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.     

Chromosomes of kinetoplastida

We have compared chromosome-sized DNA molecules (molecular karyotypes) of five genera (nine species) of kinetoplastida after cell lysis and deproteinization of DNA in agarose blocks and size fractionation of the intact DNA molecules by pulsed field gradient (PFG) gel electrophoresis. With the possible exception of Trypanosoma vivax and Crithidia fasciculata, all species have at least 20 chromosomes. There are large differences between species in molecular karyotype and in the chromosomal distribution of the genes for alpha- and beta-tubulin, rRNA and the common mini-exon sequence of kinetoplastid mRNAs. In all cases, the rRNA genes are in DNA that is larger than 500 kb. Whereas T. brucei has approximately 100 mini-chromosomes of 50-150 kb, only few are found in T. equiperdum; T. vivax has no DNA smaller than 2000 kb. As all three species exhibit antigenic variation, small chromosomes with telomeric variant surface glycoprotein genes cannot be vital to the mechanism of antigenic variation. The apparent plasticity of kinetoplastid genome composition makes PFG gel electrophoresis a potentially useful tool for taxonomic studies.     

Improved separation of chromosome-sized DNA from Trypanosoma brucei, stock 427-60.

Separation of chromosome-sized DNA from the parasitic protozoan Trypanosoma brucei had previously resulted in the fractionation of DNA molecules that ranged in size from 50 kb up to roughly 1.5 Mb. The number of larger chromosomes and their size, accounting for 80% of the DNA of T. brucei remained unclear. We have now size separated these larger DNA molecules by pulsed field gel electrophoresis (PFG) and resolve a total of 20 bands, accounting for roughly 120 chromosomes, ranging in size from 50 kb up to the size of the largest, 5.7 Mb chromosome of Schizosaccharomyces pombe. Three different VSG gene expression sites were located to chromosomes of 430 kb, 1.5 Mb and 3 Mb, respectively. We have not been able to identify additional, previously cryptic DNA rearrangements, that could explain the activation or inactivation of the expression sites.     

Coordinate transcription of variant surface glycoprotein genes and an expression site associated gene family in Trypanosoma brucei

Trypanosoma brucei variant surface glycoprotein (VSG) genes are activated either by duplicative (DA) transposition of the gene to a pre-activated expression site or by nonduplicative (NDA) activation of a previously silent telomeric gene. We have obtained a recombinant clone spanning the 5' barren region of the expression linked copy of the duplicated VSG gene 117a. By DNA sequence and hybridization analyses we have identified a pleomorphic family of 14-25 non-VSG genes that lie upstream of both DA and NDA VSG expression sites. These expression site associated genes (ESAGs) encode 1.2 kb poly(A)+ mRNAs that are specifically transcribed from the active VSG expression telomere in mammalian bloodstream stages of T. brucei but, in common with VSG genes, are not transcribed in procyclic culture forms. cDNA and genomic sequences predict open reading frames that are conserved in the two ESAGs examined.     

Trypanosome variant surface glycoprotein genes expressed early in infection

We have studied further the genes for trypanosomal variant surface glycoproteins expressed during a chronic infection of rabbits with Trypanosoma brucei, strain 427. We show that there are three closely related chromosomal-internal isogenes for VSG 121; expression of one of these genes is accompanied by the duplicate transposition of the gene to a telomeric expression site, also used by other chromosome-internal VSG genes. The 3' end of the 121 gene is replaced during transposition with another sequence, also found in the VSG mRNAs of two other variants. We infer that an incoming VSG gene duplicate recombines with the resident gene in the expression site and may exchange ends in this process. The extra expression-linked copy of the 121 gene is lost when another gene enters the expression site. However, when the telomeric VSG gene 221 is activated without duplication the extra 121 gene copy is inactivated without detectable alterations in or around the gene. We have also analysed the VSG genes expressed very early when trypanosomes are introduced into rats or tissue culture. The five genes identified in 24 independent switching events were all found to be telomeric genes and we calculate that the telomeric 1.8 gene has a 50% chance of being activated in this trypanosome strain when the trypanosome switches the VSG that is synthesized. We argue that the preferential expression of telomeric VSG genes is due to two factors: first, some telomeric genes reside in an inactive expression site, that can be reactivated; second, telomeric genes can enter an active expression site by a duplicative telomere conversion and this process occurs more frequently than the duplicative transposition of chromosome-internal genes to an expression site.     

Telomere conversion in trypanosomes.

Activation of the gene coding for variant surface glycoprotein (VSG) 118 in Trypanosoma brucei proceeds via a duplicative transposition to a telomeric expression site. The resulting active expression-linked extra copy (ELC) is usually flanked by DNA that lacks sites for most restriction enzymes and that is thought to interfere with the cloning of the ELC as recombinant DNA in Escherichia coli. We have circumvented this problem by cloning an aberrant 118 ELC gene, flanked at the 3'-side by at least 1 kb DNA, that contains restriction enzyme sites. Our analysis shows that this DNA and the 3'-end of the 118 ELC gene are derived from another VSG gene (1.1006) that is permanently located at a telomeric position. We propose that the 3'-end of the 1.1006 gene and (all of) its 3' flanking sequence moved to the expression site by a telomere conversion. Such a telomere conversion can also account for the appearance of an extra copy of the 1.1006 gene detected in a sub-population of our trypanosome strain.     

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.     

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.     

Cloning and characterization of a variant surface glycoprotein expression site from Trypanosoma equiperdum.

Variant surface glycoprotein (VSG) genes of African trypanosomes are expressed when they are inserted into one of several telomere-linked expression sites. We cloned and characterized an 11-kilobase (kb) DNA fragment located upstream of an expressed VSG gene. A DNA sequence of 1.8 kb that is located immediately upstream of the inserted VSG gene contains sequences homologous to the 76-base-pair repeats described as being upstream of VSG genes in Trypanosoma brucei (D. A. Campbell, M. P. Van Bree, and J. C. Boothroyd, Nucleic Acids Res. 12:2759-2774). There are no such sequences elsewhere in the 11-kb cloned region. Southern blot analysis using probes from the cloned region revealed multiple unlinked copies of the same or very similar regions. At least three of these are located near telomeres, and two have been shown to be used for the expression of known Trypanosoma equiperdum VSG genes. Like VSG genes, the upstream sequences themselves can be duplicated and deleted. The choice of expression site to be used by a duplicated VSG gene is nonrandom; the site used for expression of the parental VSG gene is strongly favored for use in the daughter variant. Furthermore, even when the parental expression site is not used, the VSG gene occupying it is replaced. Thus, an active expression site is a preferential target for gene conversion in the next variation event.     

Multiple chromosomes in bacteria. The yin and yang of trp gene localization in Rhodobacter sphaeroides 2.4.1.

The existence of multiple chromosomes in bacteria has been known for some time. Yet the extent of functional solidarity between different chromosomes remains unknown. To examine this question, we have surveyed the well-described genes of the tryptophan biosynthetic pathway in the multichromosomal photosynthetic eubacterium Rhodobacter sphaeroides 2.4.1. The genome of this organism was mutagenized using Tn5, and strains that were auxotrophic for tryptophan (Trp(-)) were isolated. Pulsed-field gel mapping indicated that Tn5 insertions in both the large (3 Mb CI) and the small (0.9 Mb CII) chromosomes created a Trp(-) phenotype. Sequencing the DNA flanking the sites of the Tn5 insertions indicated that the genes trpE-yibQ-trpGDC were at a locus on CI, while genes trpF-aroR-trpB were at locus on CII. Unexpectedly, trpA was not found downstream of trpB. Instead, it was placed on the CI physical map at a locus 1.23 Mb away from trpE-yibQ-trpGDC. To relate the context of the R. sphaeroides trp genes to those of other bacteria, the DNA regions surrounding the trp genes on both chromosomes were sequenced. Of particular significance was the finding that rpsA1, which encodes ribosomal protein S1, and cmkA, which encodes cytidylate monophosphate kinase, were on CII. These genes are considered essential for translation and chromosome replication, respectively. Southern blotting suggested that the trp genes and rpsA1 exist in single copy within the genome. To date, this topological organization of the trp "operon" is unique within a bacterial genome. When taken with the finding that CII encodes essential housekeeping functions, the overall impression is one of close regulatory and functional integration between these chromosomes.     

An analysis of cosmid clones of nuclear DNA from Trypanosoma brucei shows that the genes for variant surface glycoproteins are clustered in the genome

Trypanosoma brucei contains more than a hundred genes coding for the different variant surface glycoproteins (VSGs). Activation of some of these genes involves the duplication of the gene (the basic copy or BC) and transposition of the duplicate to an expression site (yielding the expression-linked copy or ELC). We have cloned large fragments of genomic DNA in cosmid vectors in Escherichia coli. Cosmids containing the BCs of genes 117, 118 and 121 were readily obtained, but DNA containing the ELCs was strongly selected against in the cosmid and plasmid cloning systems used. We have analysed the distribution of VSG genes in the genome using probes for the sequences at the edges of the transposed segment which are partially homologous among these genes. In genomic cosmid clone banks, about 9% of all colonies hybridize with probes from the 5'- and 3'-edges of the transposed segment, showing that these sequences are linked in the genome. Moreover, the 117 and 118 BC cosmids contain several additional putative VSG genes in tandem, as deduced from hybridization and sequence analyses. We conclude that the VSG genes are highly clustered and share common sequences at the borders of the transposed segment.     

Resolution of Acanthamoeba castellanii chromosomes by pulsed field gel electrophoresis and construction of the initial linkage map

Pulsed field gel electrophoresis has been used to resolve chromosome-sized DNA molecules in fungi and parasites but has not yet been used successfully to examine the chromosomes of other lower eukaryotes used extensively for biochemical research such as Acanthamoeba, Physarum, and Dictyostelium. Here we show an electrophoretic karyotype of the protozoan Acanthamoeba castellanii using orthogonal field alternating gel electrophoresis (OFAGE). There are about 20 small chromosomes ranging in size from 220 kb to >2 Mb. We have assembled initial linkage groups assigning all of the cloned Acanthamoeba genes to chromosome-sized DNA molecules. Actin, suggested to have three or more non-allelic genes, maps to at least eight distinct chromosome bands. Two myosin II genes localize to two different chromosomal bands while myosin IB and 18S rRNA map to unresolved larger chromosomes.Abbreviations OFAGE Orthogonal field alternating gel electrophoresis     

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.     

Construction of trypanosome artificial mini-chromosomes.

We report the preparation of two linear constructs which, when transformed into the procyclic form of Trypanosoma brucei, become stably inherited artificial mini-chromosomes. Both of the two constructs, one of 10 kb and the other of 13 kb, contain a T.brucei PARP promoter driving a chloramphenicol acetyltransferase (CAT) gene. In the 10 kb construct the CAT gene is followed by one hygromycin phosphotransferase (Hph) gene, and in the 13 kb construct the CAT gene is followed by three tandemly linked Hph genes. At each end of these linear molecules are telomere repeats and subtelomeric sequences. Electroporation of these linear DNA constructs into the procyclic form of T.brucei generated hygromycin-B resistant cell lines. In these cell lines, the input DNA remained linear and bounded by the telomere ends, but it increased in size. In the cell lines generated by the 10 kb construct, the input DNA increased in size to 20-50 kb. In the cell lines generated by the 13 kb constructs, two sizes of linear DNAs containing the input plasmid were detected: one of 40-50 kb and the other of 150 kb. The increase in size was not the result of in vivo tandem repetitions of the input plasmid, but represented the addition of new sequences. These Hph containing linear DNA molecules were maintained stably in cell lines for at least 20 generations in the absence of drug selection and were subsequently referred to as trypanosome artificial mini-chromosomes, or TACs.