Intramolecular recombination as a source of mitochondrial chromosome heteromorphism in Neurospora

Approximately 20% of the genome is missing and an equivalent amount is under-represented in the mitochondrial chromosome population of a stopper (stp) mutant of Neurospora crassa during the stopped phase of its cyclical growth pattern. At this stage, a 21 kb (7.2 mu) circular molecule, one-third the length of the normal chromosome, is the predominant form. A complementary 43 kb (14.6 mu) circle appears upon resumption of growth. The circles arise by reciprocal recombination at or near directly repeated tRNAmet sequences and the frequency of the two depends upon their rates of replication from replication origins unique to each of them. The 7.2 and 14.6 mu circles are the most frequent of the heteromorphic derivatives found within wild-type mitochondrial chromosome populations.     

Recombination and Replication of Plasmid-like Derivatives of a Short Section of the Mitochondrial Chromosome of Neurospora Crassa

The 21-kbp mitochondrial chromosome of the stp-ruv strain of Neurospora crassa undergoes regional amplification yielding plasmid-like supercoiled circles varying in size from subunit length to very high multimers. A comparison of the base sequence of the five plasmids studied, with the region of the chromosome from which they were derived, indicated that the amplified chromosomal segments were determined by a recombination-excision process near or within two structurally distinctive regions. One of these, consisting of nearly uninterrupted strings of Cs and Gs straddling tandem PstI site direct repeats, could form an extended hairpin loop with only a few mismatches. It was found at or near the 5' exchange point of all of the plasmids. An extended 35-bp sequence containing 17-bp direct repeats was the primary 3' site of exchange. Base sequence changes were found in the vicinity of exchange points. Most notable of these was a G insertion and T to C transition within a section of the 5' region likely to form a hairpin loop, suggesting the involvement of a mismatch repair-like mechanism in the recombination process. The sequence, TATATAGACATATA, was identified as a likely candidate for the site of replication initiation. A nearly identical sequence was found common to all of the corresponding plasmids of Podospora anserina and was reported near the presumed replication origin of the Drosophila yakuba mitochondrial chromosome. A search of GenBank revealed a remarkable association of the consensus sequence, TATATAGAXATATA, with the plus strand of organelle DNA.     

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 Bacteroides mobilizable insertion element, NBU1, integrates into the 3' end of a Leu-tRNA gene and has an integrase that is a member of the lambda integrase family.

NBU1 is a 10.3-kbp integrated Bacteroides element that can be induced to excise from the chromosome and can be mobilized to a recipient by trans-acting functions provided by certain Bacteroides conjugative transposons. The NBU1 transfer intermediate is a covalently closed circle, which is presumed to be the form that integrates into the recipient genome. We report here that a 2.4-kbp segment of NBU1 was all that was required for site-specific integration into the chromosome of Bacteroides thetaiotaomicron 5482. This 2.4-kbp region included the joined ends of the NBU1 circular form (attN1) and a single open reading frame, intN1, which encoded the integrase. Previously, we had found that NBU1 integrates preferentially into a single site in B. thetaiotaomicron 5482. We have now shown that the NBU1 target site is located at the 3' end of a Leu-tRNA gene. The NBU1 integrase gene, intN1, was sequenced. The predicted protein had little overall amino acid sequence similarity to any proteins in the databases but had limited carboxy-terminal similarity to the integrases of lambdoid phages and to the integrases of the gram-positive conjugative transposons Tn916 and Tn1545. We also report that the intN1 gene is expressed constitutively.     

Association of transformation of xenosomes from nonkiller to killer with extrachromosomal DNA.

Extrachromosomal DNA in the form of covalently closed circular DNA molecules was isolated from killer and nonkiller xenosomes, bacterial endosymbionts of the marine protozoan Parauronema acutum. Restriction endonuclease digests of these molecules derived from 12 isolates revealed consistent, readily identifiable, differences in the pattern of fragments of the killer as compared with those present in the nonkiller. Transformation of the nonkiller to killer by infection is also accompanied by a change from the nonkiller to killer pattern. Based on analysis of fragments resulting from restriction endonuclease digests, two circular duplex DNA molecules, each 63 kilobase pairs (kbp) in length, were identified in the 263-20 nonkiller stock and mapped. The maps revealed that each possesses a single BamHI site and multiple BglI, BstIIE, PstI, and SalI sites. A distinguishing feature of these maps is that the two molecules share a region about 17 kbp in length in which multiple restriction sites are in register with each other. Allowing for a 0.5-kbp insertion or deletion and the introduction or removal of only a few restriction sites, an additional stretch extending approximately 31 kbp beyond this sequence could also be considered to be homologous. The structure of the killer plasmid appears to be more complex, and we have been unable, as yet, to construct physical maps for this DNA. We postulate that the killer plasmid DNA is composed of three, perhaps four, circular 63-kbp duplexes, at least one which contains a single BamHI site and another which contains two BamHI sites. The remaining molecules may represent copies of either or both of the other two, modified to contain additional restriction sites. Transformation from the nonkiller to the killer is visualized as the insertion of restriction sites at various points along parent nonkiller plasmid DNA molecules. The mechanism by which these sites are introduced is unknown.     

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.     

Isolation of mycoplasma virus L2 insertion variants and miniviruses.

We isolated two spontaneous variants of mycoplasma virus L2. Both variants, designated L2ins1 and L2ins2, contained a 3.1-kilobase-pair (kbp) insertion in the 11.8-kbp wild-type L2 genome. The insert DNA was shown to be derived from two noncontiguous regions of the L2 genome, and L2ins1 and L2ins2 differed only in the location of the 3.1-kbp insertion. We also isolated L2 miniviruses from serial passages of L2, L2ins1, and L2ins2 viruses. Miniviruses contained circular DNA molecules of 3.1 kbp or multimers of 3.1 kbp. Minivirus 3.1-kbp DNAs had the same sequences as the 3.1-kbp insert DNAs found in L2ins1 and L2ins2 viruses. Miniviruses were not infectious and interfered with the growth of L2, L2ins1, and L2ins2 viruses; hence, L2 miniviruses appeared to be defective interfering particles.     

Molecular Characterization of the Mitochondrial DNA of a New Stopper Mutant Er-3 of Neurospora Crassa

An ethidium bromide-induced stopper mutant of Neurospora crassa is characterized at the molecular level. The mutant has two populations of mitochondrial DNA: a defective predominant mutant molecule and a basal level of the wild-type molecule. The aberrant DNA resulted after a 25-kbp deletion from the wild-type mitochondrial chromosome, which included major genes such as cytb, co1 and oli2. The deletion endpoints are located in the second intron of the ND5 gene, and in a sequence 250 nucleotides upstream of the co2 gene. The recombination has taken place between two nine nucleotide repeats CCCCGCCCC, one of which is close to a PstI palindrome at its 5' end. Thus the mutant ER-3 differs from all the other stopper mutants described previously in the extent and location of the deletions in the mtDNA.     

Two two-gene macronuclear chromosomes of the hypotrichous ciliates Oxytricha fallax and O. trifallax generated by alternative processing of the 81 locus

We describe the first known macronuclear chromosomes that carry more than one gene in hypotrichous ciliated protozoa. These 4.9- and 2.8-kbp chromosomes each consist almost exclusively of two protein-coding genes, which are conserved and transcribed. The two chromosomes share a common region that consists of a gene that is a member of the family of mitochondrial solute carrier genes (CR-MSC; [Williams and Herrick (1991): Nucleic Acids Res 19:4717–4724]. Each chromosome also carries another gene appended to its common region: The 4.9-kbp chromosome also carries a gene that encodes a protein that is rich in glutamine and charged amino acids and bears regions of heptad repeats characteristic of coiled-coils. Its function is unknown. The second gene of the 2.8 kbp chromosome is a mitochondrial solute carrier gene (LA-MSC); thus, the 2.8-kbp chromosome consists of two mitochondrial solute carrier paralogs. Phylogenetic analysis indicates that the two genes were duplicated before ciliates diverged from the main eukaryotic lineage and were subsequently juxtaposed. The CR- and LA-MSC genes are each interrupted by three introns. The introns are not in homologous positions, suggesting that they may have originated from multiple group II intron transpositions. These chromosomes and their genes are encoded in the Oxytricha germline by the 81 locus. This locus is alternatively processed to generate a nested set of three macronuclear chromosomes, the 4.9- and 2.8-kbp chromosomes and a third (1.6 kbp) which consists almost exclusively of the shared common gene, CR-MSC. Such alternative processing is common in macronuclear development of O. fallax [Cartinhour and Herrick (1984): Mol Cell Biol 4:931–938]. Possible functions for alternative processing are considered; e.g., it may serve to physically link genes to allow co-regulation or co-replication by a common cis-acting sequence. Dev. Genet. 20:348–357, 1997. © 1997 Wiley-Liss, Inc.     

A family of repeated sequences dispersed through the genome of Lilium henryi

A family of dispersed repeats longer than 7 kilobase pairs (kbp) has been identified in the very large genome of Lilium henryi, and two subregions cloned. Initially a rapidly reannealing probe (C₀t<1 M s) was prepared by hydroxyapatite chromatography. Half the copies of all sequences repeated 15000 times per genome are expected to reanneal by this C₀t value. The probe hydridized to abundant fragments of 2, 5, and 7 kbp released from genomic DNA by Bam HI digestion. Twelve 2-kb fragments and ten 5-kb sequences were cloned into pBR322. Restriction mapping of the two sets of clones showed individual members to be quite similar. Length variation was no more than 200 base pairs (bp) between repeats, and consensus sites were present on 80%–90% of occasions. In situ hybridization using representative 2-kbp and 5-kbp clones showed each sequence to be dispersed throughout all chromosomal regions. Studies on the genomic organization suggested that the 2-kbp and 5-kbp sequences are usually adjacent, and that occasional absence of the internal Bam HI site results in the release of the 7-kbP fragment. There are at least 13000 copies of the full repeat per L. henryi genome, thus accounting for approximately 0.3% of the total of 32 million kbp.     

Identification of the Mitochondrial Genome in the Chrysophyte Alga Ochromonas danica

ABSTRACT. Analysis of total DNA isolated from the Chrysophyte alga Ochromonas danica revealed, in addition to nuclear DNA, two genomes present as numerous copies per cell. The larger genome (?120 kilobase pairs or kbp) is the plastid DNA, which is identified by its hybridization to plasmids containing sequences for the photosynthesis genes rbcL, psbA, and psbC. The smaller genome (40 kbp) is the mitochondrial genome as identified by its hybridization with plasmids containing gene sequences of plant cytochrome oxidase subunits I and II. Both the 120- and 40-kbp genomes contain genes for the small and large subunits of rDNA. The mitochondrial genome is linear with terminal inverted repeats of about 1.6 kbp. Two other morphologically similar species were examined, Ochromonas minuta and Poteriochromonas malhamensis. All three species have linear mitochondrial DNA of 40 kbp. Comparisons of endonuclease restriction-fragment patterns of the mitochondrial and chloroplast DNAs as well as those of their nuclear rDNA repeats failed to reveal any fragment shared by any two of the species. Likewise, no common fragment size was detected by hybridization with plasmids containing heterologous DNA or with total mitochondrial DNA of O. danica; these observations support the taxonomic assignment of these three organisms to different species. The Ochromonas mitochondrial genomes are the first identified in the chlorophyll a/c group of algae. Combining these results with electron microscopic observations of putative mitochondrial genomes reported for other chromophytes and published molecular studies of other algal groups suggests that all classes of eukaryote algae may have mitochondrial genomes < 100 kbp in size, more like other protistans than land plants.     

The Neurospora crassa genome: cosmid libraries sorted by chromosome

A Neurospora crassa cosmid library of 12,000 clones (at least nine genome equivalents) has been created using an improved cosmid vector pLorist6Xh, which contains a bacteriophage lambda origin of replication for low-copy-number replication in bacteria and the hygromycin phosphotransferase marker for direct selection in fungi. The electrophoretic karyotype of the seven chromosomes comprising the 42.9-Mb N. crassa genome was resolved using two translocation strains. Using gel-purified chromosomal DNAs as probes against the new cosmid library and the commonly used medium-copy-number pMOcosX N. crassa cosmid library in two independent screenings, the cosmids were assigned to chromosomes. Assignments of cosmids to linkage groups on the basis of the genetic map vs. the electrophoretic karyotype are 93 +/- 3% concordant. The size of each chromosome-specific subcollection of cosmids was found to be linearly proportional to the size of the particular chromosome. Sequencing of an entire cosmid containing the qa gene cluster indicated a gene density of 1 gene per 4 kbp; by extrapolation, 11,000 genes would be expected to be present in the N. crassa genome. By hybridizing 79 nonoverlapping cosmids with an average insert size of 34 kbp against cDNA arrays, the density of previously characterized expressed sequence tags (ESTs) was found to be slightly <1 per cosmid (i.e., 1 per 40 kbp), and most cosmids, on average, contained an identified N. crassa gene sequence as a starting point for gene identification.     

动物线粒体基因组变异研究进展

动物mtDNA大多是共价闭合的环状双链分子,一般由2个非编码区和37个编码基因组成,不同动物线粒体基因组大小变异明显.孑遗疟虫(Plasmodium reichenowi)的线粒体基因组最小,仅为5966bp;领鞭毛虫(Monosiga brevicollis)的最大,达76568bp.动物线粒体基因组大小变异的原因主要有:控制区串联重复元件的变异;基因重复;基因重叠与基因间隔区大小的差异;基因缺失和增加.     

Telomere exchange between linear replicons of Borrelia burgdorferi

Spirochetes in the genus Borrelia carry a linear chromosome and numerous linear plasmids that have covalently closed hairpin telomeres. The overall organization of the large chromosome of Borrelia burgdorferi appears to have been quite stable over recent evolutionary time; however, a large fraction of natural isolates carry differing lengths of DNA that extend the right end of the chromosome between about 7 and 20 kbp relative to the shortest chromosomes. We present evidence here that a rather recent nonhomologous recombination event in the B. burgdorferi strain Sh-2-82 lineage has replaced its right chromosomal telomere with a large portion of the linear plasmid lp21, which is present in the strain B31 lineage. At least two successive rounds of addition of linear plasmid genetic material to the chromosomal right end appear to have occurred at the Sh-2-82 right telomere, suggesting that this is an evolutionary mechanism by which plasmid genetic material can become part of the chromosome. The unusual nonhomologous nature of this rearrangement suggests that, barring horizontal transfer, it can be used as a unique genetic marker for this lineage of B. burgdorferi chromosomes.     

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).     

Isolation and characterization of full-length chromosomes from non-culturable plant-pathogenic Mycoplasma-like organisms

We describe the isolation and characterization of full-length chromosomes from non-culturable plant-pathogenic, mycoplasma-like organisms (MLOs). MLO chromosomes are circular and their sizes (640 to 1185kbp) are heterogeneous. Divergence in the range of chromosome sizes is apparent between MLOs in the two major MLO disease groups, and chromosome size polymorphism occurs among some related agents. MLO chromosome sizes overlap those of culturable mycoplasmas; consequently, small genome size alone cannot explain MLO non-culturability. Hybridization with cloned MLO-specific chromosomal and 16S rRNA probes detected two separate chromosomes in some MLO ‘type’ strains. Large DNA molecules that appear to be MLO megaplasmids were also demonstrated. The ability to characterize full-length chromosomes from virtually any non-culturable prokaryote should greatly facilitate the molecular and genetic analysis of these difficult bacteria.     

Glycosylation of human LDL and its metabolism in human skin fibroblasts

Extrachromosomal DNA of heterogeneous size has been isolated from bursal lymphocytes and splenocytes of five week old chickens, and from splenocytes of mice. This DNA contains covalently closed circles, open circles, and open circles with tails. Open circular molecules with and without tails are more frequent than covalently closed species, and the total number of small circular DNA molecules per cell is in the range of 100–200 copies.     

Identification of the site of interruption in relaxed circles producing during bacteriophage lambda DNA circle replication.

The DNA that accumulates in the lambda infection restricted to the early (circular) stage of replication consists of approximately two-thirds covalently closed circles and one-third relaxed circles bearing a single interruption in either strand of the duplex. The latter molecules are presumed to be a unique class in that the interruption is not repairable by DNA polymerase and ligase. Preferential radioisotopic labeling of the region immediately adjacent to the interruption, followed by hybridization to sheared fragments of the lambda chromosome with varying guanine plus cytosine content, suggested that the nick resides at the position of the mature molecular ends of the lambda chromosome. Digestion of the labeled molecules with restriction enzymes and reconstruction experiments in which Hershey circles were generated by annealing of interrupted strands isolated from the relaxed circles support this interpretation. The results indicate that the relaxed circles consist of a population containing one interruption in either of the two strands of the duplex jointly representing the two "nicks" contained in Hershey circles (in which the cohesive ends are annealed). These molecules could result from the inability of the maturation function to make the required staggered endonucleolytic cuts when the DNA substrate is a monomeric circle rather than a multimeric linear molecule. Alternatively, this interruption could be the result of an endonucleolytic cutting event critical to DNA replication.