Detection of natural Trypanosoma vivax infections in pigs with microhaematocrit centrifugation and amplification of ITS1 rDNA.

Different species of trypanosomes may infect their mammalian hosts both singly or in combination. This study was undertaken to determine the trypanosome species that may be afflicting pigs in Uganda. Blood was collected from pigs of all ages and sexes from two districts, Kasese in Western and Jinja in Central Uganda. Of the 133 pig blood samples from Kasese that were tested for trypanosomes using the microhaematocrit centrifugation technique (MHCT), none was found to be infected. However, of the 253 pigs from Jinja district, nine were infected with trypanosomes of which three had T. vivax as determined by MHCT. However, application of the ITS1 rDNA PCR test revealed that eight pigs had T. vivax in mixed infections and one pig had T. vivax monolithic infection. These observations show that under certain circumstances, pigs may be important reservoirs for, as well as hosts to, T. vivax, contrary to earlier reports.

The African trypanosome genome.

The haploid nuclear genome of the African trypanosome, Trypanosoma brucei, is about 35 Mb and varies in size among different trypanosome isolates by as much as 25%. The nuclear DNA of this diploid organism is distributed among three size classes of chromosomes: the megabase chromosomes of which there are at least 11 pairs ranging from 1 Mb to more than 6 Mb (numbered I-XI from smallest to largest); several intermediate chromosomes of 200-900 kb and uncertain ploidy; and about 100 linear minichromosomes of 50-150 kb. Size differences of as much as four-fold can occur, both between the two homologues of a megabase chromosome pair in a specific trypanosome isolate and among chromosome pairs in different isolates. The genomic DNA sequences determined to date indicated that about 50% of the genome is coding sequence. The chromosomal telomeres possess TTAGGG repeats and many, if not all, of the telomeres of the megabase and intermediate chromosomes are linked to expression sites for genes encoding variant surface glycoproteins (VSGs). The minichromosomes serve as repositories for VSG genes since some but not all of their telomeres are linked to unexpressed VSG genes. A gene discovery program, based on sequencing the ends of cloned genomic DNA fragments, has generated more than 20 Mb of discontinuous single-pass genomic sequence data during the past year, and the complete sequences of chromosomes I and II (about 1 Mb each) in T. brucei GUTat 10.1 are currently being determined. It is anticipated that the entire genomic sequence of this organism will be known in a few years. Analysis of a test microarray of 400 cDNAs and small random genomic DNA fragments probed with RNAs from two developmental stages of T. brucei demonstrates that the microarray technology can be used to identify batteries of genes differentially expressed during the various life cycle stages of this parasite.

The molecular karyotype of the megabase chromosomes of Trypanosoma brucei stock 427.

We present the molecular karyotype of the megabase chromosomes of Trypanosoma brucei stock 427, clone 221a. This cloned stock is most commonly used in research laboratories in genetic manipulation experiments and in studies of antigenic variation. Using 116 previously characterised chromosome-specific markers, we identify 11 diploid pairs of megabase chromosomes and detect no loss of synteny in EST and gene marker distribution between this stock and the genome project reference stock TREU 927/4. Nevertheless, the chromosomes of 427 are all larger than their homologues in 927, except chromosomes IIa and IXa. The greatest size variation is seen in chromosome I, the smallest of which is 1.1 Mb (927-Ia) and the largest 3.6 Mb (427-Ib). The total nuclear DNA content of both stocks has been estimated by comparison of the mobility of T. brucei and yeast chromosomes. Trypanosomes of stock 427 contain approximately 16.5 Mb more megabase chromosomal DNA than those of stock 927. We have detected the presence of bloodstream-form expression-site-associated sequences on eight or more megabase chromosomes. These sequences are not found on the same chromosomes in each stock. We have determined the chromosomal band location of nine characterised variant surface glycoprotein genes, including the currently expressed VSG 221. Our results demonstrate both the stability of the T. brucei genome, as illustrated by the conservation of syntenic groups of genes in the two stocks, and the polymorphic nature of the genomic regions involved in antigenic variation. We propose that the chromosomes of stock 427 be numbered to correspond to their homologues in the genome project reference stock TREU 927/4.

Status of protozoan genome analysis: trypanosomatids.

The three trypanosomatid genome projects have employed common strategies which include: analysis of pulsed-field gel electrophoretic chromosomal karyotypes; physical mapping using big DNA (cosmid, pacmid P1, bacterial artificial chromosome, yeast artificial chromosome) libraries; partial cDNA sequence analysis to develop sets of expressed sequence tags (ESTs) for gene discovery and use as markers in physical mapping; genomic sequencing; dissemination of information through development of web-sites and ACeDB-based fully integrated databases; and establishment of functional genomics programmes to maximize useful application of genome data. Highlights of the projects to date have been the demonstration that, despite extensive chromosomal size polymorphisms for diploid homologues within Africa trypanosomes, T. cruzi or Leishmania, the physical linkage groups for markers on each chromosome are retained across all isolates/species studied within each group. For African trypanosomes, detailed analysis of chromosome 1 has demonstrated that repetitive sequences and the two retroposon-like elements RIME and INGI are localized to a defined region at one end of the chromosome, with the bulk of the central region of the chromosome containing genes coding for expressed proteins. Comparative mapping shows that, although subtelomeric changes account for a large proportion of the polymorphism in chromosome size in African trypanosomes, there are significant expansions and contractions in regions across the entire chromosome. The highlight of the genomic sequencing projects has been the demonstration of just 2 putative transcriptional units of chromosome 1 of Leishmania major, extending on opposite strands from a point in the central region of the chromosome. A similar observation made on 93.4 kb of contiguous sequence for T. cruzi chromosome 3 suggests the presence of promoter and regulatory elements at the junctions of large polycistronic transcriptional units. All data obtained from the genome projects are made available through the public domain, which has prompted changing philosophies in how we approach analysis of the biology of these organisms, and strategies that we can employ now in the search for new therapies and vaccines.

Predominance of duplicative VSG gene conversion in antigenic variation in African trypanosomes.

A number of mechanisms have been described by which African trypanosomes undergo the genetic switches that differentially activate their variant surface glycoprotein genes (VSGs) and bring about antigenic variation. These mechanisms have been observed mainly in trypanosome lines adapted, by rapid syringe passaging, to laboratory conditions. Such "monomorphic" lines, which routinely yield only the proliferative bloodstream form and do not develop through their life cycle, have VSG switch rates up to 4 or 5 orders of magnitude lower than those of nonadapted lines. We have proposed that nonadapted, or pleomorphic, trypanosomes normally have an active VSG switch mechanism, involving gene duplication, that is depressed, or from which a component is absent, in monomorphic lines. We have characterized 88 trypanosome clones from the first two relapse peaks of a single rabbit infection with pleomorphic trypanosomes and shown that they represent 11 different variable antigen types (VATs). The pattern of appearance in the first relapse peak was generally reproducible in three more rabbit infections. Nine of these VATs had activated VSGs by gene duplication, the tenth possibly also had done so, and only one had activated a VSG by the transcriptional switch mechanism that predominates in monomorphic lines. At least 10 of the donor genes have telomeric silent copies, and many reside on minichromosomes. It appears that trypanosome antigenic variation is dominated by one, relatively highly active, mechanism rather than by the plethora of pathways described before.

Multiple causes of size variation in the diploid megabase chromosomes of African tyrpanosomes.

The chromosomes of many protozoans are polymorphic in size, but African trypanosomes contain diploid homologues which are exceptionally size-polymorphic. We present the first complete analysis of the structure of a Trypanosoma brucei megabase chromosome which reveals the concentration of repetitive sequence, non-random distribution of transposon-like elements, and a hemizygous variant surface glycoprotein gene expression site. Subsequent comparative analyses of size-polymorphic homologues show that the repetitive regions are highly polymorphic, as demonstrated in studies on the chromosomes of other protozoan parasites. We show that a large number of the transposon-like elements are located in these regions. However, although we have shown elsewhere that synteny is maintained in coding regions, homologous chromosomes may vary along their entire length. Thus, the variable chromosomal location of variant surface glycoprotein expression gene sites, the expansion and contraction of repetitive DNA, the number of putative transposons, sequence polymorphism at chromosome ends, and expansion and contraction within or between coding regions all contribute to huge chromosomal size polymorphisms in T brucei.

Nuclear and genome organization of Trypanosoma brucei.

In this article, Klaus Ersfeld, Sara Melville and Keith Gull review current understanding of the structural organization of the nucleus of Trypanosoma brucei, and summarize recent data pertinent to the organization of its genome. Until recently, the cell biology of the trypanosome nucleus and issues of DNA organization and gene expression have often been treated as separate themes. However, recent work emphasizes the need for a more holistic approach to understanding these aspects of the biology of this parasite.

Genomics and the biology of parasites.

Despite the advances of modern medicine, the threat of chronic illness, disfigurement, or death that can result from parasitic infection still affects the majority of the world population, retarding economic development. For most parasitic diseases, current therapeutics often leave much to be desired in terms of administration regime, toxicity, or effectiveness and potential vaccines are a long way from market. Our best prospects for identifying new targets for drug, vaccine, and diagnostics development and for dissecting the biological basis of drug resistance, antigenic diversity, infectivity and pathology lie in parasite genome analysis, and international mapping and gene discovery initiatives are under way for a variety of protozoan and helminth parasites. These are far from ideal experimental organisms, and the influence of biological and genomic characteristics on experimental approaches is discussed, progress is reviewed and future prospects are examined.

The molecular karyotype of the megabase chromosomes of Trypanosoma brucei and the assignment of chromosome markers.

We present the molecular karyotype of the megabase chromosomes of Trypanosoma brucei stock TREU927/4 (927). We have identified 11 diploid chromosomes ranging in size from 1 to 5.2 Mb approximately and pairs of homologues differ in size by up to 15%. A total of 401 cDNA probes were hybridised to T. brucei stock 927 chromosomes and 168 chromosome-specific markers were defined. Most of these markers were hybridised to the separated chromosomal DNA of two other cloned field isolates and four F1 progeny clones from a laboratory cross. The chromosomes vary in size by up to two and a half times between stocks and the DNA content of the 11 pairs of homologues varies by up to 33% in different stocks. Stock 927 contains the smallest chromosomes and the least nuclear genomic DNA. Nevertheless, all 11 syntenic groups of cDNA probes are maintained in all stocks. In the F1 hybrids only we have identified one extra PFG band to which none of our probes hybridise. We have shown that probes thought to be specific for the bloodstream-form variant surface glycoprotein expression sites hybridise to different chromosomes in different stocks and may hybridise to either one or both of a homologous pair of chromosomes. We have also determined the chromosomal location of the ribosomal RNA gene arrays.

Parasite genome analysis. Genome research in Trypanosoma brucei: chromosome size polymorphism and its relevance to genome mapping and analysis.

Before the development of pulsed field gel electrophoresis (PFGE), little was known of the chromosomal organization of Trypanosoma brucei. This technique first revealed that the nuclear genome was subdivided into distinct size classes of chromosomes, subsequently shown to have disparate genetic roles in the life cycle of the parasite. PFGE also facilitated the determination of chromosome ploidy and the observation that apparent homologues often differed significantly in size within and between isolates. While the biological reasons underlying this plasticity may prove very interesting, nevertheless it could pose real problems for the global analysis of the T. brucei genome. Therefore, before undertaking large scale physical mapping, it is necessary to determine the number and size of chromosomes in the reference stock; to compare these to the chromosomes of other stocks to determine the relative sizes of homologues; and to investigate the deoxyribonucleic acid content of the size of polymorphic regions in order to assess how these may affect the execution of a physical mapping programme.