mRNA cap ribose methylation is essential for trypanosome viability, providing the first functional role for the cap 4.

Genomic rearrangements and transcriptional analysis of the spliced leader-associated retrotransposon in RNA interference-deficient Trypanosoma brucei

The Trypanosoma brucei genome is colonized by the site-specific non-LTR retrotransposon SLACS, or spliced leader-associated conserved sequence, which integrates exclusively into the spliced leader (SL) RNA genes. Although there is evidence that the RNA interference (RNAi) machinery regulates SLACS transcript levels, we do not know whether RNAi deficiency affects the genomic stability of SLACS, nor do we understand the mechanism of SLACS transcription. Here, we report that prolonged culturing of RNAi-deficient T. brucei cells, but not wild-type cells, results in genomic rearrangements of SLACS. Furthermore, two populations of SLACS transcripts persist in RNAi-deficient cells: a full-length transcript of approximately 7 kb and a heterogeneous population of small SLACS transcripts ranging in size from 450 to 550 nt. We provide evidence that SLACS transcription initiates at the +1 of the interrupted SL RNA gene and proceeds into the 5' UTR and open reading frame 1 (ORF1). This transcription is carried out by an RNA polymerase with alpha-amanitin sensitivity reminiscent of SL RNA synthesis and is dependent on the SL RNA promoter. Additionally, we show that both sense and antisense small SLACS transcripts originate from ORF1 and that they are associated with proteins in vivo. We speculate that the small SLACS transcripts serve as substrates for the production of siRNAs to regulate SLACS expression.

Spliced Leader RNA-Mediated trans-Splicing in a Dinoflagellate, Karenia brevis

Spliced leader (SL) trans-splicing is a form of mRNA processing originally described in parasitic kinetoplastids. During this reaction, a short RNA sequence is transferred from the 5'-end of an SL transcript to a splice acceptor site on pre-mRNA molecules. Here we report numerous mRNAs from a dinoflagellate, Karenia brevis, which contain an identical leader sequence at their 5'-terminal end. Furthermore, we have isolated a gene from K. brevis encoding a putative SL RNA containing the conserved splice donor site immediately following the leader sequence. A 1,742-bp DNA fragment encoding a K. brevis 5S gene repeat was found to encode the SL RNA gene, as well as a U6 small nuclear RNA (snRNA) gene, and binding sites for the core components of the splicesome (Sm proteins) involved in RNA splicing. Therefore the K. brevis SL RNA appears to be in a genomic arrangement typical of SL genes in a number of species known to mature their mRNAs by trans-splicing. Additionally, we show that the SL gene exists as a stable snRNA and has a predicted secondary structure typical of SL RNAs. The data presented here support the hypothesis that an SL RNA is present in K. brevis and that maturation of a percentage of mRNAs in K. brevis occurs via a trans-splicing process in which a common SL sequence is added to the 5'-end of mature mRNAs. The occurrence of SL trans-splicing in a dinoflagellate extends the known phylogenetic range of this process.

The promoter and transcribed regions of the Leishmania tarentolae spliced leader RNA gene array are devoid of nucleosomes

BACKGROUND

The spliced leader (SL) RNA provides the 5' m7G cap and first 39 nt for all nuclear mRNAs in kinetoplastids. This small nuclear RNA is transcribed by RNA polymerase II from individual promoters. In Leishmania tarentolae the SL RNA genes reside in two multi-copy tandem arrays designated MINA and MINB. The transcript accumulation from the SL promoter on the drug-selected, episomal SL RNA gene cassette pX-tSL is ~10% that of the genomic array in uncloned L. tarentolae transfectants. This disparity is neither sequence- nor copy-number related, and thus may be due to interference of SL promoter function by epigenetic factors. To explore these possibilities we examined the nucleoplasmic localization of the SL RNA genes as well as their nucleosomal architecture.

RESULTS

The genomic SL RNA genes and the episome did not co-localize within the nucleus. Each genomic repeat contains one nucleosome regularly positioned within the non-transcribed intergenic region. The 363-bp MINA array was resistant to micrococcal nuclease digestion between the -258 and -72 positions relative to the transcription start point due to nucleosome association, leaving the promoter elements and the entire transcribed region exposed for protein interactions. A pattern of ~164-bp protected segments was observed, corresponding to the amount of DNA typically bound by a nucleosome. By contrast, nucleosomes on the pX-tSL episome were randomly distributed over the episomal SL cassette, reducing transcription factor access to the episomal promoter by approximately 74%. Cloning of the episome transfectants revealed a range of transcriptional activities, implicating a mechanism of epigenetic heredity.

CONCLUSION

The disorganized nucleosomes on the pX episome are in a permissive conformation for transcription of the SL RNA cassette approximately 25% of the time within a given parasite. Nucleosome interference is likely the major factor in the apparent transcriptional repression of the SL RNA gene cassette. Coupled with the requirement for run-around transcription that drives expression of the selectable drug marker, transcription of the episomal SL may be reduced even further due to sub-optimal nucleoplasmic localization and initiation complex disruption.

Spliced leader RNA trans-splicing in dinoflagellates

Through the analysis of hundreds of full-length cDNAs from fifteen species representing all major orders of dinoflagellates, we demonstrate that nuclear-encoded mRNAs in all species, from ancestral to derived lineages, are trans-spliced with the addition of the 22-nt conserved spliced leader (SL), DCCGUAGCCAUUUUGGCUCAAG (D = U, A, or G), to the 5' end. SL trans-splicing has been documented in a limited but diverse number of eukaryotes, in which this process makes it possible to translate polycistronically transcribed nuclear genes. In SL trans-splicing, SL-donor transcripts (SL RNAs) contain two functional domains: an exon that provides the SL for mRNA and an intron that contains a spliceosomal (Sm) binding site. In dinoflagellates, SL RNAs are unusually short at 50-60 nt, with a conserved Sm binding motif (AUUUUGG) located in the SL (exon) rather than the intron. The initiation nucleotide is predominantly U or A, an unusual feature that may affect capping, and hence the translation and stability of the recipient mRNA. The core SL element was found in mRNAs coding for a diverse array of proteins. Among the transcripts characterized were three homologs of Sm-complex subunits, indicating that the role of the Sm binding site is conserved, even if the location on the SL is not. Because association with an Sm-complex often signals nuclear import for U-rich small nuclear RNAs, it is unclear how this Sm binding site remains on mature mRNAs without impeding cytosolic localization or translation of the latter. The sequences reported in this paper have been deposited in the GenBank database (accession nos. AF 512889, DQ 864761-DQ 864971, DQ 867053-DQ 867070, DQ 884413-DQ 884451, EF 133854-EF 133905, EF 133961-EF 134003, EF 134083-EF 134402, EF 141835, and EF 143070-EF 143105).

RNAi interference of XPO1 and Sm genes and their effect on the spliced leader RNA in Trypanosoma brucei

In trypanosomes, trans-splicing is a major essential RNA-processing mechanism that involves the addition of a spliced leader sequence to all mRNAs from a small RNA species, known as the spliced leader RNA (SL RNA). SL RNA maturation is poorly understood and it is not clear where assembly with Sm proteins takes place. In this study, we followed the localization of the SL RNA during knockdown of Sm proteins and XPO1, which in metazoa functions in transport of mRNA and U snRNAs from the nucleus to the cytoplasm. We found that XPO1 has no role in SL RNA biogenesis in wild-type cells, or when the cells are depleted of Sm proteins. During Sm depletion, 'defective' SL RNA lacking cap modification at position +4 first accumulates in the nucleus, suggesting that Sm assembly on SL RNA most probably takes place in this compartment. Only after massive nuclear accumulation is the 'defective' SL RNA exported to the cytoplasm to form SL RNP-C, which may be a route to dispose of SL RNA when its normal biogenesis is blocked.

SL1 RNA gene recovery from Enterobius vermicularis ancient DNA in pre-Columbian human coprolites

Enterobius vermicularis, pinworm, is one of the most common helminths worldwide, infecting nearly a billion people at all socio-economic levels. In prehistoric populations the paleoparasitological findings show a pinworm homogeneous distribution among hunter-gatherers in North America, intensified with the advent of agriculture. This same increase also occurred in the transition from nomad hunter-gatherers to sedentary farmers in South America, although E. vermicularis infection encompasses only the ancient Andean peoples, with no record among the pre-Colombian populations in the South American lowlands. However, the outline of pinworm paleoepidemiology has been supported by microscopic finding of eggs recovered from coprolites. Since molecular techniques are precise and sensitive in detecting pathogen ancient DNA (aDNA), and also could provide insights into the parasite evolutionary history, in this work we have performed a molecular paleoparasitological study of E. vermicularis. aDNA was recovered and pinworm 5S rRNA spacer sequences were determined from pre-Columbian coprolites (4110 BC-AD 900) from four different North and South American archaeological sites. The sequence analysis confirmed E. vermicularis identity and revealed a similarity among ancient and modern sequences. Moreover, polymorphisms were identified at the relative positions 160, 173 and 180, in independent coprolite samples from Tulán, San Pedro de Atacama, Chile (1080-950 BC). We also verified the presence of peculiarities (Splicing leader (SL1) RNA sequence, spliced donor site, the Sm antigen biding site, and RNA secondary structure) which characterise the SL1 RNA gene. The analysis shows that the SL1 RNA gene of contemporary pinworms was present in pre-Columbian E. vermicularis by 6110 years ago. We were successful in detecting E. vermicularis aDNA even in coprolites without direct microscopic evidence of the eggs, improving the diagnosis of helminth infections in the past and further pinworm paleoepidemiological studies.

A non-universal transcription factor? The Leishmania tarentolae TATA box-binding protein LtTBP associates with a subset of promoters

In kinetoplastids a 39-nucleotide spliced leader RNA is trans-spliced to the 5' end of nuclear mRNAs before they can be translated, thus the spliced leader is central to gene expression in kinetoplastid biology. The spliced leader RNA genes in Leishmania tarentolae contain promoters with important sites at approximately -60 and -30. A complex forms specifically on the -60 element as shown by electrophoretic mobility shift. The -60 shift complex has an estimated mass of 159 kDa. An L. tarentolae homologue of TATA-binding protein, LtTBP, co-fractionates with the -60 shift complex. Inclusion of anti-LtTBP antiserum in the shift assay disrupts the shift, indicating that LtTBP is a component of the complex that interacts with the TATA-less -60 element of the spliced leader RNA gene promoter. Both LtTBP and LtSNAP50 are found near the spliced leader RNA gene promoter and the promoters important for tRNAAla and/or U2 snRNA gene transcription, as demonstrated by chromatin immunoprecipitation. The LtTBP appears to interact with a subset of promoters in kinetoplastids with an affinity for short transcription units.

Complete cap 4 formation is not required for viability in Trypanosoma brucei

In kinetoplastids spliced leader (SL) RNA is trans-spliced onto the 5' ends of all nuclear mRNAs, providing a universal exon with a unique cap. Mature SL contains an m(7)G cap, ribose 2'-O methylations on the first four nucleotides, and base methylations on nucleotides 1 and 4 (AACU). This structure is referred to as cap 4. Mutagenized SL RNAs that exhibit reduced cap 4 are trans-spliced, but these mRNAs do not associate with polysomes, suggesting a direct role in translation for cap 4, the primary SL sequence, or both. To separate SL RNA sequence alterations from cap 4 maturation, we have examined two ribose 2'-O-methyltransferases in Trypanosoma brucei. Both enzymes fall into the Rossmann fold class of methyltransferases and model into a conserved structure based on vaccinia virus homolog VP39. Knockdown of the methyltransferases individually or in combination did not affect growth rates and suggests a temporal placement in the cap 4 formation cascade: TbMT417 modifies A(2) and is not required for subsequent steps; TbMT511 methylates C(3), without which U(4) methylations are reduced. Incomplete cap 4 maturation was reflected in substrate SL and mRNA populations. Recombinant methyltransferases bind to a methyl donor and show preference for m(7)G-capped RNAs in vitro. Both enzymes reside in the nucleoplasm. Based on the cap phenotype of substrate SL stranded in the cytosol, A(2), C(3), and U(4) methylations are added after nuclear reimport of Sm protein-complexed substrate SL RNA. As mature cap 4 is dispensable for translation, cap 1 modifications and/or SL sequences are implicated in ribosomal interaction.

The Trypanosoma brucei La protein is a candidate poly(U) shield that impacts spliced leader RNA maturation and tRNA intron removal

By virtue of its preferential binding to poly(U) tails on small RNA precursors and nuclear localisation motif, the La protein has been implicated for a role in the stabilisation and nuclear retention of processing intermediates for a variety of small RNAs in eukaryotic cells. As the universal substrate for trans-splicing, the spliced leader RNA is transcribed as a precursor with just such a tail. La protein was targeted for selective knockdown by inducible RNA interference in Trypanosoma brucei. Of three RNA interference strategies employed, a p2T7-177 vector was the most effective in reducing both the La mRNA as well as the protein itself from induced cells. In the relative absence of La protein T. brucei cells were not viable, in contrast to La gene knockouts in yeast. A variety of potential small RNA substrates were examined under induction, including spliced leader RNA, spliced leader associated RNA, the U1, U2, U4, and U6 small nuclear RNAs, 5S ribosomal RNA, U3 small nucleolar RNA, and tRNATyr. None of these molecules showed significant variance in size or abundance in their mature forms, although a discrete subset of intermediates appear for spliced leader RNA and tRNATyr intron splicing under La depletion conditions. 5'-end methylation in the spliced leader RNA and U1 small nuclear RNA was unaffected. The immediate cause of lethality in T. brucei was not apparent, but may represent a cumulative effect of multiple defects including processing of spliced leader RNA, tRNATyr and other unidentified RNA substrates. This study indicates that La protein binding is not essential for maturation of the spliced leader RNA, but does not rule out the presence of an alternative processing pathway that could compensate for the absence of normally-associated La protein.

Intragenomic spliced leader RNA array analysis of kinetoplastids reveals unexpected transcribed region diversity in Trypanosoma cruzi

The spliced leader RNA gene (SL RNA) repeat is present in large multicopy arrays and has been used as a marker for the diversity of kinetoplastid protozoans. Intra-array variation could affect conclusions made using a randomly isolated repeat as a marker. We examined the Leishmania major (Friedlin) and Trypanosoma cruzi (CL Brener) genome projects for SL RNA repeat sequences in order to assess their homogeneity and the possible effects of sequence variation on taxonomic interpretation. Of the dozens of distinct sequence classes examined, no single copy would bias clustering analyses with regard to other closely related species or isolates. Six dimorphic sites within the T. cruzi transcribed region were found to be linked and are predicted to yield a heterogeneous SL RNA population. The variation that exists among the repeats paints a picture of the broad mechanisms of array maintenance and evolution where site-specific mutations in a single repeat may be spread throughout the array and recombined with existing repeats to create new sequence classes, all occurring under selective pressure to maintain or increase the fitness of the cell line in which these events occur.

Spliced Leader RNA–Mediated trans-Splicing in Phylum Rotifera

In kinetoplastids, Euglena, and four metazoan phyla, trans-splicing has been described as a mechanism for the generation of mature messenger RNAs (mRNAs): 5'-ends of precursor mRNAs are replaced by a short spliced leader (SL) exon from a small SL RNA. Although the full phylogenetic range is unknown, trans-splicing has not been found in vertebrates, insects, plants, or yeast. In animal groups where it does occur, i.e., nematodes, cnidarians, platyhelminths, and primitive chordates, SL RNAs do not show sequence relatedness across phyla. The apparently sporadic phylogenetic distribution and the lack of SL RNA homology have led to opposing hypotheses on its evolution, involving either an ancient origin followed by loss in multiple lineages or independent acquisition in several taxa. Here we present evidence for the occurrence of trans-splicing in bdelloid rotifers (Bdelloidea, Rotifera). A common 23-nt sequence, representing the SL exon-diagnostic of SL RNA-mediated trans-splicing-was found at the 5'-end of at least 50%-65% of mRNAs from Adineta ricciae and Philodina sp. The trans-splicing pattern in bdelloid rotifers can be unusually complex, as observed in transcripts from a heat shock protein gene, hsp82-1, where the SL exon was spliced to three alternative positions. Bdelloid rotifer SL RNAs were found to be 105 or 106 nt long and comprised the SL sequence, a conserved splice donor site and an intron containing a putative spliceosome-binding motif. Intriguingly, some similarity of rotifer SL RNA sequence and predicted secondary structure was seen to that of the predominant SL1 RNA of nematodes, although it is unlikely that this demonstrates homology. In addition, sequence corresponding to the rotifer SL exon was found at the 5'-end of a number of full-length complementary DNA (cDNA) clones in a rice (Oryza sativa) database. None of these cDNAs gave a close match with homologous plant genes, suggesting that a small but significant portion of the rice expressed sequence tag database represents sequences derived from rotifers. In summary, the description of SL-mediated trans-splicing in Rotifera extends its representation to at least five metazoan phyla, making it increasingly probable that this is a phylogenetically widespread and therefore ancient phenomenon.

3'-End polishing of the kinetoplastid spliced leader RNA is performed by SNIP, a 3'-->5' exonuclease with a Motley assortment of small RNA substrates

In all trypanosomatids, trans splicing of the spliced leader (SL) RNA is a required step in the maturation of all nucleus-derived mRNAs. The SL RNA is transcribed with an oligo-U 3' extension that is removed prior to trans splicing. Here we report the identification and characterization of a nonexosomal, 3'-->5' exonuclease required for SL RNA 3'-end formation in Trypanosoma brucei. We named this enzyme SNIP (for snRNA incomplete 3' processing). The central 158-amino-acid domain of SNIP is related to the exonuclease III (ExoIII) domain of the 3'-->5' proofreading epsilon subunit of Escherichia coli DNA polymerase III holoenzyme. SNIP had a preference for oligo(U) 3' extensions in vitro. RNA interference-mediated knockdown of SNIP resulted in a growth defect and correlated with the accumulation of one- to two- nucleotide 3' extensions of SL RNA, U2 and U4 snRNAs, a five-nucleotide extension of 5S rRNA, and the destabilization of U3 snoRNA and U2 snRNA. SNIP-green fluorescent protein localized to the nucleoplasm, and substrate SL RNA derived from SNIP knockdown cells showed wild-type cap 4 modification, indicating that SNIP acts on SL RNA after cytosolic trafficking. Since the primary SL RNA transcript was not the accumulating species in SNIP knockdown cells, SL RNA 3'-end formation is a multistep process in which SNIP provides the ultimate 3'-end polishing. We speculate that SNIP is part of an organized nucleoplasmic machinery responsible for processing of SL RNA.

Transcription initiation and termination on Leishmania major chromosome 3

Genome projects involving Leishmania and other trypanosomatids have revealed that most genes in these organisms are organized into large clusters of genes on the same DNA strand. We have previously shown that transcription of the entire Leishmania major Friedlin (LmjF) chromosome 1 (chr1) initiates bidirectionally between two divergent gene clusters. Here, we analyze transcription of LmjF chr3, which contains two convergent clusters of 67 and 30 genes, separated by a tRNA gene, with a single divergent protein-coding gene located close to the "left" telomere. Nuclear run-on analyses indicate that specific transcription of chr3 initiates bidirectionally between the single subtelomeric gene and the adjacent 67-gene cluster, close to the "right" telomere upstream of the 30-gene cluster, and upstream of the tRNA gene. Transcription on both strands terminates within the tRNA-gene region. Transient-transfection studies support the role of the tRNA-gene region as a transcription terminator for RNA polymerase II (Pol II) and Pol III, and also for Pol I.

Spliced-leader RNA trans splicing in a chordate, Oikopleura dioica, with a compact genome

trans splicing of a spliced-leader RNA (SL RNA) to the 5' ends of mRNAs has been shown to have a limited and sporadic distribution among eukaryotes. Within metazoans, only nematodes are known to process polycistronic pre-mRNAs, produced from operon units of transcription, into mature monocistronic mRNAs via an SL RNA trans-splicing mechanism. Here we demonstrate that a chordate with a highly compact genome, Oikopleura dioica, now joins Caenorhabditis elegans in coupling trans splicing with processing of polycistronic transcipts. We identified a single SL RNA which associates with Sm proteins and has a trimethyl guanosine cap structure reminiscent of spliceosomal snRNPs. The same SL RNA, estimated to be trans-spliced to at least 25% of O. dioica mRNAs, is used for the processing of both isolated or first cistrons and downstream cistrons in a polycistronic precursor. Remarkably, intercistronic regions in O. dioica are far more reduced than those in either nematodes or kinetoplastids, implying minimal cis-regulatory elements for coupling of 3'-end formation and trans splicing.

Transcription in kinetoplastid protozoa: why be normal?

Transcription in the kinetoplastid protozoa shows substantial variation from the paradigms of eukaryotic gene expression, including polycistronic transcription, a paucity of RNA polymerase (RNAP) II promoters, no qualitative regulated transcription initiation for most protein-coding genes, transcription of some protein-coding genes by RNAP I, an exclusive subnuclear location for VSG transcription, the dependence of small nuclear RNA gene transcription on an upstream tRNA gene, and the synthesis of mitochondrial tRNAs in the nucleus. Here, we present a broad overview of what is known about transcription in the kinetoplastids and what has yet to be determined.

SmD1 is required for spliced leader RNA biogenesis

The Sm-binding site of the kinetoplastid spliced leader RNA has been implicated in accurate spliced leader RNA maturation and trans-splicing competence. In Trypanosoma brucei, RNA interference-mediated knockdown of SmD1 caused defects in spliced leader RNA maturation, displaying aberrant 3'-end formation, partial formation of cap 4, and overaccumulation in the cytoplasm; U28 pseudouridylation was unaffected.

Silencing of Sm proteins in Trypanosoma brucei by RNA interference captured a novel cytoplasmic intermediate in spliced leader RNA biogenesis

In Trypanosoma brucei the small nuclear (sn) RNAs U1, U2, U4, and U5, as well as the spliced leader (SL) RNA, bind the seven Sm canonical proteins carrying the consensus Sm motif. To determine the function of these proteins in snRNA and SL RNA biogenesis, two of the Sm core proteins, SmE and SmD1, were silenced by RNAi. Surprisingly, whereas the level of all snRNAs, including U1, U2, U4, and U5 was reduced during silencing, the level of SL RNA was dramatically elevated, but the levels of U6 and spliced leader-associated RNA (SLA1) remained unchanged. The SL RNA that had accumulated in silenced cells lacked modification at the cap4 nucleotide but harbored modifications at the cap1 and cap2 nucleotides and carried the characteristic psi. This SL RNA possessed a longer tail and had accumulated in the cytoplasm in 10 and 50 S particles that were found by in situ hybridization to be present in "speckles." We propose a model for SL RNA biogenesis involving a cytoplasmic phase and suggest that the trypanosome-specific "cap4" nucleotides function as a signal for export and import of SL RNA out and into the nucleus. The SL RNA biogenesis pathway differs from that of U sn ribonucleoproteins (RNPs) in that it is the only RNA that binds Sm proteins that were stabilized under Sm depletion in a novel RNP, which we termed SL RNP-C.

The Leishmania tarentolae spliced leader contains determinants for association with polysomes

In kinetoplastids, every nuclear-derived mRNA contains an identical 39-nucleotide (nt) spliced leader at its 5'-terminus. The spliced leader is derived from substrate spliced leader RNA and joined to pre-mRNA by trans-splicing, thus providing mature mRNAs with an m7G cap and additional methylations referred to as cap 4. It was shown previously that mutations spanning nucleotides 10-39 of the spliced leader did not affect substrate spliced leader RNA transcription or trans-splicing in Leishmania tarentolae (Saito, R. M., Elgort, M. G., and Campbell, D. A. (1994) EMBO J. 13, 5460-5469). In this study we examined these sequences for a possible role in translation by assaying the association of mRNAs, which possess mutated spliced leaders, with polysomes. For the nt 28-39 mutated spliced leaders, both the substrate spliced leader RNA and the spliced leader demonstrated a wild-type methylation pattern; spliced nt 28-39 mRNA was found in polysomes. Thus, the nt 28-39 region conserved primary sequence is not a determinant of polysome association. An undermethylated cap 4 structure was present on substrate and mRNA spliced leaders in nt 20-29 mutated exons; nt 20-29 mRNA was not present in polysomes. A differential pattern of cap 4 methylation was seen between the nt 10-19 substrate spliced leader RNA and the nt 10-19 spliced leaders found in the poly(A)+ population of RNA; the nt 10-19 mRNA was not seen in polysomes. Undermethylated spliced leaders did not associate efficiently with polysomes, suggesting a requirement for the cap 4 and/or primary sequence of the spliced leader in translation. This is the first report demonstrating that the spliced leader contains critical structural or sequence determinants for association with polysomes and, hence, translation.

A new species of trypanosome, Trypanosoma desterrensis sp. n., isolated from South American bats

Trypanosomes isolated from South American bats include the human pathogen Trypanosoma cruzi. Other Trypanosoma spp. that have been found exclusively in bats are not well characterized at the DNA sequence level and we have therefore used the SL RNA gene to differentiate and characterize kinetoplastids isolated from bats in South America. A Trypanosoma sp. isolated from hats in southern Brazil was compared with the geographically diverse isolates T. cruzi marinkellei, T. vespertilionis, and T. dionisii. Analysis of the SL RNA gene repeats revealed size and sequence variability among these bat trypanosomes. We have developed hybridization probes to separate these bat isolates and have analysed the DNA sequence data to estimate their relatedness. A new species, Trypanosoma desterrensis sp. n., is proposed, for which a 5S rRNA gene was also found within the SL RNA repeat.

RNA polymerase I transcribes procyclin genes and variant surface glycoprotein gene expression sites in Trypanosoma brucei

In eukaryotes, RNA polymerase (pol) I exclusively transcribes the large rRNA gene unit (rDNA) and mRNA is synthesized by RNA pol II. The African trypanosome, Trypanosoma brucei, represents an exception to this rule. In this organism, transcription of genes encoding the variant surface glycoprotein (VSG) and the procyclins is resistant to alpha-amanitin, indicating that it is mediated by RNA pol I, while other protein-coding genes are transcribed by RNA pol II. To obtain firm proof for this concept, we generated a T. brucei cell line which exclusively expresses protein C epitope-tagged RNA pol I. Using an anti-protein C immunoaffinity matrix, we specifically depleted RNA pol I from transcriptionally active cell extracts. The depletion of RNA pol I impaired in vitro transcription initiated at the rDNA promoter, the GPEET procyclin gene promoter, and a VSG gene expression site promoter but did not affect transcription from the spliced leader (SL) RNA gene promoter. Fittingly, induction of RNA interference against the RNA pol I largest subunit in insect-form trypanosomes significantly reduced the relative transcriptional efficiency of rDNA, procyclin genes, and VSG expression sites in vivo whereas that of SL RNA, alphabeta-tubulin, and heat shock protein 70 genes was not affected. Our studies unequivocally show that T. brucei harbors a multifunctional RNA pol I which, in addition to transcribing rDNA, transcribes procyclin genes and VSG gene expression sites.

Exportin 1 mediates nuclear export of the kinetoplastid spliced leader RNA

The kinetoplastid protozoan spliced leader (SL) RNA is the common substrate pre-mRNA utilized in all trans-splicing reactions. Here we show by fluorescence in situ hybridization that the SL RNA is present in the cytoplasm of Leishmania tarentolae and Trypanosoma brucei. Treatment with the karyopherin-specific inhibitor leptomycin B was toxic to T. brucei and eliminated the cytoplasmic SL RNA, suggesting that cytoplasmic SL RNA was dependent on the nuclear exporter exportin 1 (XPO1). Ectopic expression of xpo1 with a C506S mutation in T. brucei conferred resistance to leptomycin B. A reduction in SL RNA 3' extension removal and 5' methylation of nucleotide U(4) was observed in wild-type T. brucei treated with leptomycin B, suggesting that the cytoplasmic stage is necessary for SL RNA biogenesis. This study demonstrates spatial and mechanistic similarities between the posttranscriptional trafficking of the kinetoplastid protozoan SL RNA and the metazoan cis-spliceosomal small nuclear RNAs.

Two distinct functional spliced leader RNA gene arrays in Leishmania tarentolae are found in several lizard Leishmania species

A second distinct array of spliced leader RNA genes has been found in several Leishmania species particular to lizards. This is the first report of two non-allelic arrays of spliced leader RNA genes within a species cell line. The arrays are identical to each other in their transcribed spliced leader RNA gene sequences, but variable in their non-transcribed spacer sequences. In the two arrays from Leishmania tarentolae UC strain the promoter regions are similar, but not identical, at positions shown previously to be critical for spliced leader RNA transcription. These arrays contain similar numbers of genes and are both transcribed in L. tarentolae in vitro transcription extract as well as in vivo. The -66/-58 regions of both genes, which contain an element of the spliced leader RNA gene promoter, bind proteins likely to be transcription factors in a specific manner. A survey of lizard Leishmania spp. revealed a second spliced leader RNA gene array in three of four species. Phylogenetic analyses of these sequences with each other and with the spliced leader RNA gene sequences of non-lizard Leishmania spp. and their near-relatives showed that the lizard groups are more closely related to each other than to arrays from other Leishmania spp. As the transcripts of the two arrays are identical, they may co-exist to fulfil the substantial requirement for spliced leader RNA production; however, they have the potential for differential usage modulated by their distinct promoter elements. The presence of two distinct spliced leader RNA gene arrays within a single cell type may represent dissociated evolution of two redundant loci, or a previously unsuspected level of control in the post-transcriptional gene expression within some kinetoplastids.

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.

Nuclear gene transcription and chromatin in Trypanosoma brucei

As in other eucaryotes, the nuclear genome in Trypanosoma brucei is organised into silent domains and active domains transcribed by distinct RNA polymerases. The basic mechanisms underlying eucaryotic gene transcription are conserved between humans and yeast, and understood in some detail in these cells. Meanwhile, relatively little is known about the transcription machinery, the chromatin templates or their interactions in trypanosomatids. Here, I discuss and compare nuclear gene transcription in T. brucei with transcription in other eucaryotes focusing in particular on mono-allelic transcription of genes that encode the variant surface glycoproteins.

Diplonema spp. possess spliced leader RNA genes similar to the Kinetoplastida

The phylogenetic placement of the genus Diplonema in relation to fellow phylum members Euglena and Trypanosoma has been uncertain. The spliced leader RNA gene, present in the euglenids and kinetoplastids in distinct forms, was a potential target for resolving this question. The first indication supporting a closer relationship to the kinetoplastids was the recognition of potential spliced leader RNA exon sequences in the genomic DNA of two Diplonema isolates. Examination of total cell RNA revealed transcripts in the anticipated size range at approximately 120 and 130 nt. Specific PCR amplification of a spliced leader RNA gene repeat was performed. The hallmark features of the kinetoplastid-type spliced leader RNA, specifically the 39-nt exon, splice-donor site, Sm-binding site and poly-T tract and the potential to form the requisite stem-loop structures, were found. Diplonema spp. are different from the kinetoplastids by virtue of C residues at positions 4 and 18 in the exon. While the intergenic spacer regions varied in size, each contained the complete sequence or remnants of a 5S ribosomal RNA gene. Possession of a functional spliced leader RNA gene of the kinetoplastid variety in Diplonema supports a closer evolutionary relationship with this group than with the euglenids.

Trypanosome spliced leader RNA genes contain the first identified RNA polymerase II gene promoter in these organisms

Typical general transcription factors, such as TATA binding protein and TFII B, have not yet been identified in any member of the Trypanosomatidae family of parasitic protozoa. Interestingly, mRNA coding genes do not appear to have discrete transcriptional start sites, although in most cases they require an RNA polymerase that has the biochemical properties of eukaryotic RNA polymerase II. A discrete transcription initiation site may not be necessary for mRNA synthesis since the sequences upstream of each transcribed coding region are trimmed from the nascent transcript when a short m(7)G-capped RNA is added during mRNA maturation. This short 39 nt m(7)G-capped RNA, the spliced leader (SL) sequence, is expressed as an approximately 100 nt long RNA from a set of reiterated, though independently transcribed, genes in the trypanosome genome. Punctuation of the 5' end of mRNAs by a m(7)G cap-containing spliced leader is a developing theme in the lower eukaryotic world; organisms as diverse as EUGLENA: and nematode worms, including Caenorhabditis elegans, utilize SL RNA in their mRNA maturation programs. Towards understanding the coordination of SL RNA and mRNA expression in trypanosomes, we have begun by characterizing SL RNA gene expression in the model trypanosome Leptomonas seymouri. Using a homologous in vitro transcription system, we demonstrate in this study that the SL RNA is transcribed by RNA polymerase II. During SL RNA transcription, accurate initiation is determined by an initiator element with a loose consensus of CYAC/AYR(+1). This element, as well as two additional basal promoter elements, is divergent in sequence from the basal transcription elements seen in other eukaryotic gene promoters. We show here that the in vitro transcription extract contains a binding activity that is specific for the initiator element and thus may participate in recruiting RNA polymerase II to the SL RNA gene promoter.

Tetracycline regulated gene expression in Leishmania donovani

The prokaryotic tetracycline-responsive repressor/operator system has proven to be useful for studying the function of essential genes and the expression of toxic gene products in a number of organisms, including Trypanosoma brucei. We report here the adaptation of this system for use in Leishmania. The inducible promoter construct contains a bleomycin resistance-luciferase fusion (BLE-LUC) gene driven by an rRNA promoter with two copies of the TetO sequence inserted two nucleotides upstream of the transcriptional start site. This construct showed regulation of BLE-LUC expression by two orders of magnitude when targeted into the rDNA locus in the reverse orientation relative to transcription of the rRNA genes in a Leishmania donovani cell line expressing TETR. The luciferase expression level in the absence of tetracycline was approximately 50-fold lower than that in the tubulin locus (where it is transcribed by pol II), while the expression level in the presence of tetracycline was approximately five-fold higher than that from the tubulin locus. There was no linear relationship between the level of TETR expression and the regulation, and changing of positions of operator did not increase regulation.

In vitro transcription of mutated Leishmania tarentolae spliced leader RNA genes approximates in vivo patterns

To elucidate the process of transcription in the kinetoplastids and to aid in the purification of transcription factors, we have developed a transcriptionally-competent nuclear extract from Leishmania tarentolae for the study of the spliced leader (SL) RNA gene. The extract was competent to transcribe a tagged SL RNA gene. The in vitro SL RNA transcripts initiated accurately and their synthesis was dependent on the presence of the promoter defined in vivo. The nuclear extract was then challenged rigorously using an exhaustive set of mutated SL RNA gene templates previously tested for transcriptional activity in vivo. Mutation of four nucleotides (CCGG) at positions -34 to -31 had a detrimental effect on transcription in vitro: the CC dinucleotide overlaps one element necessary in vivo. Similarly. four nucleotides (TGAC; positions -67 to -64) important for transcription in vitro overlapped the other core promoter element defined in vivo, but were generally not effective as point mutations. The promoter-binding ability of the transcriptionally-competent extract for the -60 region mutations mirrored the in vitro transcription pattern. Although it does not reflect precisely the in vivo results, this in vitro system provides us with an important tool for monitoring the purification of potential transcription factors, as well as the basis for future reconstitution experiments.