Expression Site Promoter Research Articles

Metacyclic VSG expression site promoters are recognized by the same general transcription factor that is required for RNA polymerase I transcription of bloodstream expression sites

Infectious metacyclic Trypanosoma brucei cells develop in the salivary glands of tsetse flies. A critical aspect of the developmental program leading to acquisition of infectivity is the synthesis of a variant surface glycoprotein (VSG) coat. Metacyclic VSG genes are transcribed from a set of specialized VSG expression sites (ESs) that differ from bloodstream VSG ESs by being monocistronic, being significantly shorter, lacking long stretches of 70-bp repeats, and having distinct promoter sequences. Both metacyclic and bloodstream VSG ESs are transcribed by the multifunctional T. brucei RNA polymerase I (Pol I), however the factor that recognizes the divergent metacyclic VSG ES promoters and recruits Pol I during the development to infectious cells remains unknown. We used an in vitro assay to show that the promoters for both metacyclic and bloodstream VSG ESs are recognized by the same class I transcription factor A (CITFA). This general Pol I transcription initiation factor was previously shown to be essential for the transcription of bloodstream VSG genes, procyclin genes and rRNA genes, and was demonstrated to have distinct binding affinities for these three types of promoters. We now show that differences in the sequence of individual metacyclic VSG ESs promoters determine different affinities for CITFA.

FACT plays a major role in histone dynamics affecting VSG expression site control in Trypanosoma brucei

Chromatin remodelling is involved in the transcriptional regulation of the RNA polymerase I transcribed variant surface glycoprotein (VSG) expression sites (ESs) of Trypanosoma brucei. We show that the T. brucei FACT complex contains the Pob3 and Spt16 subunits, and plays a key role in ES silencing. We see an inverse correlation between transcription and condensed chromatin, whereby FACT knockdown results in ES derepression and more open chromatin around silent ES promoters. Derepressed ESs show increased sensitivity to micrococcal nuclease (MNase) digestion, and a decrease in histones at silent ES promoters but not telomeres. In contrast, FACT knockdown results in more histones at the active ES, correlated with transcription shut-down. ES promoters are derepressed in cells stalled at the G2/M cell cycle stage after knockdown of FACT, but not in G2/M cells stalled after knockdown of cyclin 6. This argues that the observed ES derepression is a direct consequence of histone chaperone activity by FACT at the G2/M cell cycle stage which could affect transcription elongation, rather than an indirect consequence of a cell cycle checkpoint. These experiments highlight the role of the FACT complex in cell cycle-specific chromatin remodelling within VSG ESs.

Histone H1 Plays a Role in Heterochromatin Formation and VSG Expression Site Silencing in Trypanosoma brucei

The African sleeping sickness parasite Trypanosoma brucei evades the host immune system through antigenic variation of its variant surface glycoprotein (VSG) coat. Although the T. brucei genome contains ∼1500 VSGs, only one VSG is expressed at a time from one of about 15 subtelomeric VSG expression sites (ESs). For antigenic variation to work, not only must the vast VSG repertoire be kept silent in a genome that is mainly constitutively transcribed, but the frequency of VSG switching must be strictly controlled. Recently it has become clear that chromatin plays a key role in silencing inactive ESs, thereby ensuring monoallelic expression of VSG. We investigated the role of the linker histone H1 in chromatin organization and ES regulation in T. brucei. T. brucei histone H1 proteins have a different domain structure to H1 proteins in higher eukaryotes. However, we show that they play a key role in the maintenance of higher order chromatin structure in bloodstream form T. brucei as visualised by electron microscopy. In addition, depletion of histone H1 results in chromatin becoming generally more accessible to endonucleases in bloodstream but not in insect form T. brucei. The effect on chromatin following H1 knock-down in bloodstream form T. brucei is particularly evident at transcriptionally silent ES promoters, leading to 6–8 fold derepression of these promoters. T. brucei histone H1 therefore appears to be important for the maintenance of repressed chromatin in bloodstream form T. brucei. In particular H1 plays a role in downregulating silent ESs, arguing that H1-mediated chromatin functions in antigenic variation in T. brucei.

Epigenetics and transcriptional control in African trypanosomes

The African trypanosome Trypanosoma brucei is a unicellular parasite which causes African sleeping sickness. Transcription in African trypanosomes displays some unusual features, as most of the trypanosome genome is transcribed as extensive polycistronic RNA Pol II (polymerase II) transcription units that are not transcriptionally regulated. In addition, RNA Pol I is used for transcription of a small subset of protein coding genes in addition to the rDNA (ribosomal DNA). These Pol I-transcribed protein coding genes include the VSG (variant surface glycoprotein) genes. Although a single trypanosome has many hundreds of VSG genes, the active VSG is transcribed in a strictly monoalleleic fashion from one of approx. 15 telomeric VSG ESs (expression sites). Originally, it was thought that chromatin was not involved in the transcriptional control of ESs; however, this view is now being re-evaluated. It has since been shown that the active ES is depleted of nucleosomes compared with silent ESs. In addition, a number of proteins involved in chromatin remodelling or histone modification and which play a role in ES silencing {including TbISWI [T. brucei ISWI (imitation-switch protein)] and DOT1B} have recently been identified. Lastly, the telomere-binding protein TbRAP1 (T. brucei RAP1) has been shown to establish a repressive gradient extending from the ES telomere end up to the ES promoter. We still need to determine which epigenetic factors are involved in 'marking' the active ES as part of the counting mechanism of monoallelic exclusion. The challenge will come in determining how these multiple regulatory layers contribute to ES control.

The FACT subunit TbSpt16 is involved in cell cycle specific control of VSG expression sites in Trypanosoma brucei.

The African trypanosome Trypanosoma brucei monoallelically expresses one of more than 1000 Variant Surface Glycoprotein (VSG) genes. The active VSG is transcribed from one of about 15 telomeric VSG expression sites (ESs). It is unclear how monoallelic expression of VSG is controlled, and how inactive VSG ESs are silenced. Here, we show that blocking synthesis of the T. brucei FACT subunit TbSpt16 triggers a G2/early M phase cell cycle arrest in both bloodstream and insect form T. brucei. Segregation of T. brucei minichromosomes in these stalled cells is impaired, implicating FACT in maintenance of centromeres. Strikingly, knock-down of TbSpt16 results in 20- to 23-fold derepression of silent VSG ES promoters in bloodstream form T. brucei, with derepression specific to the G2/M cell cycle stage. In insect form T. brucei TbSpt16 knock-down results in 16- to 25-fold VSG ES derepression. Using chromatin immunoprecipitation (ChIP), TbSpt16 was found to be particularly enriched at the promoter region of silent but not active VSG ESs in bloodstream form T. brucei. The chromatin remodeler FACT is therefore implicated in maintenance of repressed chromatin present at silent VSG ES promoters, but is also essential for chromosome segregation presumably through maintenance of functional centromeres.

Histone deacetylases play distinct roles in telomeric VSG expression site silencing in African trypanosomes.

African trypanosomes evade the host immune response through antigenic variation, which is achieved by periodically expressing different variant surface glycoproteins (VSGs). VSG expression is monoallelic such that only one of approximately 15 telomeric VSG expression sites (ESs) is transcribed at a time. Epigenetic regulation is involved in VSG control but our understanding of the mechanisms involved remains incomplete. Histone deacetylases are potential drug targets for diseases caused by protozoan parasites. Here, using recombinant expression we show that the essential Trypanosoma brucei deacetylases, DAC1 (class I) and DAC3 (class II) display histone deacetylase activity. Both DAC1 and DAC3 are nuclear proteins in the bloodstream stage parasite, while only DAC3 remains concentrated in the nucleus in insect-stage cells. Consistent with developmentally regulated localization, DAC1 antagonizes SIR2rp1-dependent telomeric silencing only in the bloodstream form, indicating a conserved role in the control of silent chromatin domains. In contrast, DAC3 is specifically required for silencing at VSG ES promoters in both bloodstream and insect-stage cells. We conclude that DAC1 and DAC3 play distinct roles in subtelomeric gene silencing and that DAC3 represents the first readily druggable target linked to VSG ES control in the African trypanosome.

Blocking Variant Surface Glycoprotein Synthesis in Trypanosoma brucei Triggers a General Arrest in Translation Initiation

BackgroundThe African trypanosome Trypanosoma brucei is covered with a dense layer of Variant Surface Glycoprotein (VSG), which protects it from lysis by host complement via the alternative pathway in the mammalian bloodstream. Blocking VSG synthesis by the induction of VSG RNAi triggers an unusually precise precytokinesis cell-cycle arrest.Methodology/Principal FindingsHere, we characterise the cells arrested after the induction of VSG RNAi. We were able to rescue the VSG221 RNAi induced cell-cycle arrest through expression of a second different VSG (VSG117 which is not recognised by the VSG221 RNAi) from the VSG221 expression site. Metabolic labeling of the arrested cells showed that blocking VSG synthesis triggered a global translation arrest, with total protein synthesis reduced to less than 1–4% normal levels within 24 hours of induction of VSG RNAi. Analysis by electron microscopy showed that the translation arrest was coupled with rapid disassociation of ribosomes from the endoplasmic reticulum. Polysome analysis showed a drastic decrease in polysomes in the arrested cells. No major changes were found in levels of transcription, total RNA transcript levels or global amino acid concentrations in the arrested cells.ConclusionsThe cell-cycle arrest phenotype triggered by the induction of VSG221 RNAi is not caused by siRNA toxicity, as this arrest can be alleviated if a second different VSG is inserted downstream of the active VSG221 expression site promoter. Analysis of polysomes in the stalled cells showed that the translation arrest is mediated at the level of translation initiation rather than elongation. The cell-cycle arrest induced in the presence of a VSG synthesis block is reversible, suggesting that VSG synthesis and/or trafficking to the cell surface could be monitored during the cell-cycle as part of a specific cell-cycle checkpoint.

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

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

Delineation of the regulated Variant Surface Glycoprotein gene expression site domain of Trypanosoma brucei.

The African trypanosome Trypanosoma brucei is protected in the bloodstream of the mammalian host by a dense Variant Surface Glycoprotein (VSG) coat. Although an individual cell has hundreds of VSG genes, the active VSG is transcribed in a mutually exclusive fashion from one of about twenty telomeric VSG expression sites. Expression sites are regulated domains flanked by 50 bp repeat arrays and extensive tracts of repetitive elements. We have integrated exogenous rDNA and expression site promoters upstream of the 50 bp repeats of the VO2 VSG expression site. Transcription from both types of exogenous promoter is downregulated and comparable to promoters targeted into the VSG Basic Copy arrays. We show that the upstream exogenous rDNA promoter escapes VSG expression site control, as switching the downstream VO2 VSG expression site on and off does not affect its activity. Therefore, the 50 bp repeat arrays appear to be the boundary of the regulated expression site domain.

Downregulation of Trypanosoma brucei VSG expression site promoters on circular bacterial artificial chromosomes.

Trypanosoma brucei has about 20 telomeric variant surface glycoprotein (VSG) gene expression sites (ESs), which are downregulated in the insect form. We investigated the transcriptional behaviour of ES promoters on bacterial artificial chromosomes (BACs) containing two different ESs and their flanking regions on fragments of about 140kb. Four different BACs containing either the 221 or the VO2 ES were introduced into insect form T. brucei. The BACs replicated as circular episomes as shown using pulsed field gel (PFG) analysis of DNA exposed to increasing doses of gamma radiation, and digestion with Dam methylation-sensitive restriction enzymes. BAC copy number per cell varied from about 3 for the 221 ES BACs to about 15 for the VO2 ES BACs. Increasing drug selection pressure on the VO2 BAC T. brucei transformants resulted in amplification to about 80 BACs per cell. Although BACs were maintained in the absence of drug selection for at least 56 days, copy number fell and there was no evidence for centromere activity. ES promoters on small plasmid episomes introduced into insect form T. brucei in transient transfections are derepressed. In contrast, ES promoters on large BAC episomes are downregulated both on the original ES BACs, and on ES BACs selected for a drug marker driven by a rDNA promoter fused to the BAC vector. This indicates that downregulation of ES promoters in insect form T. brucei is influenced by genomic context, but does not necessitate proximity to a chromosome end.

Expression-site-associated-gene-8 ( ESAG8) is not required for regulation of the VSG expression site in Trypanosoma brucei

The expression sites (ES) of Trypanosoma brucei are multi-allelic loci from which the Variant Surface Glycoprotein genes (VSG) are expressed. Tight control of the ES transcriptional state ensures that only a single VSG is expressed at a time [1]. Although transcription initiates from multiple ES promoters, only a single ES is completely transcribed [2]. No reproducible differences in DNA sequence [3–5], in chromatin structure [6,7], or in DNA modification of repetitive flanking sequences [8,9] have been detected between the active and silent ESs. Since it is impossible to select for the complete simultaneous transcription of two ESs [10], and since deletion of the active ES promoter precipitates a switch to a previously inactive ES [7], some form of cross-talk is probably responsible for the exclusive transcriptional elongation of the active ES. Current models of ES control postulate the existence of a specific nuclear compartment from which only a single ES can be transcribed, or the presence of a limiting factor that is essential for the productive transcription of the active ES. Co-transcribed from the single ES promoter are multiple expression-site-associated-genes (ESAGs), which provide the parasite with proteins important for growth in the bloodstream (such as the transferrin receptor encoded by ESAGs 6 and 7) and proteins that may function in ES regulation. We have investigated the role of the putative regulatory protein ESAG8 [11,12]. Since different variants of ESAG8 are very highly conserved and appear to be exclusively transcribed from ESs, and because ESAG8 is present exclusively in the bloodstream form at low levels (2000–4000 molecules per cell), we hypothesized that ESAG8 might be involved in ES regulation [13]. ESAG8 consists of an N-terminal RING Zn-finger domain and a C-terminal Leucine Rich Repeat (LRR) domain. The RING Zn-finger motif can mediate the polyubiquitylation and targeted degradation of proteins in several eukaryotic systems [14] and LRR domains are involved in a variety of protein–protein interactions [15]. ESAG8 elutes from a Sephacryl-300 gel filtration column with an apparent molecular weight of approximately 300 kDa, consistent with its presence in a multi-protein complex (Hoek and Cross, submitted for publication). Our recent finding that a small portion of ESAG8 was necessary and sufficient to target the protein to the nucleolus lent further support to the idea that ESAG8 might be involved in ES control, because the ES is transcribed by RNA polymerase I [13,16–18]. To test this hypothesis, we attempted to delete ESAG8 from the actively transcribed ES. In previous experiments, we were unable to target the active ES-linked copy using the highly conserved ESAG8 coding sequence. Targeting was only successful in active ESs containing multiple copies of ESAG8, implying that the gene was essential [13]. We, therefore, designed a conditional disruption strategy to disrupt Abbre iations: ES, expression site; ESAG, expression-site-associated gene; VSG, variant surface glycoprotein. * Corresponding author. Tel.: +1-212-3277-571; fax: +1-2123277-845. E-mail address: george.cross@rockefeller.edu (G.A.M. Cross). 1 Present address: Cold Spring Harbor Laboratory, 1 Bungtown Road, Cold Spring Harbor, NY 11724, USA.

In-vitro competition analysis of procyclin gene and variant surface glycoprotein gene expression site transcription in Trypanosoma brucei

In Trypanosoma brucei, α-amanitin-resistant transcription characteristic of RNA polymerase I is initiated at ribosomal RNA gene ( RRNA), procyclin gene ( GPEET or EP1), and variant surface glycoprotein gene expression site ( VSG ES) promoters. The three promoter types do not share obvious sequence homologies, but contain a proximal domain I and a distal domain II within 80 bp upstream of the transcription initiation site. RRNA, GPEET and EP1, but not the VSG ES promoter, require additional upstream sequences for full activity. In the present study, we competed in-vitro transcription of circular template DNA with linear DNA fragments to identify promoter domains responsible for binding and sequestering essential trans-acting transcription factors. For the GPEET promoter, we found that domain III, located between positions −141 and −92, was most important for the DNA fragment to exert a transcription competition effect, whereas domain I, the only element absolutely required for transcription, was not. Moreover, insertions between promoter domains II and III reduced both transcription from the GPEET promoter and competition with the GPEET promoter fragment, suggesting that these two domains cooperate in the formation of a stable DNA–protein complex. Taken together, these results indicate a promoter structure very similar to that of the Saccharomyces cerevisiae RRNA promoter. In contrast, VSG ES promoter analysis showed that domains I and II are both necessary and sufficient to compete transcription. Despite this structural difference, our analysis provide evidence that GPEET and VSG ES promoters interact with a common factor that is also important for RRNA promoter transcription.

Transcription of ‘inactive’ expression sites in African trypanosomes leads to expression of multiple transferrin receptor RNAs in bloodstream forms

African trypanosomes express a heterodimeric transferrin receptor that mediates iron uptake from the host bloodstream. The genes encoding the receptor, ESAG6 and ESAG7, are found at the beginning of VSG expression sites: these are telomeric, polycistronic transcription units that each terminate with a gene encoding a trypanosome variant surface glycoprotein, VSG. Approximately 20 of these VSG expression sites are found in the trypanosome genome, but only one VSG is expressed at a time. The conventional view is that one expression site promoter is extremely active whereas the others are either inactive or show very low, poorly processive activity, and that all transferrin receptor molecules are encoded by the active expression site. The 3′-end of the ESAG6 gene is more than 5 kb from the promoter. We show here that 20% of ESAG6 mRNA originates from the ‘inactive’ expression sites. We suggest that many expression site promoters in trypanosomes show low-level activity throughout the life cycle, and that transcription proceeds for at least 5 kb. This suggests a simplified model of VSG expression site control, whereby the only regulated event is the strong activation of a single expression site promoter in bloodstream forms.

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.

Biosynthesis and function of the modified DNA base beta-D-glucosyl-hydroxymethyluracil in Trypanosoma brucei.

beta-D-Glucosyl-hydroxymethyluracil, also called J, is a modified DNA base conserved among kinetoplastid flagellates. In Trypanosoma brucei, the majority of J is present in repetitive DNA but the partial replacement of thymine by J also correlates with transcriptional repression of the variant surface glycoprotein (VSG) genes in the telomeric VSG gene expression sites. To gain a better understanding of the function of J, we studied its biosynthesis in T. brucei and found that it is made in two steps. In the first step, thymine in DNA is converted into hydroxymethyluracil by an enzyme that recognizes specific DNA sequences and/or structures. In the second step, hydroxymethyluracil is glucosylated by an enzyme that shows no obvious sequence specificity. We identified analogs of thymidine that affect the J content of the T. brucei genome upon incorporation into DNA. These analogs were used to study the function of J in the control of VSG gene expression sites. We found that incorporation of bromodeoxyuridine resulted in a 12-fold decrease in J content and caused a partial derepression of silent VSG gene expression site promoters, suggesting that J might strengthen transcriptional repression. Incorporation of hydroxymethyldeoxyuridine, resulting in a 15-fold increase in the J content, caused a reduction in the occurrence of chromosome breakage events sometimes associated with transcriptional switching between VSG gene expression sites in vitro. We speculate that these effects are mediated by the packaging of J-containing DNA into a condensed chromatin structure.

Selection for activation of a new variant surface glycoprotein gene expression site in Trypanosoma brucei can result in deletion of the old one

The African trypanosome Trypanosoma brucei expresses the active variant surface glycoprotein (VSG) gene in a telomeric VSG gene expression site. We have generated trypanosomes with a neomycin resistance gene inserted behind an active VSG gene expression site promoter, and a hygromycin resistance gene behind a silent one. By alternating drug selection, we could select for trypanosomes that had switched between the two marked VSG gene expression sites. Surprisingly, trypanosomes that had activated a new VSG gene expression site had often lost the old one. Using polymerase chain reaction (PCR), we screened large numbers of switched trypanosomes and found that sequences lost invariably included the drug marker near the promoter, as well as the telomeric VSG gene many tens of kilobases away. We postulate that stable activation of a new expression site requires silencing of the old one. If silencing does not occur at a sufficient rate by normal switch-off, stable activation of the new site can only occur if the old site is lost in random deletion events. The fact that we pick up these normally infrequent deletions, indicates that inactivation of the old VSG expression site could be rate limiting during switching in our strain of T. brucei.

In situ analysis of a variant surface glycoprotein expression-site promoter region in Trypanosoma brucei

In Trypanosoma brucei, the active variant surface glycoprotein genes ( vsg) are located at telomeric expression sites (ES), whose expression is highly regulated during the life cycle. In the procyclic form, all ESs are repressed. In the bloodstream form, where antigenic variation occurs, only one of approximately 20 ESs is active at a given time. We have investigated chromatin structure and DNA sequence around the ES promoter to identify cis-acting regulatory regions. A marker gene, inserted 1 kb downstream of the ES promoter, was used as a specific probe to map the position of nuclease hypersensitive sites. A prominent hypersensitive site was detected within the core promoter. This site was present in both active and inactive ES promoters, suggesting that a protein complex is bound to the promoter irrespective of its transcriptional state. However, none of the regions showed differential nuclease sensitivity between active and inactive transcriptional states. A systematic deletion analysis of the sequences surrounding the active ES promoter in situ confirmed the absence of cis-regulatory elements. We find that only 70 bp within the ES promoter are necessary to support ES regulation. Analysis of the reporter activities in an inactive bloodstream-form ES revealed the existence of an intermediate promoter activity in some clones, but we never observed full activation of more than one ES. The vsg mRNA from this intermediate ES was expressed less efficiently.

Analysis of a variant surface glycoprotein gene expression site promoter of Trypanosoma brucei by remodelling the promoter region

Trypanosoma brucei survives in the mammalian bloodstream by antigenic variation of its variant surface glycoprotein (VSG) coat. VSG genes are found in telomeric expression sites (ESs), and only one ES is fully transcribed at a time. The parasite changes its coat by either bringing another VSG gene into the active ES, or by switching on another ES and silencing the first. It has previously been shown that the promoter of an active ES can be replaced by a ribosomal promoter without affecting the function of the ES. This study has now analysed the conserved sequences flanking the ES promoter by deletion or replacement of these sequences in intact trypanosomes. The results show that the sequences 3′ of the promoter and extending down to the first protein-coding gene, ESAG 7, are not required in the bloodstream-form parasite either for high-level transcription or for switching of the ES. Transformants in which the sequences 5′ of the promoter extending up to simple-sequence 50-bp repeats had been removed were not obtained unless the 5' ES sequences were replaced with exogenous DNA, or unless the ES promoter was replaced by a ribosomal promoter, and even these transformants were rare. Transformants lacking the 5′ ES sequences displayed a less complete transcriptional repression of silent ESs. These results indicate that the area 5′ of an ES promoter is required for optimal functioning of an ES.

Changes in expression site control and DNA modification in Trypanosoma brucei during differentiation of the bloodstream form to the procyclic form

We have adapted a system for in vitro differentiation of a monomorphic trypanosome strain to monitor changes in transcription and DNA modification in expression sites during the transition of the bloodstream-form to the procyclic trypanosome. We have used trypanosomes that have a gene for drug resistance integrated in an expression site, just downstream of either an expression site promoter, or a ribosomal promoter replacing the endogenous promoter. During the transition from bloodstream-form to procyclic, the promoters in an active expression site behave as expected on the basis of previous work on these promoters in procyclics, i.e. the ribosomal replacement promoter remains fully active, whereas the expression site promoter is (incompletely) down-regulated. A silent bloodstream-form expression site promoter does not remain tightly silenced, however. There is a transient increase of transcription of the marker gene during the transition from bloodstream-form to procyclic, indicating that the control of silent expression sites differs between the bloodstream-form and the procyclic trypanosome, and that a short time is required to reset the silencing mechanisms. One of the differences between bloodstream-form and procyclic trypanosomes is the presence of the modified base β- d-glucosyl-hydroxymethyluracil (J) in and around bloodstream-form expression sites. We have studied loss of this DNA modification and find that the change in expression site control from bloodstream-form to procyclic does not require active removal of J. Base J is lost by synthesis of new, unmodified DNA, which happens after the major changes in expression site transcription have occurred.

Regulation of vsg expression site transcription and switching in Trypanosoma brucei

Current understanding of expression-site transcription in Trypanosoma brucei, has been refined by recent results of promoter manipulations at vsg expression sites (ES) and examination of the behavior of ES promoters in ectopic locations both within the ES and at other loci. In summary, ES promoter sequences inserted into non-transcribed rRNA spacers are generally inactive, or have low activity, in bloodstream and procyclic forms. Some mechanism apparently operates to ensure full activation of a single ES in bloodstream-form trypanosomes and the inactivity of all ES promoters in procyclic forms. As previously shown, a rRNA promoter can replace an ES promoter. In bloodstream forms, the replacement rRNA promoter was down-regulated in a `silent' ES but it was active in procyclic forms [1, 2]. In addition to manipulations of endogenous promoters, we have recently shown that, when an ES promoter is replaced by a T7 promoter, the T7 promoter is unregulated but transcription is attenuated before the vsg, and another ES switches on to maintain cell viability. However, T7 transcription is repressed in the context of core ES-promoter sequences in both stages, particularly in procyclic forms. These observations strongly argue that sequences in the vicinity of the ES core promoter play a role in ES control by nucleating critical events in silencing as well as in activation. Deletions of sequences surrounding the ES core promoter, in situ, did not affect its activity or regulation. In bloodstream forms, rRNA or ES promoters inserted adjacent to silent telomeres or to a non-telomeric `basic-copy' vsg were >98% repressed [3, 4]. After transformation to procyclic forms, the sub-telomeric rRNA promoter regained about 10% of its maximal activity but the `basic-copy' rRNA promoter was fully active. Similarly-positioned ES promoters remained silent in procyclic forms. These results suggest that telomere-proximal or vsg-proximal sequences might mediate suppression of transcription via position-effects that could be sufficient to suppress the expression of chromosome-internal vsg s or telomeric metacyclic vsg s, in bloodstream-form trypanosomes. Recent experiments with T7 promoters indicate that sequences within the ES core promoter might be responsible for silencing ES promoters in procyclic forms. Precedents for regulatory mechanisms that modulate transcription over large chromatin domains are reviewed and possible models for ES regulation are presented.