THE FORM AND STRUCTURE OF KINETOPLAST DNA OF CRITHIDIA

Cesium chloride centrifugation of each of the DNAs extracted from eight strains of Crithidia revealed a main band at ρ = 1.717 g/cm³ and a satellite band varying from ρ = 1.701 to 1.705 g/cm³ for the different strains By electron microscopy each DNA was shown to include circular molecules, 0.69–0.80 µ in mean contour length, and large, topologically two-dimensional masses of DNA in which the molecules appeared in the form of rosettes. DNA isolated from kinetoplast fractions of Crithidia acanthocephali was shown to consist of light satellite DNA and to be mainly in the form of large masses, 0.8 µ (mol wt = 1.54 x 10⁶ daltons) circular molecules, and a few long, linear molecules. The results of experiments involving ultracentrifugation, heating, and quenching, sonication, and endodeoxyribonuclease digestion, combined with electron microscopy, are consistent with the following hypothesis. The large DNA masses are associations of 0.8 µ circles which are mainly covalently closed. The circles are held together in groups (the rosettes) of up to 46 by the topological interlocking of each circle with many other circles in the group. A group of circles is attached to an adjacent group by one or more circles, each interlocking with many circles of both groups. Each of the associations comprises, on the average, about 27,000 circles (total mol wt 41 x 10⁹ daltons). A model is proposed for the in situ arrangement of the associations which takes into consideration their form and structure, and appearance in thin sections     

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.     

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.     

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.     

Specific fragmentation of mitochondrial DNA from Neurospora crassa by restriction endonuclease Eco R I.

Linear, size-heterogenous mitochondrial DNA from $\text{Neurospora crassa}$ was cleaved by the restriction endonuclease Eco R I into eleven specific fragments. According to their contour lengths the fragments have molecular weights between 1.1 and 14 × 10⁶. The sum of the fragments lengths is identical with the contour length (19.8 μm, 41 × 10⁶ daltons) of the few circular molecules detectable in purified DNA preparations.The results suggest sequence homogeneity of mitochondrial DNA and further demonstrate that restriction enzymes can be used to establish a physical map of an unspecifically-fragmented DNA molecule.     

Extra components in kinetoplast DNA preparations from Crithidiafasciculata

Kinetoplast DNA from the order Kinetoplastidae (trypanosomatids) exists as large associations (molecular weight 4 × 10¹⁰), made up of about 104 small, probably circular, molecules, commonly known as ‘minicircles’. These minicircles were originally thought to be identical in base composition, suggesting that the coding capacity of kinetoplast DNA is very restricted. However, linear molecules have also been observed in preparations of kinetoplast DNA, which, if they contain unique sequences, could represent additional genetic information. This linear DNA has been assumed to be derived from the kinetoplast, but the possibility of it being nuclear contamination has not been definitely ruled out. Work presented in this paper demonstrates that nuclear DNA contamination may indeed be present in kinetoplast DNA prepared by a commonly used method.     

Studies on the mechanism of DNA replication in Physarum polycephalum

The synthesis of single-stranded DNA subunits (4 × 10⁷ daltons) in Physarum polycephalum was studied by alkaline sucrose density gradient centrifugation. The results were compared with the synthesis of the double-stranded DNA molecules (2.3 × 10⁸ daltons) which they comprise, as determined from neutral sucrose density gradient centrifugation patterns. Although the initiation of synthesis of most double-stranded DNA molecules takes place relatively early in the S period, synthesis of the subunits within them is initiated throughout at least the first two hours of this period. Similarly, replicating (presumably forked) DNA molecules appear to split into daughter DNA molecules prior to the completion of synthesis of the subunits therein. The average rate of DNA chain elongation within subunits is 0.3 × 10⁶ daltons/minute. It is suggested that alkaline sucrose density gradient centrifugation may be a more sensitive method for determining the time required for the completion of replication than other methods based solely on the incorporation of radioactive DNA precursors into an acid-insoluble product.     

Bacteriophage phi X174 RF DNA replication in vivo. A study by electron microscopy.

We have investigated bacteriophage φX174 RF ² DNA replication by electron microscopy. Three different, types of replicative intermediates were observed: rolling circles, partially duplex DNA circles and structures consisting of two DNA circles connected at a single point.Rolling circles with a single-stranded or partially double-stranded DNA tail were both observed. After cleavage of the rolling circles with the restriction endonuclease from Providentia stuartii 164 (PstI) the startpoint of rolling circle replication could be located at 21 map units from the PstI cleavage site in agreement with the previously determined position of the origin of φX RF DNA replication.Partially duplex DNA circles consist of circular viral DNA strands and incomplete complementary DNA strands. After cleavage of these molecules with PstI information about the startpoints of the synthesis of the complementary DNA strand was obtained.The connected DNA circles always contain one completely double-stranded DNA circle whereas the other circle consists of either single-stranded, partially duplex or completely duplex DNA.Part of the duplex-to-duplex DNA circles represent the well-known figure eight or catenated circular dimers. The other connected DNA circles presumably represent replication intermediates which arise by the association of the end of the genome length tail of the rolling circle with the origin-terminus region. This is suggested by the fact that the point of contact between the two DNA circles is located at approximately 21 map units from the Pst1 cleavage site, i.e. at the origin-terminus region of the φX genome. The connected DNA circles may be intermediates in the circularization and cleavage of the genome-length tail of the rolling circles in vivo.A model for φX174 RF DNA replication in vivo summarizing the data obtained by biochemical (Baas et al., 1978) and electron microscopic analysis of replicative intermediates is presented (Fig. 9).     

KINETOPLAST DEOXYRIBONUCLEIC ACID OF THE HEMOFLAGELLATE TRYPANOSOMA LEWISI

Cesium chloride centrifugation of DNA extracted from cells of blood strain Trypanosoma lewisi revealed a main band, ρ = 1.707, a light satellite, ρ = 1.699, and a heavy satellite, ρ = 1.721. Culture strain T. lewisi DNA comprised only a main band, ρ = 1.711, and a light satellite, ρ = 1.699. DNA isolated from DNase-treated kinetoplast fractions of both the blood and culture strains consisted of only the light satellite DNA. Electron microscope examination of rotary shadowed preparations of lysates revealed that DNA from kinetoplast fractions was mainly in the form of single 0.4 µ circular molecules and large masses of 0.4 µ interlocked circles with which longer, often noncircular molecules were associated. The 0.4 µ circular molecules were mainly in the covalently closed form: they showed a high degree of resistance to thermal denaturation which was lost following sonication; and they banded at a greater density than linear DNA in cesium chloride-ethidium bromide gradients. Interpretation of the large masses of DNA as comprising interlocked covalently closed 0.4 µ circles was supported by the findings that they banded with single circular molecules in cesium chloride-ethidium bromide gradients, and following breakage of some circles by mild sonication, they disappeared and were replaced by molecules made up of low numbers of apparently interlocked 0.4 µ circles. When culture strain cells were grown in the presence of either ethidium bromide or acriflavin, there was a loss of stainable kinetoplast DNA in cytological preparations. There was a parallel loss of light satellite and of circular molecules from DNA extracted from these cells.     

Enhancement of transfecting activity of bacteriophage P22 DNA upon exonucleolytic erosion

The transfecting efficiency of P22 DNA on “rough” strains of Salmonella typhimurium or non-restricting mutants of Escherichia coli K12 approaches 3 × 10^?8 plaques/genome equivalent. It increases 20-fold upon complete erosion of the terminally redundant regions of the DNA molecule with either λ exonuclease or exonuclease III. Eroded DNA molecules form circles and linear oligomers upon annealing. The circular monomers display transfecting activity about ten times higher than that of eroded linear monomers or hydrogen-bonded oligomers. recB recC sbcB strains of E. coli K12 are transfected with P22 DNA with an efficiency of 1.5 × 10^?6 plaques/genome equivalent. The activity of DNA molecules on these strains is not augmented by erosion. This suggests that the activation by erosion, seen in assays on rec⁺ genotypes, is due to the formation of hydrogen-bonded circular molecules, which more readily escape degradation by the recBC nuclease.     

Molecular characterization of a stable Flac plasmid

F$\text{lac}$S is a thermostable extrachromosomal element isolated in $\text{Salmonella typhimurium}$ which is altered in its replication as compared to its precursor F_ts114$\text{lac}$. Sedimentation of both these plasmids in alkaline sucrose gradients has indicated a difference in their sizes. Contour length measurements of open circular plasmid DNA molecules photographed in the electron microscope have revealed the estimated molecular weight of F_ts114$\text{lac}$ to be 81 × 10⁶ daltons while that of F$\text{lac}$S is 109 × 10⁶ daltons. F$\text{lac}$S may carry a segment of $\text{S. typhimurium}$ chromosomal or cryptic plasmid DNA.     

Mitochondrial DNA from Podospora anserina. II. Properties of mutant DNA and multimeric circular DNA from senescent cultures.

Summary Mitochondrial (Mt) DNA from mitochondrial mutants of race s Podospora anserina and from senescent cultures of races s and A was examined. In mutants, we observed that fewer full length circles (31 ) were present; instead, smaller circles characteristic for each mutant sudied were found. Eco Rl digestion of these mutant MtDNAs indicated that in certain mutants, although specific fragments were absent, the total molecular weight of the fragments was not much different than wild-type.The properties of senescent MtDNA was strikingly different from either wild-type or mutant Mt DNA. First, a multimeric set of circular DNA was observed for both race s and A, with a monomeric repeat size of 0.89 . These circles ranged in size from 0.89 to greater than 20 ; only one molecule out of some 200 molecules was thought to be of full length (31 ). Density gradient analysis showed that there were two density species: a majority were at the same density as wild-type (1.694 g/cm³) and a second at 1.699 g/cm³. Most of the circular molecules from MtDNA isolated by either total DNA extraction or by extraction of DNA from isolated mitochondria were contained in the heavy DNA fraction. Eco R1 enzymatic digestion indicated that the light DNA had several fragments (amounting to about 23×10⁶ daltons) missing, compared with young, wild-type MtDNA. Heavy senescent MtDNA was not cleaved by Eco R1. Analysis with Hae III restriction endonuclease showed also that light senescent MtDNA was missing certain fragments. Heavy MtDNA of average size 20×10⁶ daltons, yielded only one fragment, 2,500 bp long, by digestion with Hae III restriction endonuclease. Digestion of heavy DNA with Alu I enzyme yielded 10 fragments totalling 2,570 bp. By three criteria, electron-microscopy, Eco R1 and Hae digestion, we conclude that the heavy MtDNA isolated from senescent cultures of Podospora anserina consisted of a monomeric tandemly repeating subunit of about 2,600 bp length.These results on the properties of senescent MtDNA are discussed with regard to the published properties of the rho ^- mutation in the yeast, S. cerevisiae.     

Recombinant DNA analysis indicates that the multiple chromosomes of maize mitochondria contain different sequences

Twenty-eight Bam H 1 restriction fragments were isolated from normal mitochondrial DNA of maize by recombinant DNA techniques to investigate the organization of the mitochondrial genome. Each cloned fragment was tested by molecular hybridization against a Bam digest of total mitochondrial DNA. Using Southern transfers, we identified the normal fragment of origin for d each clone. Twenty-three of the tested clones hybridized only to the fragment from which the clone was derived. In five cases, labeling of an additional band indicated some sequence repetition in the mitochondrial genome. Four clones from normal mitochondrial DNA were found which share sequences with the plasmid-like DNAs, S-1 and S-2, found in S male sterile cytoplasm. The total sequence complexity of the clones tested is 121×10⁶ d (daltons), which approximates two thirds of the total mitochondrial genome (estimated at 183×10⁶ d). Most fragments do not share homology with other fragments, and the total length of unique fragments exceeds that of the largest circular molecules observed. Therefore, the different size classes of circular molecules most likely represent genetically discrete chromosomes in a complex organelle genome. The variable abundance of different mitochondrial chromosomes is of special interest because it represents an unusual mechanism for the control of gene expression by regulation of gene copy number. This mechanism may play an important role in metabolism or biogenesis of mitochondria in the development of higher plants.     

Large circular mitochondrial DNA in Crithidia luciliae

A novel circular DNA, 11.3 μm in contour length, has been found in a pure kinetoplast DNA fraction of Crithidia luciliae. The mitochondrial nature of the kinetoplast and the absence of these large circular molecules in the nuclear fraction of DNA suggest that they constitute the mitochondrial genome of this species.     

Size distribution and maturation of newly replicated DNA through the S and G2 phases of physarum polycephalum

The size distribution of newly made DNA and the dynamics of size maturation of progeny DNA molecules were studied in the synchronous S and G2 phases of Physarum polycephalum. Pulse labeling of DNA and analysis of the products on alkaline sucrose gradients showed that synthesis of primary replication units (which will also be referred to as “Okazaki” fragments) occurred throughout the S period. Pulse and pulse-chase experiments revealed a distinct pattern of size maturation. An apparently linear increase in molecular weight of progeny DNA molecules during the first hour of the S phase occurred at a rate of approximately 4–5 × 10⁵ daltons per min at 26°C, corresponding to the joining of 6–8 Okazaki fragments. The resulting 35–45S (1.1–2.2 × 10⁷ daltons) DNA molecules may correspond to the Physarum “replicon.” The further size increases of the newly made DNA appear to occur in steps, possibly reflecting a clustering of isochronous replicons along the chromatide. These observations are discussed with regard to mechanisms of DNA replication and size maturation.     

Kinetoplast DNA of Trypanosoma brucei: Physical map of the maxicircle

Trypanosoma brucei maxicircle DNA in kinetoplast DNA (kDNA) networks was characterized with restriction endonucleases. The data allow the construction of a circular map of a 22.2-kb molecule. Based on these and previous data each T. brucei kDNA network contains about 45 maxicircles which probably have the same sequence. The maxicircle of strain 164 used in this study was slightly larger and had three EcoRI sites compared to two found in other strains. Fragments generated by digestion with BamHI were largely singly cleaved maxicircles that had a density of 1.681 g/cm³ compared to 1.693 g/cm³ for the intact network. This suggests that maxicircles have a higher A + T content than minicircles. Minicircles in the kDNA network were also characterized with restriction endonucleases. Each enzyme cleaved a specific subset of minicircles from the network. However, no single restriction endonuclease or combination of up to three of these enzymes cleaved all molecules in the network. These results are consistent with earlier results of renaturation kinetic experiments and indicate that there are many different sequence classes of mini-circle DNA.     

The segregation of kinetoplast DNA networks in Trypanosoma brucei

The kinetoplast DNA of Trypanosoma brucei consists of 10⁴ minicircles (0.3 μm) and 10² maxicircles (6 μm) held together by catenation in a complex network. In electron micrographs of kinetoplast DNA spread in a protein monolayer we have identified four types of network with the appearance of different stages in network replication and segregation. We show that each network type has characteristic properties with respect to shape, size, number, and location of maxicircle loops and nicked or covalently closed character of minicircles and maxicircles. We propose a detailed model for network segregation that involves a gradual elongation of the network, followed by network cleavage. During this process the basic network structure remains unaltered, implying a complicated mechanism of minicircle rearrangements.     

Specific Origin in SV40 DNA Replication

THE oncogenic virus SV40 contains a covalently closed circular DNA molecule of 3 × 10⁶ molecular weight¹. In infected permissive cells, SV40 DNA replicates through a Cairns type intermediate² with the parental strands forming a partially twisted, covalently closed molecule³. We have used a specific bacterial restriction endonuclease⁴ to analyse SV40 DNA replication. The restriction endonuclease of H. influenzae makes double-strand breaks in DNA at specific hexanucleotide sequences^{5, 6} and splits SV40 DNA into eleven fragments, separable by Polyacrylamide gel electrophoresis, ranging in molecular weight from 6.5 × 10⁵ (about 20% of the molecule) to 7.4 × 10⁴ (about 2.5% of the molecule). The largest eight fragments are present in the digest in amounts equimolar with the starting DNA⁴. Therefore, by digesting labelled replicating SV40 DNA and newly completed DNA and measuring the relative yield of each fragment, we could determine whether a particular region of the DNA is synthesized first or last and also estimate the time needed to replicate one molecule completely.     

Heterogeneity in sensitivity to cleavage by the restriction endonucleases ECORI and HindIII of circular kinetoplast DNA molecules of Crithidia acanthocephali

Kinetoplast DNA (kDNA) of the protozoan Crithidia acanthocephali consists mainly of an association of approximately 27,000 covalently closed, 0.8-micron (1.58 X 10(6) daltons) circular molecules apparently held together in a particular structural configuration by topological interlocking. The sensitivities of circular kDNA molecules to the restriction endonucleases EcoRI and HindIII have been studied using agarose gel electrophoresis and electron microscopy. Digestion with EcoRI or HindIII of collections of single circular molecules obtained from sonicated kDNA associations resulted in a single cleavage of 9.3 and 12% of the molecules, respectively. Digestion of intact kDNA associations with EcoRI or HindIII resulted in cleavage of 9.2 and 10.4%, respectively, of the component circular molecules, but not in detectable disruption of the characteristic structure of the associations. Analysis of the products of sequential digestion of kDNA with the two enzymes indicated that approximately 8% of the circular molecules each contain a single site sensitive to EcoRI and a single site sensitive to HindIII; 1.5-3% contain only an EcoRI-sensitive site; 3-4% contain only a HindIII-sensitive site; and the remainder (approximately 86%) are insensitive to either enzyme. Further, data obtained from sequential digestion experiments and from studies of the partial denaturation products of the circular molecules digested with EcoRI or HindIII indicated that when they occur the EcoRI site and the HindIII site are each at a unique position in all molecules, 10-13% of the circular contour length apart. Similar digestion products were found for kDNAs from different cloned organisms, suggesting that the four different kinds of circular molecules, in regard to EcoRI and HindIII sensitivity, are found in similar proportions in the kDNA association of different organisms.     

Electron microscopic and renaturation kinetic analysis of mitochondrial DNA of cytoplasmic petite mutants of Saccharomyces cerevisiae

Mitochondrial DNA isolated from a series of nine petite yeast strains and from the parent grande strain was characterized by electron microscopic and renaturation kinetic analysis. The mtDNA² from all strains contained a variety of branched molecules which may be intermediates of replication or recombination. Although no circles were observed in the grande mtDNA, all the petites contained circular mtDNA molecules. The size distribution of the circles conformed to an oligomeric series that was characteristic for each strain. In seven petites, the length series could be related to a single circle monomer size, ranging from 0.13 μm to 5.5 μm; and in two petites to two or more circular monomer lengths. In contrast to circular mtDNA, linear molecules showed no unique size distribution. Circle monomer lengths were linearly related to the kinetic complexity (κ₂ or $\text{C}{}_0\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) of sheared total mtDNA in the seven petite strains that contained a predominant single series of circle lengths. Thus in each of these petite strains the circle monomer length defined the same DNA sequence present in the linear DNA molecules of non-unique length.