Frequent independent duplicative transpositions activate a single VSG gene.

The expression of several surface antigen genes in Trypanosoma brucei is mediated by the duplicative transposition of a basic-copy variant surface glycoprotein (VSG) gene into an expression site. We determined that the appearance of variant 118, in a parasitemia, resulted from at least four independent duplicative transpositions of the same VSG 118 gene. Variants 117 and 118 both appeared at specific periods but resulted from multiple independent activations. Antigenic variants thus occur in an ordered manner. We show that in the duplicative transpositions of VSG genes, the ends of the transposed segments were homologous between the basic copy and the expression site. Sequences other than the previously reported 70-base-pair (bp) repeats could be involved. In one variant, 118 clone 1, the homology was between a sequence previously transposed into the expression site and a sequence located 6 kilobases upstream of the VSG 118 gene. In variant 118b the homology was presumably in 70-bp repeat arrays, while in a third 118 variant yet another sequence was involved. The possibility that the 70-bp repeats are important in the initial steps of the recombinational events was illustrated by a rearrangement involving a 70-bp repeat array. The data provide strong evidence for the notion that gene conversion mediates the duplicative transposition of VSG genes. We discuss a model that explains how the process of duplicative transposition can occur at random and still produce an ordered appearance of variants.     

DNA rearrangements and antigenic variation in Trypanosoma equiperdum: expression-independent DNA rearrangements in the basic copy of a variant surface glycoprotein gene.

Antigenic variation in Trypanosoma equiperdum is associated with the sequential expression of variant surface glycoprotein (VSG) genes in a process which involves gene duplication and transposition events. In this paper we present evidence that the genomic environment of the VSG-1 basic copy gene, the template for duplicated, expression-linked VSG-1 genes, differs in every trypanosome clone examined. This variation is thus independent of the expression of the VSG-1 gene, and it also appears to be restricted to the 3' genomic environment. It is also demonstrated that the DNA located 3' to the VSG-1 basic copy gene is moderately sensitive to digestion when the nuclei of either expressor or non-expressor trypanosomes are treated with DNase I.     

Trypanosome variant surface glycoprotein genes expressed early in infection

We have studied further the genes for trypanosomal variant surface glycoproteins expressed during a chronic infection of rabbits with Trypanosoma brucei, strain 427. We show that there are three closely related chromosomal-internal isogenes for VSG 121; expression of one of these genes is accompanied by the duplicate transposition of the gene to a telomeric expression site, also used by other chromosome-internal VSG genes. The 3' end of the 121 gene is replaced during transposition with another sequence, also found in the VSG mRNAs of two other variants. We infer that an incoming VSG gene duplicate recombines with the resident gene in the expression site and may exchange ends in this process. The extra expression-linked copy of the 121 gene is lost when another gene enters the expression site. However, when the telomeric VSG gene 221 is activated without duplication the extra 121 gene copy is inactivated without detectable alterations in or around the gene. We have also analysed the VSG genes expressed very early when trypanosomes are introduced into rats or tissue culture. The five genes identified in 24 independent switching events were all found to be telomeric genes and we calculate that the telomeric 1.8 gene has a 50% chance of being activated in this trypanosome strain when the trypanosome switches the VSG that is synthesized. We argue that the preferential expression of telomeric VSG genes is due to two factors: first, some telomeric genes reside in an inactive expression site, that can be reactivated; second, telomeric genes can enter an active expression site by a duplicative telomere conversion and this process occurs more frequently than the duplicative transposition of chromosome-internal genes to an expression site.     

Probabilistic order in antigenic variation of Trypanosoma brucei

Antigenic variation in African trypanosomes displays a degree of order that is usually described as 'semi-predictable' but which has not been analysed in statistical detail. It has been proposed that, during switching, the variable antigen type (VAT) being inactivated can influence which VAT is subsequently activated. Antigenic variation proceeds by the differential activation of members of the large archive of distinct variable surface glycoprotein (VSG) genes. The most popular model for ordered expression of VATs invokes differential activation probabilities for individual VSG genes, dictated in part by which of the four types of genetic locus they occupy. We have shown, in pilot experiments in cattle, correlation between the timing of appearance of VSG-specific mRNA and of lytic antibodies corresponding to seven VSGs encoded by single-copy genes. We have then determined the times of appearance of VAT-specific antibodies, as a measure of appearance of the VATs, in a statistically significant number of mouse infections (n=22). There is a surprisingly high degree of order in temporal appearance of the VATs, indicating that antigenic variation proceeds through order in the probability of activation of each VAT. In addition, for the few examples of each available, the locus type inhabited by the silent 'donor' VSG plays a significant role in determination of order. We have analysed in detail previously published data on VATs appearing in first relapse peaks, and find that the variant being switched off does not influence which one is being switched on. This differs from what has been reported for Plasmodium falciparum var antigenic variation. All these features of trypanosome antigenic variation can be explained by a one-step model in which, following an initial deactivation event, the switch process and the imposition of order early in infection arise from the inherent activation probabilities of the specific VSG being switched on.     

DNA double strand break position leads to distinct gene expression changes and regulates VSG switching pathway choice

Antigenic variation is an immune evasion strategy used by Trypanosoma brucei that results in the periodic exchange of the surface protein coat. This process is facilitated by the movement of variant surface glycoprotein genes in or out of a specialized locus known as bloodstream form expression site by homologous recombination, facilitated by blocks of repetitive sequence known as the 70-bp repeats, that provide homology for gene conversion events. DNA double strand breaks are potent drivers of antigenic variation, however where these breaks must fall to elicit a switch is not well understood. To understand how the position of a break influences antigenic variation we established a series of cell lines to study the effect of an I-SceI meganuclease break in the active expression site. We found that a DNA break within repetitive regions is not productive for VSG switching, and show that the break position leads to a distinct gene expression profile and DNA repair response which dictates how antigenic variation proceeds in African trypanosomes.     

Cloning and characterization of a variant surface glycoprotein expression site from Trypanosoma equiperdum.

Variant surface glycoprotein (VSG) genes of African trypanosomes are expressed when they are inserted into one of several telomere-linked expression sites. We cloned and characterized an 11-kilobase (kb) DNA fragment located upstream of an expressed VSG gene. A DNA sequence of 1.8 kb that is located immediately upstream of the inserted VSG gene contains sequences homologous to the 76-base-pair repeats described as being upstream of VSG genes in Trypanosoma brucei (D. A. Campbell, M. P. Van Bree, and J. C. Boothroyd, Nucleic Acids Res. 12:2759-2774). There are no such sequences elsewhere in the 11-kb cloned region. Southern blot analysis using probes from the cloned region revealed multiple unlinked copies of the same or very similar regions. At least three of these are located near telomeres, and two have been shown to be used for the expression of known Trypanosoma equiperdum VSG genes. Like VSG genes, the upstream sequences themselves can be duplicated and deleted. The choice of expression site to be used by a duplicated VSG gene is nonrandom; the site used for expression of the parental VSG gene is strongly favored for use in the daughter variant. Furthermore, even when the parental expression site is not used, the VSG gene occupying it is replaced. Thus, an active expression site is a preferential target for gene conversion in the next variation event.     

The use of incomplete genes for the construction of a Trypanosoma equiperdum variant surface glycoprotein gene.

The expression of Trypanosoma equiperdum variant surface protein (VSG) 78 is accomplished by the duplicative transposition of silent basic copy (BC) genes into a telomer-linked expression site to form an expression-linked copy (ELC). In two independent isolates expressing VSG 78, the ELC is a composite gene. The analysis of VSG 78 cDNA clones from these two Bo Tat 78 isolates and the respective BC genes revealed that both ELCs were constructed from the same three BC genes, a 3' BC which donated the last 255 bp of each ELC and two closely related 5' BCs. Although sequences of both 5' BC genes were found in each ELC, the junction with the 3' BC was provided by the same 5' BC in both cases. This 5' BC is an incomplete gene with insufficient open reading frame to code for a complete VSG and thus can only be used when joined to a competent 3' end. Furthermore, both 5' BC genes lack a conserved 14 nucleotide sequence found on all VSG mRNAs. These results support a model in which composite gene formation plays a role in the determination of the order of VSG expression. They also illustrate similarities between immunoglobulin gene and VSG gene construction.     

DNA Double-Strand Breaks and Telomeres Play Important Roles in Trypanosoma brucei Antigenic Variation

Human-infecting microbial pathogens all face a serious problem of elimination by the host immune response. Antigenic variation is an effective immune evasion mechanism where the pathogen regularly switches its major surface antigen. In many cases, the major surface antigen is encoded by genes from the same gene family, and its expression is strictly monoallelic. Among pathogens that undergo antigenic variation, Trypanosoma brucei (a kinetoplastid), which causes human African trypanosomiasis, Plasmodium falciparum (an apicomplexan), which causes malaria, Pneumocystis jirovecii (a fungus), which causes pneumonia, and Borrelia burgdorferi (a bacterium), which causes Lyme disease, also express their major surface antigens from loci next to the telomere. Except for Plasmodium, DNA recombination-mediated gene conversion is a major pathway for surface antigen switching in these pathogens. In the last decade, more sophisticated molecular and genetic tools have been developed in T. brucei, and our knowledge of functions of DNA recombination in antigenic variation has been greatly advanced. VSG is the major surface antigen in T. brucei. In subtelomeric VSG expression sites (ESs), VSG genes invariably are flanked by a long stretch of upstream 70-bp repeats. Recent studies have shown that DNA double-strand breaks (DSBs), particularly those in 70-bp repeats in the active ES, are a natural potent trigger for antigenic variation in T. brucei. In addition, telomere proteins can influence VSG switching by reducing the DSB amount at subtelomeric regions. These findings will be summarized and their implications will be discussed in this review.     

Trypanosoma brucei BRCA2 acts in antigenic variation and has undergone a recent expansion in BRC repeat number that is important during homologous recombination

Antigenic variation in Trypanosoma brucei has selected for the evolution of a massive archive of silent Variant Surface Glycoprotein (VSG) genes, which are activated by recombination into specialized expression sites. Such VSG switching can occur at rates substantially higher than background mutation and is dependent on homologous recombination, a core DNA repair reaction. A key regulator of homologous recombination is BRCA2, a protein that binds RAD51, the enzyme responsible for DNA strand exchange. Here, we show that T. brucei BRCA2 has undergone a recent, striking expansion in the number of BRC repeats, a sequence element that mediates interaction with RAD51. T. brucei BRCA2 mutants are shown to be significantly impaired in antigenic variation and display genome instability. By generating BRCA2 variants with reduced BRC repeat numbers, we show that the BRC expansion is crucial in determining the efficiency of T. brucei homologous recombination and RAD51 localization. Remarkably, however, this appears not to be a major determinant of the activation of at least some VSG genes.     

The role of duplication in the expression of a variable surface glycoprotein gene of Trypanosoma brucei

The variable surface glycoprotein (VSG) genes of Trypanosoma brucei have been classified into two groups depending upon whether or not duplication of the genes is observed when they are expressed. We report here the observation of duplication apparently linked to expression of the ILTaT 1.3 gene in the ETaR 1 trypanosome stock. In the ILTaR 1 stock, expression of the ILTaT 1.3 VSG did not involve a new duplication, but instead activation of a preexisting gene copy that had been apparently generated earlier by a duplication event analogous to that directly observed in the ETaR 1 trypanosomes. The results suggest that the well-characterised gene duplications found with other VSG genes are common to all VSG genes but are not directly responsible for controlling expression. All currently available data can be accommodated by a model that assumes that gene duplication and replacement occurs independently of antigenic switching.     

Coincident multiple activations of the same surface antigen gene in Trypanosoma brucei

Trypanosomes with a coat of variant surface glycoprotein (VSG) 118, consistently appear around day 20 when a rabbit is infected with Trypanosoma brucei strain 427. There is a single chromosome-internal gene for VSG 118 and this is activated by duplicative transposition to a telomeric expression site. We show here that the expression-linked extra copy of VSG gene 118 in a day 18 population of a chronic infection is heterogeneous, and we infer that the population is not monoclonal but is the result of multiple independent activations of the 118 gene. We show that the heterogeneity of expression-linked extra copies is also present in other trypanosome populations expressing chromosome-internal VSG genes. We present a model for the timing of VSG gene activation during chronic infection that emphasizes two features: the relative activation and inactivation frequencies of different expression sites, and the degree of homology of the sequences flanking VSG genes with expression sites.     

Gene conversions mediating antigenic variation in Trypanosoma brucei can occur in variant surface glycoprotein expression sites lacking 70-base-pair repeat sequences.

African trypanosomes undergo antigenic variation of their variant surface glycoprotein (VSG) coat to avoid immune system-mediated killing by their mammalian host. An important mechanism for switching the expressed VSG gene is the duplicative transposition of a silent VSG gene into one of the telomeric VSG expression sites of the trypanosome, resulting in the replacement of the previously expressed VSG gene. This process appears to be a gene conversion reaction, and it has been postulated that sequences within the expression site may act to initiate and direct the reaction. All bloodstream form expression sites contain huge arrays (many kilobase pairs) of 70-bp repeat sequences that act as the 5' boundary of gene conversion reactions involving most silent VSG genes. For this reason, the 70-bp repeats seemed a likely candidate to be involved in the initiation of switching. Here, we show that deletion of the 70-bp repeats from the active expression site does not affect duplicative transposition of VSG genes from silent expression sites. We conclude that the 70-bp repeats do not appear to function as indispensable initiation sites for duplicative transposition and are unlikely to be the recognition sequence for a sequence-specific enzyme which initiates recombination-based VSG switching.     

Coordinate transcription of variant surface glycoprotein genes and an expression site associated gene family in Trypanosoma brucei

Trypanosoma brucei variant surface glycoprotein (VSG) genes are activated either by duplicative (DA) transposition of the gene to a pre-activated expression site or by nonduplicative (NDA) activation of a previously silent telomeric gene. We have obtained a recombinant clone spanning the 5' barren region of the expression linked copy of the duplicated VSG gene 117a. By DNA sequence and hybridization analyses we have identified a pleomorphic family of 14-25 non-VSG genes that lie upstream of both DA and NDA VSG expression sites. These expression site associated genes (ESAGs) encode 1.2 kb poly(A)+ mRNAs that are specifically transcribed from the active VSG expression telomere in mammalian bloodstream stages of T. brucei but, in common with VSG genes, are not transcribed in procyclic culture forms. cDNA and genomic sequences predict open reading frames that are conserved in the two ESAGs examined.