An essential domain of an early-diverged RNA polymerase II functions to accurately decode a primitive chromatin landscape

A unique feature of RNA polymerase II (RNA pol II) is its long C-terminal extension, called the carboxy-terminal domain (CTD). The well-studied eukaryotes possess a tandemly repeated 7-amino-acid sequence, called the canonical CTD, which orchestrates various steps in mRNA synthesis. Many eukaryotes possess a CTD devoid of repeats, appropriately called a non-canonical CTD, which performs completely unknown functions. Trypanosoma brucei, the etiologic agent of African Sleeping Sickness, deploys an RNA pol II that contains a non-canonical CTD to accomplish an unusual transcriptional program; all protein-coding genes are transcribed as part of a polygenic precursor mRNA (pre-mRNA) that is initiated within a several-kilobase-long region, called the transcription start site (TSS), which is upstream of the first protein-coding gene in the polygenic array. In this report, we show that the non-canonical CTD of T. brucei RNA pol II is important for normal protein-coding gene expression, likely directing RNA pol II to the TSSs within the genome. Our work reveals the presence of a primordial CTD code within eukarya and indicates that proper recognition of the chromatin landscape is a central function of this RNA pol II-distinguishing domain.

High throughput sequencing analysis of Trypanosoma brucei DRBD3/PTB1-bound mRNAs

Trypanosomes are early-branched eukaryotes that show an unusual dependence on post-transcriptional mechanisms to regulate gene expression. RNA-binding proteins are crucial in controlling mRNA fate in these organisms, but their RNA substrates remain largely unknown. Here we have analyzed on a global scale the mRNAs associated with the Trypanosoma brucei RNA-binding protein DRBD3/PTB1, by capturing ribonucleoprotein complexes using UV cross-linking and subsequent immunoprecipitation. DRBD3/PTB1 associates with many transcripts encoding ribosomal proteins and translation factors. Consequently, silencing of DRBD3/PTB1 expression altered the protein synthesis rate. DRBD3/PTB1 also binds to mRNAs encoding the enzymes required to obtain energy through the oxidation of proline to succinate. We hypothesize that DRBD3/PTB1 is a key player in RNA regulon-based gene control influencing protein synthesis in trypanosomes.

The essential polysome-associated RNA-binding protein RBP42 targets mRNAs involved in Trypanosoma brucei energy metabolism

RNA-binding proteins that target mRNA coding regions are emerging as regulators of post-transcriptional processes in eukaryotes. Here we describe a newly identified RNA-binding protein, RBP42, which targets the coding region of mRNAs in the insect form of the African trypanosome, Trypanosoma brucei. RBP42 is an essential protein and associates with polysome-bound mRNAs in the cytoplasm. A global survey of RBP42-bound mRNAs was performed by applying HITS-CLIP technology, which captures protein-RNA interactions in vivo using UV light. Specific RBP42-mRNA interactions, as well as mRNA interactions with a known RNA-binding protein, were purified using specific antibodies. Target RNA sequences were identified and quantified using high-throughput RNA sequencing. Analysis revealed that RBP42 bound mainly within the coding region of mRNAs that encode proteins involved in cellular energy metabolism. Although the mechanism of RBP42's function is unclear at present, we speculate that RBP42 plays a critical role in modulating T. brucei energy metabolism.

Chromatin immunoprecipitation and microarray analysis reveal that TFIIB occupies the SL RNA gene promoter region in Trypanosoma brucei chromosomes

RNA polymerase II (RNAP-II) synthesizes the m(7)G-capped Spliced Leader (SL) RNA and most protein-coding mRNAs in trypanosomes. RNAP-II recruitment to DNA usually requires a set of transcription factors that make sequence-specific contacts near transcriptional start sites within chromosomes. In trypanosomes, the transcription factor TFIIB is necessary for RNAP-II-dependent SL RNA transcription. However, the trypanosomal TFIIB (tTFIIB) lacks the highly basic DNA binding region normally found in the C-terminal region of TFIIB proteins. To assess the precise pattern of tTFIIB binding within the SL RNA gene locus, as well as within several other loci, we performed chromatin immunoprecipitation/microarray analysis using a tiled gene array with a probe spacing of 10 nucleotides. We found that tTFIIB binds non-randomly within the SL RNA gene locus mainly within a 220-nt long region that straddles the transcription start site. tTFIIB does not bind within the small subunit (SSU) rRNA locus, indicating that trypanosomal TFIIB is not a component of an RNAP-I transcriptional complex. Interestingly, discrete binding sites were observed within the putative promoter regions of two loci on different chromosomes. These data suggest that although trypanosomal TFIIB lacks a highly basic DNA binding region, it nevertheless localizes to discrete regions of chromatin that include the SL RNA gene promoter.

Transcription and mRNA stability: parental guidance suggested

The level of an mRNA within a cell depends on both its rate of synthesis and rate of decay. Now, independent studies by Bregman et al. and Trcek et al. provide evidence that these two processes are integrated. They show that transcription factors and DNA promoters can directly influence the relative stability of transcripts that they produce.

The non-canonical CTD of RNAP-II is essential for productive RNA synthesis in Trypanosoma brucei

The carboxy-terminal domain (CTD) of the largest subunit (RPB1) of RNA polymerase II (RNAP-II) is essential for gene expression in metazoa and yeast. The canonical CTD is characterized by heptapeptide repeats. Differential phosphorylation of canonical CTD orchestrates transcriptional and co-transcriptional maturation of mRNA and snRNA. Many organisms, including trypanosomes, lack a canonical CTD. In these organisms, the CTD is called a non-canonical CTD or pseudo-CTD (ΨCTD. In the African trypanosome, Trypanosoma brucei, the ΨCTD is ∼285 amino acids long, rich in serines and prolines, and phosphorylated. We report that T. brucei RNAP-II lacking the entire ΨCTD or containing only a 95-amino-acid-long ΨCTD failed to support cell viability. In contrast, RNAP-II with a 186-amino-acid-long ΨCTD maintained cellular growth. RNAP-II with ΨCTD truncations resulted in abortive initiation of transcription. These data establish that non-canonical CTDs play an important role in gene expression.

Identification of the HIT-45 protein from Trypanosoma brucei as an FHIT protein/dinucleoside triphosphatase: substrate specificity studies on the recombinant and endogenous proteins

A new member of the FHIT protein family, designated HIT-45, has been identified in the African trypanosome Trypanosoma brucei. Recombinant HIT-45 proteins were purified from trypanosomal and bacterial protein expression systems and analyzed for substrate specificity using various dinucleoside polyphosphates, including those that contain the 5'-mRNA cap, i.e., m(7)GMP. This enzyme exhibited typical dinucleoside triphosphatase activity (EC 3.6.1.29), having its highest specificity for diadenosine triphosphate (ApppA). However, the trypanosome enzyme contains a unique amino-terminal extension, and hydrolysis of cap dinucleotides with monomethylated guanosine or dimethylated guanosine always yielded m(7)GMP (or m(2,7)GMP) as one of the reaction products. Interestingly, m(7)Gpppm(3)(N6, N6, 2'O)A was preferred among the methylated substrates. This hypermethylated dinucleotide is unique to trypanosomes and may be an intermediate in the decay of cap 4, i.e., m(7)Gpppm(3)(N6, N6, 2'O)Apm(2'O)Apm(2'O)Cpm(2)(N3, 2'O)U, that occurs in these organisms.

Predicting consensus structures for RNA alignments via pseudo-energy minimization

Thermodynamic processes with free energy parameters are often used in algorithms that solve the free energy minimization problem to predict secondary structures of single RNA sequences. While results from these algorithms are promising, an observation is that single sequence-based methods have moderate accuracy and more information is needed to improve on RNA secondary structure prediction, such as covariance scores obtained from multiple sequence alignments. We present in this paper a new approach to predicting the consensus secondary structure of a set of aligned RNA sequences via pseudo-energy minimization. Our tool, called RSpredict, takes into account sequence covariation and employs effective heuristics for accuracy improvement. RSpredict accepts, as input data, a multiple sequence alignment in FASTA or ClustalW format and outputs the consensus secondary structure of the input sequences in both the Vienna style Dot Bracket format and the Connectivity Table format. Our method was compared with some widely used tools including KNetFold, Pfold and RNAalifold. A comprehensive test on different datasets including Rfam sequence alignments and a multiple sequence alignment obtained from our study on the Drosophila X chromosome reveals that RSpredict is competitive with the existing tools on the tested datasets. RSpredict is freely available online as a web server and also as a jar file for download at http://datalab.njit.edu/biology/RSpredict.

Detecting conserved secondary structures in RNA molecules using constrained structural alignment

Constrained sequence alignment has been studied extensively in the past. Different forms of constraints have been investigated, where a constraint can be a subsequence, a regular expression, or a probability matrix of symbols and positions. However, constrained structural alignment has been investigated to a much lesser extent. In this paper, we present an efficient method for constrained structural alignment and apply the method to detecting conserved secondary structures, or structural motifs, in a set of RNA molecules. The proposed method combines both sequence and structural information of RNAs to find an optimal local alignment between two RNA secondary structures, one of which is a query and the other is a subject structure in the given set. The method allows a biologist to annotate conserved regions, or constraints, in the query RNA structure and incorporates these regions into the alignment process to obtain biologically more meaningful alignment scores. A statistical measure is developed to assess the significance of the scores. Experimental results based on detecting internal ribosome entry sites in the RNA molecules of hepatitis C virus and Trypanosoma brucei demonstrate the effectiveness of the proposed method and its superiority over existing techniques.

RADAR: a web server for RNA data analysis and research

RADAR is a web server that provides a multitude of functionality for RNA data analysis and research. It can align structure-annotated RNA sequences so that both sequence and structure information are taken into consideration during the alignment process. This server is capable of performing pairwise structure alignment, multiple structure alignment, database search and clustering. In addition, RADAR provides two salient features: (i) constrained alignment of RNA secondary structures, and (ii) prediction of the consensus structure for a set of RNA sequences. RADAR will be able to assist scientists in performing many important RNA mining operations, including the understanding of the functionality of RNA sequences, the detection of RNA structural motifs and the clustering of RNA molecules, among others. The web server together with a software package for download is freely accessible at http://datalab.njit.edu/biodata/rna/RSmatch/server.htm and http://www.ccrnp.ncifcrf.gov/~bshapiro/

Pyrimidine transport activities in trypanosomes

Parasites of the Trypanosomatidae family are unable to synthesize purines. Instead, they rely on their hosts to supply these necessary compounds. The article by Gudin et al. identifies three transport mechanisms of the equilibrative nucleoside transporter family by which nucleosides and nucleobases are transported in this medically important family of organisms. The work by Gudin et al. characterizes the dynamics of these transporters and points to further areas for future genetic and therapeutic experiments.

Spliced-leader RNA silencing: a novel stress-induced mechanism in Trypanosoma brucei

The signal-recognition particle (SRP) mediates the translocation of membrane and secretory proteins across the endoplasmic reticulum upon interaction with the SRP receptor. In trypanosomes, the main RNA molecule is the spliced-leader (SL) RNA, which donates the SL sequence to all messenger RNA through trans-splicing. Here, we show that RNA interference silencing of the SRP receptor (SRalpha) in Trypanosoma brucei caused the accumulation of SRP on ribosomes and triggered silencing of SL RNA (SLS). SLS was elicited due to the failure of the SL RNA-specific transcription factor tSNAP42 to bind to its promoter. SL RNA reduction, in turn, eliminated mRNA processing and resulted in a significant reduction of all mRNA tested. SLS was also induced under pH stress and might function as a master regulator in trypanosomes. SLS is reminiscent of, but distinct from, the unfolded protein response and can potentially act as a new target for parasite eradication.

Identification of novel snRNA-specific Sm proteins that bind selectively to U2 and U4 snRNAs in Trypanosoma brucei

In eukaryotes the seven Sm core proteins bind to U1, U2, U4, and U5 snRNAs. In Trypanosoma brucei, Sm proteins have been implicated in binding both spliced leader (SL) and U snRNAs. In this study, we examined the function of these Sm proteins using RNAi silencing and protein purification. RNAi silencing of each of the seven Sm genes resulted in accumulation of SL RNA as well as reduction of several U snRNAs. Interestingly, U2 was unaffected by the loss of SmB, and both U2 and U4 snRNAs were unaffected by the loss of SmD3, suggesting that these snRNAs are not bound by the heptameric Sm complex that binds to U1, U5, and SL RNA. RNAi silencing and protein purification showed that U2 and U4 snRNAs were bound by a unique set of Sm proteins that we termed SSm (specific spliceosomal Sm proteins). This is the first study that identifies specific core Sm proteins that bind only to a subset of spliceosomal snRNAs.

Biochemical characterization of Trypanosoma brucei RNA polymerase II

In Trypanosoma brucei, transcription by RNA polymerase II accounts for the expression of the spliced leader (SL) RNA and most protein coding mRNAs. To understand the regulation of RNA polymerase II transcription in these parasites, we have purified a transcriptionally active enzyme through affinity chromatography of its essential subunit, RPB4. The enzyme preparation is active in both promoter-independent and promoter-dependent in vitro transcription assays. Importantly, the enzyme is sensitive to alpha-amanitin inhibition, a hallmark of eukaryotic RNA polymerase II enzymes. Using mass spectrometric analysis we have identified the previously unobserved RPB12 subunit of T. brucei RNA polymerase II. TbRPB12 contains a conserved CX(2)CX(10-15)CX(2)C zinc binding motif that is characteristic of other eukaryotic RPB12 polypeptides. We also identified seven proteins that associate with T. brucei RNA polymerase II. While both bioinformatics and biochemical analysis have focused on the subunit structure of trypanosome RNA polymerases, this is the first study that reveals a functional RNA polymerase II enzyme.

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.

Gene transcription in trypanosomes

Trypanosoma brucei and the other members of the trypanosomatid family of parasitic protozoa, contain an unusual RNA polymerase II enzyme, uncoordinated mRNA 5' capping and transcription initiation events, and most likely contain an abridged set of transcription factors. Pre-mRNA start sites remain elusive. In addition, two important life cycle stage-specific mRNAs are transcribed by RNA polymerase I. This review interprets these unusual transcription traits in the context of parasite biology.

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.

Genetic regulation of protein synthesis in trypanosomes

It is becoming increasingly clear that parasitic protozoa remain a scourge to humans in the 21st century. The trypanosomes are a diverse group of insect-transmitted parasites that wiggle their way through multiple life cycle stages as they destroy human lives. Exquisitely detailed studies of these organisms reveal basic differences in gene expression that separate these single celled eukaryotes from multicellular eukaryotic organisms and have suggested numerous potential drug targets.

Assessing messenger RNA decapping in cellular extracts

Removal of the 5' cap from a messenger RNA (mRNA) is an integral part of all mRNA decay pathways and can be a highly regulated event. Assays designed to assess decapping in vitro need to effectively resolve four products of mRNA decay: 7meGpppG produced by 3'-5' shortening of the transcript by the exosome, 7meGMP produced by the scavenger decapping enzyme DcpS acting on the product of exosomal decay, 7meGDP produced by the Dcp1/2 decapping enzyme, and free phosphate, which can be generated by phosphatases in the extract acting upon either of the two products of decapping noted above. We have outlined both thin-layer chromatography and acrylamide-gel based approaches that can be used to assess decapping activities.

Characterization of deadenylation in trypanosome extracts and its inhibition by poly(A)-binding protein Pab1p

The stability of mRNAs is an important point in the regulation of gene expression in eukaryotes. The mRNA turnover pathways have been identified in yeast and mammals. However, mRNA turnover pathways in trypanosomes have not been widely studied. Deadenylation is the first step in the major mRNA turnover pathways of yeast and mammals. To better understand mRNA degradation processes in these organisms, we have developed an in vitro mRNA turnover system that is functional for deadenylation. In this system, addition of poly(A) homopolymer activates the deadenylation of poly(A) tails. The trypanosomal deadenylase activity is a 3'-->5' exonuclease specific for adenylate residues, generates 5'-AMP as a product, is magnesium dependent, and is inhibited by neomycin B sulfate. These characteristics suggest similarity with other eukaryotic deadenylases. Furthermore, this activity is cap independent, indicating a potential difference between the trypanosomal activity and PARN, but suggesting similarity to Ccr4p/Pop2p activities. Extracts immunodepleted of Pab1p required the addition of poly(A) competition to activate deadenylation. Trypanosomal Pab1p functions as an inhibitor of the activity under in vitro conditions. Pab1p appears to be one of several mRNA stability proteins in trypanosomal extracts.

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.

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.

In vivo transcriptional analysis of the spliced leader RNA gene in the trypanosomatid Leptomonas seymouri

Gene expression in all organisms requires the direct and indirect interaction of multiple proteins with specific DNA sequence elements. Using the monogenetic trypanosomatid, Leptomonas seymouri, we investigated the cis- and trans-acting components that determine expression of a central trypanosomatid RNA, the spliced leader (SL) RNA. Using base substitution mutagenesis and DNA transfection assays, we determined that the SL RNA gene promoter lies exclusively up-stream from the transcription initiation site. Accordingly, the SL RNA gene can be used as a gene cassette to express short heterologous RNAs of interest. We utilized two pharmacological agents, alpha-amanitin and tagetitoxin, and the detergent sarkosyl to assess components of the trans-acting machinery involved in transcription. The SL RNA inhibition pattern was distinct from that of alpha-tubulin, tRNA or ribosomal RNA. Taken together, these data suggest that the upstream SL RNA gene promoter serves to nucleate a transcriptional complex that is distinct, in either its initiation and/or elongation abilities, from other genes. A comparison of trypanosomatid SL RNA gene promoter structures with that found in the nematode Ascaris lumbricoides underscores a taxonomic difference in promoter architectures which may reflect differential requirements for the SL RNA in these organisms.

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

All trypanosome mRNAs have a spliced leader (SL). The SL RNA gene in Leptomonas seymouri is a member of the small nuclear RNA gene family. However, the SL RNA is required in stoichiometric amounts for trans-splicing during mRNA formation. Expression of the SL RNA gene requires sequence elements at bp -60 to -70 and bp -30 to -40 upstream from the transcription initiation site. Using conventional and affinity chromatography, we have identified and characterized an approximately 122-kDa protein, promoter-binding protein (PBP) -1, that binds to double-strand DNA. The PBP-1-binding site is within the bp -60 to -70 element determined by DNase I footprinting. Therefore, PBP-1 is the first characterized double-strand DNA binding activity that interacts with a trypanosome gene promoter. A second protein, PBP-2, interacts with the PBP-1:DNA complex and its DNase I footprint extends to include the second promoter element (bp -30 to -40). An alteration of the spacing between the two promoter elements or mutation of the second element decreases PBP-2/PBP-1:DNA stability. Taken together, these data suggest that PBP-1 and PBP-2 are components of a transcription initiation complex that assembles within the SL RNA gene promoter.

In vitro transcription of the Leptomonas seymouri SL RNA and U2 snRNA genes using homologous cell extracts

A cell-free transcription system for the spliced leader (SL) RNA gene of the trypanosomatid Leptomonas seymouri has been developed. Accurately initiated transcription was achieved using cell extracts and a template in which the transcribed region of the SL RNA was replaced with a guanosine-less sequence (G-less cassette). The extract was also able to direct accurate initiation of RNA from an L. seymouri tagged U2 snRNA gene, which may be expressed via a transcriptional apparatus shared by the SL RNA gene. In vivo transcription analysis was used previously to define essential sequence components of the SL RNA gene promoter (Hartree D, Bellofatto V. Mol Biochem Parasitol 1995:71:27-39). A substitution mutation in the upstream promoter element (bp - 50 to - 70) markedly reduced transcription in vitro as did deletion of this and the middle promoter element (bp - 30 to - 40). Thus, the in vitro transcription system correctly responds to promoter mutations and is useful for investigating SL RNA and snRNA gene expression.

Spliced leader RNA of trypanosomes: in vivo mutational analysis reveals extensive and distinct requirements for trans splicing and cap4 formation

In trypanosomes mRNAs are generated through trans splicing. The spliced leader (SL) RNA, which donates the 5'-terminal mini-exon to each of the protein coding exons, plays a central role in the trans splicing process. We have established in vivo assays to study in detail trans splicing, cap4 modification, and RNP assembly of the SL RNA in the trypanosomatid species Leptomonas seymouri. First, we found that extensive sequences within the mini-exon are required for SL RNA function in vivo, although a conserved length of 39 nt is not essential. In contrast, the intron sequence appears to be surprisingly tolerant to mutation; only the stem-loop II structure is indispensable. The asymmetry of the sequence requirements in the stem I region suggests that this domain may exist in different functional conformations. Second, distinct mini-exon sequences outside the modification site are important for efficient cap4 formation. Third, all SL RNA mutations tested allowed core RNP assembly, suggesting flexible requirements for core protein binding. In sum, the results of our mutational analysis provide evidence for a discrete domain structure of the SL RNA and help to explain the strong phylogenetic conservation of the mini-exon sequence and of the overall SL RNA secondary structure; they also suggest that there may be certain differences between trans splicing in nematodes and trypanosomes. This approach provides a basis for studying RNA-RNA interactions in the trans spliceosome.

Structure of the Leptomonas seymouri trans-spliceosomal U2 snRNA-encoding gene; potential U2-U6 snRNA interactions conform to the cis-splicing counterpart

We have characterized the U2 small nuclear RNA (snRNA)-encoding gene from the monogenetic trypanosomatid, Leptomonas seymouri (Ls), to begin to identify the RNA-RNA interactions that direct trans-splicing in kinetoplastid protozoa. The U2 gene, which is single copy in this organism, was isolated and sequenced. Although the Ls U2 snRNA contains many of the sequence and secondary structure elements that are conserved among the U2 snRNAs of cis-splicing organisms, it lacks the stem-loop III region and the intron branch point-recognition region, as do other trypanosomatid U2 snRNAs. A transcriptional promoter element within the Trypanosoma brucei U2 gene [Fantoni et al., Mol. Cell. Biol. 14 (1994) 2021-2028] is conserved in the homologous Ls gene. A crucial step in cis-splicing reactions involves specific base-pairing interactions between the U2 and U6 snRNAs. We show here that in trypanosomatids, where no cis-splicing occurs, these same interactions are possible. This highlights key similarities between the two RNA processing events.

Essential components of the mini-exon gene promoter in the trypanosomatid Leptomonas seymouri

In members of the Trypanosomatidae family of parasitic protozoa, the mini-exon (MX) genes encode the mini-exon donor RNA (medRNA) that contributes a small, 39-nt exon to all pre-mRNAs during mRNA maturation. Previously we have shown that a single copy of a MX gene can be expressed continuously from a stable episome transfected into the monogenetic trypanosomatid Leptomonas seymouri. We now identify components of the MX gene promoter. A series of 10-bp block substitution mutations in a tagged MX gene were transfected into Leptomonas on an episomal vector. Expression of tagged and endogenous medRNA was assessed in stably transformed clonal cell populations. Results show that less than half of the 757-bp MX gene is necessary for medRNA transcription and that the key components of the MX gene promoter lie within the proximal 70-bp sequence upstream from the transcription initiation site. Transcription requires several sequence-specific blocks within this 70-bp region. Leptomonas cell extracts contain protein(s) that appear to interact with a subset of these sequences in gel mobility shift assays. All trypanosomatid MX genes contain an AT-rich region at the +10 to +20 position within the transcribed region of the MX gene. Mutagenesis of this region within an episomal copy of the MX gene did not block tagged medRNA synthesis but did cause a 10-fold increase in the steady-state amount of endogenous medRNA.

Leptomonas seymouri as a model system for the analysis of gene expression in trypanosomatids

Leptomonas seymouri, a monogenetic trypanosomatid originally isolated from Dysdercus suturellus (Hemiptera), was used to develop a reverse genetic system for trypanosomatid flagellates. In many eukaryotic cell types, reverse genetics has proven to be a powerful tool for defining structure/function relationships within genes. The mini-exon genes of trypanosomatids encode key components of all cellular mRNAs. This component is a 5' "leader" RNA that is spliced onto all mRNA precursors during mRNA formation within the cell nucleus. The data presented here indicate that structure/function relationships within the mini-exon gene can be probed using the molecular genetic system developed and characterized for L. seymouri.

Differential response to RNA trans-splicing signals within the phosphoglycerate kinase gene cluster in Trypanosoma brucei

In trypanosomatids, nuclear pre-mRNA splicing is exclusively a trans-splicing reaction in which a capped, 39 nt exon, the mini-exon, is positioned 5' to an open reading frame. Differential RNA splicing might reflect specific mini-exon and 3' splice site interactions. To test this hypothesis, we compared the efficiency of mini-exon addition to three natural 3' splice acceptor sites (SASs) located within a single pre-mRNA transcript. In Trypanosoma brucei, the phosphoglycerate kinase A, B and C genes (PGK A, B and C) are co-expressed as three consecutive sequences on a polycistronic pre-mRNA. This pre-mRNA gives rise to unequal amounts of PGK A, B and C mRNAs. When the SAS from each gene was placed upstream of the luciferase open reading frame and the resultant constructs transiently transfected into T. brucei procyclic cells, luciferase activity levels indicated differential SAS utilization. Enzyme activity was low when the SAS from the A gene was present. Levels were indistinguishable when the B and C SASs were compared. After replacing luciferase with chloramphenicol acetyl transferase in the test constructs, enzyme activities were shown to directly correlate with mRNA amounts. Thus, poor splicing efficiency accounts for the differential expression of the PGK A mRNA during PGK pre-mRNA maturation. This reaction appears to reflect the polypyrimidine pattern within the 3' splice acceptor site.

Stable transformation of Leptomonas seymouri by circular extrachromosomal elements

To define the cis-acting sequences necessary for gene expression and DNA replication in trypanosomatids, we have developed a selectable vector that can be grown in Escherichia coli and maintained stably in the insect trypanosomatid Leptomonas seymouri. The vector is relatively small (6 kilobase pairs) and contains a portion of the L. seymouri alpha-tubulin gene positioned in-frame with a truncated neomycin phosphotransferase gene that confers resistance to the aminoglycoside G418. This construct is maintained in cells as a high-copy-number circular extrachromosomal element containing several head-to-tail copies of the transforming plasmid. In L. seymouri, alpha-tubulin-neomycin phosphotransferase fusion RNAs are polyadenylylated and possess a trans-spliced mini-exon. Additional DNA sequences can be inserted into the vector, propagated, and expressed in transformed cells.

The new trypanosomatid genetics

The recent development of transfection systems for trypanosomatids has removed a major obstacle to research and provides an important tool for the biochemist, immunologist and molecular biologist. Obtaining expression of a foreign gene in a trypanosomatid has been difficult. In this review, Vivian Bellofatto describes the problems and pitfalls of the process and final successes achieved.

Transcription of the procyclic acidic repetitive protein genes of Trypanosoma brucei

The procyclic acidic repetitive protein (parp) genes of Trypanosoma brucei encode a small family of abundant surface proteins whose expression is restricted to the procyclic form of the parasite. They are found at two unlinked loci, parpA and parpB; transcription of both loci is developmentally regulated. The region of homology upstream of the A and B parp genes is only 640 base pairs long and may contain sequences responsible for transcriptional initiation and regulation. Transcription upstream of this putative promoter region is not developmentally regulated and is much less active than that of the parp genes; the polymerase responsible is inhibited by alpha-amanitin, whereas that transcribing the parp genes is not. Transcription of the parp genes is strongly stimulated by low levels of UV irradiation. The putative parp promoter, when placed upstream of the chloramphenicol acetyltransferase gene, is sufficient to cause production of chloramphenicol acetyltransferase in a T. brucei DNA transformation assay. Taken together, these results suggest that a promoter for an alpha-amanitin-resistant RNA polymerase lies less than 600 nucleotides upstream of the parp genes.

Expression of a bacterial gene in a trypanosomatid protozoan

A simple and reproducible assay for DNA-mediated transfection in the trypanosomatid protozoan Leptomonas seymouri has been developed. The assay is based on expression of the Escherichia coli chloramphenicol acetyl transferase (CAT) gene flanked by Leptomonas DNA fragments that are likely to contain necessary elements for gene expression in trypanosomes. After electroporation of cells in the presence of plasmid DNA, CAT activity was detected in crude cell lysates. No activity was detected when the orientation of the L. seymouri mini-exon sequence (placed upstream of the CAT gene) was reversed, or in additional control experiments. This system provides a method for defining transcriptional control elements in trypanosomes.

Discontinuous transcription in Leptomonas seymouri: presence of intact and interrupted mini-exon gene families

Mature mRNAs of trypanosomatid protozoa result from the joining of at least two exons, which are initially transcribed as separate RNAs. In all trypanosomatids examined to date, the first exon (mini-exon) is encoded by approximately 200 tandemly reiterated genes. In characterizing the mini-exon genes of Leptomonas seymouri, we identified two predominant size classes of repetitive sequences that hybridized strongly to the L. seymouri mini-exon sequence. These two sequences are arranged as interspersed clusters. DNA sequence analysis of a clone representing the smaller size class demonstrated that these sequences have the capacity to encode a mini-exon donor (med)RNA corresponding to the 86 nt component seen in Northern blots of L. seymouri RNA. The larger size class comprises a family of related sequences, some of which contain DNA inserted into the mini-exon portion of the medRNA gene. The specific insert identified here (LINS 1) is exclusively associated with medRNA sequences, and is present in approximately 20% of the larger size class of L. seymouri medRNA genes. Disregarding the insertion, the sequences of the smaller bona fide mini-exon genes and the gene copy containing the insert were almost identical. The insert sequence is transcribed in the same direction as medRNA to yield at least four small non-polyadenylated RNAs, which appeared not to be linked to medRNA sequences.

Characterization of RNA transcripts from the alpha tubulin gene cluster of Leptomonas seymouri

A tandem cluster of alpha tubulin genes was identified in the trypanosomatid protozoan Leptomonas seymouri. One repeat unit and the first gene of the cluster, with its upstream flanking region, were cloned and analyzed for their transcriptional and coding capacities. The 12-15 copies per cell of the 4 kb repeat encode a stable 2 kb transcript, which contains a mini-exon at its 5' end and two closely spaced polyadenylation sites. Transcription of the alpha tubulin gene cluster in isolated nuclei was unidirectional. Intergenic and coding regions were transcribed at the same rate, and nascent intergenic and coding region transcripts were quantitatively linked. These results are consistent with the possibility that the primary transcripts are polycistronic, or that there is a single small intercistronic gap.

Biochemical changes associated with alpha-difluoromethylornithine uptake and resistance in Trypanosoma brucei

Procyclic Trypanosoma brucei grown in semi-defined media are sensitive to alpha-difluoromethylornithine (DFMO) (EC50 100 microM), an inhibitor of ornithine decarboxylase (ODC), a key enzyme in polyamine biosynthesis. Organisms resistant to 5 mM DFMO (EC50 greater than 20 mM) were obtained by passage in incremental amounts of drug. Resistant and wild-type cells accumulated DFMO by passive diffusion with a consequent decrease in polyamine levels, indicating inhibition of ODC in both cell types. The resistant phenotype was stable in the absence of DFMO, in which state there was no increase in ODC abundance or activity. By kinetic analysis, the ODC of resistant cells appeared normal. In wild-type and resistant cells, [3H]DFMO equally and uniquely affinity-labelled a 50 kDa polypeptide corresponding to the ODC subunit. Levels of ODC and tubulin mRNAs were elevated 4-fold in resistant cells grown in the presence of DFMO, although there was no indication of gene amplification. The intracellular concentration of dihydrotrypanothione (N1,N8-bis(glutathionyl)-spermidine), a redox intermediate unique to kinetoplastids, was unchanged in resistant cells growing in DFMO but was halved in wild-type cells exposed to DFMO for 48 h. The exceptionally elevated levels of ornithine found in DFMO-treated resistant cells most likely play a crucial role in cell survival by maintaining intracellular concentrations of dihydrotrypanothione by competing with DFMO for ODC.

Transcription initiation in vitro and in vivo at a highly conserved promoter within a 16 S ribosomal RNA gene

Transcription initiation has been shown to occur in vitro at several sites within a cloned Caulobacter crescentus ribosomal RNA gene cluster that lacks the major promoter region 5' to the 16 S rRNA gene. The predominant transcription start site in vitro was located near the 3' end of the 16 S rRNA gene. Transcription initiation from this region was also detected in vivo, when the cloned rRNA gene cluster was present on a multi-copy plasmid. The transcription start sites in vitro and in vivo were shown to be identical by S1 nuclease mapping and were found to be located approximately 300 nucleotides upstream from the 3' end of the 16 S rRNA gene. The transcript synthesized in vitro was shown to be cleaved by C. crescentus RNase III and to release the transfer RNA genes from the downstream 16 S/23 S intergenic spacer region. Analysis of the nucleotide sequence near the internal 16 S rRNA transcription start site revealed the presence of a consensus promoter sequence followed by the beginning of an open reading frame approximately 90 nucleotides downstream. Examination of the 16 S rRNA genes from other bacterial species and chloroplasts and 18 S rRNA genes from Xenopus and yeast revealed that the nucleotide sequence of this internal 16 S rRNA promoter region was highly conserved. Although the length of these 16 S and 18 S rRNA genes is slightly variable, the distance of the conserved promoter sequence from the 3' end of these genes has been conserved.

Organization and nucleotide sequence analysis of an rRNA and tRNA gene cluster from Caulobacter crescentus

rRNA genes of Caulobacter crescentus CB13 were isolated and shown to be present in two gene clusters in the genome. The organization of each rRNA gene cluster was found to be 5'-16S-tRNA spacer-23S-5S-3'. The DNA sequence of 40% of the 16S rRNA gene, the entire 16S/23S intergenic spacer region, and portions of the 23S rRNA gene were determined. Analysis of the nucleotide sequence in the 16S-23S intergenic spacer region revealed the presence of tRNAIle and tRNAAla genes. Large invert repeat sequences were found surrounding the 16S rRNA gene. These inverted repeat sequences are analogous to the RNase III-processing sites in the E. coli rRNA precursor. Small invert repeat sequences were also found flanking the individual tRNA genes. RNA polymerase-binding studies with restriction fragments of the rRNA gene cluster revealed three regions which bound enzyme, and these regions were shown to contain transcription initiation sites. One of these sites was located within the 16S gene near its 3' end, and the other two were found at the 5' end of the 23S gene.

Generation of a Tn5 promoter probe and its use in the study of gene expression in Caulobacter crescentus

A promoter probe, Tn5-VB32, was constructed and placed in a P group R plasmid containing bacteriophage Mu sequences, allowing transfer of the transposon to bacteria such as Caulobacter, Rhizobium, and Agrobacterium without retention of the plasmid. The probe carries an altered Tn5 transposon that allows detection of chromosomal promoter regions by virtue of acquired kanamycin resistance. A fragment of DNA containing the neomycin phosphotransferase II (NPT II) gene from Tn5, lacking its promoter region but retaining its translation initiation signal, was inserted into a Tn5 derivative that lacked the entire NPT II gene and a large portion of the IS50L sequence while retaining its ability to transpose. This Tn5 derivative also contained the intact tetracycline resistance-encoding region of the transposon Tn10. Transposition of the Tn5-VB32 promoter probe into the Caulobacter crescentus chromosome generated auxotrophic and motility mutants and Southern blot analysis of DNA from these mutants showed Tn5-VB32 sequences in random-sized chromosomal restriction fragments. Transcriptional regulation by exogenous cysteine of NPT II gene expression was demonstrated in a cysteine auxotroph generated by Tn5-VB32 insertional inactivation. NPT II synthesis, measured by agar plate assays of kanamycin resistance and by immunoprecipitation of the NPT II protein, was repressed in the presence of cysteine and derepressed in its absence. Several fla- mutants were also isolated by Tn5-VB32 mutagenesis and shown to confer kanamycin resistance. Insertions within temporally regulated genes, such as those involved in flagellar biosynthesis and chemotaxis functions, can now be used directly to monitor transcriptional regulation from Caulobacter promoter sequences.

Purification and characterization of an RNA processing enzyme from Caulobacter crescentus

An RNA processing enzyme has been isolated from Caulobacter crescentus which is specific for double-stranded RNA, has an absolute requirement for monovalent cations, and can be eluted from a poly I:C agarose affinity column in pure form. This enzyme, like RNase III isolated from Escherichia coli, processes precursor ribosomal RNAs and polycistronic phage mRNAs and has a monomeric Mr of approximately 20,000. The two enzymes differ, however, in the recognition of specific cleavage sites and yield different digestion products when either coliphage T7 or C. crescentus phage phi Cdl early mRNA is used as substrate. Two lines of evidence are presented which show that an RNase III activity functions as a processing enzyme in C. crescentus. (a) In an in vitro reaction, C. crescentus phage phi Cdl major early mRNA synthesized in vitro by host RNA polymerase was processed by RNase III to yield RNA species which co-migrated with phage RNA synthesized in vivo in phi Cdl-infected cells, and (b) an in vitro transcript of a C. crescentus DNA clone containing the entire 16 S gene and part of the 23 S gene was processed by C. crescentus RNase III to yield an RNA product which co-migrated with 16 S RNA. The RNase III activity isolated from C. crescentus cell extracts has potential use in the analysis of specific RNA species because it was found to be more stringent in the recognition of cleavage sites than the E. coli enzyme.