VSG gene 118 is transcribed from a cotransposed pol I-like promoter

Genomic Occupancy of the Bromodomain Protein Bdf3 Is Dynamic during Differentiation of African Trypanosomes from Bloodstream to Procyclic Forms

Trypanosoma brucei, the causative agent of human and animal African trypanosomiasis, cycles between a mammalian host and a tsetse fly vector. The parasite undergoes huge changes in morphology and metabolism during adaptation to each host environment. These changes are reflected in the different transcriptomes of parasites living in each host. However, it remains unclear whether chromatin-interacting proteins help mediate these changes. Bromodomain proteins localize to transcription start sites in bloodstream parasites, but whether the localization of bromodomain proteins changes as parasites differentiate from bloodstream to insect stages remains unknown. To address this question, we performed cleavage under target and release using nuclease (CUT&RUN) against bromodomain protein 3 (Bdf3) in parasites differentiating from bloodstream to insect forms. We found that Bdf3 occupancy at most loci increased at 3 h following onset of differentiation and decreased thereafter. A number of sites with increased bromodomain protein occupancy lie proximal to genes with altered transcript levels during differentiation, such as procyclins, procyclin-associated genes, and invariant surface glycoproteins. Most Bdf3-occupied sites are observed throughout differentiation. However, one site appears de novo during differentiation and lies proximal to the procyclin gene locus housing genes essential for remodeling surface proteins following transition to the insect stage. These studies indicate that occupancy of chromatin-interacting proteins is dynamic during life cycle stage transitions and provide the groundwork for future studies on the effects of changes in bromodomain protein occupancy. Additionally, the adaptation of CUT&RUN for Trypanosoma brucei provides other researchers with an alternative to chromatin immunoprecipitation (ChIP). IMPORTANCE The parasite Trypanosoma brucei is the causative agent of human and animal African trypanosomiasis (sleeping sickness). Trypanosomiasis, which affects humans and cattle, is fatal if untreated. Existing drugs have significant side effects. Thus, these parasites impose a significant human and economic burden in sub-Saharan Africa, where trypanosomiasis is endemic. T. brucei cycles between the mammalian host and a tsetse fly vector, and parasites undergo huge changes in morphology and metabolism to adapt to different hosts. Here, we show that DNA-interacting bromodomain protein 3 (Bdf3) shows changes in occupancy at its binding sites as parasites transition from the bloodstream to the insect stage. Additionally, a new binding site appears near the locus responsible for remodeling of parasite surface proteins during transition to the insect stage. Understanding the mechanisms behind host adaptation is important for understanding the life cycle of the parasite.

RNA polymerase I-mediated protein-coding gene expression in Trypanosoma brucei

Protein-coding genes are transcribed by RNA polymerise (pol) II in all eukaryotes analyzed to date, with the exception of the protozoan Trypanosoma brucei, where pol I can mediate expression of chloramphenicol acetyl transferase (CAT) and neomycin phosphotransferase (neo) reporter genes. The addition of the capped 39-nucleotide (nt) mini-exon to the pre-messenger RNA (mRNA) by trans-splicing in T. brucei has presumably led to the uncoupling of the requirement for production of mRNA by pol II. Here Hui-min Chung, Mary G-S. Lee and Lex Van der Ploeg review the evidence that supports the notion that pol I also transcribes a subset of naturally occurring protein-coding genes in T. brucei.

Mutational analysis of 3' splice site selection during trans-splicing

trans-Splicing is essential for mRNA maturation in trypanosomatids. A conserved AG dinucleotide serves as the 3' splice acceptor site, and analysis of native processing sites suggests that selection of this site is determined according to a 5'-3' scanning model. A series of stable gene replacement lines were generated that carried point mutations at or near the 3' splice site within the intergenic region separating CUB2.65, the calmodulin-ubiquitin associated gene, and FUS1, the ubiquitin fusion gene of Trypanosoma cruzi. In one stable line, the elimination of the native 3' splice acceptor site led to the accumulation of Y-branched splicing intermediates, which served as templates for mapping the first trans-splicing branch points in T. cruzi. In other lines, point mutations shifted the position of the first consensus AG dinucleotide either upstream or downstream of the wild-type 3' splice acceptor site in this intergenic region. Consistent with the scanning model, the first AG dinucleotide downstream of the branch points was used as the predominant 3' splice acceptor site. In all of the stable lines, the point mutations affected splicing efficiency in this region.

Transcriptional analysis of the glutamate dehydrogenase gene in the primitive eukaryote, Giardia lamblia. Identification of a primordial gene promoter

We studied gene expression in the ancient eukaryote, Giardia lamblia, by taking advantage of assays developed recently in our laboratory, which allow new genetic analyses of this organism. We examined the transcription of a 2.2-kilobase segment of the Giardia genome that contains the glutamate dehydrogenase (GDH) gene and a portion of a second open reading frame encoding an uncharacterized gene. Nuclear run-on analyses showed that the genes are transcribed as two separate units spaced less than 200 base pairs apart, and transcription of the GDH gene initiates just 3-6 nucleotides upstream of its translation start codon. We characterized the GDH promoter by transfecting Giardia with DNA constructs that used the GDH upstream sequence to drive the expression of a luciferase reporter gene. By deletion and mutational analyses, we localized promoter function to three motifs within a 50-base pair region of the GDH upstream sequence. Using band shift assays and UV cross-linking, we demonstrated specific binding of a 68-kDa protein from Giardia nuclear extracts to short poly(T) tracts contained within two of the sequence motifs on single-stranded DNA from the promoter region. This report describes one of the first functional gene promoter and its cognate DNA-binding protein in this primitive eukaryote.

Differential RNA elongation controls the variant surface glycoprotein gene expression sites of Trypanosoma brucei

The protozoan parasite Trypanosoma brucei develops antigenic variation to escape the immune response of its host. To this end, the trypanosome genome contains multiple telomeric expression sites competent for transcription of variant surface glycoprotein genes, but as a rule only a single antigen is expressed at any time. We used reverse transcription-PCR (RT-PCR) to analyse transcription of different segments of the expression sites in different variant clones of two independent strains of T. brucei. The results indicated that RNA polymerase is installed and active at the beginning of many, if not all, expression sites simultaneously, but that a progressive arrest of RNA elongation occurs in all but one site. This defect is linked to inefficient RNA processing and RNA release from the nucleus. Therefore, functional transcription in the active site appears to depend on the selective recruitment of a RNA elongation/processing machinery.

Trypanosoma brucei variant surface glycoprotein regulation involves coupled activation/inactivation and chromatin remodeling of expression sites

Trypanosoma brucei is an extracellular protozoan parasite that cycles between mammalian hosts and the tsetse vector. In bloodstream-form trypanosomes, only one variant surface glycoprotein gene (VSG) expression site (ES) is active at any time. Transcriptional switching between ESs results in antigenic variation. No VSG is transcribed in the insect procyclic stage. We have used bacteriophage T7 RNA polymerase (T7RNAP) to study the transcriptional accessibility of ES chromatin in vivo. We show that T7RNAP-mediated transcription from chromosomally integrated T7 promoters is repressed along the entire length of the ES in the procyclic form, but not in the bloodstream form, suggesting that the accessible chromatin of inactive bloodstream-form ESs is remodeled upon differentiation to yield a structure that is no longer permissive for T7RNAP-mediated transcription. In the bloodstream form, replacing the active ES promoter with a T7 promoter, which is incapable of sustaining high-level transcription of the entire ES, prompts an ES switch. These data suggest two distinct mechanisms for ES regulation: a chromatin-mediated developmental silencing of the ES in the procyclic form and a rapid coupled mechanism for ES activation and inactivation in the bloodstream form.

Co-duplication of a variant surface glycoprotein gene and its promoter to an expression site in African trypanosomes

Activation of the metacyclic variant antigen type 7 (MVAT7) variant surface glycoprotein (VSG) gene in bloodstream Trypanosoma brucei rhodesiense involves a duplicative transposition of the gene. The DNA transposition unit extends from a site approximately 3.0 kilobases upstream of the VSG gene through the coding region and includes a 73-base pair sequence that possesses promoter activity in transient transfections. This MVAT7 promoter has 80% identity to a previously characterized promoter for the MVAT4 VSG gene. Nuclear run-on assays demonstrate that the MVAT7 promoter is active in MVAT7 bloodstream organisms and that its transcript is synthesized by an RNA polymerase resistant to alpha-amanitin, consistent with previously published reports regarding VSG gene transcription. The transcription start site was identified by primer extension studies and a modified rapid amplification of cDNA ends protocol. Selective mutational analysis of the MVAT7 promoter showed that two conserved trinucleotide regions are important for full promoter function. This study demonstrates that the MVAT7 VSG gene is co-duplicated with its promoter and transcribed into a monocistronic precursor RNA.

DNA rearrangements associated with multiple consecutive directed antigenic switches in Trypanosoma brucei

Changes in variant surface glycoprotein (Vsg) expression allow Trypanosoma brucei to elude the immune response. The expressed vsg is always located at the telomeric end of a polycistronic transcription unit known as an expression site (ES). Although there are many ESs, only one is active at any particular time. The mechanisms regulating ES transcription and switching are unknown. Chromosome rearrangements within or upstream of the ES have been described to occur in occasional switch events, but no changes have been consistently associated with switching. We inserted the drug resistance genes neo and ble, conferring resistance to G418 and phleomycin, respectively, 1 kb downstream of "silent" ES promoters. This demonstrated that short-range transcription could be achieved from a silent ES promoter. From one initial transformant clone, panels of independent consecutive on-off-on switch clones were generated and analyzed. The first activation of the neo-targeted ES was always associated with deletion of the upstream tandem promoter in this ES, but no further rearrangements were detected in consecutive off-on switches of this ES. On the other hand, direct analysis of ES promoters showed that deletions and duplications occurred elsewhere. Activation of a ble-tagged 300-kb chromosome could not be achieved, but phleomycin-resistant clones could be obtained. One such clone arose from recombination between three ESs. Taken together, our experiments suggest that ES switching may occur after a period of chromosomal interactivity that may or may not leave tangible evidence in the form of detectable sequence changes.

Antigenic variation in trypanosomes: secrets surface slowly

Among pathogenic micro-organisms that evade the mammalian immune responses. Trypanosoma brucei has developed the most elaborate capacity for antigenic variation. Trypanosomes branched early during eukaryotic evolution. They are characterized by many aberrations, ranging from the unusual compartmentation of metabolic pathways to the heresy of RNA editing. The ubiquitous phenomenon of glycosylphosphatidylinositol-anchoring of eukaryotic plasma membrane proteins and RNA trans-splicing (trypanosome genes contain no introns), which adds an identical leader sequence to all trypanosome mRNAs, were first defined during studies of antigenic variation. Genetic transformation of trypanosomes and the high efficiency of gene targeting provide new opportunities to investigate the regulation of antigenic variation. There is every reason to expect trypanosomes to provide further surprises and insights into the evolution of genetic regulatory mechanisms.

Transcriptional regulation of metacyclic variant surface glycoprotein gene expression during the life cycle of Trypanosoma brucei

In antigenic variation in African trypanosomes, switching of the variant surface glycoprotein (VSG) allows evasion of the mammalian host immune response. Trypanosomes first express the VSG in the tsetse fly vector, at the metacyclic stage, in preparation for transfer into the mammal. In this life cycle stage, a small, specific subset (1 to 2%) of VSGs are activated, and we have shown previously that the system of activation and expression of metacyclic VSG (M-VSG) genes is very different from that used for bloodstream VSG genes (S.V. Graham, K.R. Matthews, P.G. Shiels, and J.D. Barry, Parasitology 101:361-367, 1990). Now we show that unlike other trypanosome genes including bloodstream VSG genes, M-VSG genes are expressed from promoters subject to exclusively transcriptional regulation in a life cycle stage-dependent manner. We have located an M-VSG gene promoter, and we demonstrate that it is specifically up-regulated at the metacyclic stage. This is the first demonstration of gene expression being regulated entirely at the level of transcription among the Kinetoplastida; all other protein-coding genes examined in these organisms are, at least partly, under posttranscriptional control. The distinctive mode of expression of M-VSG genes may be due to a stochastic mechanism for metacyclic VSG activation.

PARP promoter-mediated activation of a VSG expression site promoter in insect form Trypanosoma brucei

In trypanosomes the rRNA, PARP and VSG gene promoters mediate alpha-amanitin-resistant transcription of protein coding genes, presumably by RNA polymerase (pol) I. We compared the activity of PARP and VSG promoters integrated at one of the alleles of the largest subunit of pol II genes in insect form trypanosomes. Even though both promoters are roughly equally active in transient transformation assays in insect form trypanosomes, only the PARP promoter functioned effectively when integrated at the pol II largest subunit or other loci. Promoter activity in transient transformation assays is therefore not necessarily predictive of transcriptional activity once integrated into the trypanosome genome. The integrated fully active PARP promoter could upregulate in cis an otherwise poorly active integrated VSG promoter. The PARP promoter nucleotide sequence elements responsible for VSG promoter activation coincided with most of the important PARP promoter elements mapped previously by linker scanning mutagenesis, indicating that it is not a single unique promoter element that was responsible for VSG promoter activation. The data suggest that PARP promoter-mediated activation of the VSG promoter does not result from complementation of the VSG promoter with a single insect form-specific transcription factor whose binding site is missing from the VSG promoter and present in the PARP promoter. We favor a model in which chromatin structure at the locus is altered by the PARP promoter, allowing VSG promoter activation in insect form trypanosomes. We discuss the significance of these observations for the control of VSG promoters in insect form 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.

Molecular characterization of the largest subunit of Plasmodium falciparum RNA polymerase I

Plasmodium species possess developmentally regulated ribosomal RNA (rRNA) genes. This report describes the expression and gene structure of the largest subunit of P. falciparum RNA polymerase I (RNAPI), which is responsible for the synthesis of rRNA. The RNAPI largest subunit gene was present as a single copy gene on chromosome 9. Three exons encode the 2910-amino acid RNAPI polypeptide (340 140 Da). A comparison of Plasmodium, Trypanosoma, and Saccharomyces cerevisiae nuclear RNAP largest subunits identified conserved amino acid positions and class-specific amino acid positions. Novel amino acid insertions were found between RNAPI conserved regions A and B (region A'), D and DE1 (region D'), DE2 and E (region DE2'), and F and G (region F'). Leucine zipper domains were found within regions D', DE2, and DE2'. A novel serine-rich repeat domain, a domain with homology to the C-terminal domain of eukaryotic upstream binding factor (UBF), and 4 highly conserved casein kinase II (CKII) Ser/Thr phosphorylation motifs were found within a 127-amino acid sub-region of enlarged region F'. The novel RNAPI serine-rich repeat contained a conserved motif, Ser-X3-Ser, which was also identified in the serine-rich repeat domains of the P. falciparum RNAPII and RNAPIII largest subunits, as well as within a highly homologous serine-rich repeat from trophozoite antigen R45. The results of this molecular analysis indicate that phosphorylation and dephosphorylation mechanisms regulate the activity of P. falciparum RNAPI.

Disruption of largest subunit RNA polymerase II genes in Trypanosoma brucei

Two types of largest subunit RNA polymerase II (pol II) genes (pol IIA and pol IIB), differing in 3 amino acid substitutions, are encoded in the Trypanosoma brucei (stock 427-60) genome. As a result, the alpha-amanitin-resistant transcription of the procyclic acidic repetitive protein (PARP) and variant surface glycoprotein (VSG) genes was proposed to involve a modified, alpha-amanitin-resistant form of the largest subunit of pol II. Alternatively, pol I could transcribe the PARP and VSG genes. To discriminate between these two models, we deleted the N-terminal domain (about one-third of the polypeptide), which encodes the amino acid substitutions which discriminated the pol IIA and pol IIB genes, at both pol IIB alleles. The pol IIB- trypanosomes still transcribe the PARP genes and the VSG gene promoter region in insect-form trypanosomes by alpha-amanitin-resistant RNA polymerases, while control housekeeping genes are transcribed in an alpha-amanitin-sensitive manner, presumably by pol IIA. We conclude that the alpha-amanitin-resistant transcription of protein coding genes in T. brucei is not mediated by a diverged form of the largest subunit of pol II and that the presence of both the pol IIA and pol IIB genes is not essential for trypanosome viability. This conclusion was further supported by the finding that individual trypanosome variants exhibited allelic heterogeneity for the previously identified amino acid substitutions and that various permutations of the polymorphic amino acids generate at least four different types of largest subunit pol II genes. The expression of the PARP genes and the VSG gene promoter region by alpha-amanitin-resistant RNA polymerases in the pol IIB- trypanosomes provides evidence for transcription of these genes by pol I.

Disruption of largest subunit RNA polymerase II genes in Trypanosoma brucei

Two types of largest subunit RNA polymerase II (pol II) genes (pol IIA and pol IIB), differing in 3 amino acid substitutions, are encoded in the Trypanosoma brucei (stock 427-60) genome. As a result, the alpha-amanitin-resistant transcription of the procyclic acidic repetitive protein (PARP) and variant surface glycoprotein (VSG) genes was proposed to involve a modified, alpha-amanitin-resistant form of the largest subunit of pol II. Alternatively, pol I could transcribe the PARP and VSG genes. To discriminate between these two models, we deleted the N-terminal domain (about one-third of the polypeptide), which encodes the amino acid substitutions which discriminated the pol IIA and pol IIB genes, at both pol IIB alleles. The pol IIB- trypanosomes still transcribe the PARP genes and the VSG gene promoter region in insect-form trypanosomes by alpha-amanitin-resistant RNA polymerases, while control housekeeping genes are transcribed in an alpha-amanitin-sensitive manner, presumably by pol IIA. We conclude that the alpha-amanitin-resistant transcription of protein coding genes in T. brucei is not mediated by a diverged form of the largest subunit of pol II and that the presence of both the pol IIA and pol IIB genes is not essential for trypanosome viability. This conclusion was further supported by the finding that individual trypanosome variants exhibited allelic heterogeneity for the previously identified amino acid substitutions and that various permutations of the polymorphic amino acids generate at least four different types of largest subunit pol II genes. The expression of the PARP genes and the VSG gene promoter region by alpha-amanitin-resistant RNA polymerases in the pol IIB- trypanosomes provides evidence for transcription of these genes by pol I.

Molecular variation in trypanosomes

Several species of the genus Trypanosoma cause parasitic diseases of considerable medical and veterinary importance throughout Africa, Asia and the Americas. These parasites exhibit considerable intra-species genetic diversity and variation, which has complicated their taxonomic classification. This diversity and variation can be defined at the level of both the genome and of individual genes. The nuclear genome shows considerable inter- and intra-species plasticity in terms of chromosome number and size (molecular karyotype). The mitochondrial (kDNA) genome also varies considerably between species, especially in terms of minicircle size and organization. There is also considerable intra-specific sequence diversity in minicircles and within the Variable Region of the maxicircle. Restriction enzyme analysis of this diversity has lead to the concept of 'schizodemes'. At the gene level, isoenzyme analysis has proven very useful for strain and isolate identification, with the classification into numerous 'zymodemes'. Considerable antigenic diversity has also been identified in T. cruzi and T. brucei, with the development of 'serodemes' in the latter. In addition to this inter-strain diversity, African trypanosomes (T. brucei, T. congolense, and T. vivax) exhibit the phenomenon of antigenic variation, where individual parasites are able to express any one of hundreds of different copies of the Variant Surface Glycoprotein gene at any particular time. The molecular mechanisms underlying antigenic variation are now understood in considerable detail. The implication of this molecular diversity and variation are discussed in terms of trypanosome taxonomy and disease control.

A proposed mechanism for promoter-associated DNA rearrangement events at a variant surface glycoprotein gene expression site

The expressed variant cell surface glycoprotein (VSG) gene of the protozoan parasite Trypanosoma brucei is invariably found at one of several telomeric VSG gene expression sites (ESs). The active ES in variant 118 clone 1 is found on a 1.5-Mb chromosome, and the promoter region is located more than 45 kb upstream of the VSG gene. We had previously shown that DNA rearrangement events occurred in the promoter region, specifically at inactivation of this ES (K. M. Gottesdiener, H.-M. Chung, S. L. Brown, M. G.-S. Lee, and L. H. T. Van der Ploeg, Mol. Cell. Biol. 11:2467-2477, 1991). In this report, we describe the cloning of the entire 17-kb promoter region, which revealed the presence of two identical 2.15-kb tandem promoter repeats separated by 13 kb of DNA. The two virtually identical promoter repeats both function efficiently in directing transcription in transient transfection assays in insect-form trypanosomes. We characterized the DNA rearrangement events that occur at ES inactivation, and by studying both of the reciprocal products of this recombination event, we infer that these result from direct (promoter) repeat recombination, formation of heteroduplex DNA, and a reciprocal exchange event that releases a circular DNA as a side product of the reaction. The finding of DNA recombinational events in a region of the VSG gene ES that encodes the promoter(s), and their relatively frequent occurrence at ES inactivation, suggests a possible role in ES control.

A proposed mechanism for promoter-associated DNA rearrangement events at a variant surface glycoprotein gene expression site

The expressed variant cell surface glycoprotein (VSG) gene of the protozoan parasite Trypanosoma brucei is invariably found at one of several telomeric VSG gene expression sites (ESs). The active ES in variant 118 clone 1 is found on a 1.5-Mb chromosome, and the promoter region is located more than 45 kb upstream of the VSG gene. We had previously shown that DNA rearrangement events occurred in the promoter region, specifically at inactivation of this ES (K. M. Gottesdiener, H.-M. Chung, S. L. Brown, M. G.-S. Lee, and L. H. T. Van der Ploeg, Mol. Cell. Biol. 11:2467-2477, 1991). In this report, we describe the cloning of the entire 17-kb promoter region, which revealed the presence of two identical 2.15-kb tandem promoter repeats separated by 13 kb of DNA. The two virtually identical promoter repeats both function efficiently in directing transcription in transient transfection assays in insect-form trypanosomes. We characterized the DNA rearrangement events that occur at ES inactivation, and by studying both of the reciprocal products of this recombination event, we infer that these result from direct (promoter) repeat recombination, formation of heteroduplex DNA, and a reciprocal exchange event that releases a circular DNA as a side product of the reaction. The finding of DNA recombinational events in a region of the VSG gene ES that encodes the promoter(s), and their relatively frequent occurrence at ES inactivation, suggests a possible role in ES control.

The promoter for the procyclic acidic repetitive protein (PARP) genes of Trypanosoma brucei shares features with RNA polymerase I promoters

All eukaryotic protein-coding genes are believed to be transcribed by RNA polymerase (Pol) II. An exception may exist in the protozoan parasite Trypanosoma brucei, in which the genes encoding the variant surface glycoprotein (VSG) and procyclic acidic repetitive protein (PARP) are transcribed by an RNA polymerase that is resistant to the Pol II inhibitor alpha-amanitin. The PARP and VSG genes were proposed to be transcribed by Pol I (C. Shea, M. G.-S. Lee, and L. H. T. Van der Ploeg, Cell 50:603-612, 1987; G. Rudenko, M. G.-S. Lee, and L. H. T. Van der Ploeg, Nucleic Acids Res. 20:303-306, 1992), a suggestion that has been substantiated by the finding that trypanosomes can transcribe protein-coding genes by Pol I (G. Rudenko, H.-M. Chung, V. P. Pham, and L. H. T. Van der Ploeg, EMBO J. 10:3387-3397, 1991). We analyzed the sequence elements of the PARP promoter by linker scanning mutagenesis and compared the PARP promoter with Pol I, Pol II, and Pol III promoters. The PARP promoter appeared to be of limited complexity and contained at least two critical regions. The first was located adjacent to the transcription initiation site (nucleotides [nt] -69 to +12) and contained three discrete domains in which linker scanning mutants affected the transcriptional efficiency: at nt -69 to -56, -37 to -11, and -11 to +12. The second region was located between nt -140 and -131, and a third region may be located between nt -228 and -205. The nucleotide sequences of these elements, and their relative positioning with respect to the transcription initiation site did not resemble those of either Pol II or Pol III promoter elements, but rather reflected the organization of Pol I promoters in (i) similarity in the positioning of essential domains in the PARP promoter and Pol I promoter, (ii) strong sequence homology between the PARP core promoter element (nt -37 to -11) and identically positioned nucleotide sequences in the trypanosome rRNA and VSG gene promoters, and (iii) moderate effects on promoter activity of mutations around the transcription initiation site.

The promoter for the procyclic acidic repetitive protein (PARP) genes of Trypanosoma brucei shares features with RNA polymerase I promoters

All eukaryotic protein-coding genes are believed to be transcribed by RNA polymerase (Pol) II. An exception may exist in the protozoan parasite Trypanosoma brucei, in which the genes encoding the variant surface glycoprotein (VSG) and procyclic acidic repetitive protein (PARP) are transcribed by an RNA polymerase that is resistant to the Pol II inhibitor alpha-amanitin. The PARP and VSG genes were proposed to be transcribed by Pol I (C. Shea, M. G.-S. Lee, and L. H. T. Van der Ploeg, Cell 50:603-612, 1987; G. Rudenko, M. G.-S. Lee, and L. H. T. Van der Ploeg, Nucleic Acids Res. 20:303-306, 1992), a suggestion that has been substantiated by the finding that trypanosomes can transcribe protein-coding genes by Pol I (G. Rudenko, H.-M. Chung, V. P. Pham, and L. H. T. Van der Ploeg, EMBO J. 10:3387-3397, 1991). We analyzed the sequence elements of the PARP promoter by linker scanning mutagenesis and compared the PARP promoter with Pol I, Pol II, and Pol III promoters. The PARP promoter appeared to be of limited complexity and contained at least two critical regions. The first was located adjacent to the transcription initiation site (nucleotides [nt] -69 to +12) and contained three discrete domains in which linker scanning mutants affected the transcriptional efficiency: at nt -69 to -56, -37 to -11, and -11 to +12. The second region was located between nt -140 and -131, and a third region may be located between nt -228 and -205. The nucleotide sequences of these elements, and their relative positioning with respect to the transcription initiation site did not resemble those of either Pol II or Pol III promoter elements, but rather reflected the organization of Pol I promoters in (i) similarity in the positioning of essential domains in the PARP promoter and Pol I promoter, (ii) strong sequence homology between the PARP core promoter element (nt -37 to -11) and identically positioned nucleotide sequences in the trypanosome rRNA and VSG gene promoters, and (iii) moderate effects on promoter activity of mutations around the transcription initiation site.

The PARP and VSG genes of Trypanosoma brucei do not resemble RNA polymerase II transcription units in sensitivity to Sarkosyl in nuclear run-on assays

Addition of the ionic detergent N-lauroylsarcosine (Sarkosyl) affects the efficiency of transcription of genes of the protozoan Trypanosoma brucei in nuclear run-on assays. Transcription of the PARP (procyclin or procyclic acidic repetitive protein), variant cell surface glycoprotein (VSG) and ribosomal RNA (rRNA) genes was resistant or increased after addition of Sarkosyl. In contrast, the transcription of seven protein coding house keeping genes and the mini-exon donor RNA (medRNA) genes was completely abolished by the addition of Sarkosyl, while the transcription of the 5S rRNA genes showed an intermediate sensitivity. We conclude that Sarkosyl can be used to discriminate between the different types of trypanosome transcription units. The PARP and VSG protein coding genes had previously been postulated to be transcribed by an RNA polymerase I-like enzyme on the basis of their resistance to the RNA polymerase II inhibitor alpha-amanitin. This model is now supported by their resistance to the addition of Sarkosyl.

Alpha-amanitin-resistant transcription units in trypanosomes: a comparison of promoter sequences for a VSG gene expression site and for the ribosomal RNA genes

Transcription of the predominant surface antigen genes in Trypanosoma brucei is unusual in its resistance to the RNA polymerase inhibitor alpha-amanitin, a property typical for rDNA transcription in eukaryotes. Transcription of most other protein-coding genes in trypanosomes is sensitive to alpha-amanitin. To investigate whether RNA polymerase I, the polymerase that transcribes rRNA genes, can give rise to functional mRNAs in trypanosomes, we have fused the putative promoter of the T.brucei rRNA genes to the chloramphenicol acetyl transferase (CAT) gene and determined CAT activity after transient expression of chimeric constructs in procyclic trypanosomes. We show here that the rRNA promoter yields the same high CAT activity as the promoters for the two predominant surface antigen genes of trypanosomes, the Variant-specific Surface Glycoprotein (VSG) gene of bloodstream trypanosomes and the procyclin gene of insect-form trypanosomes, both of which are also transcribed by an alpha-amanitin-insensitive RNA polymerase. RNA polymerase I of trypanosomes seems therefore able to synthesize pre-mRNAs that are effectively processed into translatable mRNAs. Dissection of the promoter segments showed the minimal elements for a VSG gene expression site promoter to be confined to a segment of -60 to +77 bp, overlapping the most 5' putative transcription start sites as determined in vivo by RNase protection experiments. For the ribosomal promoter region a segment of -258 to +200 bp relative to the putative transcription start site was sufficient for maximal CAT activity. There is a precise requirement for specific nucleotides at the rRNA transcription start site. We detect no homology between the sequences required for promoter function of the three alpha-amanitin-resistant transcription units, rRNA, VSG and procyclin (parp) genes. This suggests that the sequence-specific recognition of these promoters either occurs by common factors detecting sequence homologies that escape us, or by separate factors that bind to different DNA sequences but interact with a common alpha-amanitin-resistant RNA polymerase.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

Expression site-associated genes transcribed independently of variant surface glycoprotein genes in Trypanosoma brucei

Expression site-associated genes (ESAGs) of Trypanosoma brucei are found upstream of variant surface glycoprotein (VSG) genes in bloodstream expression sites. There are at least 6 different ESAGs in each of these expression sites, and each ESAG is repetitive in the genome. ESAGs are believed to reside only in VSG expression sites and to be co-transcribed with the VSG gene from a common alpha-amanitin-insensitive promoter. Our results show that this is not always true. The transcriptionally active 1.22 metacyclic expression site contains no ESAGs, but ESAGs are highly transcribed in these cells. The level of transcription indicates that more than one copy of each of these genes is active. Furthermore, some of these genes are transcribed, to produce steady state RNA, in procyclic culture cells which do not express the VSG gene: there is differential expression of ESAGs between the bloodstream and procyclic phases of the trypanosome life cycle. Thus ESAGs can be transcribed outwith an active VSG gene expression site and in the absence of expression of the VSG.

RNA-protein complexes mediate in vitro capping of the spliced-leader primary transcript and U-RNAs in Trypanosoma cruzi

A 39-nucleotide spliced leader (SL) is joined to the 5' ends of trypanosome mRNAs in a bimolecular or trans-splicing process. The SL in Trypanosoma cruzi is transcribed as an approximately 110-nucleotide RNA (SL-RNA or SL primary transcript) bearing the 39-nucleotide SL at the 5' end. The SL-RNA is 5' capped by a guanylyltransferase activity prior to trans-splicing and trypanosome mRNAs thus obtain their mature caps from the SL by trans-splicing. We have previously characterized a guanylyltransferase activity from T. cruzi nuclear extracts and shown that this capping activity has an unusual ATP dependence and an apparent specificity for the SL-RNA and U-RNAs. Herein, we show that the capping activity sediments as a 12-15S particle during velocity sedimentation in glycerol gradients and fractionates as a greater than 150-kDa particle during large-pore gel filtration chromatography. Moreover, the endogenous substrate RNAs--the SL-RNA and U-RNAs--consistently copurify with the capping activity, suggesting that the activity and the substrates form a ribonucleoprotein particle. The capping activity and substrate RNAs are not dissociated in isopycnic Cs2SO4 gradients and band at a density expected for an RNA-protein complex, confirming the existence of ribonucleoprotein particles bearing both the activity and its substrate RNAs. Finally, we partially purified these ribonucleoprotein particles and showed that the capping activity remains ATP dependent and highly specific for the SL-RNA and the U-RNAs. These observations are consistent with the hypothesis that one of the functions of trans-splicing is for mRNA capping.

Characterization of a novel developmentally regulated gene from Trypanosoma brucei encoding a potential phosphoprotein

We have isolated a cDNA clone corresponding to a single-copy nuclear gene that is upregulated at the mRNA level during in vitro differentiation of bloodstream trypomastigotes of strains of both Trypanosoma brucei brucei and Trypanosoma brucei rhodesiense to procyclic forms. Transcript levels begin to increase within minutes of introduction of bloodstream forms into culture and peak well before cultures exhibit a procyclic morphology. This increase in transcript levels was found to occur both in the absence of protein synthesis and in a nontransforming strain blocked very early in the developmental program, both conditions under which accumulation of procyclic acidic repetitive protein (PARP) transcripts did not occur in control experiments. DNA sequence analysis reveals an open reading frame sufficient to encode a protein of approximately 50 kDa within the cDNA, but data base searches for homology at either the amino acid or nucleotide level revealed no related sequences. A high density of kinase consensus target sites in the deduced amino acid sequence suggests that the gene product may be a phosphoprotein.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

Characterization of VSG gene expression site promoters and promoter-associated DNA rearrangement events

The expressed variant cell surface glycoprotein (VSG) gene of Trypanosoma brucei is located at the 3' end of a large, telomeric, polycistronic transcription unit or expression site. We show that the region 45 kb upstream of the VSG gene, in the expression site on a 1.5-Mb chromosome, contains at least two promoters that are arranged in tandem, directing the transcription of the expression site. DNA rearrangement events occur specifically, at inactivation of the expression site, and these events delete the most upstream transcribed region and replace it with a large array of simple-sequence DNA, leaving the downstream promoter intact. Because of the placement of simple-sequence DNA, the remaining downstream promoter now becomes structurally identical to previously described VSG promoters. The downstream promoter is repetitive in the genome, since it is present at several different expression sites. Restriction fragment length polymorphism mapping allows grouping of the expression sites into two families, those with and those without an upstream transcription unit, and the DNA rearrangement events convert the expression sites from one type to the other. Deletion of the upstream transcription unit also leads to the loss of several steady-state RNAs. The findings may indicate a role for promoter-associated DNA rearrangement events, and/or interactions between tandemly arranged promoters, in expression site transcriptional control.

Characterization of VSG gene expression site promoters and promoter-associated DNA rearrangement events

The expressed variant cell surface glycoprotein (VSG) gene of Trypanosoma brucei is located at the 3' end of a large, telomeric, polycistronic transcription unit or expression site. We show that the region 45 kb upstream of the VSG gene, in the expression site on a 1.5-Mb chromosome, contains at least two promoters that are arranged in tandem, directing the transcription of the expression site. DNA rearrangement events occur specifically, at inactivation of the expression site, and these events delete the most upstream transcribed region and replace it with a large array of simple-sequence DNA, leaving the downstream promoter intact. Because of the placement of simple-sequence DNA, the remaining downstream promoter now becomes structurally identical to previously described VSG promoters. The downstream promoter is repetitive in the genome, since it is present at several different expression sites. Restriction fragment length polymorphism mapping allows grouping of the expression sites into two families, those with and those without an upstream transcription unit, and the DNA rearrangement events convert the expression sites from one type to the other. Deletion of the upstream transcription unit also leads to the loss of several steady-state RNAs. The findings may indicate a role for promoter-associated DNA rearrangement events, and/or interactions between tandemly arranged promoters, in expression site transcriptional control.

A family of genes related to a new expression site-associated gene in Trypanosoma equiperdum

Two genes, belonging to a new expression site-associated gene family of six to eight members in Trypanosoma equiperdum and Trypanosoma brucei, have been cloned from a T. equiperdum variant. One of them, called ESAG-9c, is contained in the 1.78-C expression site and is found just upstream of the 5' barren region. The other one, called ESAG-9u, is unique in the family, is not telomere linked, and apparently is not expression site related. A 2-kb poly(A)+ mRNA is detected with probes for this ESAG-9 family in all T. equiperdum variants examined. By using polymerase chain reaction and restriction fragment length polymorphism techniques, it has been possible to distinguish between ESAG-9c and ESAG-9u and to show that ESAG-9c is transcribed in an expression site-specific manner. However, ESAG-9u (or another gene in the family having identical characteristics) is transcribed in all variants, regardless of the expression site used by these variants. Thus, this ESAG-9 family contains at least one gene that is under expression site control but might have other genes that are not. The function of these ESAG-9 genes is unknown. Transcripts homologous to ESAG-9 were detected in T. brucei bloodstream forms but not in procyclics.

Antigenic variation in Trypanosoma brucei: a telomeric expression site for variant-specific surface glycoprotein genes with novel features

African trypanosomes evade the immune response of their host by periodically changing their variant surface glycoprotein (VSG) coat. Each coat is encoded by a separate VSG gene. Expressed genes are in a telomeric expression site (ES) and there are several sites in each trypanosome. To study the transcription control of VSG genes in Trypanosoma brucei we have analyzed an ES, called the dominant ES (DES), that readily switches off and on. The promoter area of the DES is very similar to that of the 221 ES (Zomerdijk et al., 1990). It can be switched off and on in vivo without detectable DNA alterations in the vicinity of the transcription start and it can drive high transient expression of a reporter gene in transfection experiments. However, there are also two major differences between the DES and the 221 ES. First, one version of the DES contains an additional upstream transcription unit overlapping the VSG gene ES promoter. The presence of this upstram transcription is dispensable, however, for the VSG gene ES promoter is active, even if transcription through this start from the upstream promoter is blocked using UV light. Moreover, a second version of the DES present in another trypanosome variant does not produce these upstream transcripts. Secondly, we find that the inactivation of DES transcription in one trypanosome variant is accompanied by DNA alterations in the DES upstream (greater than 2 kb) of the transcription start; reactivation of DES transcription is accompanied by another alteration far upstream. Although we cannot exclude that these DNA rearrangements are incidental, our results raise the possibility that the activity of ES promoters is negatively controlled in cis by far upstream sequences not included in transfection constructs and that alterations in these sequences may lead to (in)activation of the promoter.

A family of genes related to a new expression site-associated gene in Trypanosoma equiperdum

Two genes, belonging to a new expression site-associated gene family of six to eight members in Trypanosoma equiperdum and Trypanosoma brucei, have been cloned from a T. equiperdum variant. One of them, called ESAG-9c, is contained in the 1.78-C expression site and is found just upstream of the 5' barren region. The other one, called ESAG-9u, is unique in the family, is not telomere linked, and apparently is not expression site related. A 2-kb poly(A)+ mRNA is detected with probes for this ESAG-9 family in all T. equiperdum variants examined. By using polymerase chain reaction and restriction fragment length polymorphism techniques, it has been possible to distinguish between ESAG-9c and ESAG-9u and to show that ESAG-9c is transcribed in an expression site-specific manner. However, ESAG-9u (or another gene in the family having identical characteristics) is transcribed in all variants, regardless of the expression site used by these variants. Thus, this ESAG-9 family contains at least one gene that is under expression site control but might have other genes that are not. The function of these ESAG-9 genes is unknown. Transcripts homologous to ESAG-9 were detected in T. brucei bloodstream forms but not in procyclics.

Structure of a telomeric expression site for variant specific surface antigens in Trypanosoma brucei

We have studied the organization of the expression site, in which most chromosome-internal variant-specific surface glycoprotein (VSG) genes of Trypanosoma brucei strain 427 are expressed (the dominant expression site) and compared it to the previously characterized VSG 221 expression site. With the exception of a 500 bp segment and a VSG pseudogene, which are absent from the dominant expression site, overall all major sequence elements of the two sites are organized similarly, as judged from their relative mapping positions by UV inactivation of transcription. Transcription is insensitive to 1 mg alpha-amanitin per ml, a characteristic property of VSG gene expression sites analyzed thus far. The sequence elements of the dominant expression site include at least one other expressed gene of unknown function and homologues of at least two other open reading frames. The large internal duplication of the 60-kb 221 expression site appear to be missing from the dominant site, resulting in a shorter, 40-kb transcription unit. As judged from its relative sensitivity to UV inactivation of transcription, a subsidiary promoter, identified by other methods in the dominant expression site appears fully dependent for its activity on the promoter located 40 kb upstream of the VSG gene. We conclude that all VSG gene expression sites may be similarly organized as large polygenic transcription units.

In vitro capping in Trypanosoma cruzi identifies and shows specificity for the spliced leader RNA and U-RNAs

Messenger RNA maturation in trypanosomes requires a trans-splicing event in which a capped 39 nucleotide leader sequence, the spliced leader (SL), from the 5' terminus of a small RNA (SL-RNA) is joined to the 5' termini of protein coding gene transcripts. We have developed nuclear extracts from Trypanosoma cruzi that label three small endogenous RNAs in the presence of [alpha-32P]GTP. Herein, we have characterized this labelling as 5' capping and shown that the capping activity exhibits an unusual ATP dependence. Moreover, partial sequence analysis identified the three cap-labelled RNAs as the T. cruzi SL-RNA, and two U-RNAs previously uncharacterized in T. cruzi, U2 and Ux. Finally, the capping reaction in the T. cruzi extracts showed apparent specificity for these RNAs--other endogenous or exogenous transcripts were not capped. The apparent specificity of this in vitro capping activity closely reflects the in vivo requirements; i.e., only the SL- and U-RNAs need to be capped since mature mRNAs are capped via trans-splicing. These observations are consistent with the hypothesis that one of the functions of trans-splicing is to supply 5' caps to mature trypanosome mRNAs.

Procyclic acidic repetitive protein (PARP) genes located in an unusually small alpha-amanitin-resistant transcription unit: PARP promoter activity assayed by transient DNA transfection of Trypanosoma brucei

At least one of the procyclic acidic repetitive protein (PARP or procyclin) loci of Trypanosoma brucei is a small (5- to 6-kilobase) polycistronic transcription unit which is transcribed in an alpha-amanitin-resistant manner. Its single promoter, as mapped by run-on transcription analysis and UV inactivation of transcription, is located immediately upstream of the first alpha-PARP gene. Transcription termination occurs in a region approximately 3 kilobases downstream of the beta-PARP gene. The location of the promoter was confirmed by its ability to direct transcription of the bacterial chloramphenicol acetyltransferase gene in insect-form (procyclic) T. brucei. The putative PARP promoter is located in the region between the 3' splice acceptor site (nucleotide position 0) and nucleotide position -196 upstream of the alpha-PARP genes. Regulatory regions influencing the levels of PARP expression may be located further upstream. We conclude that a single promoter, which is located very close to the 3' splice acceptor site of the alpha-PARP genes, directs the transcription of a small, polycistronic, and alpha-amanitin-resistant transcription unit.

Procyclic acidic repetitive protein (PARP) genes located in an unusually small alpha-amanitin-resistant transcription unit: PARP promoter activity assayed by transient DNA transfection of Trypanosoma brucei

At least one of the procyclic acidic repetitive protein (PARP or procyclin) loci of Trypanosoma brucei is a small (5- to 6-kilobase) polycistronic transcription unit which is transcribed in an alpha-amanitin-resistant manner. Its single promoter, as mapped by run-on transcription analysis and UV inactivation of transcription, is located immediately upstream of the first alpha-PARP gene. Transcription termination occurs in a region approximately 3 kilobases downstream of the beta-PARP gene. The location of the promoter was confirmed by its ability to direct transcription of the bacterial chloramphenicol acetyltransferase gene in insect-form (procyclic) T. brucei. The putative PARP promoter is located in the region between the 3' splice acceptor site (nucleotide position 0) and nucleotide position -196 upstream of the alpha-PARP genes. Regulatory regions influencing the levels of PARP expression may be located further upstream. We conclude that a single promoter, which is located very close to the 3' splice acceptor site of the alpha-PARP genes, directs the transcription of a small, polycistronic, and alpha-amanitin-resistant transcription unit.

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.

Transcription of the heat shock 70 locus in Trypanosoma brucei

The 23-kb heat shock 70 locus of the protozoan parasite Trypanosoma brucei encodes several tightly clustered genes. From 5' to 3', a cognate hsp70 gene (gene 1) (see preceding paper, Lee et al.) is separated from a cluster of five identical hsp70 genes (genes 2-6) by about 6 kb of DNA that encodes several RNAs of unknown function. Polycistronic transcripts could be detected in the tandem array of hsp70 genes 2-6 and the maturation of the hsp70 pre-mRNAs involves addition of mini-exons on at least two different alternate 3' splice acceptor sites. Potential heat shock transcription factor binding sites are present upstream of hsp70 gene 2 and in the intergenic regions of hsp70 genes 2-6, but could not be found upstream of the cognate hsp70 gene 1.

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.

Trypanosoma brucei: posttranscriptional control of the variable surface glycoprotein gene expression site

The arrest of variable surface glycoprotein (VSG) synthesis is one of the first events accompanying the differentiation of Trypanosoma brucei bloodstream forms into procyclic forms, which are characteristic of the insect vector. This is because of a very fast inhibition of VSG gene transcription which occurs as soon as the temperature is lowered. We report that this effect is probably not controlled at the level of transcription initiation, since the beginning of the VSG gene expression site, about 45 kilobases upstream from the antigen gene, remains transcribed in procyclic forms. The permanent activity of the promoter readily accounts for the systematic reappearance, upon return to the bloodstream form after cyclical transmission, of the antigen type present before passage to the tsetse fly. The abortive transcription of the VSG gene expression site appears linked to RNA processing abnormalities. Such posttranscriptional controls may allow the modulation of gene expression in a genome organized in large multigenic transcription units.

Trypanosoma brucei: enrichment by UV of intergenic transcripts from the variable surface glycoprotein gene expression site

The expression site for the variable surface glycoprotein (VSG) gene AnTat 1.3A of Trypanosoma brucei is 45 kilobases long and encompasses seven expression site-associated genes (ESAGs) (E. Pays, P. Tebabi, A. Pays, H. Coquelet, P. Revelard, D. Salmon, and M. Steinert, Cell 57:835-845, 1989). After UV irradiation, several large transcripts from the putative promoter region were strongly enriched. We report that one such major transcript starts near the poly(A) addition site of the first gene (ESAG 7), spans the intergenic region, and extends to the poly(A) addition site of the second gene (ESAG 6), thus bypassing the normal 3' splice site of the ESAG 6 mRNA. Since this transcript is spliced, we conclude that UV irradiation does not inhibit splicing but stabilizes unstable processing products. This demonstrates that at least some intergenic regions of the VSG gene expression site are continuously transcribed in accordance with a polycistronic transcription model.

Trypanosoma brucei: posttranscriptional control of the variable surface glycoprotein gene expression site

The arrest of variable surface glycoprotein (VSG) synthesis is one of the first events accompanying the differentiation of Trypanosoma brucei bloodstream forms into procyclic forms, which are characteristic of the insect vector. This is because of a very fast inhibition of VSG gene transcription which occurs as soon as the temperature is lowered. We report that this effect is probably not controlled at the level of transcription initiation, since the beginning of the VSG gene expression site, about 45 kilobases upstream from the antigen gene, remains transcribed in procyclic forms. The permanent activity of the promoter readily accounts for the systematic reappearance, upon return to the bloodstream form after cyclical transmission, of the antigen type present before passage to the tsetse fly. The abortive transcription of the VSG gene expression site appears linked to RNA processing abnormalities. Such posttranscriptional controls may allow the modulation of gene expression in a genome organized in large multigenic transcription units.

Trypanosoma brucei: enrichment by UV of intergenic transcripts from the variable surface glycoprotein gene expression site

The expression site for the variable surface glycoprotein (VSG) gene AnTat 1.3A of Trypanosoma brucei is 45 kilobases long and encompasses seven expression site-associated genes (ESAGs) (E. Pays, P. Tebabi, A. Pays, H. Coquelet, P. Revelard, D. Salmon, and M. Steinert, Cell 57:835-845, 1989). After UV irradiation, several large transcripts from the putative promoter region were strongly enriched. We report that one such major transcript starts near the poly(A) addition site of the first gene (ESAG 7), spans the intergenic region, and extends to the poly(A) addition site of the second gene (ESAG 6), thus bypassing the normal 3' splice site of the ESAG 6 mRNA. Since this transcript is spliced, we conclude that UV irradiation does not inhibit splicing but stabilizes unstable processing products. This demonstrates that at least some intergenic regions of the VSG gene expression site are continuously transcribed in accordance with a polycistronic transcription model.

The genes and transcripts of an antigen gene expression site from T. brucei

The AnTat 1.3A antigen gene expression site of T. brucei was cloned from genomic libraries of the 200 kb expressor chromosome. In addition to the antigen gene, it contains seven putative coding regions (ESAGs, for expression site-associated genes), as well as a RIME retroposon. The polypeptide encoded by ESAG 4 shows homology to yeast adenylate cyclase, and possesses structural features of a transmembrane protein. The expression site is transcribed by a pol l-like polymerase in the parasite bloodstream form only, but sequences similar to ESAGs 5, 4, and 2 are also transcribed constitutively elsewhere, by a polymerase sensitive to alpha-amanitin. Ultraviolet irradiation, which seems to block RNA processing, allows the tentative mapping of a transcription promoter about 45 kb upstream of the antigen gene.

Complete sequence of the gene encoding the largest subunit of RNA polymerase I of Trypanosoma brucei

We have set out to clone the trypanosomal gene encoding the largest subunit of RNA polymerase I. We screened a genomic library with a synthetic oligonucleotide probe encoding an eleven amino acid sequence motif, YNADFDGDEMN, which has been found in all eukaryotic RNA polymerase largest subunit genes analyzed so far. We isolated the Trp11 locus and determined the complete sequence of the gene encoded within this locus. The deduced amino acid sequence contains the highly conserved RNA polymerase domains as well as the previously identified RNA polymerase I-specific hydrophilic insertions. Therefore, the gene most closely resembles the largest subunit of RNA polymerase I.