Possible DNA modification in GC dinucleotides of Trypanosoma brucei telomeric sequences; relationship with antigen gene transcription

Dinucleotide biases in the genomes of prokaryotic and eukaryotic dsDNA viruses and their hosts

The genomes of cellular organisms display CpG and TpA dinucleotide composition biases. Such biases have been poorly investigated in dsDNA viruses. Here, we show that in dsDNA virus, bacterial, and eukaryotic genomes, the representation of TpA and CpG dinucleotides is strongly dependent on genomic G + C content. Thus, the classical observed/expected ratios do not fully capture dinucleotide biases across genomes. Because a larger portion of the variance in TpA frequency was explained by G + C content, we explored which additional factors drive the distribution of CpG dinucleotides. Using the residuals of the linear regressions as a measure of dinucleotide abundance and ancestral state reconstruction across eukaryotic and prokaryotic virus trees, we identified an important role for phylogeny in driving CpG representation. Nonetheless, phylogenetic ANOVA analyses showed that few host associations also account for significant variations. Among eukaryotic viruses, most significant differences were observed between arthropod-infecting viruses and viruses that infect vertebrates or unicellular organisms. However, an effect of viral DNA methylation status (either driven by the host or by viral-encoded methyltransferases) is also likely. Among prokaryotic viruses, cyanobacteria-infecting phages resulted to be significantly CpG-depleted, whereas phages that infect bacteria in the genera Burkolderia and Staphylococcus were CpG-rich. Comparison with bacterial genomes indicated that this effect is largely driven by the general tendency for phages to resemble the host's genomic CpG content. Notably, such tendency is stronger for temperate than for lytic phages. Our data shed light into the processes that shape virus genome composition and inform manipulation strategies for biotechnological applications.

Cell Cycle, Telomeres, and Telomerase in Leishmania spp.: What Do We Know So Far?

Leishmaniases belong to the inglorious group of neglected tropical diseases, presenting different degrees of manifestations severity. It is caused by the transmission of more than 20 species of parasites of the Leishmania genus. Nevertheless, the disease remains on the priority list for developing new treatments, since it affects millions in a vast geographical area, especially low-income people. Molecular biology studies are pioneers in parasitic research with the aim of discovering potential targets for drug development. Among them are the telomeres, DNA–protein structures that play an important role in the long term in cell cycle/survival. Telomeres are the physical ends of eukaryotic chromosomes. Due to their multiple interactions with different proteins that confer a likewise complex dynamic, they have emerged as objects of interest in many medical studies, including studies on leishmaniases. This review aims to gather information and elucidate what we know about the phenomena behind Leishmania spp. telomere maintenance and how it impacts the parasite’s cell cycle.

Sleeping Sickness: A Tale of Two Clocks

Sleeping sickness is caused by a eukaryotic unicellular parasite known to infect wild animals, cattle, and humans. It causes a fatal disease that disrupts many rhythmic physiological processes, including daily rhythms of hormonal secretion, temperature regulation, and sleep, all of which are under circadian (24-h) control. In this review, we summarize research on sleeping sickness parasite biology and the impact it has on host health. We also consider the possible evolutionary advantages of sleep and circadian deregulation for the parasite.

Defining the sequence requirements for the positioning of base J in DNA using SMRT sequencing

Base J (β-D-glucosyl-hydroxymethyluracil) replaces 1% of T in the Leishmania genome and is only found in telomeric repeats (99%) and in regions where transcription starts and stops. This highly restricted distribution must be co-determined by the thymidine hydroxylases (JBP1 and JBP2) that catalyze the initial step in J synthesis. To determine the DNA sequences recognized by JBP1/2, we used SMRT sequencing of DNA segments inserted into plasmids grown in Leishmania tarentolae. We show that SMRT sequencing recognizes base J in DNA. Leishmania DNA segments that normally contain J also picked up J when present in the plasmid, whereas control sequences did not. Even a segment of only 10 telomeric (GGGTTA) repeats was modified in the plasmid. We show that J modification usually occurs at pairs of Ts on opposite DNA strands, separated by 12 nucleotides. Modifications occur near G-rich sequences capable of forming G-quadruplexes and JBP2 is needed, as it does not occur in JBP2-null cells. We propose a model whereby de novo J insertion is mediated by JBP2. JBP1 then binds to J and hydroxylates another T 13 bp downstream (but not upstream) on the complementary strand, allowing JBP1 to maintain existing J following DNA replication.

Tb927.10.6900 encodes the glucosyltransferase involved in synthesis of base J in Trypanosoma brucei

Base J is a DNA modification found in the genome of Trypanosoma brucei and all other kinetoplastids analyzed, where it replaces a small fraction of Ts, mainly in telomeric and chromosome-internal transcription initiation and termination regions. The synthesis of base J is a two-step process whereby a specific T is converted to HOMedU (hydroxymethyldeoxyuridine) and subsequently glucosylated to generate J. The thymidine hydroxylases (JPB1 and JBP2) that catalyze the first step have been characterized, but the identity of the glucosyltransferase catalyzing the second step has proven elusive. Recent bioinformatic analysis by Iyer et al. (Nucleic Acids Res 2013;41:7635) suggested that Tb927.10.6900 encodes the glucosyltransferase (HmdUGT) responsible for converting HOMedU to J in T. brucei. We now present experimental evidence to validate this hypothesis; null mutants of Tb927.10.6900 are unable to synthesize base J. Orthologues from related kinetoplastids show only modest conservation, with several insertion sequences found in those from Leishmania and related genera.

Base J: discovery, biosynthesis, and possible functions

In 1993, a new base, beta-d-glucopyranosyloxymethyluracil (base J), was identified in the nuclear DNA of Trypanosoma brucei. Base J is the first hypermodified base found in eukaryotic DNA. It is present in all kinetoplastid flagellates analyzed and some unicellular flagellates closely related to trypanosomatids, but it has not been found in other protozoa or in metazoa. J is invariably present in the telomeric repeats of all organisms analyzed. Whereas in Leishmania nearly all J is telomeric, there are other repetitive DNA sequences containing J in T. brucei and T. cruzi, and most J is outside telomeres in Euglena. The biosynthesis of J occurs in two steps: First, a specific thymidine in DNA is converted into hydroxymethyldeoxyuridine (HOMedU), and then this HOMedU is glycosylated to form J. This review discusses the identification and localization of base J in the genome of kinetoplastids, the enzymes involved in J biosynthesis, possible biological functions of J, and J as a potential target for chemotherapy of diseases caused by kinetoplastids.

African trypanosomes contain 5-methylcytosine in nuclear DNA

It is currently unclear if there are modified DNA bases in Trypanosoma brucei other than J-base. We identify herein a cytosine-5 DNA methyltransferase gene and report the presence and location of 5-methylcytosine in genomic DNA. Our data demonstrate that African trypanosomes contain a functional cytosine DNA methylation pathway.

Telomeric localization of the modified DNA base J in the genome of the protozoan parasite Leishmania

Base J or β-d-glucosylhydroxymethyluracil is a DNA modification replacing a fraction of thymine in the nuclear DNA of kinetoplastid parasites and of Euglena. J is located in the telomeric sequences of Trypanosoma brucei and in other simple repeat DNA sequences. In addition, J was found in the inactive variant surface glycoprotein (VSG) expression sites, but not in the active expression site of T. brucei, suggesting that J could play a role in transcription silencing in T. brucei. We have now looked at the distribution of J in the genomes of other kinetoplastid parasites. First, we analyzed the DNA sequences immunoprecipitated with a J-antiserum in Leishmania major Friedlin. Second, we investigated the co-migration of J- and telomeric repeat-containing DNA sequences of various kinetoplastids using J-immunoblots and Southern blots of fragmented DNA. We find only ∼1% of J outside the telomeric repeat sequences of Leishmania sp. and Crithidia fasciculata, in contrast to the substantial fraction of non-telomeric J found in T. brucei, Trypanosoma equiperdum and Trypanoplasma borreli. Our results suggest that J is a telomeric base modification, recruited for other (unknown) functions in some kinetoplastids and Euglena.

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.

J-binding protein increases the level and retention of the unusual base J in trypanosome DNA

The nuclear DNA of Trypanosoma brucei and other kinetoplastid flagellates contains the unusual base beta-d-glucosyl-hydroxymethyluracil, called J, replacing part of the thymine in repetitive sequences. We have described a 100 kDa protein that specifically binds to J in duplex DNA. We have now disrupted the genes for this J-binding protein (JBP) in T. brucei. The disruption does not affect growth, gene expression or the stability of some repetitive DNA sequences. Unexpectedly, however, the JBP KO trypanosomes contain only about 5% of the wild-type level of J in their DNA. Excess J, randomly introduced into T. brucei DNA by growing the cells in the presence of the J precursor 5-hydroxymethyldeoxyuridine, is lost by simple dilution as the KO trypanosomes multiply, showing that JBP does not protect J against removal. In contrast, cells containing JBP lose excess J only sluggishly. We conclude that JBP is able to activate the thymine modification enzymes to introduce additional J in regions of DNA already containing a basal level of J. We propose that JBP is a novel DNA modification maintenance protein.

Site-specific interactions of JBP with base and sugar moieties in duplex J-DNA. Evidence for both major and minor groove contacts

Beta-D-Glucosyl-hydroxymethyluracil, also called base J, is an unusually modified DNA base conserved among Kinetoplastida. Base J is found predominantly in repetitive DNA and correlates with epigenetic silencing of telomeric variant surface glycoprotein genes. We have previously identified a J-binding protein (JBP) in Trypanosoma, Leishmania, and Crithidia, and we have shown that it is a structure-specific binding protein. Here we examine the molecular interactions that contribute to recognition of the glycosylated base in synthetic DNA substrates using modification interference, modification protection, DNA footprinting, and photocross-linking techniques. We find that the two primary requirements for J-DNA recognition include contacts at base J and a base immediately 5' of J (J-1). Methylation interference analysis indicates that the requirement of the base at position J-1 is due to a major groove contact independent of the sequence. DNA footprinting of the JBP.J-DNA complex with 1,10-phenanthroline-copper demonstrates that JBP contacts the minor groove at base J. Substitution of the thymine moiety of J with cytosine reduces the affinity for JBP approximately 15-fold. These data indicate that the sole sequence dependence for JBP binding may lie in the thymine moiety of base J and that recognition requires only two specific base contacts, base J and J-1, within both the major and minor groove of the J-DNA duplex.

Recognition of base J in duplex DNA by J-binding protein

beta-d-Glucosylhydroxymethyluracil, also called base J, is an unusual modified DNA base conserved among Kinetoplastida. Base J is found predominantly in repetitive DNA and correlates with epigenetic silencing of telomeric variant surface glycoprotein genes. We have previously found a J-binding protein (JBP) in Trypanosoma, Leishmania, and Crithidia. We have now characterized the binding properties of recombinant JBP from Crithidia using synthetic J-DNA substrates that contain the glycosylated base in various DNA sequences. We find that JBP recognizes base J only when presented in double-stranded DNA but not in single-stranded DNA or in an RNA:DNA duplex. It also fails to interact with free glucose or free base J. JBP is unable to recognize nonmodified DNA or intermediates of J synthesis, suggesting that JBP is not directly involved in J biosynthesis. JBP binds J-DNA with high affinity (K(d) = 40-140 nm) but requires at least 5 bp flanking the glycosylated base for optimal binding. The nature of the flanking sequence affects binding because J in a telomeric sequence binds JBP with higher affinity than J in another sequence known to contain J in trypanosome DNA. We conclude that JBP is a structure-specific DNA-binding protein. The significance of these results in relation to the biological role and mechanism of action of J modification in kinetoplastids is discussed.

An update on antigenic variation in African trypanosomes

African trypanosomes can spend a long time in the blood of their mammalian host, where they are exposed to the immune system and are thought to take advantage of it to modulate their own numbers. Their major immunogenic protein is the variant surface glycoprotein (VSG), the gene for which must be in one of the 20--40 specialized telomeric expression sites in order to be transcribed. Trypanosomes escape antibody-mediated destruction through periodic changes of the expressed VSG gene from a repertoire of approximately 1000. How do trypanosomes exclusively express only one VSG and how do they switch between them?

Control and function of the bloodstream variant surface glycoprotein expression sites in Trypanosoma brucei

African trypanosomes escape the host immune response through a periodical change of their surface coat made of one major type of protein, the variant surface glycoprotein. From a repertoire of a thousand variant surface glycoprotein genes available, only one is expressed at a time, and this takes place in a specialised expression site itself selected from a collection of an estimated 20-30 sites. As the specialised expression sites are long polycistronic transcription units, the variant surface glycoprotein is co-transcribed with several other genes termed expression site-associated genes. How do the trypanosomes only use a single specialised expression site at a time? Why are there two dozen specialised expression sites? What are the functions of the other genes of these transcription units? We review the currently available answers to these questions.

The anatomy and transcription of a monocistronic expression site for a metacyclic variant surface glycoprotein gene in Trypanosoma brucei

African trypanosomes evade the immune response of their mammalian hosts by switching the expression of their variant surface glycoprotein genes (vsg). The bloodstream trypanosome clone MVAT4 of Trypanosoma brucei rhodesiense expresses a metacyclic vsg as a monocistronic RNA from a promoter located 2 kilobases (kb) upstream of its start codon. Determination of 23 kb of sequence at the metacyclic variant antigen type 4 (MVAT) vsg expression site (ES) revealed an ES-associated gene (esag) 1 preceded by an ingi retroposon and an inverted region containing an unrelated vsg, short stretches of 70-bp repeats and a pseudo esag 3. Nuclear run-on experiments indicate that the 18-kb region upstream of the MVAT4 vsg promoter is transcriptionally silent. However, multiple members of different esag families are expressed from elsewhere in the genome. The MVAT4 vsg promoter is highly repressed in the procyclic stage, in contrast to the known polycistronic vsg ESs which undergo abortive transcription. Activation of the MVAT4 vsg ES occurs in situ without nucleotide sequence changes, although this monocistronic ES undergoes a pattern of base J modifications similar to that reported for the polycistronic ESs. The relative simplicity of the MVAT4 vsg ES and the uncoupled expression of the vsg and esags provide a unique opportunity for investigating the molecular mechanisms responsible for antigenic variation in African trypanosomes.

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.

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 beta-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.

beta-D-glucosyl-hydroxymethyluracil is a conserved DNA modification in kinetoplastid protozoans and is abundant in their telomeres

The unusual DNA base beta-D-glucosyl-hydroxymethyluracil, called "J, " replaces approximately 0.5-1% of Thy in DNA of African trypanosomes but has not been found in other organisms thus far. In Trypanosoma brucei, J is located predominantly in repetitive DNA, and its presence correlates with the silencing of telomeric genes. Using antibodies specific for J, we have developed sensitive assays to screen for J in a range of organisms and have found that J is not limited to trypanosomes that undergo antigenic variation but is conserved among Kinetoplastida. In all kinetoplastids tested, including the human pathogens Leishmania donovani and Trypanosoma cruzi, J was found to be abundantly present in the (GGGTTA)n telomere repeats. Outside Kinetoplastida, J was found only in Diplonema, a small phagotrophic marine flagellate, in which we also identified 5-MeCyt. Fractionation of Diplonema DNA showed that the two modifications are present in a common genome compartment, which suggests that they may have a similar function. Dinoflagellates appear to contain small amounts of modified bases that may be analogs of J. The evolutionary conservation of J in kinetoplastid protozoans suggests that it has a general function, repression of transcription or recombination, or a combination of both. T. brucei may have recruited J for the control of genes involved in antigenic variation.

beta-D-glucosyl-hydroxymethyluracil, a novel base in African trypanosomes and other Kinetoplastida

A novel base, beta-D-glucosyl-hydroxymethyluracil or J for short, was recently discovered in DNA of bloodstream form Trypanosoma brucei. The base is predominantly found in the hexameric repeat arrays of chromosome telomeres and in adjacent repetitive sub-telomeric DNA, and it is made by modification of specific thymines in DNA. J is present in inactive telomeric variant surface glycoprotein (VSG) genes, but not in active ones, suggesting a link between the presence of J and repression of the telomeric expression sites for VSG genes. The presence of J in DNA is specific for bloodstream form trypanosomes, as J is absent in insect form (procyclic) T. brucei. In addition to African trypanosomes, J has been found in DNA from other Kinetoplastida that do not undergo antigenic variation, such as Leishmania and Crithidia. The biological function of J remains to be deciphered.

Localization of the modified base J in telomeric VSG gene expression sites of Trypanosoma brucei

African trypanosomes such as Trypanosoma brucei undergo antigenic variation in the bloodstream of their mammalian hosts by regularly changing the variant surface glycoprotein (VSG) gene expressed. The transcribed VSG gene is invariably located in a telomeric expression site. There are multiple expression sites and one way to change the VSG gene expressed is by activating a new site and inactivating the previously active one. The mechanisms that control expression site switching are unknown, but have been suggested to involve epigenetic regulation. We have found previously that VSG genes in silent (but not active) expression sites contain modified restriction endonuclease cleavage sites, and we have presented circumstantial evidence indicating that this is attributable to the presence of a novel modified base beta-D-glucosyl-hydroxymethyluracil, or J. To directly test this, we have generated antisera that specifically recognize J-containing DNA and have used these to determine the precise location of this modified thymine in the telomeric VSG expression sites. By anti J-DNA immunoprecipitations, we found that J is present in telomeric VSG genes in silenced expression sites and not in actively transcribed telomeric VSG genes. J was absent from inactive chromosome-internal VSG genes. DNA modification was also found at the boundaries of expression sites. In the long 50-bp repeat arrays upstream of the promoter and in the telomeric repeat arrays downstream of the VSG gene, J was found both in silent and active expression sites. This suggests that silencing results in a gradient of modification spreading from repetitive DNA flanks into the neighboring expression site sequences. In this paper, we discuss the possible role of J in silencing of expression sites.

Shared themes of antigenic variation and virulence in bacterial, protozoal, and fungal infections

Pathogenic microbes have evolved highly sophisticated mechanisms for colonizing host tissues and evading or deflecting assault by the immune response. The ability of these microbes to avoid clearance prolongs infection, thereby promoting their long-term survival within individual hosts and, through transmission, between hosts. Many pathogens are capable of extensive antigenic changes in the face of the multiple constitutive and dynamic components of host immune defenses. As a result, highly diverse populations that have widely different virulence properties can arise from a single infecting organism (clone). In this review, we consider the molecular and genetic features of antigenic variation and corresponding host-parasite interactions of different pathogenic bacterial, fungal, and protozoan microorganisms. The host and microbial molecules involved in these interactions often determine the adhesive, invasive, and antigenic properties of the infecting organisms and can dramatically affect the virulence and pathobiology of individual infections. Pathogens capable of such antigenic variation exhibit mechanisms of rapid mutability in confined chromosomal regions containing specialized genes designated contingency genes. The mechanisms of hypermutability of contingency genes are common to a variety of bacterial and eukaryotic pathogens and include promoter alterations, reading-frame shifts, gene conversion events, genomic rearrangements, and point mutations.

Manipulation of the vsg co-transposed region increases expression-site switching in Trypanosoma brucei

Disruption of a region of DNA in Trypanosoma brucei immediately upstream of the expressed telomere-proximal variant surface glycoprotein gene (vsg), known as the co-transposed region (CTR), can cause a dramatic increase in the rate at which the active expression site (ES) is switched off and a new ES is switched on. Deletion of most of the CTR in two ESs caused a greater than 100-fold increase in the rate of ES switching, to about 1.3 x 10(-4) per generation. A more dramatic effect was observed when the entire CTR and the 5' coding region of the expressed vsg221 were deleted. In this case a new ES was activated within a few cell divisions. This switch also occurred in cell lines where a second vsg had been inserted into the ES, prior to CTR deletion. These cell lines, which stably co-expressed the inserted and endogenous Vsgs, in equal amounts, did not differ from the wild-type in growth rate or switching frequency, suggesting that simultaneous expression of two Vsgs has no intrinsic effect. CTR deletion did not disturb the inserted vsg117. We tentatively conclude that it was not the disruption of the vsg221 in itself that destabilized the ES. All of the observed switches occurred without additional detectable DNA rearrangements in the switched ES. Deletion of the 70-bp repeats and/or a vsg pseudogene upstream of the CTR did not affect ES stability. Several speculative interpretations of these observation are offered, the most intriguing of which is that the CTR plays some role in modulating chromatin conformation at an ES.

The telomeric GGGTTA repeats of Trypanosoma brucei contain the hypermodified base J in both strands

We have previously shown that nuclear DNA of bloodstream from Trypanosoma brucei contains a novel base beta-glucosyl-hydroxymethyluracil, called J. Base J is enriched in minichromosome fractions but not in the minichromosome internal repeats, suggesting the association of J with telomeric DNA. To test whether J is present in the long telomeric (GGGTTA)n repeat arrays, which are 2-26 kb in T.brucei, we have purified these arrays both by hybrid selection and by isolating 2-26 kb fragments from DNA digested with multiple restriction enzymes. We find that in purified telomeric repeats approximately 13% of T is replaced by J, compared to 0.8% in total DNA, and we estimate that approximately 50% of the total J is in these repeats. Highly purified complementary strands of the repeats were obtained by alkaline CsCl equilibrium centrifugation. In the (TAACCC)n strand 14% of T was replaced by J. In the (GGGTTA)n strand approximately 36% of the second T was replaced by J; the first T was not detectably replaced. Modified bases have not been found in telomeric repeats before. How the bulky base J affects telomere function and structure in bloodstream form trypanosomes remains to be determined.

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.

A developmentally regulated position effect at a telomeric locus in Trypanosoma brucei

Trypanosoma brucei undergoes antigenic variation in the mammalian host. This can be achieved by activation and inactivation of telomeric variant-specific surface glycoprotein genes (vsg). In procyclic (insect midgut stage) cells, Vsg is not expressed. The mechanisms that regulate transcription of vsg expression sites (ESs) are unknown. Here we demonstrate that transcription from three different promoters was repressed when they were inserted at a transcriptionally silent telomere-proximal locus in bloodstream-form cells. This position effect was stable and heritable. Only transcription from an ES promoter was repressed in procyclic cells. The observed position effect and the promoter-specific developmental regulation suggest that these phenomena reflect the mechanisms that regulate vsg expression.

A ribosomal DNA promoter replacing the promoter of a telomeric VSG gene expression site can be efficiently switched on and off in T. brucei

Trypanosoma brucei survives in the mammalian blood-stream by regularly changing its variant surface glycoprotein (VSG) coat. The active VSG gene is located in a telomeric expression site, and coat switching occurs either by replacing the transcribed VSG gene or by changing the expression site that is active. To determine whether VSG expression site control requires promoter-specific sequences, we replaced the active VSG expression site promoter in bloodstream-form T. brucei with a ribosomal DNA (rDNA) promoter. These transformants were fully infective in laboratory animals, and the rDNA promoter, which is normally constitutively active, was efficiently inactivated and reactivated in the context of the VSG gene expression site. As there is no sequence similarity between the VSG expression site promoter and the rDNA promoter, VSG expression site control does not involve sequences specific to the VSG expression site promoter. We conclude that an epigenetic mechanism, such as telomeric silencing, is involved in VSG expression site control in bloodstream-form T. brucei.

Control of gene expression in trypanosomes

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

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.

A strand bias occurs in point mutations associated with variant surface glycoprotein gene conversion in Trypanosoma rhodesiense

We previously described a bloodstream Trypansoma rhodesiense clone, MVAT5-Rx2, whose isolation was based on its cross-reactivity with a monoclonal antibody (MAb) directed against a metacyclic variant surface glycoprotein (VSG). When the duplicated, expressed VSG gene in MVAT5-Rx2 was compared with its donor (basic copy) gene, 11 nucleotide differences were found in the respective 1.5-kb coding regions (Y. Lu, T. Hall, L. S. Gay, and J. E. Donelson, Cell 72:397-406, 1993). Here we describe a characterization of two additional bloodstream trypanosome clones, MVAT5-Rx1 and MVAT5-Rx3, whose VSGs are expressed from duplicated copies of the same donor VSG gene. The three trypanosome clones each react with the MVAT5-specific MAb, but they have different cross-reactivities with a panel of other MAbs, suggesting that their surface epitopes are similar but nonidentical. Each of the three gene duplication events occurs at a different 5' crossover site within a 76-bp repeat and is associated with a different set of point mutations. The 35, 11, and 28 point mutations in the duplicated VSG coding regions of Rx1, Rx2, and Rx3, respectively, exhibit a strand bias. In the sense strand, of the 74 total mutations generated in the three duplications, 54% are A-to-G or G-to-A (A:G) transitions and 7% are C:T transitions, while 26% are C:A transversions and 13% are C:G transversions. No T:G or T:A transversions occurred. Possible models for the generation of these point mutations are discussed.

A strand bias occurs in point mutations associated with variant surface glycoprotein gene conversion in Trypanosoma rhodesiense

We previously described a bloodstream Trypansoma rhodesiense clone, MVAT5-Rx2, whose isolation was based on its cross-reactivity with a monoclonal antibody (MAb) directed against a metacyclic variant surface glycoprotein (VSG). When the duplicated, expressed VSG gene in MVAT5-Rx2 was compared with its donor (basic copy) gene, 11 nucleotide differences were found in the respective 1.5-kb coding regions (Y. Lu, T. Hall, L. S. Gay, and J. E. Donelson, Cell 72:397-406, 1993). Here we describe a characterization of two additional bloodstream trypanosome clones, MVAT5-Rx1 and MVAT5-Rx3, whose VSGs are expressed from duplicated copies of the same donor VSG gene. The three trypanosome clones each react with the MVAT5-specific MAb, but they have different cross-reactivities with a panel of other MAbs, suggesting that their surface epitopes are similar but nonidentical. Each of the three gene duplication events occurs at a different 5' crossover site within a 76-bp repeat and is associated with a different set of point mutations. The 35, 11, and 28 point mutations in the duplicated VSG coding regions of Rx1, Rx2, and Rx3, respectively, exhibit a strand bias. In the sense strand, of the 74 total mutations generated in the three duplications, 54% are A-to-G or G-to-A (A:G) transitions and 7% are C:T transitions, while 26% are C:A transversions and 13% are C:G transversions. No T:G or T:A transversions occurred. Possible models for the generation of these point mutations are discussed.

beta-D-glucosyl-hydroxymethyluracil: a novel modified base present in the DNA of the parasitic protozoan T. brucei

We have previously shown that the DNA of the unicellular eukaryote T. brucei contains about 0.1% of a novel modified base, called J. The presence of J correlates with a DNA modification associated with the silencing of telomeric expression sites for the variant surface antigens of trypanosomes. Here we show that J is 5-((beta-D-glucopyranosyloxy)-methyl)-uracil (shortened to beta-D-glucosyl-hydroxymethyluracil), a base not previously found in DNA. We discuss putative pathways for the introduction of this base modification at specific positions in the DNA and the possible contribution of this modification to repression of surface antigen gene expression.

The identification of hydroxymethyluracil in DNA of Trypanosoma brucei

We have previously reported the detection of two unusual nucleotides, pdJ and pdV, in the DNA of Trypanosoma brucei (Gommers-Ampt et al., 1991). pdJ was found to be a novel nucleotide and is possibly involved in the regulation of variant specific surface antigen gene expression in trypanosomes. Recent evidence suggests that V could be a precursor of J, making V a key compound in the study of the biosynthesis and function of J. We have therefore determined the structure of V and here we present proof that V is HOMeU. The identity is based on a detailed comparison of dV(p) with authentic HOMedU(p), showing: I) co-migration in three different liquid chromatography analyses II) identical UV absorbance characteristics III) identical behavior in acetyl-pentafluorobenzyl derivatization and subsequent Gas chromatography/Mass spectrometry (GC/MS). The GC/MS technique has not been used before to analyse HOMedU purified from biological material. Because of its high sensitivity, it may also be useful for the detection of the low amounts of HOMedU resulting from oxidative damage of DNA.

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.

Antigenic variation in African trypanosomes

African trypanosomes evade the humoral immune response by periodically changing the antigenic identity of their variant cell-surface glycoprotein (VSG) coat. Antigenic variation relies on DNA rearrangement events that can translocate a silent VSG gene to a telomerically located VSG gene expression site. Antigenic switches can also be brought about by the differential transcriptional control of the expression sites, only one of which is transcribed at any time.

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.

Evidence of absence of Trypanosoma cruzi kinetoplast DNA methylation by restriction endonuclease analysis

Eight kinetoplast DNA samples from very different T. cruzi zymodemes were digested with the isoschizomer group of enzymes (MspI-HpaII) and (MboI-Sau 3AI), able to detect DNA methylation on cytidine and adenine for the CCGG and GATC sequences, respectively. Restriction digestion analysis of each kDNA with both isoschizomer groups of enzymes did not display a different profile suggesting that maxicircles and minicircles on this trypanosomatid are not methylated.

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.

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.

DNA methylation in Trypanosoma cruzi

DNA isolated from the protozoan Trypanosoma cruzi has been found to contain 5-methylcytosine. Analysis of T. cruzi DNA by both HpaII and MspI restriction endonucleases suggests that the sequence -CCGG- is not methylated. Probably T. cruzi DNA also contains N6-methyladenine. This report constitutes the first clear demonstration of the presence of methylated bases in the nuclear DNA from trypanosomes.

A novel telomeric gene conversion in Trypanosoma brucei

Gene conversion is one mechanism of antigenic variation in Trypanosoma brucei. Variant surface glycoprotein (VSG) genes are duplicated by this process to telomeric locations from which they may be expressed. We examined four independent antigenic switches in which the IsTaR 1.1 minichromosomal VSG gene is duplicated to a large chromosome where it is expressed. An unusual feature of three of these telomeric gene conversions is that the distance between the VSG gene and the end of the chromosome is identical for both the basic and duplicated copies following the antigenic switch. This suggests that the gene conversion is initiated 5' to the VSG gene and extends to the end of the telomere. The data also suggest that events other than simple nucleotide addition account for telomeric growth.

Nucleoside analysis of DNA from Trypanosoma brucei and Trypanosoma equiperdum

We have digested trypanosome DNA with a combination of pancreatic DNase I, nuclease P1 and bovine alkaline phosphatase and fractionated the resulting nucleosides on a Supelcosil LC-18-S column by high pressure liquid chromatography. We find less than 0.1% unusual nucleosides, both in Trypanosoma brucei and in a Trypanosoma equiperdum stock, in contrast to a previous report of an unusual nucleoside replacing dC at 1.3% of total nucleosides in T. equiperdum. Our results agree with previous suggestions that the modification of inactive telomeric expression sites for variant-specific surface glycoprotein genes in T. brucei only affects a very small fraction of the total DNA.

Trypanosoma brucei variant-specific glycoprotein gene chromatin is sensitive to single-strand-specific endonuclease digestion

Active variant surface glycoprotein (VSG) gene chromatin is preferentially digested by the restriction enzyme HinfI in nuclei of bloodstream variants of Trypanosoma brucei. HinfI sensitivity of VSG gene chromatin is not observed in nuclei of relapse variants in which the VSG gene has been inactivated in situ. Active VSG gene chromatin is preferentially degraded by the single-strand-specific endonucleases S1 and Bal31. This sensitivity is not the result of pre-existing single-strand breaks or a detectably altered nucleosomal organization. Trypanosome nuclei in which the run-on transcription of VSG genes has been specifically shut down have been used to show that Hinfl and Bal31 sensitivity is not dependent upon continued transcription of the VSG gene. The presence of single-stranded DNA regions within VSG gene chromatin is consistent with a model in which VSG genes are activated by increased torsional stress.

Characterization of genes coding for two major metacyclic surface antigens in Trypanosoma brucei

In African trypanosomes, only a very small fraction of the total repertoire of variable antigen types (VATs) is expressed by the metacyclic form. In Trypanosoma brucei stock EATRO 1125, the VATs AnTat 1.30 and 1.45 are reproducibly present in about 15% and 4% of the metacyclic population, respectively. The genes encoding the corresponding antigens or variant surface glycoproteins (VSGs) are in telomeres of large chromosomes, as are some non-metacyclic VSG genes from the same stock. Their activation mechanism has been studied in seven independent clones, 3 of which, referred to as 'first wave' metacyclic VATs (M-VATs), have been cloned from the first wave of parasitemia after cyclic transmission. In all these clones, activation of the antigen gene was linked to the transposition of an expression linked copy (ELC) of the gene to a telomeric expression site. For first wave M-VATs, this site seems variable, although restricted to large chromosomes, and it can be re-used for VSG gene expression in the bloodstream form. In 'late bloodstream' M-VATs, isolated from established chronic infections, the active expression site, at the end of a 200 kb chromosome, is the one preferred for the expression of late antigen types. It can be concluded that no characteristic feature in the genomic location and expression mechanism can distinguish metacyclic antigen genes from those expressed in the bloodstream forms, although the control of their expression must clearly be different.