Maurice Steinert

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

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

Trypanosoma brucei repeated element with unusual structural and transcriptional properties

The genome of Trypanosoma brucei contains up to 400 copies of a conserved sequence (TRS, trypanosome repeated sequence). The majority of TRS copies (TRS1) are 5.2 X 10(3) base-pairs (kb) and are flanked by different separate halves of the previously described transposable element RIME (ribosomal mobile element), although a variant copy (TRS2) contains only the central 1.45 kb portion and lacks RIME. TRS1 elements can probably undergo transposition, since they are dispersed in all chromosome size classes and are bordered by direct repeats of about four base-pairs. Some TRS1 elements may contain an open reading frame over almost their entire length (1651 codons), encoding a protein showing homology with reverse transcriptase. TRS probes detect poly(A)+ transcripts of 5 to 9 kb, generated by a polymerase moderately sensitive to alpha-amanitin. Transcription is developmentally regulated. Both TRS and RIME sense transcripts are preferentially synthesized compared to anti-sense transcripts, and are much more abundant in bloodstream forms than in cultured procyclics.

Trypanosoma brucei : constitutive activity of the VSG and procyclin gene promoters

The variant surface glycoprotein (VSG) and procyclin are the major surface proteins of the bloodstream and procyclic stages, respectively, of Trypanosoma brucei. The promoter regions of the VSG and procyclin gene transcription units could be mapped thanks to the specific enrichment of initial transcripts that occurs following UV irradiation. Whereas the VSG gene is 45 kb distant from its promoter, procyclin genes are located immediately downstream. We show, by run‐on assays on isolated nuclei and by cDNA analysis, that transcription occurs from both promoters in bloodstream as well as in procyclic forms. It is inferred that the control of the stage‐specific expression of VSG and procyclin genes is not effected at the level of transcription initiation, but most probably by interfering with the elongation and stability of the specific transcripts.

Gene conversion as a mechanism for antigenic variation in Trypanosomes

Expression of the gene coding for the trypanosome AnTat 1.1 surface antigen is linked to the duplicative transposition of a basic copy (BC) of this gene to an expression site. In two trypanosome clones successively derived from AnTat 1.1 (AnTat 1.10 and AnTat 1.1B) we found evidence that gene conversions are involved in the transformation of the AnTat 1.1 transposed element into the two new surface antigen coding sequences. Although the three resultant mRNAs--AnTat 1.1, 1.10, and 1.1B--are different, they still share large homologies. Two of them, AnTat 1.1 and 1.1B, code for surface coats that are indistinguishable by conventional serological techniques, whereas AnTat 1.10 has been found different by the same methods. The three genomic rearrangements involve two of the five members of the AnTat 1.1 gene family. These two members are both located in unstable telomeric regions similar to the expression site, each in a different orientation with respect to the DNA terminus. We have concluded that the duplicative transposition is achieved by a gene conversion that may affect variable lengths of the same silent genes, and that different members of the same surface antigen gene family can contribute to the diversification of the antigen repertoire.

Structure and transcription of the actin gene of Trypanosoma brucei.

In Trypanosoma brucei, the actin gene is present in a cluster of two, three, or four tandemly linked copies, depending on the strain. Each cluster seems to exist in two allelic versions, as suggested by the polymorphism of both gene number and restriction fragment length in the DNA from cloned trypanosomes. The amplification of the gene copy number probably occurs through unequal sister chromatid exchange. The chromosomes harboring the actin genes belong to the large size class. The coding sequence was 1,128 nucleotides long and showed 60 to 70% homology to other eucaryotic actin genes. Surprisingly, this homology seemed weaker with Trypanosoma congolense, Trypanosoma cruzi, Trypanosoma vivax, Trypanosoma mega, or Leishmania actin-specific sequences. The mRNA was around 1.6 kilobases long and was synthesized at the same level in bloodstream and procyclic forms of the parasite. Large RNA precursors, up to 7.7 kilobases, were found in a pattern identical in strains containing either two or three gene copies. Probing of the flanking regions of the gene with either steady-state or in vitro transcripts, as well as S1 nuclease protection and primer extension experiments, allowed mapping of the 3 splice site of the actin mRNA, 38 nucleotides upstream from the translation initiation codon. A variably sized poly(dT) tract was found about 30 base pairs ahead of the splice site. The largest detected actin mRNA precursor seemed to give rise to at least two additional stable mRNAs. The RNA polymerase transcribing the actin gene exhibited the same sensitivity to inhibition by alpha-amanitin as that transcribing both the spliced leader and the bulk of polyadenylated mRNAs.

Modifications of a trypanosoma b. brucei antigen gene repertoire by different DNA recombinational mechanisms

In the Trypanosoma b. brucei AnTat 1.1C clone, the gene coding for the variant-specific surface antigen is telomeric and appears as a hybrid sequence, partially modified by gene conversion. This conversion is very similar to that observed in another AnTat 1.1-expressor clone (AnTat 1.1B). This sequence is not activated by duplicative transposition, although it could be activated by duplication in another clone (AnTat 1.10). Instead activation of the AnTat 1.1C gene seems operated by reciprocal recombination between its own telomere and the telomere carrying the previous (AnTat 1.16) ELC. Indeed, from the switch to AnTat 1.1C onward, the AnTat 1.16 ELC becomes a new silent member of its gene family, whereas in the variant directly derived from AnTat 1.1C (AnTat 1.3B), the AnTat 1.1C-containing telomere is lost, probably replaced by a large duplicate, at least 40 kb long, of the AnTat 1.3 gene-containing telomere. Different DNA rearrangement mechanisms used by the trypanosome to change its antigenic type thus contribute, by gain and loss of genes, to the evolution of the repertoire for surface antigens.

Differential expression of a family of putative adenylate/guanylate cyclase genes in Trypanosoma brucei

The expression site for the variant surface glycoprotein (VSG) gene of Trypanosoma brucei contains several genes of unknown function (ESAGs, for expression site-associated genes). Among these, ESAG 4 shows homology to eukaryotic adenylate/guanylate cyclase genes, in the region encoding the presumptive enzyme catalytic domain. This gene belongs to a family of related sequences, and hybridizes to the genomic DNA of other trypanosomatids, such as Trypanosoma congolense, Trypanosoma vivax and Trypanosoma mega. While ESAG 4 is transcribed only in bloodstream forms by a RNA polymerase resistant to alpha-amanitin, at least three other members of this family are transcribed in both bloodstream and procyclic forms, by a RNA polymerase sensitive to the drug. These genes encode different putative transmembrane proteins showing high sequence conservation in the region corresponding to the adenylate/guanylate cyclase catalytic domain.

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

Polymorphism in restriction site cleavage (PstI, SphI, PvuII, HindIII) has been noticed in several occasions in the telomeric sequences harbouring trypanosome variant-specific antigen genes (1, 2, 3). This polymorphism has been further investigated and seems best interpreted as due to partial DNA modification in GC dinucleotides. The actively transcribed telomeric genes do not exhibit such a polymorphism; furthermore, in at least three independent cases, gene inactivation is linked to the appearance of polymorphism. It could thus be hypothesized that DNA modification prevents antigen gene transcription, or vice-versa. We report however that at least some telomeric antigen-specific sequences of the procyclic trypanosomes (in vitro culture form) are not polymorphic, although they do not synthesize any variant-specific antigen mRNA. There is thus no absolute relationship between the absence of polymorphism and antigen gene transcription.

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

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

Inactivation and reactivation of a variant-specific antigen gene in cyclically transmitted Trypanosoma brucei

In Trypanosoma brucei, the activation of the variant‐specific antigen gene AnTat 1.1 proceeds by the synthesis of an additional gene copy, the AnTat 1.1 ELC, which is transposed to a new location, the expression site, where it is transcribed. Using the AnTat 1.1 variant to infect flies, we investigated the fate of the AnTat 1.1 ELC during cyclic transmission of T. brucei. We show here that the AnTat 1.1 ELC is conserved in procyclic trypanosomes, obtained either from the midgut of infected Glossina or from cultures, and in metacyclic trypanosomes, although the AnTat 1.1 serotype is not detected among metacyclic antigen types. This same AnTat 1.1 ELC, which is thus silent as the parasite develops in the insect vector, can be reactivated without duplication during the first parasitemia wave following cyclical transmission. This re‐expression of the conserved ELC accounts for the early appearance of the ‘ingested’ antigenic type after passage through the fly.