Characterization of two protein activities that interact at the promoter of the trypanosomatid spliced leader RNA

TBP and SNAP50 transcription factors bind specifically to the Pr77 promoter sequence from trypanosomatid non-LTR retrotransposons

Background

Trypanosomatid genomes are colonized by active and inactive mobile DNA elements, such as LINE, SINE-like, SIDER and DIRE retrotransposons. These elements all share a 77-nucleotide-long sequence at their 5′ ends, known as Pr77, which activates transcription, thereby generating abundant unspliced and translatable transcripts. However, transcription factors that mediates this process have still not been reported.

Methods

TATA-binding protein (TBP) and small nuclear RNA-activating protein 50 kDa (SNAP50) recombinant proteins and specific antibodies raised against them were generated. Protein capture assay, electrophoretic mobility-shift assays (EMSA) and EMSA competition assays carried out using these proteins and nuclear proteins of the parasite together to specific DNA sequences used as probes allowed detecting direct interaction of these transcription factors to Pr77 sequence.

Results

This study identified TBP and SNAP50 as part of the DNA-protein complex formed by the Pr77 promoter sequence and nuclear proteins of Trypanosoma cruzi. TBP establishes direct and specific contact with the Pr77 sequence, where the DPE and DPE downstream regions are docking sites with preferential binding. TBP binds cooperatively (Hill coefficient = 1.67) to Pr77 and to both strands of the Pr77 sequence, while the conformation of this highly structured sequence is not involved in TBP binding. Direct binding of SNAP50 to the Pr77 sequence is weak and may be mediated by protein–protein interactions through other trypanosomatid nuclear proteins.

Conclusions

Identification of the transcription factors that mediate Pr77 transcription may help to elucidate how these retrotransposons are mobilized within the trypanosomatid genomes and their roles in gene regulation processes in this human parasite.

Graphic abstract

Supplementary Information

The online version contains supplementary material available at 10.1186/s13071-021-04803-5.

Transcriptional regulation of snRNAs and its significance for plant development

Small nuclear RNA (snRNA) represents a distinct class of non-coding RNA molecules. As these molecules have fundamental roles in RNA metabolism, including pre-mRNA splicing and ribosomal RNA processing, it is essential that their transcription be tightly regulated in eukaryotic cells. The genome of each organism contains hundreds of snRNA genes. Although the structures of these genes are highly diverse among organisms, the trans-acting factors that regulate snRNA transcription are evolutionarily conserved. Recent studies of the Arabidopsis thaliana srd2-1 mutant, which is defective in the snRNA transcription factor, provide insight into the physiological significance of snRNA regulation in plant development. Here, I review the current understanding of the molecular mechanisms underlying snRNA transcription.

Trans-acting proteins regulating mRNA maturation, stability and translation in trypanosomatids

In trypanosomatids, alterations in gene expression in response to intrinsic or extrinsic signals are achieved through post-transcriptional mechanisms. In the last 20 years, research has concentrated on defining the responsible cis-elements in the untranslated regions of several regulated mRNAs. More recently, the focus has shifted towards the identification of RNA-binding proteins that act as trans-acting factors. Trypanosomatids have a large number of predicted RNA-binding proteins of which the vast majority have no orthologues in other eukaryotes. Several RNA-binding proteins have been shown to bind and/or regulate the expression of a group of mRNAs that code for functionally related proteins, indicating the possible presence of co-regulated mRNA cohorts.

SL RNA genes of the ascidian tunicates Ciona intestinalis and Ciona savignyi

We characterized by bioinformatics the trans-spliced leader donor RNA (SL RNA) genes of two ascidians, Ciona intestinalis and Ciona savignyi. The Ciona intestinalis genome contains approximately 670 copies of the SL RNA gene, principally on a 264-bp tandemly repeated element. Fluorescent in-situ hybridization mapped most of the repeats to a single site on the short arm of chromosome 8. The Ciona intestinalis genome also contains approximately 100 copies of a >3.6-kb element that carries 1) an SL RNA-related sequence (possible a pseudogene) and 2) genes for the U6 snRNA and a histone-like protein. The Ciona savignyi genome contains two SL RNA gene classes having the same SL sequence as Ciona intestinalis but differing in the intron-like segments. These reside in similar but distinct repeat units of 575 bp ( approximately 410 copies) and 552 bp ( approximately 250 copies) that are arranged as separate tandem repeats. In neither Ciona species is the 5S RNA gene present within the SL RNA gene repeat unit. Although the number of SL RNA genes is similar, there is little sequence similarity between the intestinalis and savignyi repeat units, apart from the region encoding the SL RNA itself. This suggests that cis-regulatory elements involved in transcription and 3'-end processing are likely to be present within the transcribed region. The genomes of both Ciona species also include > 100 dispersed short elements containing the 16-nt SL sequence and up to 6 additional nucleotides of the SL RNA sequence.

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.

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.

Characterization of a new gene (SLC10) with a spliced leader from Taenia solium

An unknown gene, SLC10, was cloned by spliced leader-based polymerase chain reaction from Taenia solium. The full length of SLC10 was found to be 635 bp, encoding an 18.223 kDa protein. ELISA results showed that none of 70 normal and 75 cysticercosis sera samples reacted with purified recombinant SLC10 protein. Using an immunohistochemical method, it was revealed that the native SLC10 protein distributed extensively in inner cyst walls but not in the scolex in Cysticercus cellulosae. Together with predicted results, it is suggested that the SLC10 protein is a non-secretory structural protein, which is not involved in induction of the host's immune reactions against infection at least at the larval stage.

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.

A divergent transcription factor TFIIB in trypanosomes is required for RNA polymerase II-dependent spliced leader RNA transcription and cell viability

Transcription by RNA polymerase II in trypanosomes deviates from the standard eukaryotic paradigm. Genes are transcribed polycistronically and subsequently cleaved into functional mRNAs, requiring trans splicing of a capped 39-nucleotide leader RNA derived from a short transcript, the spliced leader (SL) RNA. The only identified trypanosome RNA polymerase II promoter is that of the SL RNA gene. We have previously shown that transcription of SL RNA requires divergent trypanosome homologs of RNA polymerase II, TATA binding protein, and the small nuclear RNA (snRNA)-activating protein complex. In other eukaryotes, TFIIB is an additional key component of transcription for both mRNAs and polymerase II-dependent snRNAs. We have identified a divergent homolog of the usually highly conserved basal transcription factor, TFIIB, from the pathogenic parasite Trypanosoma brucei. T. brucei TFIIB (TbTFIIB) interacted directly with the trypanosome TATA binding protein and RNA polymerase II, confirming its identity. Functionally, in vitro transcription studies demonstrated that TbTFIIB is indispensable in SL RNA gene transcription. RNA interference (RNAi) studies corroborated the essential nature of TbTFIIB, as depletion of this protein led to growth arrest of parasites. Furthermore, nuclear extracts prepared from parasites depleted of TbTFIIB, after the induction of RNAi, required recombinant TbTFIIB to support spliced leader transcription. The information gleaned from TbTFIIB studies furthers our understanding of SL RNA gene transcription and the elusive overall transcriptional processes in trypanosomes.

Trypanosomal TBP functions with the multisubunit transcription factor tSNAP to direct spliced-leader RNA gene expression

Protein-coding genes of trypanosomes are mainly transcribed polycistronically and cleaved into functional mRNAs in a process that requires trans splicing of a capped 39-nucleotide RNA derived from a short transcript, the spliced-leader (SL) RNA. SL RNA genes are individually transcribed from the only identified trypanosome RNA polymerase II promoter. We have purified and characterized a sequence-specific SL RNA promoter-binding complex, tSNAP(c), from the pathogenic parasite Trypanosoma brucei, which induces robust transcriptional activity within the SL RNA gene. Two tSNAP(c) subunits resemble essential components of the metazoan transcription factor SNAP(c), which directs small nuclear RNA transcription. A third subunit is unrelated to any eukaryotic protein and identifies tSNAP(c) as a unique trypanosomal transcription factor. Intriguingly, the unusual trypanosome TATA-binding protein (TBP) tightly associates with tSNAPc and is essential for SL RNA gene transcription. These findings provide the first view of the architecture of a transcriptional complex that assembles at an RNA polymerase II-dependent gene promoter in a highly divergent eukaryote.

Actively transcribing RNA polymerase II concentrates on spliced leader genes in the nucleus of Trypanosoma cruzi

RNA polymerase II of trypanosomes, early diverging eukaryotes, transcribes long polycistronic messages, which are not capped but are processed by trans-splicing and polyadenylation to form mature mRNAs. The same RNA polymerase II also transcribes the genes coding for the spliced leader RNA, which are capped, exported to the cytoplasm, processed, and reimported into the nucleus before they are used as splicing donors to form mRNAs from pre-mRNA polycistronic transcripts. As pre-mRNA and spliced leader transcription events appear to be uncoupled, we studied how the RNA polymerase II is distributed in the nucleus of Trypanosoma cruzi. Using specific antibodies to the T. cruzi RNA polymerase II unique carboxy-terminal domain, we demonstrated that large amounts of the enzyme are found concentrated in a domain close to the parasite nucleolus and containing the spliced leader genes. The remaining RNA polymerase II is diffusely distributed in the nucleoplasm. The spliced leader-associated RNA polymerase II localization is dependent on the cell transcriptional state. It disperses when transcription is blocked by alpha-amanitin and actinomycin D. Tubulin genes are excluded from this domain, suggesting that it may exclusively be the transcriptional site of spliced leader genes. Trypomastigote forms of the parasite, which have reduced spliced leader transcription, show less RNA polymerase II labeling, and the spliced leader genes are more dispersed in the nucleoplasm. These results provide strong evidences that transcription of spliced leader RNAs occurs in a particular domain in the T. cruzi nucleus.

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.

The Trypanosoma brucei spliced leader RNA and rRNA gene promoters have interchangeable TbSNAP50-binding elements

In the protist parasite Trypanosoma brucei, the small nuclear spliced leader (SL) RNA and the large rRNAs are key molecules for mRNA maturation and protein synthesis, respectively. The SL RNA gene (SLRNA) promoter recruits RNA polymerase II and consists of a bipartite upstream sequence element (USE) and an element close to the transcription initiation site. Here, we analyzed the distal part of the ribosomal (RRNA) promoter and identified two sequence blocks which, in reverse orientation, closely resemble the SLRNA USE by both sequence and spacing. A detailed mutational analysis revealed that the ribosomal (r)USE is essential for efficient RRNA transcription in vivo and that it functions in an orientation-dependent manner. Moreover, we showed that USE and rUSE are functionally interchangeable and that rUSE stably interacted with an essential factor of SLRNA transcription. Finally, we demonstrated that the T.brucei homolog of the recently characterized transcription factor p57 of the related organism Leptomonas seymouri specifically bound to USE and rUSE. Since p57 and its T.brucei counterpart are homologous to SNAP50, a component of the human small nuclear RNA gene activation protein complex (SNAPc), both SLRNA and RRNA transcription in T.brucei may depend on a SNAPc-like transcription factor.

RNA polymerase II-dependent transcription in trypanosomes is associated with a SNAP complex-like transcription factor

Spliced leader RNA transcription is essential for cell viability in trypanosomes. The SL RNA genes are expressed from the only defined RNA polymerase II-dependent promoter identified to date in the trypanosome genome. The SL RNA gene promoter has been shown by in vitro and in vivo analyses to have a tripartite architecture. The upstream most cis-acting element, called PBP-1E, is located between 70 and 60 bp upstream from the transcription start site. This essential element functions along with two downstream elements to direct efficient and proper initiation of transcription. Electrophoretic mobility-shift studies detected a 122-kDa protein, called PBP-1, which interacts with PBP-1E. This protein is the first sequence-specific, double-stranded DNA-binding protein isolated in trypanosomes. Three polypeptides copurify with PBP-1 activity, suggesting that PBP-1 is composed of 57-, 46-, and 36-kDa subunits. We have cloned the genes that encode the 57- and 46-kDa subunits. The 46-kDa protein is a previously uncharacterized protein and may be unique to trypanosomes. Its predicted tertiary structure suggests it binds DNA as part of a complex. The 57-kDa subunit is orthologous to the human small nuclear RNA-activating protein (SNAP)50, which is an essential subunit of the SNAP complex (SNAPc). In human cells, SNAPc binds to the proximal sequence element in both RNA polymerase II- and III-dependent small nuclear RNA gene promoters. These findings identify a surprising link in the transcriptional machinery across a large evolutionary distance in the regulation of small nuclear RNA genes in eukaryotes.

Identification of mRNA decapping activities and an ARE-regulated 3' to 5' exonuclease activity in trypanosome extracts

mRNA turnover is a regulated process that contributes to the steady state level of cytoplasmic mRNA. The amount of each mRNA determines, to a large extent, the amount of protein produced by that particular transcript. In trypanosomes, there is little transcriptional regulation; therefore, differential mRNA stability significantly contributes to mRNA levels in each stage of the parasite life cycle. To investigate the enzymatic activities that contribute to mRNA turnover, we developed a cell-free system for mRNA turnover using the trypanosome Leptomonas seymouri. We identified a decapping activity that removed m(7)GDP from mRNAs that contain an m(7)GpppN cap at their 5' end. In yeast, the release of m(7)GDP by the pyrophosphatase Dcp1p/Dcp2p is a rate-limiting step in mRNA turnover. A secondary enzymatic activity, similar to the human cap scavenger activity, was identified in the trypanosome extracts. Both the human and trypanosome scavenger activities generate m(7)GMP from short capped RNA and are inhibited by addition in trans of m(7)GpppG. A third enzymatic activity uncovered in the parasite extracts functioned as a 3' to 5' exonuclease. Importantly, this exonuclease activity was stimulated by an AU-rich element present in the RNA. In summary, the cell-free system has defined several RNA turnover steps that likely contribute to regulated mRNA decay in trypanosomes.

The Leptomonas seymouri spliced leader RNA promoter requires a novel transcription factor

The spliced leader RNA gene promoter in Leptomonas seymouri requires three promoter elements for efficient and accurate transcription of the spliced leader RNA. The upstream most element appears to have a functional homolog in Leishmania species and in the African trypanosomes. The protein factor, promoter binding protein-1, interacts with the upstream element and appears to function as a basal transcription factor. Promoter binding protein-1 has three subunits; 36, 41 and 57 kDa. Using microsequencing techniques, we have obtained peptide sequence from each subunit. These data have enabled us to recently identify the Leptomonas gene that encodes the 41 kDa subunit. The 41 kDa subunit, comprised of 381 amino acids, is a founding member of a new class of transcription factors since extensive database searches revealed no homology to any known protein. This subunit, encoded by a single copy gene, has a potential nuclear localisation signal at amino acid positions 71-76. There are also multiple dileucine repeats with unknown function. Anti-41 kDa protein polyclonal antibodies are being employed to test the function of the 41 kDa subunit in PBP-1 activities.

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.

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.

PPB1, a putative spliced leader RNA gene transcription factor in Trypanosoma cruzi

In trypanosomatids, the spliced leader RNA, or SL RNA, donates its 5' 39 nucleotides to mature nuclear mRNAs in a process termed trans-splicing. We have previously characterized the SL RNA gene from Trypanosoma cruzi and identified its transcription promoter, including a 14 nt proximal sequence element, or PSE, that binds a putative transcription factor and activates transcription of the gene. Herein, we describe establishment of a yeast one-hybrid system using the 14 nt PSE as bait, and use this system to select T. cruzi cDNAs encoding a putative transcription factor that activates transcription of the SL RNA gene. The cDNA was selected from a normalized library and encodes an approximately 45 kDa putative PSE promoter-binding protein, PPB1. PPB1 in vitro translated or overexpressed in and isolated from transformed E. coli, showed PSE-specific binding activity by electrophoretic mobility shift assays. Finally, overexpression of PPB1 in T. cruzi led to increased expression of the SL RNA gene as well as reporter genes in episomal constructs under the control of the SL RNA gene promoter. These observations suggest that PPB1 is a transcription factor that plays an important role in SL RNA gene expression.

Transcription of the kinetoplastid spliced leader RNA gene

In recent years, much has been learned about the cis-elements controlling transcription of the kinetoplastid spliced leader (SL) RNA gene. The SL RNA gene contains the first 39 nucleotides that are trans-spliced on to all nuclear-derived mRNAs in these organisms. Transcription initiation is determined by two precisely spaced upstream elements and transcription termination is directed by the downstream poly-T tract, although the RNA polymerase responsible for SL RNA synthesis is still questioned. In this article, David Campbell, Nancy Sturm and Michael Yu review the field of kinetoplastid SL RNA gene transcription, address past proposals in light of current data and discuss some of the differences that appear in the literature.

Transcription initiation at the TATA-less spliced leader RNA gene promoter requires at least two DNA-binding proteins and a tripartite architecture that includes an initiator element

Eukaryotic transcriptional regulatory signals, defined as core and activator promoter elements, have yet to be identified in the earliest diverging group of eukaryotes, the primitive protozoans, which include the Trypanosomatidae family of parasites. The divergence within this family is highlighted by the apparent absence of the "universal" transcription factor TATA-binding protein. To understand gene expression in these protists, we have investigated spliced leader RNA gene transcription. The RNA product of this gene provides an m(7)G cap and a 39-nucleotide leader sequence to all cellular mRNAs via a trans-splicing reaction. Regulation of spliced leader RNA synthesis is controlled by a tripartite promoter located exclusively upstream from the transcription start site. Proteins PBP-1 and PBP-2 bind to two of the three promoter elements in the trypanosomatid Leptomonas seymouri. They represent the first trypanosome transcription factors with typical double-stranded DNA binding site recognition. These proteins ensure efficient transcription. However, accurate initiation is determined an initiator element with a a loose consensus of CYAC/AYR (+1), which differs from that found in metazoan initiator elements as well as from that identified in one of the earliest diverging protozoans, Trichomonas vaginalis. Trypanosomes may utilize initiator element-protein interactions, and not TATA sequence-TATA-binding protein interactions, to direct proper transcription initiation by RNA polymerase II.

Single nucleotide resolution of promoter activity and protein binding for the Leishmania tarentolae spliced leader RNA gene

In Kinetoplastid protozoa, trans-splicing is a central step in the maturation of nuclear mRNAs. In Leishmania, a common 39 nt spliced-leader (SL) is transferred via trans-splicing from the precursor 96 nt SL RNA to the 5' terminus of all known protein-encoding RNAs. In this study, promoter elements of the L. tarentolae SL RNA gene have been identified with respect to transcriptional activity and putative transcription factor binding. We have mapped the essential regions in the SL RNA gene promoter at single nucleotide resolution using both in vivo transcription and in vitro protein/DNA binding approaches. Two regions located upstream of the SL RNA gene were identified: a GN3CCC element at -39 to -33 and a GACN5G element at -66 to -58 were essential for SL RNA gene transcription in stably transfected cells. Consistent with other known bipartite promoter elements, the spacing between the GN3CCC and GACN5G elements was found to be critical for proper promoter function and correct transcription start point selection, as was the distance between the two elements and the wild-type transcription start point. The GACN5G element interacts specifically and in a double-stranded form with a protein(s) in Leishmania nuclear extracts. The degree of this protein DNA interaction in vitro correlated with SL RNA gene transcription efficiency in vivo, consistent with a role of the protein as a transcription factor. The core nucleotides GACN5G fit the consensus PSE promoter structure of pol II-transcribed snRNA genes in metazoa.