Direct and inverted DNA repeats associated with P-glycoprotein gene amplification in drug resistant Leishmania.

The H circle of Leishmania species contains a 30 kb inverted duplication separated by two unique DNA segments, a and b. The corresponding H region of chromosomal DNA has only one copy of the duplicated DNA. We show here that the chromosomal segments a and b are flanked by inverted repeats (198 and 1241 bp) and we discuss how these repeats could lead to formation of H circles from chromosomal DNA. Selection of Leishmania tarentolae for methotrexate resistance indeed resulted in the de novo formation of circles with long inverted duplication, but two mutants selected for arsenite resistance contained new H region plasmids without such duplications. One of these plasmids appears due to a homologous recombination between two P-glycoprotein genes with a high degree of sequence homology. Our results show how the same DNA region in Leishmania may be amplified to give plasmids with or without long inverted duplications and apparently by different mechanisms.

The amplified H circle of methotrexate-resistant leishmania tarentolae contains a novel P-glycoprotein gene.

Acquired resistance to methotrexate in Leishmania species is often associated with the amplification of H circles, 68 kb duplex DNA circles containing a 30 kb inverted repeat. We report here that the H circle of Leishmania tarentolae contains an open reading frame, ltpgpA, that has the attributes of P-glycoproteins (large plasma membrane proteins known to extrude lipophilic drugs from mammalian cells). Although amplification of H circles is associated with proportionally increased levels of a 5.5 kb transcript of the ltpgpA gene, such methotrexate resistant mutants are not cross-resistant to any of the drugs extruded by mammalian multi-drug resistant cells. In Leishmania, ltpgpA is part of a gene family containing at least two other members. Sequences homologous to one of the nucleotide binding sites of ltpgpA are conserved in other kinetoplastida.

The H circles of Leishmania tarentolae are a unique amplifiable system of oligomeric DNAs associated with drug resistance.

We have induced drug resistance against methotrexate, an inhibitor of dihydrofolate reductase, and CB3717, an inhibitor of thymidylate synthetase in a strain of Leishmania tarentolae. The drug-resistant strains contain extrachromosomal DNA circles of 68 kilobases with a 30-kilobase inverted duplication flanked by 4- and 5 kilobase unique segments. We show that these circles are highly homologous to the drug-induced H circles of L. tropica (1). All three L. tarentolae strains analyzed contain a chromosomal copy of the H region without duplication, but two of the three strains contain extrachromosomal H circles as well, predominantly present as H circle dimers in one strain and as tetramers in the other. After induction of methotrexate resistance, monomeric circles, presumably derived from the oligomers, become the major type of circle. Our results indicate that the H region represents a genomic region that can be copied at very low frequency to yield circles by a precise, but unusual mechanism under natural conditions in wild-type cells. Although superficially analogous to the episomes of bacteria, the system is without precedent in nature.

Kinetoplast DNA of Trypanosoma evansi.

We show here that the kinetoplast DNA (kDNA) networks from six Trypanosoma evansi strains differ from those of T. brucei by their lack of maxi-circles and absence of mini-circle sequence heterogeneity. The lack of maxi-circles is sufficient to account for the inability of T. evansi to multiply in tsetse flies, since this requires functional mitochondria containing maxi-circle gene products. Judged by restriction enzyme analysis, five of the six T. evansi strains contain mini-circles that differ less than 4% in sequence. This type A mini-circle is found in strains from East Africa, West Africa and South America. Another strain from East Africa contains a very different mini-circle (type B), which shows about the same degree of hybridization to type A mini-circles as to a mini-circle from T. brucei. We propose that the pronounced sequence heterogeneity of the mini-circles of T. brucei has arisen by recombination of strains that had diverged for long periods of time in reproductive isolation. We further propose that the homogeneous mini-circles of T. evansi (and T. equiperdum) reflect the inability of species to mate. This proposal implies that mini-circle heterogeneity indicates (infrequent) genetic exchange and that all kinetoplastid flagellates with heterogeneous mini-circles exchange DNA.

Kinetoplast DNA from Trypanosoma vivax and T. congolense.

We have analysed kinetoplast DNA (kDNA) of the African trypanosomes Trypanosoma vivax and T. congolense. The maxi-circles from these organisms resemble those of T. brucei in size, but only to a limited extent in sequence as judged from restriction enzyme digests and DNA X DNA hybridization. The kDNA networks of T. vivax have three distinguishing features: they contain the highest maxi-circle concentration of any kDNA (at least twice that of T. brucei); they contain the smallest mini-circles (465 bp) yet found thus far and the width of the kDNA nucleoid in thin sections is correspondingly small (55 nm against 91 nm for T. brucei); they contain a substantial fraction of mini-circle dimers.

Further analysis of intraspecific variation in Trypanosoma brucei using restriction site polymorphisms in the maxi-circle of kinetoplast DNA.

We have compared the maxi-circle kinetoplast DNA of 21 Trypanosoma brucei sp. stocks by analysis of restriction sites for nine restriction endonucleases. The analysis shows most of these stocks to have a maxi-circle sequence similar to that of 11 previously analysed stocks, with a difference of less than 3% between any two stocks. However, seven stocks stand out from the rest with at least two sites lost or gained for six of the nine restriction enzymes used. These seven distinctive stocks fall into two groups with some shared and some unique polymorphisms. One group had already been designated the kiboko group on the basis of isoenzyme patterns, but the relationship between nuclear markers and maxi-circle type is less clear-cut for the other group, designated sindo. Both groups seem to be in a wild animal-tsetse fly transmission cycle, with occasional infections in domestic stock, and may be reproductively isolated from the main T. brucei sp. population. The existence of the kiboko and sindo sub-groups shows that the maxi-circle is not shielded from evolutionary change. The lack of difference observed between the maxi-circles of the majority of T. brucei sp. stocks, including the gambiense and rhodesiense variants, must therefore reflect their close homology. Two geographical trends occur in T. brucei as a whole: (a) a trend in maxi-circle size, with increasing length of the variable region from West to East Africa, and (b) a greater frequency of certain restriction enzyme polymorphisms in East African stocks as compared to West African stocks.

DNA circles with cruciforms from Isospora (Toxoplasma) gondii.

We have isolated a closed circular duplex DNA fraction from the unicellular parasite Isospora (Toxoplasma) gondii and examined the purified DNA by electron microscopy. A major part of this circular DNA consists of 12-micron circles containing a cruciform with 0.5-micron tails. We also found 23-micron circles with the properties expected of head-to-tail dimers of the 12-micron circles. Some of these dimers have two cruciforms with 0.4-micron tails, some have one cruciform with 0.8-micron tails. When ethidium bromide was diffused into the DNA solution, circles with tails were replaced by twisted circles without tails. Direct mixing of the DNA with high ethidium bromide concentrations (5 micrograms/ml) gave rise to highly twisted circles with tails. This proves that the tailed circles are covalently continuous and indicates that ethidium bromide blocks branch migration. The 0.5-micron tails are part of a 1.7-micron palindrome, which was visualized by spreading denatured DNA under snap-back conditions. We argue that the cruciform is not present in vivo and that the 12-micron circles may represent the mitochondrial DNA of Toxoplasma.

Quantitation of genetic differences between Trypanosoma brucei gambiense, rhodesiense and brucei by restriction enzyme analysis of kinetoplast DNA.

We have compared a total of 44 recognition sites for 12 restriction endonucleases on the 20 kilobase pair maxi-circle of kinetoplast DNA from nine Trypanosoma brucei stocks, four which are known to be infective to man (tow 'gambiense' and two 'rhodesiense' variants). In addition to five polymorphic sites, these DNAs differ in the size of a 5 kilo-base pair region which is cleaved only by one of the restriction enzymes tested and which varies in size over 1.5 kilo-base pairs. Our analysis shows that the maxi-circle sequences of these stocks are very similar, the maximal calculated difference between any two being 3%. A relatively large difference was found between a rhodesiense stock from uganda and one from Zambia, confirming the distinction between northern and southern East African rhodesiense stocks found by analysis of enzyme polymorphisms (Gibson et al. (1980) Adv. Parasitol. 18, 175-246). The gambiense variants could not be identified by unique restriction site polymorphisms, but contained the smallest maxi-circle found thus far in T. Brucei. Our results indicate that T. brucei stocks infective and not infective to man are so closely related as to preclude their differentiation by analysis of kinetoplast DNA. This analysis is useful, however, in providing quantitative information about relatedness of stocks.

Variations in maxi-circle and mini-circle sequences in kinetoplast DNAs from different Trypanosoma brucei strains.

We have compared a total of 30 recognition sites for eight restriction endonucleases on the 20-kilobase-pair maxi-circle of kinetoplast DNAs from five different Trypanosoma brucei strains. In addition to three polymorphic sites were have found a 5 kilobase-pair region that is not cleaved by any of the eight enzymes and that varies in size over 1 kilobase pair in the strains analysed. Mini-circles from these five strains, digested with endonuclease TaqI or MboII, yield very complex fragment patterns, showing that extensive mini-circle sequence heterogeneity is a common characteristic of these T. brucei strains. The size distribution of mini-circle fragments in these digests was identical for different clones of the 427 strain, but very different for mini-circles from different strains. These results show that maxi-circle sequence is conserved, whereas mini-circle sequence is not. Restriction digests of maxi-circles could be useful in determining how closely two Trypanosoma strains are related, whereas mini-circle digests can serve as sensitive tags for individual strains.

Maxi-circles and mini-circles in kinetoplast DNA from trypanosoma cruzi.

Maxi-circles are a minor component of kinetoplast DNAs from all trypanosomatids studied, but they have not previously been found in Trypanosoma cruzi; We have spread intact kinetoplast DNA from the epimastigotes of strain Y in protein monolayers and analysed the mini-circle networks by electron microscopy. Long loops up to 10 micrometer were present, extending from the network rim; these are considered typical of maxi-circles. The presence of maxi-circles was proven by digestion of kinetoplast DNA with restriction endonucleases and S1 nuclease. This released a minor DNA component, detectable by agarose gel electrophoresis, which hybridized to maxi-circle DNA from Trypanosoma brucei. The molecular weight of the linearized maxi-circle of Trypanosoma cruzi is 26 . 10(6), as judged from its electrophoretic mobility in 0.6% agarose. Our restriction enzyme analysis of the mini-circles of Trypanosoma cruzi has confirmed their sequence heterogeneity and internally-repeated structure. We have found that more than 90% of the mini-circles are cut into 1/4 length molecules by endonuclease TaqI. Denaturation and renaturation of mini-circles, cut once with endonuclease MboI, mainly yields linear and circular molecules with single-stranded eyes and tails in electron micrographs. This shows that 1/4 repeats contain sub-segments in which sequence divergence is extensive. Our EcoRI and HapII digests differ in fragment size distribution from those previously reported. This suggests that this distribution may not be a stable characteristic of the Y strain.

The maxi-circle of Trypanosoma brucei kinetoplast DNA.

We have constructed a fragment map of the maxi-circle component from kinetoplast DNA networks of Trypanosoma brucei brucei (East African Trypanosomiasis Research Organization strain No. 427), using restriction endonucleases PstI, HapII, EcoRI, BglI, HindIII, HhaI, SstI, XbaI, HaeIII and Sau-96I. Although the 20 kilo-base pair map contains 30 fragments, there is a 6.5 kilo-base pair 'silent' segment which lacks recognition sites for any of these enzymes. In CsCl intact kinetoplast DNA has a buoyant density of 1.690 g/cm3, whereas a kinetoplast DNA fraction enriched in maxi-circle sequences contains an additional component at 1.682 g/cm3. The possibility that the 'silent' segment is very rich in A + T is discussed.