Frequent ectopic recombination of virulence factor genes in telomeric chromosome clusters of P. falciparum.

Persistent and recurrent infections by Plasmodium falciparum malaria parasites result from the ability of the parasite to undergo antigenic variation and evade host immune attack. P. falciparum parasites generate high levels of variability in gene families that comprise virulence determinants of cytoadherence and antigenic variation, such as the var genes. These genes encode the major variable parasite protein (PfEMP-1), and are expressed in a mutually exclusive manner at the surface of the erythrocyte infected by P. falciparum. Here we identify a mechanism by which var gene sequences undergo recombination at frequencies much higher than those expected from homologous crossover events alone. These recombination events occur between subtelomeric regions of heterologous chromosomes, which associate in clusters near the nuclear periphery in asexual blood-stage parasites or in bouquet-like configurations near one pole of the elongated nuclei in sexual parasite forms. We propose that the alignment of var genes in heterologous chromosomes facilitates gene conversion and promotes the diversity of antigenic and adhesive phenotypes. The association of virulence factors with a specific nuclear subcompartment may also have implications for variation during mitotic recombination in asexual blood stages.

Antigenic variation at the surface of infected erythrocytes in plasmodium falciparum

Os membros da família dos genes var de Plasmodium falciparum codificam para receptores que desempenham um papel importante na patogenicidade da malária. O mecanismo responsável pela seleçäo da expressäo dos diferentes membros da família dos genes var ("switching") tem sido estdado utilizando populações de parasitas clonados, selecionados por suas características adesivas. O parasita expressa um único gene var o estágio de trofozoíto do seu ciclo de vida. Análises dos sítios de expressäo, ativos ou inativos, dos genes var demonstraram que o controle da expressäo ocorre durante a transcriçäo e a ativaçäo destes genes ocorre "in situ". Observamos que näo há sobreposiçäo no repertório dos genes var para diferentes isolados de laboratório, sugerindo desta maneira a existência de mecanismos para a geraçäo de diversidade desta família gênica. Experimentos de "fluorescence in situ hybridization" (FISH) mostraram que as extremidades dos cromossomos de P. falciparum estäo fisicamente associados e que esta formaçäo é importante para a geraçäo da diversidade dos genes var.

Identification of the telomere in Trypanosoma cruzi reveals highly heterogeneous telomere lengths in different parasite strains.

Here we describe the cloning and characterisation of the Trypanosoma cruzi telomere. In the Y strain, it is formed by typical GGGTTA repeats with a mean size of approximately 500 bp. Adjacent to the telomere repeats we found a DNA sequence with significant homology to the T.cruzi 85 kDa surface antigen (gp85). Examination of the telomere in nine T.cruzi strains reveals differences in the organisation of chromosome ends. In one group of strains the size of the telomere repeat is relatively homogeneous and short (0.5-1.5 kb) as in the Y strain, while in the other, the length of the repeat is very heterogeneous and significantly longer, ranging in size from 1 to >10 kb. These different strains can be grouped similarly to previously existing classifications based on isoenzyme loci, rRNA genes, mini-exon gene sequences, randomly amplified polymorphic DNA and rRNA promoter sequences, suggesting that differential control of telomere length and organisation appeared as an early event in T. cruzi evolution. Two-dimensional pulsed field gel electrophoresis analysis shows that some chromosomes carry telomeres which are significantly larger than the mean telomere length. Importantly, the T.cruzi telomeres are organised in nucleosomal and non-nucleosomal chromatin.

Linkage analysis in a large family with nonspecific X-linked mental retardation.

We report on a large 5-generation family with "nonspecific" X-linked mental retardation. Nine living affected males have an IQ between 50 and 70 but have normal stature, facial appearance, and testicular volumes and no other abnormalities. Two obligate carrier females had borderline intellectual abilities and visual-psychomotor difficulties similar to those seen in affected males. Results of chromosome studies, including fragile X, were normal in males and females. Linkage analysis was undertaken, with 19 X-specific chromosomal restriction fragment length polymorphisms (RFLPs), giving a maximal LOD score of 1.60 at a 0.10 recombination fraction for F9, suggesting a localization to distal Xq for the mutant gene in this family.

Linkage analysis in the fragile X syndrome using multiple distal Xq polymorphic DNA markers.

Linkage data using the polymorphic loci F9, DXS105, DXS98, DXS52, DXS15, and F8 and the DNA probe 1A1 are presented from 14 families segregating for fragile X [fra(X)] syndrome. Recombination fractions corresponding to the maximum LOD scores obtained by two-point linkage analysis suggest that DXS98 (Zmax = 3.23, theta = 0.0) and DXS105 (Zmax = 2.09, theta = 0.0) are the closest markers proximal to FRAXA and that DXS52 is the closest distal marker (Zmax = 3.55, theta = 0.16). FRAXA is located within a 25 cM interval between F9 and DXS52, coincident with DXS98, on multipoint linkage analysis. Phase-known three way crossover information places F8 outside the cluster (DXS52, DXS15, 1A1). Confidence limits for the markers DXS98 and DXS52 are relatively wide (0.0-0.15 and 0.06-0.31, respectively), but when used in combination with cytogenetic examination offer improved carrier detection in comparison with cytogenetic analysis alone.

Evidence for genetic heterogeneity in tuberous sclerosis.

The question of genetic heterogeneity in tuberous sclerosis (TSC) was addressed by genetic linkage studies in eight affected families using nine polymorphic markers (EFD126.3, MCT136, ABO, ABL, AK1, and MCOA12 from distal 9q, and PBGD, MCT128.1, and 1CJ52.208M from distal 11q). The data as a whole supported a TSC locus on distal 9q, the peak lod score on multipoint analysis being 3.77 at 6 cM proximal to the Abelson oncogene locus (ABL). However, analysis of two point lod scores using the HOMOG programs showed significant evidence for genetic heterogeneity (p = 0.01), linkage to ABL being unlikely in one family. After exclusion of the unlinked family, multipoint analysis gave a peak lod score of 6.1 in the vicinity of ABL. The family unlinked to ABL showed no recombinants with two chromosome 11 probes, but was too small to provide significant evidence for linkage. Genetic heterogeneity in TSC will complicate efforts to clone the causative genes and severely limit the use of linked probes for carrier detection and prenatal diagnosis.

Linkage of the tuberous sclerosis locus to a DNA polymorphism detected by v-abl.

Linkage analysis was undertaken in six families with tuberous sclerosis (TS) using a restriction fragment length polymorphism detected by v-abl. No recombinants were observed in 13 informative meioses (four phase known) giving a maximum lod score of 3.18 at zero recombination (confidence limits 0 to 0.15). This provides further evidence for the assignment of TS to 9q34 and should facilitate cloning of the structural gene, genetic counselling, and first trimester prenatal diagnosis.

Linkage analysis using multiple Xq DNA polymorphisms in normal families, families with the fragile X syndrome, and other families with X linked conditions.

Multipoint linkage analysis was undertaken with eight Xq cloned DNA sequences which identify one or more restriction fragment length polymorphisms in 26 families. These families comprise seven phase known normal families with three or more males in the third generation, seven families segregating for haemophilia B, one large family with dyskeratosis congenita, and 11 families with the fragile X syndrome. Phase known meioses informative for three or more loci supported the order centromere--DXYS1--DXS107--DXS102, DXS51--F9--FRAXA--DXS15, DXS52, F8--Xqter in each group of families studied. One of the normal families was segregating for protan colour blindness and showed a phase known recombination which would support the order centromere--F9--DXS52--CBP--Xqter. With the exception of DXYS1, all of these sequences have been localised to Xq27----qter by in situ hybridisation or hybridisation to Xq fragment panels, and on this basis should lie within 20 cM of one another. No recombination was observed between the sequences localised to Xq28, namely DXS52, F8, and DXS15 (between DXS15 and DXS52 Z = 12.25 at theta = 0 with confidence limits of 0 to 5 cM). However, an excess of recombination was apparent in the region of FRAXA with maximal lod scores as follows: F9 versus FRAXA (Z = 2.05, theta = 0.19), DXS52 versus FRAXA (Z = 1.85, theta = 0.26), and DXS15 versus FRAXA (Z = 1.33, theta = 0.27). No consistent differences were observed in the frequency of recombination when families with the fragile X syndrome were compared with normal families or families segregating for other X linked conditions. These results are compared with other published work and support the conclusion that although measurable linkage exists between these flanking markers and FRAXA, the intervals as measured by the frequency of meiotic recombination will seriously limit their clinical usefulness.

Assignment of the gene for dyskeratosis congenita to Xq28.

Dyskeratosis congenita is an X-linked recessive disorder with diagnostic dermatological features, bone marrow hypofunction, and a predisposition to neoplasia in early adult life. Linkage analysis was undertaken in an extensive family with the condition using the Xg blood group and 17 cloned X chromosomal DNA sequences which recognise restriction fragment length polymorphisms (RFLPs). No recombination was observed between the locus for dyskeratosis congenita (DKC) and the RFLPs identified by DXS52 (St14-1) (Zmax = 3.33 at theta max = 0 with 95% confidence limits of 0 to 14cM). Similarly no recombination was observed for the disease locus and F8 (Zmax = 1.23 at theta max = 0) nor for DXS15 (Zmax = 1.62 at theta max = 0), but both of these markers were only informative in part of the family whereas DXS52 was fully informative. DXS52, DXS15, and F8 are known to be tightly linked and have previously been assigned to Xq28. Thus the gene for dyskeratosis congenita can be assigned to Xq28. These DNA sequence polymorphisms will be of clinical value for carrier detection and prenatal diagnosis.