DNA breaks as triggers for antigenic variation in African trypanosomes

The DNA repair machinery has been co-opted for antigenic variation in African trypanosomes. New work directly demonstrates that a double-strand break initiates a switch in the expressed variant surface coat.     

The dynamics of antigenic variation and growth of African trypanosomes

Antigenic variation in African trypanosomes, which is a simple strategy for survival in the immune host, is rendered complex by its magnitude. For protection from nonspecific immunity and escape from specific immunity, each trypanosome is covered by a replaceable surface coat composed of the variant surface glycoprotein (VSG), which specifies the variable antigen type (VAT) of the trypanosome. Antigenic variation is the process by which the trypanosome switches from one coat to another. Here, David Barry and Michael Turner consider this phenomenon within the context of the course of trypanosome infection.     

The relative significance of mechanisms of antigenic variation in African trypanosomes

The large number of genes involved in antigenic variation in African trypanosomes has been the focus of a wide literature that describes an almost bewildering array of mechanisms for their differential activation. To the outsider searching for an underlying strategy for antigenic variation, this can appear as a rather disordered and confusing picture. Here, David Barry argues that an understanding of which mechanisms are significant, which ones are primarily inconsequential and which ones perhaps even arise from overdependence on laboratory models, might be achieved by turning attention to trypanosomes that have not undergone adaptation in laboratory conditions. Application of such an approach has led to a proposal for a main mechanism for antigenic variation.     

Antigenic variation in African trypanosomes: monitoring progress

Antigenic variation is central to the success of African trypanosomes and other eukaryotic, bacterial and viral pathogens. Our understanding of the control and execution of this immune evasion strategy in trypanosomes is incomplete, despite the molecular basis of antigenic variation being first described over 20 years ago. Recent research progress in this field is highlighted here and some of the unresolved questions raised.     

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.     

The biochemical basis of arsenical-diamidine crossresistance in African trypanosomes.

Resistance to currently used drugs is a serious problem in most fields of antimicrobial chemotherapy. Crossresistance between two of the major classes of drug used in the treatment of African trypanosomiasis, the melaminophenyl arsenicals and diamidines is easily selected in the laboratory. Here, Mike Barrett and Alan Fairlamb outline the mechanism underlying this crossresistance, which appears to arise as a result of alterations in an unusual adenosine transporter involved in the uptake of these drugs.     

Genetic basis of Neisseria gonorrhoeae lipooligosaccharide antigenic variation.

Neisseria gonorrhoeae lipooligosaccharide (LOS) undergoes antigenic variation at a high rate, and this variation can be monitored by changes in a strain's ability to bind LOS-specific monoclonal antibodies. We report here the cloning and identification of a gene, lsi-2, that can mediate this variation. The DNA sequence of lsi-2 has been determined for N. gonorrhoeae 1291, a strain that expresses a high-molecular-mass LOS, and a derivative of this strain, RS132L, that produces a truncated LOS. In the parental strain, lsi-2 contains a string of 12 guanines in the middle of its coding sequence. In cells that had antigenically varied to produce a truncated LOS, the number of guanines in lsi-2 was altered. Site-specific deletions were constructed to verify that expression of a 3.6-kDa LOS is due to alterations in lsi-2.     

Genetic exchange in African trypanosomes

African trypanosomes are important pathogens of humans and domestic animals, but little was known, until recently, of the genetic system of these parasites. Recent results demonstrate the existence of nonobligatory genetic exchange between different stocks of T. brucei. A number of models have been put forward for the mechanism of genetic exchange, including a fusion model with subsequent random loss of chromosomes and a more conventional mendelian system.     

Metabolic compartmentation in African trypanosomes

Differences between host and parasite energy metabolism are eagerly sought after as potential targets for antiparasite chemotherapy. In Kinetoplastia, the first seven steps of glycolysis are compartmented inside glycosomes, organelles that are related to the peroxisomes of higher eukaryotes. This arrangement is unique in the living world. In this review, Christine Clayton and Paul Michels discuss the implications of this unusual metabolic compartmentation for the regulation of trypanosome energy metabolism, and describe how an adequate supply of energy is maintained in different species and life cycle stages.