Tricircular mitochondrial genomes of Brassica and Raphanus: reversal of repeat configurations by inversion.

We constructed complete physical maps of the tripartite mitochondrial genomes of two Crucifers, Brassica nigra (black mustard) and Raphanus sativa (radish). Both genomes contain two copies of a direct repeat engaged in intragenomic recombination. The outcome of this recombination in black mustard is to interconvert a 231 kb master chromosome with two subgenomic circles of 135 kb and 96 kb. In radish, a 242 kb master chromosome interconverts with subgenomic circles of 139 kb and 103 kb. The recombination repeats are 7 kb in size in black mustard and 10 kb in radish, and are nearly identical except for two insertions in the radish repeat relative to the black mustard one. The two repeat configurations present on the master chromosome of black mustard are located on the subgenomes of radish and vice-versa. To explain this, we postulate the existence of an evolutionarily intermediate mitochondrial genome in which the recombination repeats were (are) present in an inverted orientation. The recombination repeats described for these two species are completely different from those previously found in the closely related species B. campestris, implying that such repeats are created and lost frequently in plant mitochondrial DNAs and making it less than likely that recombination occurs in a site-specific manner.     

Tripartite mitochondrial genome of spinach: physical structure, mitochondrial gene mapping, and locations of transposed chloroplast DNA sequences.

A complete physical map of the spinach mitochondrial genome has been established. The entire sequence content of 327 kilobase pairs (kb) is postulated to occur as a single circular molecule. Two directly repeated elements of approximately 6 kb, located on this "master chromosome", are proposed to participate in an intragenomic recombination event that reversibly generates two "subgenomic" circles of 93 kb and 234 kb. The positions of protein and ribosomal RNA-encoding genes, determined by heterologous filter hybridizations, are scattered throughout the genome, with duplicate 26S rRNA genes located partially or entirely within the 6 kb repeat elements. Filter hybridizations between spinach mitochondrial DNA and cloned segments of spinach chloroplast DNA reveal at least twelve dispersed regions of inter-organellar sequence homology.     

Rolling-circle replication of mitochondrial DNA in the higher plant Chenopodium album (L.).

The mitochondrial genomes of higher plants are larger and more complex than those of all other groups of organisms. We have studied the in vivo replication of chromosomal and plasmid mitochondrial DNAs prepared from a suspension culture and whole plants of the dicotyledonous higher plant Chenopodium album (L.). Electron microscopic studies revealed sigma-shaped, linear, and open circular molecules (subgenomic circles) of variable size as well as a minicircular plasmid of 1.3 kb (mp1). The distribution of single-stranded mitochondrial DNA in the sigma structures and the detection of entirely single-stranded molecules indicate a rolling-circle type of replication of plasmid mp1 and subgenomic circles. About half of the sigma-like molecules had tails exceeding the lengths of the corresponding circle, suggesting the formation of concatemers. Two replication origins (nicking sites) could be identified on mpl by electron microscopy and by a new approach based on the mapping of restriction fragments representing the identical 5' ends of the tails of sigma-like molecules. These data provide, for the first time, evidence for a rolling-circle mode of replication in the mitochondria of higher plants.     

Strand switching during rolling circle replication of plasmid-like DNA circles in the mitochondria of the higher plant Chenopodium album (L.)

The structure of sigma-like mitochondrial DNA molecules prepared from suspension cultured cells of Chenopodium album (L.) was studied by electron microscopy. These molecules were highly variable in size, ranging from about 1 to 104 kb, and had single- and double-stranded regions typical for rolling circle replicating intermediates. Partial denaturation studies confirmed that these structures constitute rolling circles. Close inspection of the circle-tail junctions of the replication fork at high magnification suggests that in circles with a double-stranded tail, both strands of the tail seem to be covalently attached to the circle in about 27% of the molecules. This observation can be explained by a phenomenon called strand switching or strand splippage during rolling circle replication, similar to a mechanism proposed for bacterial replicons or in vitro replicating constructs harboring bacteriophage T4 replication origins.     

Analysis of a 120-Kilobase Mitochondrial Chromosome in Maize

The organization of the mitochondrial genome in plants is not well understood. In maize mitochondrial DNA (mtDNA) several subgenomic circular molecules as well as an abundant fraction of linear molecules have been seen by electron microscopy. It has been hypothesized that the circular molecules are the genetic entities of the mitochondrial genome while the linear molecules correspond to randomly sheared mtDNA. A model has been proposed that explains the mechanism of generation of subgenomic circles (of a predictable size) by homologous recombination between pairs of large direct repeats found on a large (approximately 570 kb for the fertile (N) cytoplasm) master circle. So far the physical entities of the mitochondrial genome, as they exist in vivo, and the genes they carry, have not been identified. For this purpose, we used two gel systems (pulsed field gel electrophoresis and Eckhardt gels) designed to resolve large DNA. Large DNA was prepared from the Black Mexican Sweet (BMS) cultivar. We resolved several size classes of mtDNA circles and designate these as chromosomes. A 120 kb chromosome was mapped in detail. It is shown to contain the three ribosomal genes (rrn26, rrn18 and rrn5) plus two genes encoding subunits of cytochrome oxidase (Cox1 and Cox3); it appears to be colinear with the 570-kb master circle map of another fertile cytoplasm (B37N) except at the "breakpoints" required to form the 120-kb circle. The presence of the 120-kb chromosome could not have been predicted by homologous recombination through any of the known repetitive sequences nor is it a universal feature of normal maize mitochondria. It is present in mitochondria of BMS suspension cultures and seedlings, but is not detectable in seedlings of B37N. No master genome was detected in BMS.     

A family of yeast expression vectors containing the phage f1 intergenic region

The construction and characterization of a family of yeast expression vectors is described. They have the following features: plasmid replication and selection (ApR) in Escherichia coli, packaging of single-stranded (ss) DNA upon infection of E. coli with a filamentous helper phage, replication in Saccharomyces cerevisiae based on the 2 mu plasmid origin of replication (ori), selection in yeast by complementation of LEU2 (pVT-L series, size 6.3 kb) or URA3 gene (pVT-U series, size 6.9 kb) and seven unique restriction sites for cloning within an 'expression cassette' which includes the promoter and 3' sequence of the ADH1 gene. The multiple cloning site as well as the ori and intergenic region of the phage f1 have been cloned in two orientations for convenient gene cloning and ssDNA strand selection. As a result any of these eight vectors can be chosen for cloning, expressing genes in yeast, sequencing and mutagenesis without the need for recloning into specialized vectors.     

Completion of Replication Map of Saccharomyces cerevisiae Chromosome III

In Saccharomyces cerevisiae chromosomal DNA replication initiates at intervals of approximately 40 kb and depends upon the activity of autonomously replicating sequence (ARS) elements. The identification of ARS elements and analysis of their function as chromosomal replication origins requires the use of functional assays because they are not sufficiently similar to identify by DNA sequence analysis. To complete the systematic identification of ARS elements on S. cerevisiae chromosome III, overlapping clones covering 140 kb of the right arm were tested for their ability to promote extrachromosomal maintenance of plasmids. Examination of chromosomal replication intermediates of each of the seven ARS elements identified revealed that their efficiencies of use as chromosomal replication origins varied widely, with four ARS elements active in < or = 10% of cells in the population and two ARS elements active in > or = 90% of the population. Together with our previous analysis of a 200-kb region of chromosome III, these data provide the first complete analysis of ARS elements and DNA replication origins on an entire eukaryotic chromosome.     

Change in chromosome number associated with a double deletion in the Neurospora crassa mitochondrial chromosome

The mitochondrial genome of Neurospora is usually found in a single covalently closed circular 62-kbp DNA molecule. We report here that the mitochondrial genome of a phenotypic revertant of a stopper mutant (stp-ruv) is contained primarily in two separate, nonoverlapping, autonomously replicating circular chromosomes. The circles, one about 21 kbp and the other somewhat less than 36 kbp are derived from the most frequent classes of recombinant chromosomes (21 and 41 kbp) in the chromosomal population of mitochondria in the original stopper mutant. The new, more stable chromosomal configuration, is associated with the deletion of two sequences (1 kbp and 4 kbp) at the splice junctions of the two circles. The data suggest that both deletions are likely to have originated from a single recombinational event involved in generating the 36-kbp circle. Secondary, spontaneously arising derivatives of stp-ruv have been found to yield, at high copy number, short sections of the 21-kbp circle in covalently closed supercoiled circles varying from unit length to very high multimers. The amplified segments span a common segment likely to contain the replication origin of the 21-kbp chromosome.     

Identification and mapping of regions that confer plasmid functions and of sites for excisive recombination of plasmid pMMC7105

Summary Strain PP808 of Pseudomonas syringae pv. phaseolicola contains pEXC8080 (34.6 kb), the smallest of several plasmids that originated by partial excision of the cryptic plasmid, pMMC7105 (150 kb), from the host chromosome. This excision plasmid is derived entirely of sequences from pMMC7105 and contains a 24 kb region referred to as common DNA, which is present in each of the other excision plasmids. A six enzyme restriction endonuclease map was constructed of pEXC8080. The replication region was mapped by identifying small restriction fragments that conferred replication properties to pMB1 plasmids that otherwise fail to replicate in Pseudomonas. This region is located within the common DNA and is 0.8–3.8 kb in size. Sequences from pEXC8080 failed to stabilize pMB1 derivatives in Pseudomonas in the absence of antibiotic selection, but stability functions were mapped to a region of pMMC7105 that presumably remains integrated in the chromosome of strain PP808. An incompatibility region was mapped to a 7.3 kb region on pEXC8080 that is closely linked to, but not included within, the replication region. The recombination site was mapped to a 1.2 kb region of the fusion fragment that was formed upon excision of pEXC8080. RS-I, a repetitive sequence, found on pMMC7105 was present in the fusion fragment at the site of recombination. RS-I was also mapped to BamHI fragments that recombined upon excision of pEXC8080 and suggest that it provides sites for homologous recombination.     

Replication of kinetoplast DNA maxicircles

The kinetoplast DNA of Crithidia fasciculata is a massive network composed of thousands of topologically interlocked circles. Most of these circles are minicircles (2.5 kb), and about 50 are maxicircles (37 kb). Previous studies showed that minicircles replicate, after release from the network, via Cairns (theta) intermediates. Here we show that maxicircles replicate, while attached to the network, by an entirely different mechanism involving rolling circle intermediates. After the network-bound maxicircle has finished replication, the branch of the rolling circle is apparently cleaved off to form a linear free maxicircle. A restriction map of the linearized free maxicircles shows that these molecules have unique termini, one of which presumably corresponds to the replication origin.     

Three copies of a single recombination repeat occur on the 443 kb master circle of the Petunia hybrida 3704 mitochondrial genome.

At 443 kb, the map of Petunia hybrida line 3704 mitochondrial DNA is the largest yet produced from a dicot plant. Regions of similarity to known plant mitochondrial genes and to the chloroplast genome have been placed on a master circle. One long repeated sequence, apparently active in recombination, is present in three copies. Two copies of 6.6 kb occur in a direct orientation and are separated by 199 kb. A third truncated copy of 3.5 kb is inverted relative to the other two and is separated from the others by 99 and 145 kb. The presence of the recombination repeats predicts a multipartite molecular organization, consisting of four master circles and three subgenomic circles. Two other repeated regions were found not to be substrates for, or products of recombination. The absence of recombination at certain reiterated regions indicates that there is specificity of recombination at the recombination repeats.     

Organelle DNAs: The bit players in malaria parasite DNA replication

The replication mechanics of the extrachromosomal DNAs of the malaria parasite are beginning to be anravelled. At 6 kb, the mitochondrial genome is the smallest known and, unlike higher eukaryotes, its multiple copies per cell occur as polydisperse linear concatemers. Here, Don Williamson, Peter Preiser and Iain Wilson discuss recent evidence that this DNA replicates by a process akin to those of certain bacteriophages, which make use of extensive recombination coupled with rolling circles. The parasite's second extrachromosomal DNA, a 35 kb circular molecule thought to be a plastid remnant inherited from a remote photoautotroph, probably replicates in a more familiar fashion from conventional origins or D loops. Improved understanding of both organelle's replicative mechanisms could give new leads to malaria chemotherapy.     

Mitochondrial DNA recombination in Brassica campestris

The structure of the mitochondrial genome in plants is unclear, but appears to consist of mostly linear DNA with some other structures, including branched molecules and subgenomic circles. Mitochondrial DNA (mtDNA) recombination was analyzed in Brassica campestris, which has one of the smallest mitochondrial genomes (218 kb) in higher plants. Field-inversion gel electrophoresis (FIGE) separated mtDNA into discrete populations that each represents the entire genome. Electron microscopy revealed large, mostly linear molecules trapped in the wells, slower migrating populations with mostly linear DNA and a low level of circular and networked mtDNA molecules of 10–140 kbp, and a fast migrating population of 10–50 kbp linear mtDNA. Some smaller than genome size circular molecules and circles with tails were observed, and may represent recombination or rolling circle replication intermediates. Hybridization of end-labeled mtDNA suggests there may be specific ends (or recombination hotspots) for some linear molecules. Analysis of mtDNA enriched by BND-cellulose and separated by two-dimensional agarose gel electrophoresis shows the presence of complex recombination structures and the presence of significant single-stranded regions in mtDNA. These findings provide further evidence that DNA recombination contributes to the complex structure of mtDNA in plants.     

The replication checkpoint control in Bacillus subtilis: identification of a novel RTP-binding sequence essential for the replication fork arrest after induction of the stringent response

We have shown previously that induction of the stringent response in Bacillus subtilis resulted in the arrest of chromosomal replication between 100 and 200 kb either side of oriC at distinct stop sites, designated LSTer and RSTer, left and right stringent terminators respectively. This replication checkpoint was also shown to involve the RTP protein, normally active at the chromosomal terminus. In this study, we show that the replication block is absolutely dependent upon RelA, correlated with high levels of ppGpp, but that efficient arrest at STer sites also requires RTP. DNA-DNA hybridization data indicated that one or more such LSTer sites mapped to gene yxcC (-128 kb from oriC). A 7.75 kb fragment containing this gene was cloned into a theta replicating plasmid, and plasmid replication arrest, requiring both RelA and RTP, was demonstrated. This effect was polar, with plasmid arrest only detected when the fragment was orientated in the same direction with respect to replication, as in the chromosome. This LSTer2 site was further mapped to a 3.65 kb fragment overlapping the next40 probe. Remarkably, this fragment contains a 17 bp sequence (B'-1) showing 76% identity with an RTP binding site (B sequence) present at the chromosomal terminus. This B'-1 sequence, located in the gene yxcC, efficiently binds RTP in vitro, as shown by DNA gel retardation studies and DNase I footprinting. Importantly, precise deletion of this sequence abolished the replication arrest. We propose that this modified B site is an essential constituent of the LSTer2 site. The differences between arrest at the normal chromosomal terminus and arrest at LSTer site are discussed.     

The mitochondrial genome of the soybean cyst nematode, Heterodera glycines

We sequenced the entire coding region of the mitochondrial genome of Heterodera glycines. The sequence obtained comprised 14.9 kb, with PCR evidence indicating that the entire genome comprised a single, circular molecule of approximately 21-22 kb. The genome is the most T-rich nematode mitochondrial genome reported to date, with T representing over half of all nucleotides on the coding strand. The genome also contains the highest number of poly(T) tracts so far reported (to our knowledge), with 60 poly(T) tracts ≥ 12 Ts. All genes are transcribed from the same mitochondrial strand. The organization of the mitochondrial genome of H. glycines shows a number of similarities compared with Radopholus similis, but fewer similarities when compared with Meloidogyne javanica. Very few gene boundaries are shared with Globodera pallida or Globodera rostochiensis. Partial mitochondrial genome sequences were also obtained for Heterodera cardiolata (5.3 kb) and Punctodera chalcoensis (6.8 kb), and these had identical organizations compared with H. glycines. We found PCR evidence of a minicircular mitochondrial genome in P. chalcoensis, but at low levels and lacking a noncoding region. Such circularised genome fragments may be present at low levels in a range of nematodes, with multipartite mitochondrial genomes representing a shift to a condition in which these subgenomic circles predominate.     

Homologous recombination generates T-loop-sized deletions at human telomeres

The t-loop structure of mammalian telomeres is thought to repress nonhomologous end joining (NHEJ) at natural chromosome ends. Telomere NHEJ occurs upon loss of TRF2, a telomeric protein implicated in t-loop formation. Here we describe a mutant allele of TRF2, TRF2DeltaB, that suppressed NHEJ but induced catastrophic deletions of telomeric DNA. The deletion events were stochastic and occurred rapidly, generating dramatically shortened telomeres that were accompanied by a DNA damage response and induction of senescence. TRF2DeltaB-induced deletions depended on XRCC3, a protein implicated in Holliday junction resolution, and created t-loop-sized telomeric circles. These telomeric circles were also detected in unperturbed cells and suggested that t-loop deletion by homologous recombination (HR) might contribute to telomere attrition. Human ALT cells had abundant telomeric circles, pointing to frequent t-loop HR events that could promote rolling circle replication of telomeres in the absence of telomerase. These findings show that t-loop deletion by HR influences the integrity and dynamics of mammalian telomeres.     

Reconstitution of a minimal mtDNA replisome in vitro

We here reconstitute a minimal mammalian mitochondrial DNA (mtDNA) replisome in vitro. The mtDNA polymerase (POLgamma) cannot use double-stranded DNA (dsDNA) as template for DNA synthesis. Similarly, the TWINKLE DNA helicase is unable to unwind longer stretches of dsDNA. In combination, POLgamma and TWINKLE form a processive replication machinery, which can use dsDNA as template to synthesize single-stranded DNA (ssDNA) molecules of about 2 kb. The addition of the mitochondrial ssDNA-binding protein stimulates the reaction further, generating DNA products of about 16 kb, the size of the mammalian mtDNA molecule. The observed DNA synthesis rate is 180 base pairs (bp)/min, corresponding closely to the previously calculated value of 270 bp/min for in vivo DNA replication. Our findings provide the first biochemical evidence that TWINKLE is the helicase at the mitochondrial DNA replication fork. Furthermore, mutations in TWINKLE and POLgamma cause autosomal dominant progressive external ophthalmoplegia (adPEO), a disorder associated with deletions in mitochondrial DNA. The functional interactions between TWINKLE and POLgamma thus explain why mutations in these two proteins cause an identical syndrome.     

Insertion of a foreign nucleotide sequence into mitochondrial DNA causes senescence in Neurospora intermedia

The kalilo variants of Neurospora contain a cytoplasmic genetic factor that causes senescence. This factor is a 9.0 kb transposable element (kalDNA) that lacks nucleotide sequence homology with mtDNA and is inserted into the mitochondrial chromosome, often at sites located within the open reading frame in the intron-DNA of the mitochondrial 25S-rRNA gene. Genomes containing the "foreign" DNA insert accumulate during growth, and death occurs as the cells become deficient in functional large and small subunits of mitochondrial ribosomes. The kalDNA transposon may be an "activator" element that causes breaks in mtDNA. Nonsenescing [+] strains of Neurospora do not contain kalDNA.     

Structurally stable Bacillus subtilis cloning vectors

Cloning of long DNA segments (greater than 5 kb) in Bacillus subtilis is often unsuccessful when naturally occurring small (less than 10 kb) plasmids are used as vectors. In this work we show that vectors derived from the large (26.5 kb) plasmids pAM beta 1 and pTB19 allow efficient cloning and stable maintenance of long DNA segments (up to 33 kb). The two large plasmids differ from the small ones in several ways. First, replication of the large plasmids does not lead to accumulation of detectable amounts of ss DNA, whereas the rolling-circle replication typical for small plasmids does. In addition, the replication regions of the two large plasmids share no sequence homology with the corresponding regions of the known small plasmids, which are highly conserved. Taken together, these observations suggest that the mode of replication of the large plasmids is different from that of small plasmids. Second, short repeated sequences recombine much less frequently when carried on large than on small plasmids. This indicates that large plasmids are structurally much more stable than small ones. We suggest that the high structural stability of large plasmids is a consequence of their mode of replication and that plasmids which do not replicate as rolling circles should be used whenever it is necessary to clone and maintain long DNA segments in any organism.