Identification of a telomeric DNA sequence in Trypanosoma brucei

A simple repetitive DNA sequence in the nuclear genome of Trypanosoma brucei, consisting of tandem repeats of the hexanucleotide 5' CCCTAA 3', was identified as being telomeric by several criteria. This sequence was specifically labeled with T. brucei genomic DNA as the template for in vitro nick translation by DNA polymerase I, and was present in Bal 31 nuclease sensitive, genomic restriction fragments of the large sizes expected in this organism for at least some telomeric regions. The same repeated sequence was found in six other flagellates tested. A segment of DNA from T. brucei including this telomeric sequence was cloned in pBR322 and characterized. The cloned segment contained a sequence highly homologous to the 3' ends of several variant surface glycoprotein mRNAs, upstream of the tandemly repeated hexanucleotide sequence.     

Extensive turnover of telomeric DNA at a Plasmodium berghei chromosomal extremity marked by a rare recombinational event.

The dynamics of telomere turnover were studied in Plasmodium, whose telomeric structures consist of linear, recognisable sequences of two distinct repeats (TTTAGGG and TTCAGGG). Independent recombinant clones containing a well-defined chromosomal extremity of Plasmodium berghei, both before and after a rare insertion event took place, were obtained from clonal parasite populations and analysed. The insertion, which splits the original telomere and causes a significant reduction in the size of the telomeric structure, is shown to consist of an integer number of subtelomeric repeats typical of P.berghei, flanked on both sides by telomere-derived motifs. Analysis of the telomeric repeat sequence heterogeneity in the otherwise homogeneous populations examined, is compatible with a model in which diversification of a given telomere is driven by the occurrence of breakpoints whose frequency rapidly increases along the telomeric tract when moving in the outward direction. The breakpoints might be due either to terminal deletions followed by random serial addition of the two repeat versions, or to recombination events. The shortening/elongation mechanism is favoured against the recombination hypothesis because of the absence of higher-order patterns in the sequence of telomeric repeats.     

S1 nuclease sensitivity of a double-stranded telomeric DNA sequence.

We examined structural properties of poly d(C4A2).d(T2G4), the telomeric DNA sequence of the ciliated protozoan Tetrahymena. Under conditions of high negative supercoiling, poly d(C4A2).d(T2G4) inserted in a circular plasmid vector was preferentially sensitive to digestion with S1 nuclease. Only the C4A2 strand was sensitive to first-strand S1 cutting, with a markedly skewed pattern of hypersensitive sites in tracts of either 46 or 7 tandem repeats. Linear poly d(C4A2).(T2G4) showed no preferential S1 sensitivity, no circular dichroism spectra indicative of a Z-DNA conformation, no unusual Tm, and no unusual migration in polyacrylamide gel electrophoresis. The S1 nuclease sensitivity properties are consistent with a model proposed previously for supercoiled poly d(CT).d(AG) (Pulleyblank et al., Cell 42:271-280, 1985), consisting of a double-stranded, protonated, right-handed underwound helix. We propose that this structure is shared by related telomeric sequences and may play a role in their biological recognition.     

Chromosome translocation in Plasmodium berghei.

We describe a chromosome translocation in a karyotype mutant of the rodent malarial parasite Plasmodium berghei. In this mutant (named EP) a small chromosome (chromosome 7), which has exhibited a size range between 0.9 and 1.4 Mb in other clones of P. berghei, is translocated to chromosome 13 or 14 with a size of about 3 Mb. By comparison of Apa-I restriction fragments of the chromosomes from mutant EP and from a reference clone (named HP) of P. berghei, we found evidence for a junction of subtelomeric chromosome 7 sequences and internal chromosome 13/14 sequences. In addition, a new chromosome of 1.4 Mb (named EP7) is present in mutant EP, which is (mainly) composed of sequences of chromosome 13/14. EP7 contains one telomeric region derived from chromosome 13/14. We found evidence that internal sequences of chromosome 13/14 are joined to telomeric sequences in the other telomeric region of EP7. The karyotype of mutant EP was stable during asexual and sexual multiplication and we found no indications for phenotypic changes.     

Plasmodium berghei - infected red cells sorted according to DNA content.

A cell-sorting method is described for the analysis and separation of red blood cells in Plasmodium berghei-infected mouse blood based on their DNA content. This method involves a selective uptake of the bis-benzimidazole dye 33258 Hoechst, a DNA-binding dye, by red blood cells containing parasites. Infected blood is incubated at 37 degrees C with the dye then washed at 4 degrees C to remove unbound dye. Uninfected cells are then non-fluorescent at the characteristic wavelengths for 33258 Hoechst excitation and emission, whereas parasitized cells display fluorescence intensities in approximately direct proportion tothe number of parasite nuclei (i.e. amount of parasite DNA) within the cell and can be sorted accordingly. Providing cells were incubated in a complex nutrient medium during dye uptake at 37 degrees C, the sorted parasite-infected cells produced lethal P. berghei infections when injected into BALB/c mice. The dye-labelling technique is simple and sufficient red blood cells at various stages of infection can be collected for biochemical or immunochemical studies by cell sorting.     

A DNA sequence of Drosophila melanogaster with a differential telomeric distribution

A DNA sequence (8–19T) of 2.3 kilobase pairs (kb) of Drosophila melanogaster was localized by in situ hybridization to the extreme ends of polytene chromosomes and to the chromocenter. The relative abundance of this sequence at the ends of polytene chromosomes X2L2R3L3R is 13.41.902.7. This differential distribution is probably due to different copy numbers at the individual telomeric regions. Restriction enzyme analysis of genomic DNA shows that 8–19T sequences are interspersed with other sequences. The clone 8–19T, which contains most of this interspersed repetitive sequence, is itself not internally repetitive but has a complex sequence composition. Some of these sequences are transcribed into poly(A)⁺RNA. We suggest that the ends of Drosophila chromosomes are of a complex arrangement with some sequences common to all ends.     

Organization of subtelomeric repeats in Plasmodium berghei.

Several (but not all) Plasmodium berghei chromosomes bear in the subtelomeric position a cluster of 2.3-kilobase (kb) tandem repeats. The 2.3-kb unit contains 160 base pairs of telomeric sequence. The resulting subtelomeric structure is one in which stretches of telomeric sequences are periodically spaced by a 2.1-kb reiterated sequence. This periodic organization of internal telomeric sequences might be related to chromosome-size polymorphisms involving the loss or addition of subtelomeric 2.3-kb units.     

The four ribosomal DNA units of the malaria parasite Plasmodium berghei. Identification, restriction map, and copy number analysis

The four ribosomal RNA genes (rDNA units) of the rodent malaria parasite, Plasmodium berghei, were identified and mapped by restriction enzyme analysis and Southern blot hybridization of genomic DNA. Although the four genes share common characteristics, they appear to be internally different from each other in expanse and sequence. One HindIII site near the 3' end of the coding region for the large rRNA is the only restriction site which we have detected that is conserved in all of the genes. The distance between the conserved HindIII site and the coding region for the small rRNA is at least 1-2 kilobases longer in two of the rDNA units than in a third unit. None of the four rDNA units were linked by restriction mapping where about 150 kilobases of the genome were accounted for. The copy number of two of the rDNA units was determined to be approximately 1 per haploid genome by quantitative analysis of cloned (plasmid) DNA versus genomic DNA digests on Southern blots. The other two genes also appear to be present in 1 copy. Restriction analysis confirms both the low copy number and that these genes are not in an easily recognizable tandem array. The low number of rDNA units requires that new copies of the genome produced during intraerythrocytic growth be active in RNA synthesis soon after their replication.