Cloning of the replication origin from Drosophila virilis mitochondrial DNA.

Mitochondrial DNA from $\text{Drosophila}$ contains high “A+T”-rich region. Its DNA replication starts in the “A+T”-rich region and proceeds unidirectionally around the molecule. In order to determine precise location of the DNA replication origin and elucidate unique feature of its nucleotide sequence, the “A+T”-rich region of mitochondrial DNA from $\text{Drosophila}\text{virilis}$ has been cloned in $\text{Escherichia}\text{coli}$. The chimeric plasmid DNA containing the “A+T”-rich region stimulates $\text{in}\text{vitro}$ DNA replication system from $\text{Drosophila}\text{virilis}$ mitochondria about ten fold higher than the parental plasmid DNA, as does native mitochondrial DNA.     

Adenovirus DNA replication in vitro: Origin and direction of daughter strand synthesis

We have characterized a soluble enzyme system from adenovirus-infected cells that is capable of replicating exogenously added adenovirus DNA in vitro. Maximal DNA synthesis is observed when DNA-protein complex, isolated from purified adenovirus virions, is added as template. Under these conditions DNA replication starts at or near either end of the template. Daughter strand synthesis then proceeds in the 5′ to 3′ direction displacing the parental strand of the same polarity. Thus, the r daughter strand is synthesized from right to left on the conventional map of the adenovirus genome, and the l daughter strand is synthesized from left to right. This course of events is the same as that which occurs during adenovirus DNA replication in vivo. In contrast, when deproteinized adenovirus DNA is added to the in vitro system, the limited DNA synthesis that is observed appears to be due to a repair-like reaction. In particular, synthesis can begin at many sites within the template, and the synthetic product consists largely of short DNA chains that are covalently linked to template DNA strands.     

DNA replication in cell-free extracts from Drosophila melanogaster.

We have developed an efficient in vitro replication system from 0-2 h Drosophila melanogaster embryos. Demembranated Xenopus sperm DNA when incubated in such an extract first becomes enclosed in a nucleus-like structure with a nuclear envelope and a karyoskeleton. It then undergoes one round of semiconservative replication--this replication appears completely dependent on nuclear formation. Up to 30% of input DNA is nucleated in one reaction. Efficient nuclear formation and replication are dependent on a cold treatment step, prior to disruption of the embryos. They also depend on the age of the embryos used. Extracts from older embryos (0-5 h) are capable of nuclear formation, although at a much reduced efficiency, and repair synthesis, but seem to have lost the ability to initiate DNA replication. In addition to replicating sperm DNA this system appears capable of carrying out semi-conservative replication on some plasmids. However, it cannot use these to trigger nuclear formation; replication is only seen if the plasmids are coincubated with sperm DNA. The in vitro formed nuclei have not been observed to trigger nuclear envelope breakdown and entry into mitosis. However, they can re-replicate the DNA if the nuclei are permeabilized. This system should be a useful complement to the previously isolated Xenopus in vitro replication system. In addition the amenability of Drosophila to genetic study should open up new approaches not previously possible with Xenopus.     

Chromosome-sized DNA molecules from Drosophila

Measurements of viscoelastic retardation times of detergent-Pronase lysates of Drosophila cells demonstrated the presence of large numbers of DNA molecules of a size commensurate with that of the chromosomes. The values estimated from the retardation times for the molecular weights of the largest molecules ranged from about 20×10⁹ to 80×10⁹ daltons depending on the species of Drosophila. The molecular weights of the DNA molecules were independent of the metaphase shapes (i.e., metacentric or submetacentric), but were proportional to the DNA contents of the chromosomes in the case of translocations or deletions. It was concluded, therefore, that the DNA molecules must run the length of the chromosome and cannot be discontinuous at the centromere. When compared with the values of the DNA contents of Drosophila chromosomes determined by other methods, the results were consistent with the model of one, or possibly two, DNA molecules per chromosome; the simplest conclusion, that there is only one DNA molecule per chromosome (for simple chromosomes), rests on a long extrapolation of an empirical relation between retardation time and molecular weight, but is also favored by indirect evidence. Further possibilities which could not be excluded were that the large DNA molecules contained Pronase-resistant, non-DNA links, or that a fraction of smaller DNA molecules might also have been present in the chromosomes. Chromosome-sized DNA molecules were obtained almost quantitatively from unsynchronized cultured cells, suggesting that the size of the chromosomal DNA is conserved throughout much of the cell cycle. The molecules were stable for periods of up to several days at 50° C in solutions containing detergent, Pronase, and EDTA.     

Complex mitochondrial DNA in Drosophila.

The larval mtDNA isolated from D. virilis, D. simulans and D. melanogaster exists in complex molecular forms in addition to the simple monomeric circular form. The frequency of circular dimers and oligomers is highly elevated in apparently normal larval tissues. These complex forms of mtDNA are separable on agarose gels. Hind III restriction endonuclease and electron microscopic analyses used in the present study have revealed that circular dimers are simply the circular concatemers of two monomeric circles which are arranged in a head-to-tail structure with no detectable heterologous regions such as insertions or deletions. The electrophoretic patterns of Hind III digested mtDNAs of D. simulans and D. melanogaster (sibling species) are identical and distinguishable from that of distantly related species, D. virilis.     

Origin and direction of replication of the bacteriocinogenic plasmid Clo DF13.

Cairn's type replicative intermediates of both the wildtype Clo DF13 plasmid and the copy mutant CLO DF13 cop3 were isolated by dye-buoyant density centrifugation. Replicative intermediates were linearized at the HpaI or Sa1I cleavage site, and examined with the electron-microscope. The data show that replication of both the Clo DF13 wild type plasmid and the Clo DF13 cop3 plasmid, initiates at about 2.8% on the physical map. Replication proceeds unindirectionally and counterclockwise on this map.     

Evidence for discontinuous replication of circular mitochondrial DNA molecules from Novikoff rat ascites hepatoma cells

Double-forked circular molecules of mitochondrial DNA (mtDNA) from rat tissues, indicated by their form and size to be replicative intermediates, are of two structurally distinct classes. Molecules of the first class are totally double stranded. Molecules of the second class are defined by one daughter segment being totally or partially single stranded. Length histograms of daughter segments measuring between 2% and 44% of the total 5-µm molecular contour were constructed from samples of both classes of replicating molecules derived from mtDNA or Novikoff rat ascites hepatoma cells. For single strand-containing molecules, the lengths fell into eight distinct, reproducible groups with mean values separated by 4.1–7.6% of the circular contour length. For totally double stranded molecules, the lengths fell into seven groups, corresponding to seven of the groups found for single strand-containing molecules. These results suggest that along at least 44% of the contour of mtDNA molecules there exist discrete points at which DNA synthesis tends to be arrested. This may indicate that there are pauses in normal mtDNA synthesis. However, as the DNA used in these experiments was isolated from mitochondrial fractions, the findings may indicate that continuation of synthesis beyond specific points on the nucleotide strands requires a factor which is not available after cell disruption.     

A Drosophila model of mitochondrial DNA replication: proteins, genes and regulation

Mitochondrial biogenesis is a critical process in animal development, cellular homeostasis and aging. Mitochondrial DNA replication is an essential part of this process, and both nuclear and mitochondrial DNA mutations are found to result in mitochondrial dysfunction that leads to developmental defects and delays, aging and disease. Drosophila provides an amenable model system to study mitochondrial biogenesis in normal and disease states. This review provides an overview of current approaches to study the proteins involved in mitochondrial DNA replication, the genes that encode them and their regulation. It also presents a survey of cell and animal models under development to mimic the pathophysiology of human mitochondrial disorders.     

Origin and differentiation of human mitochondrial DNA.

A recent study of mitochondrial DNA (mtDNA) polymorphism has generated much debate about modern human origins by proposing the existence of an "African Eve" living 200,000 years ago somewhere in Africa. In an attempt to synthesize information concerning human mtDNA genetic polymorphism, all available data on mtDNA RFLP have been gathered. A phylogeny of the mtDNA types found in 10 populations reveals that all types could have issued from a single common ancestral type. The distribution of shared types between continental groups indicates that caucasoid populations could be the closest to an ancestral population from which all other continental groups would have diverged. A partial phylogeny of the types found in five other populations also demonstrates that the myth of an African Eden was based on an incorrect "genealogical tree" of mtDNA types. Two measures of molecular diversity have been computed on all samples on the basis of mtDNA type frequencies, on one hand, and on the basis of the number of polymorphic sites in the samples, on the other. A large discrepancy is found between the two measures except in African populations; this suggests the existence of some differential selective mechanisms. The lapse of time necessary for creating the observed molecular diversity from an ancestral monomorphic population has been calculated and is found generally greater in Oriental and caucasoid populations. Implications concerning human mtDNA evolution are discussed.     

Diversity in organization and the origin of gene orders in the mitochondrial DNA molecules of the genus Saccharomyces

Sequencing of the Saccharomyces cerevisiae nuclear and mitochondrial genomes provided a new background for studies on the evolution of the genomes. In this study, mitochondrial genomes of a number of Saccharomyces yeasts were mapped by restriction enzyme analysis, the orders of the genes were determined, and two of the genes were sequenced. The genome organization, i.e., the size, presence of intergenic sequences, and gene order, as well as polymorphism within the coding regions, indicate that Saccharomyces mtDNA molecules are dynamic structures and have undergone numerous changes during their evolution. Since the separation and sexual isolation of different yeast lineages, the coding parts have been accumulating point mutations, presumably in a linear manner with the passage of time. However, the accumulation of other changes may not have been a simple function of time. Larger mtDNA molecules belonging to Saccharomyces sensu stricto yeasts have acquired extensive intergenic sequences, including guanosine-cytosine-rich clusters, and apparently have rearranged the gene order at higher rates than smaller mtDNAs belonging to the Saccharomyces sensu lato yeasts. While within the sensu stricto group transposition has been a predominant mechanism for the creation of novel gene orders, the sensu lato yeasts could have used both transposition- and inversion-based mechanisms.     

Intraspecific diversity of nucleotide sequences within the adenine + thymine-rich region of mitochondrial DNA molecules of Drosophila mauritiana, Drosophila melanogaster and Drosophila simulans.

Mitochondrial DNA (mtDNA) molecules from Drosophila mauritiana, D. melanogaster, and D. simulans contain a single adenine + thymine (A+T)-rich region, which is similarly located in all molecules, but varies in size among these species. Using agarose gel electrophoresis and electron microscopy, a difference in occurrence of one EcoRI site, and a difference in size (approximately 0.7 kb) of the A+T-rich regions was found between mtDNA molecules of flies of two female lines of D. mauritiana. In heteroduplexes constructed between these two kinds of mtDNA molecules, two or three regions of strand separation, each comprising single strands of unequal length, were apparent near the center of the A+T-rich region. Using the structural differences between D. mauritiana mtDNA molecules it was demonstrated the mtDNA of this species is maternally inherited. Differences in length of A+T-rich regions were also found between mtDNA molecules of two geographically separated strains of D. melanogaster, and between mtDNA molecules of two geographically separated strains of D. simulans. However, in both cases, in heteroduplexes constructed between mtDNA molecules of different strains of one species, the A+T-rich regions appeared completely paired.     

Conservation of epigenetic regulation, ORC binding and developmental timing of DNA replication origins in the genus Drosophila

There is much interest in how DNA replication origins are regulated so that the genome is completely duplicated each cell division cycle and in how the division of cells is spatially and temporally integrated with development. In the Drosophila melanogaster ovary, the cell cycle of somatic follicle cells is modified at precise times in oogenesis. Follicle cells first proliferate via a canonical mitotic division cycle and then enter an endocycle, resulting in their polyploidization. They subsequently enter a specialized amplification phase during which only a few, select origins repeatedly initiate DNA replication, resulting in gene copy number increases at several loci important for eggshell synthesis. Here we investigate the importance of these modified cell cycles for oogenesis by determining whether they have been conserved in evolution. We find that their developmental timing has been strictly conserved among Drosophila species that have been separate for approximately 40 million years of evolution and provide evidence that additional gene loci may be amplified in some species. Further, we find that the acetylation of nucleosomes and Orc2 protein binding at active amplification origins is conserved. Conservation of DNA subsequences within amplification origins from the 12 recently sequenced Drosophila species genomes implicates members of a Myb protein complex in recruiting acetylases to the origin. Our findings suggest that conserved developmental mechanisms integrate egg chamber morphogenesis with cell cycle modifications and the epigenetic regulation of origins.     

Mitochondrial single-stranded DNA-binding protein is required for mitochondrial DNA replication and development in Drosophila melanogaster

The discovery that several inherited human diseases are caused by mtDNA depletion has led to an increased interest in the replication and maintenance of mtDNA. We have isolated a new mutant in the lopo (low power) gene from Drosophila melanogaster affecting the mitochondrial single-stranded DNA-binding protein (mtSSB), which is one of the key components in mtDNA replication and maintenance. lopo(1) mutants die late in the third instar before completion of metamorphosis because of a failure in cell proliferation. Molecular, histochemical, and physiological experiments show a drastic decrease in mtDNA content that is coupled with the loss of respiration in these mutants. However, the number and morphology of mitochondria are not greatly affected. Immunocytochemical analysis shows that mtSSB is expressed in all tissues but is highly enriched in proliferating tissues and in the developing oocyte. lopo(1) is the first mtSSB mutant in higher eukaryotes, and its analysis demonstrates the essential function of this gene in development, providing an excellent model to study mitochondrial biogenesis in animals.     

Evoluation of Drosophila mitochondrial DNAs. Analysis of heteroduplex molecules.

We have mapped the single block of non-homologous sequences and measured the extent and distribution of base-pair substitutions within the homologous sequences in Drosophila melanogaster: Drosophila virilis heteroduplex mitochondrial DNAs (mtDNAs). Of the 4.8 kilobases long, unusually (A + T)-rich region in D. melanogaster mtDNA, only 0.5 kilobases can react with related, but not identical sequences in D. virilis mtDNA, while the rest (4.3 kilobases in the long arm of a heteroduplex loop) is replaced by a shorter, non-homologous region (1.0 kilobases in the short arm of the loop). No additional heterologous regions are evident. Homologous sequences have accumulated on the average 15.5% base-pair changes. Regionally, these substitutions are relatively uniformly distributed (14.5--16.5%) except for a single, more conserved region (10--13%), which presumably represents the ribosomal cistrons. The lack of general sequence stability suggests that the invariant topographic organization of the nucleotide sequence, previously recognized among Drosophila mtDNAs, is under more stringent selection than the sequence per se.