Characteristics of kinetoplastic DNA from Leptomonas pessoai

The kinetoplast (mitochondrial) DNA from trypanosomatid Leptomonas pessoai represents a network, composed of mini-circles heterogeneous in base sequence and homogeneous maxi-circles and thus has the main structural features in common with DNAs from kinetoplasts of other Trypanosomatidae. The size of mini-circular molecules of DNA is 1,35 kilobase pairs (kbp) and that of maxicircular molecules-30,9 kbp. Based on the data of single and double restriction cleavages the physical map of the maxi-circular molecules was constructed for the endonucleases BamHI, BglII, BspI , HindIII, MspI, SalGI and PstI.     

Replication of kinetoplast DNA in isolated kinetoplasts from Crithidia fasciculata. Identification of minicircle DNA replication intermediates

The kinetoplast DNA (kDNA) of trypanosomes is comprised of thousands of DNA minicircles and 20-50 maxicircles catenated into a single network. We show that kinetoplasts isolated from the trypanosomatid species Crithidia fasciculata incorporate labeled nucleotides and support minicircle DNA replication in a manner which mimics two characteristics of minicircle replication in vivo: 1) the minicircles are replicated as free molecules and subsequently reattached to the kDNA network, and 2) a replication intermediate having a structure consistent with a highly gapped minicircle species is generated. In addition, a class of minicircle DNA replication intermediates is observed containing discontinuities at specific sites within each of the newly synthesized DNA strands. By using a strain of C. fasciculata possessing nearly homogenous minicircles, we were able to map the discontinuities to two small regions situated 180 degrees apart on the minicircle. Each region has two sites at which a discontinuity can occur, one on each strand and separated by approximately 100 base pairs. These sites may represent origins of minicircle DNA replication.     

Presence of genes of ribosomal and transfer RNAs in kinetoplast DNA from two Crithidia species

The coding properties of kinetoplast DNA from two respresentatives of the order Kinetoplastidae--Crithidia oncopelti and C. fasciculata--were studied. Experiments on hybridization of the whole network and fraction of minicircles with labelled 23S and 16S rRNA and with tRNA isolated from kinetoplasts of C. oncopelti clearly demonstrated the presence of the genes for these RNAs in the whole network and their absence in the minicircles. It may be thus concluded that the genes of ribosomal and transfer RNAs are localized in the maxicircular molecules. Similar efficiency of hybridization of rRNAs from C. oncopelti with kDNA from C. fasciculata and C. oncopelti revealed significant conservativity of ribosomal genes in the protozoa under study.     

Characterization of the molecular components in kinetoplast- mitochondrial DNA of Trypanosoma equiperdum. Comparative study of the dyskinetoplastic and wild strains

The structure of the kinetoplast DNA of Trypanosoma equiperdum has been studied and compared to the structure of the circular mitochondrial DNA extracted from a dyskinetoplastic strain of T. equiperdum. In T. equiperdum wild type, the kinetoplast DNA constitutes approximately 6% of the total cellular DNA and is composed of approximately 3,000 supercoiled minicircles of 6.4 x 10(5) daltons and approximately 50 circular supercoiled molecules of 15.4 x 10(6) daltons topologically interlocked; The buoyant density in CsCl of the minicircles is 1.691 g/cm 3. The large circles have a buoyant density of 1.684 g/cm 3, are homogeneous in size and are selectively cleaved by several restriction endonucleases which do not cleave the minicircles. The cleavage sites of six different restriction endonucleases have been mapped on the large circle. The minicircles are cleaved by two other restriction endonucleases, and their cleavage sites have been mapped. The mitochondrial DNA extracted from the dyskinetoplastic strain of T. equiperdum represents 7% of the total DNA of the cell and is composed of supercoiled circles, heterogeneous in size, and topologically associated in catenated oligomers. Its buoyant density in CsCl is 1.688 g/cm 3. These molecules are not cleaved by any of the eight restriction endonucleases tested. The reassociation kinetics of in vitro labeled kDNA minicircles and large circles has been studied. The results indicate that the minicircles as well as the large circles are homogeneous in sequence and that the circular DNA of the dyskinetoplastic strain has no sequence in common with the kDNA of the wild strain.     

Kinetoplast DNA of Bodo caudatus: a noncatenated structure.

The kinetoplast DNA (kDNA) of trypanosomes and other parasitic members of the order Kinetoplastida is organized as a complex network containing thousands of catenated circular DNA molecules. We found that the kDNA of a free-living kinetoplastida, Bodo caudatus, exists as a noncatenated structure. The kDNA of B. caudatus represents about 40% of the total cellular DNA, and the major components of this DNA are large circles of 10 and 12 kilobases (kb). Our results indicate that these circles are analogous to trypanosome kDNA minicircles despite their large size and noncatenated form. The kDNA of B. caudatus also contains a minor component of 19 kb which is transcribed. The 19-kb molecules are probably analogous to the maxicircles of trypanosomes. The properties of the B. caudatus kDNA suggest that the catenated network structure of trypanosome kDNA is not required for maxicircle segregation during kinetoplast division or for the expression of the maxicircle genome.     

Physicochemical properties of kinetoplast DNA from Crithidia acanthocephali. Crithidia luciliae, and Trypanosoma lewisi

The protozoa Crithidia and Trypanosoma contain within a mitochondrion a mass of DNA known as kinetoplast DNA (kDNA) which consists mainly of an association of thousands of small circular molecules of similar size held together by topological interlocking. Using kDNA from Crithidia acanthocephali, Crithidia luciliae, and Trypanosoma lewisi, physicochemical studies have been carried out with intact associations and with fractions of covalently closed single circular molecules, and of open single circular and unit length linear molecules obtained from kDNA associations by sonication, sucrose sedimentation, and cesium chloride-ethidium bromide equilibrium centrifugation. Buoyant density analyses failed to provide evidence for base composition heterogeneity among kDNA molecules within a species. The complementary nucleotide strands of kDNA molecules of all three species had distinct buoyant densities in both alkaline and neutral cesium chloride. For C. acanthocephali kDNA, these buoyant density differences were shown to be a reflection of differences in base composition between the complementary nucleotide strands. The molar ratios of adenine: thymine:guanine:cytosine, obtained from deoxyribonucleotide analyses were 16.8:41.0:28.1:14.1 for the heavy strand and 41.6:16.6:12.8:29.0 for the light strand. Covalently closed single circular molecules of C. acanthocephali (as well as intact kDNA associations of C. acanthocephali and T. lewisi) formed a single band in alkaline cesium chloride gradients, indicating their component nucleotide strands to be alkaline insensitive. Data from buoyant density, base composition, and thermal melting analyses suggested that minor bases are either rare or absent in Crithidia kDNA. The kinetics of renaturation of 32P labeled C. acanthocephali kDNA measured using hydroxyapatite chromatography were consistent with at least 70% of the circular molecules of this DNA having the same nucleotide sequence. Evidence for sequence homologies among the kDNAs of all three species was obtained from buoyant density analyses of DNA in annealed mixtures containing one component kDNA strand from each of two species.     

Comparative study of kinetoplast DNA in culture, blood and intracellular forms of Trypanosoma cruzi.

A comparative study has been made on the kinetoplast DNA (kDNA) from I in culture epimastigote, blood trypomastigote and intracellular amastigote stages of Trypanosoma cruzi. The basic properties of the kDNA in all 3 forms were identical. Thus the DNA was in the form of networks of density 1.698-9 g/cm3 and with sedimentation coefficients (S20w) of approximately 5500, the networks being composed of large complexes of minicircular and apparently linear molecules, the former having contour lengths of 0.45 MICROMETer. Several differences were noted. The ultrastructural arrangement of the kDNA in the kinetoplast of the blood stage consisted of three to four double rows of DNA as compared to one double layered row in the other two stages. There was proportionately more kDNA in the blood stages, suggesting that, since the networks have apparently the same size (see above), more than one is present. DNA loops situated at the periphery of the kDNA networks were observed in higher proportion in blood and intracellular forms. Dimeric and oligomeric circles were present in the kDNA of the blood and intracellular stages in much greater proportion than in culture epimastigote stages. Few large circular molecules, heterogeneous in size, were also observed in intracellular blood stages. There were some differences, mainly quantitative, in the gel electrophoresis patterns after endonuclease digestion.     

On the mechanism of pairing of single- and double-stranded DNA molecules by the recA and single-stranded DNA-binding proteins of Escherichia coli

The pairing of single- and double-stranded DNA molecules at homologous sequences promoted by recA and single-stranded DNA-binding proteins of Escherichia coli follows apparent first-order kinetics. The initial rate and first-order rate constant for the reaction are maximal at approximately 1 recA protein/3 and 1 single-stranded DNA-binding protein/8 nucleotides of single-stranded DNA. The initial rate increases with the concentration of duplex DNA; however, the rate constant is independent of duplex DNA concentration. Both the rate constant and extent of reaction increase linearly with increasing length of duplex DNA over the range 366 to 8623 base pairs. In contrast, the rate constant is independent of the size of the circular single-stranded DNA between 6,400 and 10,100 nucleotides. No significant effect on reaction rate is observed when a single-stranded DNA is paired with 477 base pairs of homologous duplex DNA joined to increasing lengths of heterologous DNA (627-2,367 base pairs). Similarly, heterologous T7 DNA has no effect on the rate of pairing. These findings support a mechanism in which a recA protein-single-stranded DNA complex interacts with the duplex DNA to produce an intermediate in which the two DNA molecules are aligned at homologous sequences. Conversion of the intermediate to a paranemic joint then occurs in a rate-determining unimolecular process.     

Mitochondrial DNA ligases of Trypanosoma brucei

The mitochondrial DNA of Trypanosoma brucei, termed kinetoplast DNA or kDNA, consists of thousands of minicircles and a small number of maxicircles catenated into a single network organized as a nucleoprotein disk at the base of the flagellum. Minicircles are replicated free of the network but still contain nicks and gaps after rejoining to the network. Covalent closure of remaining discontinuities in newly replicated minicircles after their rejoining to the network is delayed until all minicircles have been replicated. The DNA ligase involved in this terminal step in minicircle replication has not been identified. A search of kinetoplastid genome databases has identified two putative DNA ligase genes in tandem. These genes (LIG k alpha and LIG k beta) are highly diverged from mitochondrial and nuclear DNA ligase genes of higher eukaryotes. Expression of epitope-tagged versions of these genes shows that both LIG k alpha and LIG k beta are mitochondrial DNA ligases. Epitope-tagged LIG k alpha localizes throughout the kDNA, whereas LIG k beta shows an antipodal localization close to, but not overlapping, that of topoisomerase II, suggesting that these proteins may be contained in distinct structures or protein complexes. Knockdown of the LIG k alpha mRNA by RNA interference led to a cessation of the release of minicircles from the network and resulted in a reduction in size of the kDNA networks and rapid loss of the kDNA from the cell. Closely related pairs of mitochondrial DNA ligase genes were also identified in Leishmania major and Crithidia fasciculata.     

Heterogeneity of the kinetoplast DNA molecules of Trypanosoma cruzi.

Kinetoplast DNA (kDNA) of the culture form of Trypanosoma cruzi is cleaved by restriction endonucleases (HpaII, HindII, EcoRI, and HaeIII). The analysis of the cleavage patterns proves that the minicircles (free circulargenome units) are heterogeneous in base sequences. The same results are obtained with the complex kDNA network which is composed of the association of minicircles and linear molecules. Kinetic studies of the renaturation of kDNA previously cleaved by HpaII into fragments of the genome unit size show at least two populations of molecules. About 75% of these molecules correspond to the fast renaturing population having the molecular complexity of the minicircles. The molecules of the slow renaturing population have a much higher molecular complexity than the minicircles and do not seem to be related to the majority of the long linear molecules.     

Evidence for a partial RNA transcript of the small circular component of kinetoplast DNA of Crithidia acanthocephali.

The major component of kinetoplast DNA (kDNA) in the protozoan Crithidia acanthocephali is an association of approximately 27,000, 0.8 micrometers (1.58 x 10(6) dalton) circular molecules apparently held together in a particular structural configuration by topological interlocking. We have carried out hybridization experiments between kDNA samples containing one or the other of the two complementary (H and L) strands of purified 0.8 micrometers molecules derived from mechanically disrupted associations and RNA samples prepared either from whole C. acanthocephali cells or from a mitochondrion-enriched fraction. The results of experiments involving cesium sulfate buoyant density centrifugation indicate that whole cell RNA contains a component(s) complementary to all kDNA H strands, but none complementary to kDNA L strands. Similar results were obtained using mitochondrion-associated RNA. Digestion of RNA/DNA hybrids and suitable controls with the single-strand-specific nuclease S1 indicated that 10% of the kDNA H strand is involved in hybrid formation. Visualization of RNA/DNA hybrids stained with bacteriophage T4 gene 32 protein revealed that hybridation involves a single region of each kDNA H strand, equal to approximately 10% of the molecule length. These data suggest that at least 10% of the small circular component of kDNA of Crithidia acanthocephali is transcribed.     

Chain length determination of small double- and single-stranded DNA molecules by polyacrylamide gel electrophoresis.

We describe the use of polyacrylamide gel electrophoresis to estimate chain lengths of double- and single-stranded DNA molecules in the size range 20-1000 base pairs (or nucleotides). Double-stranded DNA molecules of known length produced either by organic synthesis or by restriction endonuclease digestion of viral DNAs were used as standards. The relative electrophoretic mobilities of these standards were examined on both nondenaturing (aqueous) polyacrylamide gels and on denaturing gels containing 7 M urea or 98% formamide. Electrophoretic mobility of DNA is a linear function of the log of molecular weight if appropriate conditions are used, although exceptions are noted. Chain lengths can be conveniently estimated by using as standards bacteriophage gamma DNA restriction fragments or commercially available tracking dyes.     

Molecular and morphological studies of Brazilian Trypanosoma evansi stocks: the total absence of kDNA in trypanosomes from both laboratory stocks and naturally infected domestic and wild mammals

The kinetoplast DNA (kDNA) minicircle molecules of 14 Brazilian stocks of Trypanosoma evansi were studied by morphological approaches (Giemsa and 4'-6'-diamidino-2-phenylindole staining and transmission electron microscopy) and molecular approaches (probing with an oligonucleotide complementary to the minicircle origin of replication and polymerase chain reaction amplification of a minicircle sequence). All methods indicated the absence of both a typical kinetoplast and kDNA minicircles, even in a very small number of parasites of a single stock or in small numbers of copies of molecules per cell. We did not detect any altered kDNA molecules. There were no kDNA molecules in either old or new stocks of T. evansi maintained by successive passages in mice. Similarly, no kDNA minicircles were detected in trypanosomes in blood smears from naturally infected domestic and wild animals. Thus, the total absence of kDNA in Brazilian stocks of T. evansi from both domestic and wild mammals is probably the natural state of Brazilian T. evansi.     

The configuration of DNA replication sites within the Trypanosoma brucei kinetoplast

The kinetoplast is a concatenated network of circular DNA molecules found in the mitochondrion of many trypanosomes. This mass of DNA is replicated in a discrete "S" phase in the cell cycle. We have tracked the incorporation of the thymidine analogue 5-bromodeoxyuridine into newly replicated DNA by immunofluorescence and novel immunogold labeling procedures. This has allowed the detection of particular sites of replicated DNA in the replicating and segregating kinetoplast. These studies provide a new method for observing kinetoplast DNA (kDNA) replication patterns at high resolution. The techniques reveal that initially the pattern of replicated DNA is antipodal and can be detected both on isolated complexes and in replicating kDNA in vivo. In Trypanosoma brucei the opposing edges of replicating kDNA never extend around the complete circumference of the network, as seen in other kinetoplastids. Furthermore, crescent-shaped labeling patterns are formed which give way to labeling of most of the replicating kDNA except the characteristic midzone. The configuration of these sites of replicated DNA molecules is different to previous studies on organisms such as Crithidia fasciculata, suggesting differences in the timing of replication of mini and maxicircles and/or organization of the replicative apparatus in the kinetoplast of the African trypanosome.     

Organized packaging of kinetoplast DNA networks

The kinetoplast DNA (kDNA) of Trypanosoma equiperdum is organized as a complex structure of catenated circular DNA molecules. The major component of the kDNA network is the one kilobase minicircle that is present at about 10,000 copies per network. We have developed two assays to examine the structure of kDNA networks compacted in vitro with spermidine. Our results suggest that minicircles are arranged into a regular structure with an exposed domain which is DNAase I- and restriction-sensitive and a protected domain which is resistant to restriction endonucleases and DNAase I. This regularly packaged structure is dependent upon spermidine compaction and the circularity of the kDNA, but does not require supercoiled minicircles or catenated networks.     

Replication of kinetoplast DNA of Crithidia acanthocephali. I. Density shift experiments using deuterium oxide

The protozoan Crithidia acanthocephali contains, within a modified region of a mitochondrion, a mass of DNA known as kinetoplast DNA (kDNA). This DNA consists mainly of an association of approximately 27,000 covalently closed 0.8-mum circular molecules which are apparently held together in a definite ordered manner by topological interlocking. After culturing of C. acanthocephali cells for 25 generations in medium containing 75% deuterium oxide, both nuclear DNA (rhonative, nondeuterated=1.717 g/cm3) and kDNA (rhonative, nondeuterated=1.702 g/cm3) increased in buoyant density by 0.012 g/cm3. The replication of the two DNAs was studied by cesium chloride buoyant density analysis of DNAs from exponentially growing cells taken at 1.0, 1.4, 2.0, 3.0, and 4.0 cell doublings after transfer of cells from D2O- containing medium into medium containing only normal water. The results obtained from analysis of both native and denatured nuclear DNAs indicate that this DNA replicates semiconservatively. From an analysis of intact associations of kDNA, it appears that this DNA doubles once per generation and that the newly synthesized DNA does not segregate from parental DNA. Fractions of covalently closed single circular molecules and of open circular and unit length linear molecules were obtained from associations of kDNA by sonication, sucrose sedimentation, and cesium chloride-ethidium bromide equilibrium gradient centrifugation. Buoyant density profiles obtained from these fractions indicate that: (a) doubling of the kDNA results from the replication of each circular molecule rather than from repeated replication of a small fraction of the circular molecules; (b) replication of kDNA is semiconservative rather than conservative, but there is recombination between the circles at an undefined time during the cell cycle.     

Kinetoplast DNA permits characterization of pathogenic plant trypanosomes of economic importance

Summary— Twelve Phytomonas isolates were obtained from different plants originating from several countries and cultured in vitro in complex media. The kinetoplast DNA (kDNA) was purified and observed by electron microscopy. The structure of kDNA from all isolates appeared as a large network of interlocked minicircles with some maxicircles extruding from the network, as has often been shown for Trypanosomatidae. Topoisomerase II resolved the kDNA network into free minicircles which were then analyzed by electron microscopy and by electrophoresis in agarose gel. The minicircle sizes varied from 1.3 to 2.8 kilobase pairs according to the Phytomonas isolate. The analysis by restriction endonucleases revealed a base sequence heterogeneity in the minicircles of 10 of these Phytomonas isolates. By contrast, in 2 Phytomonas isolates, more than 90% of their minicircle content was found to be homogeneous. Most interestingly, the minicircle cleavage patterns were found to be different between Phytomonas isolates and thus could be used to distinguish them.