The Trypanosoma brucei protein phosphatase gene: polycistronic transcription with the RNA polymerase II largest subunit gene

Genome-wide quantification of polycistronic transcription in Leishmania major

Leishmania major is a human-pathogenic, obligate parasite and the etiological agent of the most prevalent, cutaneous form of leishmaniasis, which is an important neglected, tropical disease with ~1.2 million new infections per year. Leishmania, and the whole order Trypanosomatida, are early eukaryotes with highly diverged gene expression and regulation pathways, setting them apart from their mammalian hosts and from most other eukaryotes. Using precision run-on sequence analysis, we performed a genome-wide mapping and density analysis of RNA polymerases in isolated nuclei of the protozoan parasite Leishmania major. We map transcription initiation sites at divergent strand switch regions and head-tail regions within the chromosomes and correlate them with known sites of chromatin modifications. We confirm continuous, polycistronic RNA synthesis in all RNA polymerase II-dependent gene arrays but find small varying RNA polymerase activities in polycistronic transcription units (PTUs), excluding gene-specific transcription regulation, but not PTU-specific variations. Lastly, we find evidence for transcriptional pausing of all three RNA polymerase classes, hinting at a possible mechanism of transcriptional regulation.IMPORTANCELeishmania spp. are pathogens of humans and animals and cause one of the most important neglected tropical diseases. Regulation of gene expression in Leishmania but also in the related Trypanosoma is radically different from all eukaryotic model organisms, dispensing with regulated, gene-specific transcription, and relying instead on highly regulated translation. Our work sheds light on the initiation, elongation, and termination of transcription, maps unidirectional, polycistronic transcription units, provides evidence for transcriptional pausing at or near starting points of RNA synthesis, and quantifies the varying transcription rates of the polycistronic transcription units. Our results will further the understanding of these important pathogens and should provide a valuable resource for researchers in the field of eukaryotic microbiology.

Trypanosomatid protein phosphatases

Protein phosphorylation is one of the most important post-translational modifications regulating various signaling processes in all known living organisms. In the cell, protein phosphatases and protein kinases play a dynamic antagonistic role, controlling the phosphorylation state of tyrosine (Tyr), serine (Ser) and threonine (Thr) side chains of proteins. The reversible phosphorylation modulates protein function, through initiating conformational changes, which influences protein complex formation, alteration of enzyme activity and changes in protein stability and subcellular localization. These molecular changes affect signaling cascades regulating the cell cycle, differentiation, cell-cell and cell-substrate interactions, cell motility, the immune response, ion-channel and transporter activities, gene transcription, mRNA translation, and basic metabolism. In addition to these processes, in unicellular parasites, like Trypanosoma brucei, Trypanosoma cruzi and Leishmania spp., additional signaling pathways have evolved to enable the survival of parasites in the changing environment of the vector and host organism. In recent years the genome of five trypanosomatid genomes have been sequenced and annotated allowing complete definition of the composition of the trypanosomatid phosphatomes. The very diverse environments involved in the different stages of the kinetoplastids' life cycle might have played a role to develop a set of trypanosomatid-specific phosphatases in addition to orthologues of many higher eukaryote protein phosphatases present in the kinetoplastid phosphatomes. In spite of their well-described phosphatomes, few trypanosomatid protein phosphatases have been characterized and studied in vivo. The aim of this review is to give an up to date scope of the research, which has been carried out on trypanosomatid protein phosphatases.

Life-cycle and growth-phase-dependent regulation of the ubiquitin genes of Trypanosoma cruzi

BACKGROUND

Trypanosoma cruzi, the causative agent of Chagas disease, exhibits a complex life cycle that is accompanied by the stage-specific gene expression. At the molecular level, very little is known about gene regulation in trypanosomes. Complex gene organizations coupled with polycistronic transcription units make the analysis of regulated gene expression difficult in trypanosomes. The ubiquitin genes of T. cruzi are a good example of this complexity. They are organized as a single cluster containing five ubiquitin fusion (FUS) and five polyubiquitin (PUB) genes that are polycistronically transcribed but expressed differently in response to developmental and environmental changes.

METHODS

Gene replacements were used to study FUS and PUB gene expression at different stages of growth and at different points in the life cycle of T. cruzi.

RESULTS

Based on the levels of reporter gene expression, it was determined that FUS1 expression was downregulated as the parasites approached stationary phase, whereas PUB12.5 polyubiquitin gene expression increased. Conversely, FUS1 expression increases when epimastigotes and amastigotes differentiate into trypomastigotes, whereas the expression of PUB12.5 decreases when epimastigotes differentiate into amastigotes and trypomastigotes.

CONCLUSIONS

Although the level of CAT activity in logarithmic growing epimastigotes is six- to seven-fold higher when the gene was expressed from the FUS1 locus than when expressed from the PUB12.5 locus, the rate of transcription from the two loci was the same implying that post-transcriptional mechanisms play a dominant role in the regulation of gene expression.

A novel protein phosphatase 2A (PP2A) is involved in the transformation of human protozoan parasite Trypanosoma cruzi

Here we provide evidence for a critical role of PP2As (protein phosphatase 2As) in the transformation of Trypanosoma cruzi. In axenic medium at pH 5.0, trypomastigotes rapidly transform into amastigotes, a process blocked by okadaic acid, a potent PP2A inhibitor, at concentrations as low as 0.1 microM. 1-Norokadaone, an inactive okadaic acid analogue, did not affect the transformation. Electron microscopy studies indicated that okadaic acid-treated trypomastigotes had not undergone ultrastructural modifications, reinforcing the idea that PP2A inhibits transformation. Using a microcystin-Sepharose affinity column we purified the native T. cruzi PP2A. The enzyme displayed activity against 32P-labelled phosphorylase a that was inhibited in a dose-dependent manner by okadaic acid. The protein was also submitted to MS and, from the peptides obtained, degenerate primers were used to clone a novel T. cruzi PP2A enzyme by PCR. The isolated gene encodes a protein of 303 amino acids, termed TcPP2A, which displayed a high degree of homology (86%) with the catalytic subunit of Trypanosoma brucei PP2A. Northern-blot analysis revealed the presence of a major 2.1-kb mRNA hybridizing in all T. cruzi developmental stages. Southern-blot analysis suggested that the TcPP2A gene is present in low copy number in the T. cruzi genome. These results are consistent with the mapping of PP2A genes in two chromosomal bands by pulsed-field gel electrophoresis and chromoblot hybridization. Our studies suggest that in T. cruzi PP2A is important for the complete transformation of trypomastigotes into amastigotes during the life cycle of this protozoan parasite.

Two novel RNA binding proteins from Trypanosoma brucei are associated with 5S rRNA

We have previously reported the identification of two closely related RNA binding proteins from Trypanosoma brucei which we have termed p34 and p37. The predicted primary structures of the two proteins are highly homologous with one major difference, an 18-amino-acid insert in the N-terminal region of p37. These two proteins have been localized to the nucleus based on immunofluorescence microscopy. To gain insight into their function, we have utilized UV crosslinking, coimmunoprecipitation, and sucrose density gradients to identify T. brucei RNA species that associate with p34 and p37. These experiments have demonstrated a specific interaction of both p34 and p37 with the 5S ribosomal RNA and indicate that other RNA species are unlikely to be specifically bound. This suggests a role for p34 and p37 in the import and/or assembly pathway of T. brucei 5S rRNA in ribosome biogenesis.

Cloning and characterization of a novel serine/threonine protein phosphatase type 5 from Trypanosoma brucei

Reversible protein phosphorylation is essential for the regulation of numerous cellular functions and differentiation. The haemo-flagellated parasitic protozoan Trypanosoma brucei, the causative agent for African trypanosomiasis undergoes various stages of cellular differentiation during its digenetic life cycle. A complete cDNA of a unique serine/threonine phosphatase type five (TbPP5) was cloned and characterized from T. brucei. TbPP5 contains an open reading frame of 1416 bp that encodes a protein of about 53 kDa and exists as a single copy gene in the T. brucei genome. The deduced amino acid sequence showed 45-48% overall identity and 60-65% similarity with protein phosphatase 5's (PP5) from different species. Analysis of the primary sequence revealed that TbPP5 contains three TPR motifs at the N-terminal region (amino acid residues 7-107) while the phosphatase catalytic domain occurs in the C-terminal region (amino acid residues 210-410). A TbPP5 cDNA hybridized with a transcript of 2.5 kb which is present at similar levels in the procyclic and the bloodstream forms. However, the level of expression of the TbPP5 protein (52 kDa) detected by an antibody developed against a recombinant protein produced in E. coli was about 2-fold higher in the procyclic than the bloodstream form. The TbPP5 transcript level gradually decreased in cells grown in the logarithmic phase to the stationary phase in culture. Moreover, 18 h serum starvation of the procyclic forms decreased the level of the specific transcript about 3-fold suggesting that this protein may play a role during the active growth phase of the organism. The recombinant protein showed phosphatase activity which was stimulated about 2.6-fold by arachidonic acid with half-maximal activity at 75 microM. Indirect immuno-fluorescence of permeabilized cells revealed that the protein is localized in the cytosol and the nucleus This is the first report for the identification of a type 5 serine/threonine protein phosphatase in an ancient eukaryote such as T. brucei.

The Leishmania major RNA polymerase II largest subunit lacks a carboxy-terminus heptad repeat structure and its encoding gene is linked with the calreticulin gene

The gene encoding the RNA polymerase II largest subunit (RPOIILS) has been isolated and sequenced from the kinetoplastid protozoan, Leishmania (Leishmania) major. The RPOIILS gene was shown to be present as a single copy and is composed of an uninterrupted open reading frame of 4.99 kb, specifying a protein 1663 aa in length with a predicted molecular mass of approximately 185 kDa. The carboxy terminus domain (CTD) of the RPOIILS from L. (L.) major, typical of the more evolutionary primitive protozoa, lacked a heptad repeat structure which is present in higher eukaryotes and some other protozoan phyla. Comparison of the predicted aa composition of the CTD from a diverse range of eukaryotic species revealed the abundance of Ser and Pro residues as the only discernible evolutionary conservative feature. A putative ATG start codon for an additional expressed sequence was located 1.1 kb downstream of the L. (L.) major RPOIILS gene stop codon. Nucleic acid database searches revealed the identity of this gene as that encoding the calcium binding protein calreticulin (CLT). The close proximity of the RPOIILS and CLT genes in L. (L.) major raises the possibility that these genes are transcribed as part of the same polycistronic unit.

Pathways involved in environmental sensing in trypanosomatids

Digenetic parasites, such as those of the order Kinetoplastida, must respond to extracellular and intracellular signals as they adapt to new environments within their different hosts. Evidence for signal transduction has been obtained for Trypanosoma brucei, T. cruzi and Leishmania, as reviewed here by Marilyn Parsons and Larry Ruben. Although the broad picture suggests similarities with the mammalian host, there are large gaps in our understanding of these processes; this probably contributes to a perception of differences. Nonetheless, current evidence suggests that the trypanosomatids might lack certain classes of signalling molecules found in other organisms.

Transcription of protein-coding genes in trypanosomes by RNA polymerase I

In eukaryotes, RNA polymerase (pol) II transcribes the protein-coding genes, whereas RNA pol I transcribes the genes that encode the three RNA species of the ribosome [the ribosomal RNAs (rRNAs)] at the nucleolus. Protozoan parasites of the order Kinetoplastida may represent an exception, because pol I can mediate the expression of exogenously introduced protein-coding genes in these single-cell organisms. A unique molecular mechanism, which leads to pre-mRNA maturation by trans-splicing, facilitates pol I-mediated protein-coding gene expression in trypanosomes. Trans-splicing adds a capped 39-nucleotide mini-exon, or spliced leader transcript, to the 5' end of the main coding exon posttranscriptionally. In other eukaryotes, the addition of a 5' cap, which is essential for mRNA function, occurs exclusively as a result of RNA pol II-mediated transcription. Given the assumption that cap addition represents the limiting factor, trans-splicing may have uncoupled the requirement for RNA pol II-mediated mRNA production. A comparison of the alpha-amanitin sensitivity of transcription in naturally occurring trypanosome protein-coding genes reveals that a unique subset of protein-coding genes-the variant surface glycoprotein (VSG) expression sites and the procyclin or the procyclic acidic repetitive protein (PARP) genes-are transcribed by an RNA polymerase that is resistant to the mushroom toxin alpha-amanitin, a characteristic of transcription by RNA pol I. Promoter analysis and a pharmacological characterization of the RNA polymerase that transcribes these genes have strengthened the proposal that the VSG expression sites and the PARP genes represent naturally occurring protein-coding genes that are transcribed by RNA pol I.

Identification and characterization of cAMP-dependent protein kinase and its possible direct interactions with protein phosphatase-1 in marine dinoflagellates

We have examined the nature of signal transduction involving reversible protein phosphorylation in marine Prorocentrale species. Of particular interest is the marine dinoflagellate Prorocentrum lima in which the tumour promoter okadaic acid is produced and may interfere with signal transduction. We have identified cAMP-dependent protein kinase (PKA) activity in P. lima, P. micans, and P. minimum. The P. lima enzyme was characterized biochemically and appears to consist of two different isoforms in the R2C2 configuration. Whole cell extracts of P. micans and P. minimum treated with the specific PKA inhibitor peptide PKI (5-24) or cAMP demonstrated altered intensities of phosphopeptide 32P labeling, most likely involving regulation of a protein phosphatase via PKA activity. A primary candidate for PKA regulation is protein phosphatase-1 (PP-1), which in P. lima possesses a classical PKA consensus phosphorylation site. We demonstrate that a peptide fragment of PP-1 from P. lima corresponding to this PKA phosphorylation site can be effectively phosphorylated by PKA and dephosphorylated by calcineurin. We speculate that PP-1 activity among several lower eukaryotes may be mediated directly by reversible phosphorylation. Higher eukaryotes may have developed inhibitor proteins to provide more complex regulation of protein phosphatase activity.

Control of gene expression in trypanosomes

Trypanosomes are protozoan agents of major parasitic diseases such as Chagas' disease in South America and sleeping sickness of humans and nagana disease of cattle in Africa. They are transmitted to mammalian hosts by specific insect vectors. Their life cycle consists of a succession of differentiation and growth phases requiring regulated gene expression to adapt to the changing extracellular environment. Typical of such stage-specific expression is that of the major surface antigens of Trypanosoma brucei, procyclin in the procyclic (insect) form and the variant surface glycoprotein (VSG) in the bloodstream (mammalian) form. In trypanosomes, the regulation of gene expression is effected mainly at posttranscriptional levels, since primary transcription of most of the genes occurs in long polycistronic units and is constitutive. The transcripts are processed by transsplicing and polyadenylation under the influence of intergenic polypyrimidine tracts. These events show some developmental regulation. Untranslated sequences of the mRNAs seem to play a prominent role in the stage-specific control of individual gene expression, through a modulation of mRNA abundance. The VSG and procyclin transcription units exhibit particular features that are probably related to the need for a high level of expression. The promoters and RNA polymerase driving the expression of these units resemble those of the ribosomal genes. Their mutually exclusive expression is ensured by controls operating at several levels, including RNA elongation. Antigenic variation in the bloodstream is achieved through DNA rearrangements or alternative activation of the telomeric VSG gene expression sites. Recent discoveries, such as the existence of a novel nucleotide in telomeric DNA and the generation of point mutations in VSG genes, have shed new light on the mechanisms and consequences of antigenic variation.

The protein phosphatase inhibitor okadaic acid induces defects in cytokinesis and organellar genome segregation in Trypanosoma brucei

Mitosis and cytokinesis are events that are highly coordinated in most eukaryotic cell cycles. African trypanosomes possess a single mitochondrion and must additionally coordinate the organellar division cycle. Here we report that okadaic acid, a potent and specific inhibitor of protein phosphatases PP1and PP2A, uncouples these cycles in living trypanosomes. Cell cycle analysis of treated cells revealed elevated DNA content. Microscopic examination indicated that okadaic acid treatment yielded multinucleate cells with a single mitochondrial network indicating these cells have undergone mitosis but failed to complete cytokinesis. Immunofluorescence analysis of 5-bromo-2-deoxyuridine incorporation demonstrated that the mitochondrial DNA was replicated but did not segregate. The dose response curve for inhibition of the normal cell cycle paralleled that for the in vitro inhibition of protein phosphatase activities with IC50s of approximately 20 nM okadaic acid. These results suggest the involvement of a PP1/PP2A-like activity in coordinating mitosis, mitochondrial DNA division and cytokinesis in trypanosomes.

A monocistronic transcript for a trypanosome variant surface glycoprotein

Many protein-encoding genes of African trypanosomes are transcribed as large polycistronic pre-mRNAs that are processed into individual mRNAs containing a 5' spliced leader and 3' poly(A). The 45- to 60-kb pre-mRNAs encoding some variant surface glycoproteins (VSGs) contain as many as eight unrelated coding regions. Here we identify the promoter for a metacyclic VSG gene that is expressed without duplication in a bloodstream trypanosome clone. This 70-bp promoter is located 2 kb upstream of the telomere-linked VSG gene and directs the synthesis of a monocistronic VSG pre-mRNA lacking the 5' spliced leader. Its sequence only slightly resembles those of other known trypanosome promoters, but it does cross-hybridize with several related sequences elsewhere in the genome. These results suggest that a new class of trypanosome promoters has been found, whose function is to initiate monocistronic transcription of those VSG genes normally expressed during the metacyclic stage.

A monocistronic transcript for a trypanosome variant surface glycoprotein

Many protein-encoding genes of African trypanosomes are transcribed as large polycistronic pre-mRNAs that are processed into individual mRNAs containing a 5' spliced leader and 3' poly(A). The 45- to 60-kb pre-mRNAs encoding some variant surface glycoproteins (VSGs) contain as many as eight unrelated coding regions. Here we identify the promoter for a metacyclic VSG gene that is expressed without duplication in a bloodstream trypanosome clone. This 70-bp promoter is located 2 kb upstream of the telomere-linked VSG gene and directs the synthesis of a monocistronic VSG pre-mRNA lacking the 5' spliced leader. Its sequence only slightly resembles those of other known trypanosome promoters, but it does cross-hybridize with several related sequences elsewhere in the genome. These results suggest that a new class of trypanosome promoters has been found, whose function is to initiate monocistronic transcription of those VSG genes normally expressed during the metacyclic stage.

The Saccharomyces cerevisiae gene PPH3 encodes a protein phosphatase with properties different from PPX, PP1 and PP2A

A clone encoding the catalytic subunit of a protein phosphatase from Saccharomyces cerevisiae was isolated. Except for replacement of IIe-245 by Met the structure of the phosphatase was identical to that encoded by PPH3 (Ronne, H., Carlberg, M., Hu, G. Z. and Nehlin, J. O. (1991). Mol. Cell. Biochem. 11, 4876-4884) and exhibited 63% sequence identity to PPX cloned from a rabbit liver cDNA library (Brewis, N.D., Street, A.J., Prescott, A.R. and Cohen, P.T.W. (1993). EMBO J. 12, 987-996). Expression of active enzyme was achieved in Escherichia coli mutants which were generated by a genetic selection based on functional complementation of bacterial phosphoserine phosphatase. Though some of the properties of PPH3 resembled those of protein phosphatase 2A and PPX, others were different. PPH3 exhibited lower sensitivity against inhibition by okadaic acid, showed different substrate specificity and required a divalent cation (Mn2+ was preferred before Mg2+ and Ca2+) for activity when assayed with phospho-histone as a substrate. However, 25% of maximum activity was observed in the absence of divalent cations when the peptide LRRAS(P)LG was used as substrate. The PPH3-protein was also identified by chromatography of extracts from S. cerevisiae on DEAE-cellulose. Protein immunoreactive with an antiserum raised against the non-conserved N-terminal 53 amino acids of PPH3 was coeluted with a single peak of LRRAS(P)LG dephosphorylating activity.

Conservation analysis and structure prediction of the protein serine/threonine phosphatases. Sequence similarity with diadenosine tetraphosphatase from Escherichia coli suggests homology to the protein phosphatases

A multiple sequence alignment of 44 serine/threonine-specific protein phosphatases has been performed. This reveals the position of a common conserved catalytic core, the location of invariant residues, insertions and deletions. The multiple alignment has been used to guide and improve a consensus secondary-structure prediction for the common catalytic core. The location of insertions and deletions has aided in defining the positions of surface loops and turns. The prediction suggests that the core protein phosphatase structure comprises two domains: the first has a single, beta sheet flanked by alpha helices, while the second is predominantly alpha helical. Knowledge of the core secondary structures provides a guide for the design of site-directed-mutagenesis experiments that will not disrupt the native phosphatase fold. A sequence similarity between eukaryotic serine/threonine protein phosphatases and the Escherichia coli diadenosine tetraphosphatase has been identified. This extends over the N-terminal 100 residues of bacteriophage phosphatases and E. coli diadenosine tetraphosphatase. Residues which are invariant amongst these classes are likely to be important in catalysis and protein folding. These include Arg92, Asn138, Asp59, Asp88, Gly58, Gly62, Gly87, Gly93, Gly137, His61, His139 and Val90 and fall into three clusters with the consensus sequences GD(IVTL)HG, GD(LYF)V(DA)RG and GNH, where brackets surround alternative amino acids. The first two consensus sequences are predicted to fall in the beta-alpha and beta-beta loops of a beta-alpha-beta-beta secondary-structure motif. This places the predicted phosphate-binding site at the N-terminus of the alpha helix, where phosphate binding may be stabilised by the alpha-helix dipole.

Alternative splicing within and between alleles of the ATPase gene 1 locus of Trypanosoma brucei

The P-type ATPase gene TBA1 of Trypanosoma brucei belongs to a polycistronic transcription unit. We analyzed the structure and expression of a 4-kb region located immediately downstream from TBA1. This region is unique and contains two large open reading frames transcribed into stable mRNAs. These putative genes, termed ADG1 and ADG2, can respectively encode a 24-kDa and a 81-kDa protein. The intergenic spacings between the polyadenylation sites and the next 3' splice acceptor sites are very short: 148 bp between TBA1 and ADG1, and 127 bp between ADG1 and ADG2. Transcripts from each of the two ADG1 alleles can be detected, indicating that both homologs are transcribed. These transcripts are differentially spliced due to a single base difference which destroys in one homolog the AG acceptor site present in the other. In the 'mutant' allele an alternative downstream splice acceptor site is used. Despite its sequence conservation in both alleles, this splice site is only used in the allele lacking the upstream AG acceptor site. The major population of ADG1 transcripts exhibit a long 5'-untranslated extension and no 3'-terminal tail, but a minor population shows a smaller 5'-untranslated region due alternative splicing closer to the initiation codon of the gene. The steady-state amounts of transcripts from individual genes in this region are differentially stage-regulated.

Genomic and transcriptional linkage of the genes for calmodulin, EF-hand 5 protein, and ubiquitin extension protein 52 in Trypanosoma brucei

We report genomic linkage of a pair of tandem, identical ubiquitin-extension protein 52 (EP52) genes, a novel EF-hand superfamily member gene (EFH5), and the calmodulin gene cluster in Trypanosoma brucei. The intergenic regions of these four genes are short: about 108 bp between the calmodulin gene C and the EFH5 gene, about 111 bp between the EFH5 gene and the ubiquitin-EP52/1 gene, and about 116 bp between the ubiquitin-EP52/1 and -EP52/2 genes. RNA molecules that span these three intergenic regions have been detected by polymerase chain reaction, which suggests that the genes are transcribed in a polycistronic manner. Transcription of the calmodulin, EFH5, and ubiquitin-EP52 genes in isolated nuclei is rapidly inactivated by UV irradiation, which further strengthens the hypothesis that this cluster of three different genes is transcribed in a polycistronic manner and suggests that they are under the control of a single distant upstream promoter. These results suggest that polycistronic transcription is common in trypanosomes and will probably be found for most, if not all, protein-encoding genes. The presence of at least three housekeeping genes with different known or potential regulatory functions within a polycistronic unit suggests that regulation of transcription initiation plays an important role in the coordinated expression of housekeeping genes in trypanosomes.

Genomic and transcriptional linkage of the genes for calmodulin, EF-hand 5 protein, and ubiquitin extension protein 52 in Trypanosoma brucei

We report genomic linkage of a pair of tandem, identical ubiquitin-extension protein 52 (EP52) genes, a novel EF-hand superfamily member gene (EFH5), and the calmodulin gene cluster in Trypanosoma brucei. The intergenic regions of these four genes are short: about 108 bp between the calmodulin gene C and the EFH5 gene, about 111 bp between the EFH5 gene and the ubiquitin-EP52/1 gene, and about 116 bp between the ubiquitin-EP52/1 and -EP52/2 genes. RNA molecules that span these three intergenic regions have been detected by polymerase chain reaction, which suggests that the genes are transcribed in a polycistronic manner. Transcription of the calmodulin, EFH5, and ubiquitin-EP52 genes in isolated nuclei is rapidly inactivated by UV irradiation, which further strengthens the hypothesis that this cluster of three different genes is transcribed in a polycistronic manner and suggests that they are under the control of a single distant upstream promoter. These results suggest that polycistronic transcription is common in trypanosomes and will probably be found for most, if not all, protein-encoding genes. The presence of at least three housekeeping genes with different known or potential regulatory functions within a polycistronic unit suggests that regulation of transcription initiation plays an important role in the coordinated expression of housekeeping genes in trypanosomes.

Genomic organisation and expression of a differentially-regulated gene family from Leishmania major

We have isolated and characterised a differentially-regulated gene family in the protozoan parasite Leishmania major. The family contains 5 genes linked within a 10Kb region of the genome: three of the genes are closely related in DNA sequence, the other two have only limited homology. Post-transcriptional control of the differential expression pattern is suggested by detection of precursor RNA molecules containing intergenic sequences and evidence that mature mRNA molecules contain a 35nt spliced leader sequence at their 5' ends. These features support a model of polycistronic transcription in which the stability and differential processing of precursor RNA molecules determine the steady state levels of mature mRNA. We have identified several DNA sequence motifs within the gene family that have potential roles in differential processing and/or RNA stability: an alternative 5' splice acceptor site for trans-splicing; a putative polyadenylation site; and a region of potential secondary structure within 3' flanking sequences. The 3' sequence elements are conserved in those genes that share the same pattern of differential regulation. To our knowledge, this is the first example of coordinated differential-regulation of a non-identical gene cluster in Leishmania.

Characterization of trypanosome protein phosphatase 1 and 2A catalytic subunits

Oligonucleotides corresponding to highly conserved regions of mammalian protein phosphatase catalytic subunits were used in the polymerase chain reaction (PCR) to generate an amplification product from genomic DNA of Trypanosoma brucei rhodesiense. The PCR product was used to screen a T. b. rhodesiense cDNA library for cDNA clones encoding putative protein phosphatase catalytic subunits. Two cDNA clones, (TPP1A and TPP1B) representing two distinct type 1 catalytic subunit isotypes, encode 39-kDa proteins of 346 amino acids that show 66% and 40% identity, respectively, to mammalian protein phosphatase 1 and 2A catalytic subunits. Both cDNAs are derived from 2.3-kb mRNAs, and Northern blot analysis has provided indirect evidence that these mRNAs are part of the same transcription unit as mRNAs for RNA polymerase II largest subunit. Another cDNA, TPP2, represents the type 2A class of phosphatases and codes for a 34.5-kDa protein of 303 amino acids. The deduced amino acid sequence has 39% and 55% identity, respectively, to the catalytic subunits of mammalian protein phosphatase 1 and 2A. Southern and Northern blot analyses are consistent with TPP2 being encoded by a single copy gene from which is derived a mRNA of 2.5 kb. This finding constitutes the first example in eukaryotes in which a single gene encodes the type 2A class of protein phosphatases. Sera from mice immunized with TPP1A fusion protein reacted with the catalytic subunits of mammalian types 1, 2A and 2B protein phosphatases. However, antisera to TPP2 fusion protein was specific for the type 2A catalytic subunit and recognized a polypeptide of 35 kDa in a Western blot of crude trypanosomal lysate.

Phylogenetic analysis of the RNA polymerases of Trypanosoma brucei, with special reference to class-specific transcription

We have sequenced the genes encoding to largest subunits of the three classes of DNA-dependent RNA polymerases of Trypanosoma brucei. The nucleotide and deduced amino acid sequences were compared and aligned with the corresponding sequences of other eukaryotes. Phylogenetic relationships were subsequently calculated with a distant matrix, a bootstrapped parsimony and a maximum-likelihood method. These independent calculations resulted in trees with very similar topologies. The analyses show that all the largest subunits of T. brucei are evolutionarily distant members within each of the three RNA polymerase classes. An early separation of the trypanosomal subunits from the eukaryotic lineage might form the fundamental basis for the unusual transcription process of this species. Finally, all dendrograms show a separate ramification for the largest subunit of RNA polymerase I, II and III. RNA polymerase II and/or III form a bifurcation with the archaebacterial lineage, RNA polymerase I, however, arises separately from the eubacterial beta' lineage. This suggests that the three eukaryotic RNA polymerase classes are not simply derived by two gene duplications of an ancestral gene with subsequent differentiation.