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.     

Leaky transcription of variant surface glycoprotein gene expression sites in bloodstream african trypanosomes.

Trypanosoma brucei undergoes antigenic variation by periodically switching the expression of its variant surface glycoprotein (VSG) genes (vsg) among an estimated 20-40 telomere-linked expression sites (ES), only one of which is fully active at a given time. We found that in bloodstream trypanosomes one ES is transcribed at a high level and other ESs are expressed at low levels, resulting in organisms containing one abundant VSG mRNA and several rare VSG RNAs. Some of the rare VSG mRNAs come from monocistronic ESs in which the promoters are situated about 2 kilobases upstream of the vsg, in contrast to the polycistronic ESs in which the promoters are located 45-60 kilobases upstream of the vsg. The monocistronic ES containing the MVAT4 vsg does not include the ES-associated genes (esag) that occur between the promoter and the vsg in polycistronic ESs. However, bloodstream MVAT4 trypanosomes contain the mRNAs for many different ESAGs 6 and 7 (transferrin receptors), suggesting that polycistronic ESs are partially active in this clone. To explain these findings, we propose a model in which both mono- and polycistronic ESs are controlled by a similar mechanism throughout the parasite's life cycle. Certain VSGs are preferentially expressed in metacyclic versus bloodstream stages as a result of differences in ESAG expression and the proximity of the promoters to the vsg and telomere.     

Antigenic variation during the developmental cycle of Trypanosoma brucei

During the complex life cycle of Trypanosoma brucei, changes in the exposed surface antigens occur in both the mammalian host and the insect vector (Glossina spp.). These antigenic changes are associated with alterations of the variant surface glycoprotein (VSG) composition or with the loss of the VSG. In the bloodstream of the mammalian host, trypanosomes successfully evade destruction by the host's immune response by continuously expressing alternative VSGs, at low frequency, which are not destroyed by host antibodies. When ingested by the tsetse fly, the bloodstream trypanosomes rapidly lose their surface coat and surface membrane antigens are exposed which are normally covered in the bloodstream. In the salivary glands of the tsetse fly, the trypanosomes differentiate to the metacyclic stage, which reacquires a surface coat. The antigenic composition of the metacyclics is heterogeneous. The same metacyclic types are expressed regardless of the bloodstream antigenic type ingested by the tsetse fly. In the mammal the metacyclics differentiate to long-slender bloodstream forms but continue to express the metacyclic VSG for at least three days. The next VSGs expressed in the mammalian host appear to be influenced by the antigenic type ingested by the tsetse. The ingested antigenic type is often expressed in the first parasitemia following expression of the metacyclic antigenic types.     

Duplicative activation mechanisms of two trypanosome telomeric VSG genes with structurally simple 5'' flanks.

In the mammalian bloodstream, African trypanosomes express variant surface glycoprotein (VSG) genes from a family of long and complex telomeric expression sites. VSG switching generally occurs by the duplication of different VSG genes into these sites by gene conversion involving a series of 70 base pair (70bp) repeats in the 5' flank. In contrast, when VSG is first synthesised by trypanosomes in the tsetse fly at the metacyclic stage, a separate set of telomeric expression sites is activated. These latter telomeres appear not to act as recipients in gene conversion. We have found that the structure of two such expression sites is simple, with very short 70bp repeat regions and very little other sequence in common with bloodstream expression sites. However, the two telomeres readily act as donors in VSG gene conversion in the bloodstream and we show for one a consistent association of the conversion 5' end point with the short 70bp repeat region. These findings help explain why a very predictable set of VSGs is expressed in the tsetse fly and have implications for VSG gene conversion mechanisms.     

Expression of whole and hybrid genes in Trypanosoma equiperdum antigenic variation.

A rapid technique involving the S1 nuclease resistance of RNA:DNA duplexes has been used to screen four Trypanosoma equiperdum variant surface glycoprotein (VSG) genes for evidence of hybrid gene structure in their transcribed regions. The results suggest that VSGs appearing early in a chronic infection each have a complete co-linear basic copy (BC) of their expressed gene while VSGs appearing later in infection are particularly associated with BC genes which are recombined before being expressed. The intensities of the S1-protected bands from hybrid VSGs indicate that the basic and expression linked copies are present in equivalent gene dosages. In addition, studies are presented on the expression of two additional VSG genes in T. equiperdum, VSG 4 and VSG 78, which (i) show that the basic copies are not located on telomeres even though one (VSG 4) is expressed early in infection and (ii) emphasize the role of a predominant expression site in T. equiperdum while nevertheless confirming the presence of multiple expression sites.     

Exposed epitopes on a Trypanosoma equiperdum variant surface glycoprotein altered by point mutations.

African trypanosomes are covered by a dense protein layer that is immunologically distinct on different trypanosome isolates and is termed the variant surface glycoprotein (VSG). The different VSGs are expressed in a general order, where some VSGs appear preferentially early in infection and others only later. The exposed epitopes on a late antigen, VSG 78, of T.equiperdum were studied by the technique of monoclonal antibody (MAb) escape selection. MAbs that neutralize trypanosomes bearing VSG 78 reacted with the VSG only when it was attached to the trypanosome surface, suggesting that the most immunogenic surface epitopes are conformational. Trypanosome clones resistant to one of the MAbs yet still expressing VSG 78 or 78(20) were isolated in vitro. Two independent variants resistant to MAb H3 changed Ser192 to Arg by a single base change in the VSG gene and a variant resistant to MAb H21 had a single base change that converted Gln172 to Glu. A variant resistant to MAb H7 had several changes in the VSG gene, a gene conversion in the 5' region and an isolated mutation in codon 220 that is proposed to be responsible for the resistance phenotype. The isotypic bias of the MAbs against VSG 78 and an analysis of the natural variants that are resistant to MAb 78H21 suggest that glycosylation plays a role in the immunogenicity of these proteins. The analysis defines some of the exposed amino acid residues and demonstrates that VSG genes are altered by mutations and small gene conversions as well as replaced by large gene conversion-like events. The results provide biological data supporting the model of VSG structure obtained by crystallographic studies.     

Sequences of three VSG mRNAs expressed in a mixed population of Trypanosoma brucei rhodesiense

A cDNA library was constructed from a mixed population of bloodstream Trypanosoma brucei rhodesiense expressing at least three different VSGs, one of which is immunologically similar to a VSG present during the metacyclic stage. Complete sequence determinations of three full length VSG cDNAs showed that the 5' spliced leader sequence is located 20-26 nucleotides upstream of the start codons of each of the three VSG mRNAs. Two of the VSGs (472 and 487 aa) are members of one C-terminal isotype group while the other, metacyclic-like, VSG (517 aa) is a member of the other C-terminal group. Since VSGs of different sequences have similar three-dimensional structures, comparison of many different VSGs sequences should lead to a more detailed understanding of the relationship between primary and tertiary structures of proteins in general. GenBank accession numbers: M33823, M33824, and M33825.     

Characteristics of trypanosome variant antigen genes active in the tsetse fly.

Trypanosoma brucei contains a repertoire of more than 100 different genes for Variant Surface Glycoproteins (VSGs). A small and strain-specific fraction of these genes is expressed in the salivary glands of the tsetse fly (M-genes), giving rise to metacyclic Variable Antigen Types (M-VATs). Antibodies produced in a chronic trypanosome infection initiated by syringe inoculation of bloodstream forms into mammals (i.e. against B-VATs), will react with most of the M-VATs suggesting that these B-VATs express VSG genes that are similar or identical to M-genes. We have cloned DNA complementary to the VSG mRNA of four of such B-VATs and used this to characterize the corresponding VSG genes. In three of the four VATs we find a single VSG gene hybridizing with the cDNA probe and we provide supporting evidence that this gene is expressed as an M-gene. In the bloodstream repertoire these genes appear to be activated by duplicative translocation to another telomere. In all four variants the putative M-genes are telomeric and in the three cases where the location of the genes on chromosome-sized DNA molecules could be determined, the genes were located in large DNA, whereas the majority of the telomeric VSG genes are in chromosomes less than 1000 kb. Our results are best explained by models for M-gene activation involving telomeric expression sites for these genes which are separate from those used by bloodstream forms. The implications of these results for vaccination are discussed.     

VSG 117 gene is conservatively present and early expressed in Trypanosma evansi YNB stock

African trypanosomes, including Trypanosoma brucei and the closely related species Trypanosoma evansi, are flagellated unicellular parasites that proliferate extracellularly in the mammalian bloodstream and tissue spaces. They evade host immune system by periodically switching their variant surface glycoprotein (VSG) coat. Each trypanosome possesses a vast archive of VSGs with distinct sequence identity and different strains contain different archive of VSGs. VSG 117 was reported as a widespread VSG detected in the genomes of all the T. brucei strains. In this study, the presence and expression of VSG 117 gene was observed in T. evansi YNB stock by RT-PCR with VSG-specific primers. We further confirmed that this VSG tends to be expressed in the early stage of T. evansi infections (on day 12-15) by immuno-screening the previously isolated infected blood samples. It is possible that the VSG 117 gene evolved and spread through the African trypanosome population via genetic exchange, before T. evansi lost its ability to infect tsetse fly. Our finding provided an evidence of the close evolutionary relationship between T. evansi and T. brucei, in the terms of VSG genes.     

Mung bean nuclease cleaves preferentially at the boundaries of variant surface glycoprotein gene transpositions in trypanosome DNA

Telomere-linked genes coding for the variant surface glycoproteins (VSGs) of African trypanosomes have been difficult to clone because their flanking regions frequently lack restriction sites. Therefore, we constructed a genomic DNA library of fragments generated by digestion of purified trypanosome DNA with mung bean nuclease, an enzyme that cleaves before and after genes in Plasmodium falciparum DNA (McCutchan, T. F., Hansen, J. L., Dame, J. B., and Mullins, J. A. (1984) Science 225, 625-628). Southern hybridizations with several gene probes showed that under the appropriate conditions mung bean nuclease produces discrete trypanosome DNA fragments that are as clearly resolved on an agarose gel as restriction fragments. The majority of VSG genes are on fragments of about 1.7 kilobase pairs. To examine the sites of mung bean nuclease cleavage, the insert boundary sequences of eight recombinant clones in the library containing VSG genes were determined. In general, mung bean nuclease cleaved 300-800 base pairs in front of the VSG start codon and within 50 base pairs on either side of the termination codon. These regions also form the boundaries of VSG gene conversion events indicating that the enzyme recognizes, in part, a conformational structure rather than a specific sequence. The analyzed clones included both telomere-linked and interior basic copy VSG genes indicating that the library potentially contains all of the telomere-linked VSG genes in the genome.     

Size fractionation of Trypanosoma brucei DNA: localization of the 177-bp repeat satellite DNA and a variant surface glycoprotein gene in a mini-chromosomal DNA fraction

We have size-fractionated intact DNA from Trypanosoma brucei into a major large DNA fraction (greater than 350S) and minor middle-sized (60-250S) and small (less than 60S) DNA fractions. Large DNA contains the rRNA genes, the basic copy genes for several variant surface glycoproteins (VSGs), including one which lies near a telomer, and the expression-linked copies of the two VSG genes. The middle-sized DNA contains at least one VSG gene, but the hybridization of this fraction with probes for the conserved repetitive sequences that mark the edges of the transposed segments of VSG genes, suggests that it may contain many VSG genes. The 177-bp repeat satellite DNA is also exclusively found in this fraction.     

Genomic organization and context of a trypanosome variant surface glycoprotein gene family.

We have defined the genomic organization and genomic context of a Trypanosoma brucei brucei gene family encoding variant surface glycoproteins (VSGs). This gene family is neither tandemly repeated nor closely linked in the genome, and is not located on small or intermediate size chromosomes. Two dispersed repeated sequence elements, RIME-ingi and the upstream repeat sequence, are linked to members of this gene family; however, the upstream repeat sequences are closely linked only to the basic copy. In other isolates of T.b. brucei this gene family appears conserved with some variation; a restriction fragment length polymorphism found among these isolates suggests the hypothesis that VSG genes may occasionally be diploid. A model accounting for both the generation of dispersed families of VSG genes, and for the interstrain variability of VSG genes, is proposed.     

analysis of genomic rearrangements associated with two variable antigen genes of Trypanosoma brucei.

Some variable surface glycoprotein (VSG) genes of Trypanosoma brucei undergo duplication and transposition when they are expressed. We report here the cloning of cDNAs coding for two VSGs from the ILtar 1 repertoire. Analysis of the genomes of trypanosomes expressing these and other antigens shows that there is no additional copy of the sequences coding for eight VSG in expressing clones of trypanosomes, and reveals rearrangements analogous to those previously described for the gene for another VSG from this antigen repertoire. The data indicate that duplication does not accompany the expression of these VSG genes. Transposition to a specific expression site cannot be excluded, but would have to involve either a much larger segment of DNA, or movement to a region of much greater homology with the previous flanking sequences, than is observed for VSG genes that are duplicated when expressed. It is reasoned that the control of expression by coupled duplication and transposition is not sufficient to account for the selection of a single VSG gene for expression.