Mobile genetic elements in protozoan parasites.

Mobile genetic elements, by virtue of their ability to move to new chromosomal locations, are considered important in shaping the evolutionary course of the genome. They are widespread in the biological kingdom. Among the protozoan parasites several types of transposable elements are encountered. The largest variety is seen in the trypanosomatids-Trypanosoma brucei, Trypanosoma cruzi and Crithidia fasciculata. They contain elements that insert site-specifically in the spliced-leader RNA genes, and others that are dispersed in a variety of genomic locations. Giardia lamblia contains three families of transposable elements. Two of these are subtleomeric in location while one is chromosome-internal. Entamoeba histolytica has an abundant retrotransposon dispersed in the genome. Nucleotide sequence analysis of all the elements shows that they are all retrotransposons, and, with the exception of one class of elements in T. cruzi, all of them are non-long-terminal-repeat retrotransposons. Although most copies have accumulated mutations, they can potentially encode reverse transcriptase, endonuclease and nucleic-acid-binding activities. Functionally and phylogenetically they do not belong to a single lineage, showing that retrotransposons were acquired early in the evolution of protozoan parasites. Many of the potentially autonomous elements that encode their own transposition functions have nonautonomous counterparts that probably utilize the functions in trans. In this respect these elements are similar to the mammalian LINEs and SINEs (long and short interspersed DNA elements), showing a common theme in the evolution of retrotransposons. So far there is no report of a DNA transposon in any protozoan parasite. The genome projects that are under way for most of these organisms will help understand the evolution and possible function of these genetic elements.

The heat-shock response in Trypanosoma cruzi and Crithidia fasciculata

Molecular aspects of heat-shock response were investigated in monogenetic and digenetic members of the Trypanosomatidae and the data obtained compared. Trypanosoma cruzi and Crithidia fasciculata differ in the number of heat-shock proteins (HSPs) induced and in the range of supra-optimal temperature induction of these proteins. Whereas low molecular weight Hsps were induced by high temperature in Crithidia, this effect was only seen in T. cruzi after ethanol treatment. The 61 kDa peptide of T. cruzi, induced by heat, was characterized as a HSP60 family member by Western blot using a Mycobacterium polyclonal anti-HSP60 antibody. The HSP61 aa. sequence, deduced from the isolated HSP60 gene and its mRNA product were characterized. The predicted aa. sequence has shown the presence of a mitochondrial peptide leader and no large domains of aa. sequence conservation were found when compared to other known HSP60, in contrast to what is observed in HSP70. Furthermore, the HSP60 gene is apparently conserved in T. cruzi, C. fascilulata and Leishmania as suggested by genomic Southern blot analysis.

Trypanosoma cruzi topoisomerase II: a target enzyme for the chemotherapy of Chagas' disease? Cloning and characterization of its encoding gene

The study of Trypanosoma cruzi type II DNA-topoisomerase should provide new clues for the rational development of new drugs for the chemotherapy of Chagas' disease. This enzyme is very likely involved in the processes leading to T. cruzi replication and differentiation since both processes are blocked by bacterial type II DNA topoisomerase inhibitors. In this article, we review and discuss our recent data related to the cloning, sequencing, and expression of T. cruzi type II topoisomerase