Rearrangements in the Physarum polycephalum mitochondrial genome associated with a transition from linear mF-mtDNA recombinants to circular molecules

Although mitochondrial DNA (mtDNA) is transmitted to progeny from one parent only in Physarum polycephalum, the mtDNAs of progeny of mF⁺ plasmodia vary in structure. To clarify the mechanisms associated with the mitochondrial plasmid mF that generate mtDNA polymorphisms, 91 progeny of four strains (KM88 × JE8, KM88 × TU111, KM88 × NG111, Je90) were investigated using RFLP analysis, PCR, and pulse-field gel electrophoresis (PFGE). Nine mtDNA rearrangement types were found, with rearrangements occurring exclusively in the mF regions. PFGE revealed that, in the groups containing rearranged mtDNA, the linear mF–mtDNA recombinants had recircularized. Sequencing the rearranged region of one of the progeny suggested that the mF plasmid and the mtDNA recombine primarily at the ID sequences, linearizing the circular mtDNA. Recombination between the terminal region of the mF plasmid and a region about 1 kbp upstream of the mitochondrial/plasmid ID sequence results in a rearranged circular mtDNA, with variations caused by differences in the secondary recombination region.     

Constitutive homologous recombination between mitochondrial DNA and a linear mitochondrial plasmid in Physarum polycephalum

Summary In one particular myxamoebal strain (NG7; mF⁺) of Physarum polycephalum, a linear mitochondrial plasmid (mF plasmid) which promotes mitochondrial fusion has been identified. A mating between mF^- strains, that do not carry the mF plasmid, resulted in uniparental inheritance of the mtDNA. In matings between mF⁺ and mF^- strains a recombination occurred between the mtDNA and the mF plasmid, and recombinant mtDNA was generated with the end of the mF plasmid as its ends. The DNA sequences of the recombination site in the mtDNA and the mF plasmid, and of the recombinant mtDNA, revealed that the mF plasmid had a 473-bp sequence that was identical to, but slightly shorter than, a 477-bp sequence of the mtDNA. This so-called identical sequence was found at the junction between unique sequences of the mF plasmid and the mtDNA in the recombinant mtDNA. Thus, the recombination between the mtDNA and the mF plasmid was due to reciprocal crossing-over at the identical sequence.     

The mating type-specific homeodomain genes <Emphasis Type="Italic">SXI1α</Emphasis> and <Emphasis Type="Italic">SXI2a</Emphasis> coordinately control uniparental mitochondrial inheritance in <Emphasis Type="Italic">Cryptococcus neoformans</Emphasis>

In the great majority of sexual eukaryotes, mitochondrial genomes are inherited almost exclusively from a single parent. While many hypotheses have been proposed to explain this phenomenon, very little is known about the genetic elements controlling uniparental mitochondria inheritance. In the bipolar, isogamous basidiomycete yeast Cryptococcus neoformans, progeny from crosses between strains of mating type a (MATa) and mating type α (MATα) typically inherit mitochondrial DNA (mtDNA) from the MATa parent. We recently demonstrated that a mating type α (MATα)-specific gene SXI1α, controls mitochondrial inheritance in C. neoformans. Here, we show that another homeodomain gene SXI2a in the alternative mating type MATa is also required for uniparental mtDNA inheritance in this fungus. Disruption of SXI2a resulted in biparental mtDNA inheritance in the zygote population with significant numbers of progeny inheriting mtDNA from the MATa parent, the MATα parent, and both the MATa and the MATα parents. In addition, progeny from same-sex mating between MATα strains showed a biparental mitochondrial inheritance pattern. Our results suggest that SXI1α and SXI2a coordinately control uniparental mitochondrial inheritance in C. neoformans.     

Inheritance of mitochondrial DNA in sexual crosses and protoplast cell fusions in Lentinula edodes

By using mitochondrial DNA (mtDNA) restriction fragment length polymorphisms (RFLPs) as genetic markers, the modes of mitochondrial inheritance in sexual crosses and protoplast cell fusions of the higher basidiomycete Lentinula edodes were examined. All newly established dikaryons from reciprocal crosses between compatible monokaryons carrying different mtDNA RFLP phenotypes retained mtDNA genotypes from one of the monokaryons, suggesting that mitochondrial inheritance is principally uniparental. In contrast, it was shown that recombinant mtDNA genomes arose in some dikaryons obtained after protoplast cell fusion. Based on these results, a possible mechanism for mitochondrial inheritance in L. edodes is discussed.     

Interaction between mitochondrial DNA and mitochondrial plasmids in Claviceps purpurea: analysis of plasmid-homologous sequences upstream of the IrRNA-gene

Homology of two linear, mitochondrial (mt) Claviceps purpurea plasmids, pC1K1 and pClT5, to the upstream region of the large ribosomal RNA gene in the mtDNA of three strains (W3, T5 and K) has been investigated in detail to explore the widespread phenomenon of homology between mt plasmids and mtDNA in C. purpurea. Sequence comparison indicates that recombination between free plasmids and mtDNA is the cause of the observed homology. The process is similar to the integration of the structurally related adenoviruses into the mammalian genome. As in other fungi, palindromic sequences seem to be involved in this mitochondrial recombination process.     

Characterization and prevalence of a circular mitochondrial plasmid in senescence-prone isolates of Neurospora intermedia

Genetic and molecular analyses of the phenomenon of senescence—i.e., irreversible loss of growth and reproductive potential upon subculturing—in Neurospora intermedia strain M1991-60A, collected from Maddur in southern India, showed the presence of plasmid pMaddur1, which is homologous to the senescence-inducing circular mitochondrial plasmid, pVarkud. Maternal inheritance of senescence in M1991-60A correlated to the formation of variant pMaddur1, its subsequent insertion into mitochondrial (mt)DNA and the accumulation of defective mtDNA with the pMaddur1insert. PCR-based analyses for similar plasmids in 147 natural isolates of Neurospora from Maddur showed that nearly 40% of the strains had pMaddur1 or pMaddur2 that shared 97–98% sequence homology with pVarkud and pMauriceville. Nearly 50% of the strains that harbored either pMaddur1 or pMaddur2, also contained a circular Varkud satellite plasmid (pVS). Size polymorphism maps to the cluster of PstI sites in the non-coding region. Whereas senescence of nearly 40% of N. intermedia strains may be due to pMaddur, the presence in seven strains of pVS but not pMaddur and the absence of either of these two plasmids in other senescence-prone isolates suggests yet undiscovered mechanisms of senescence in the Maddur strains.     

Early zygote-specific nuclease in mitochondria of the true slime mold Physarum polycephalum

The active, selective digestion of mtDNA from one parent is a possible molecular mechanism for the uniparental inheritance of mtDNA. In Physarum polycephalum, mtDNA is packed by DNA-binding protein Glom, which packs mtDNA into rod-shaped mt-nucleoids. After the mating, mtDNA from one parent is selectively digested, and the Glom began to disperse. Dispersed Glom was retained for at least 6 h after mtDNA digestion, but disappeared completely by about 12 h after mixing two strains. We identified two novel nucleases using DNA zymography with native-PAGE and SDS-PAGE. One is a Ca²⁺-dependent, high-molecular-weight nuclease complex (about 670 kDa), and the other is a Mn²⁺-dependent, high-molecular-weight nuclease complex (440–670 kDa); the activity of the latter was detected as a Mn²⁺-dependent, 13-kDa DNase band on SDS-PAGE. All mitochondria isolated from myxamoebae had mt-nucleoids, whereas half of the mitochondria isolated from the zygotes at 12 h after mixing had lost the mt-nucleoids. The activity of the Mn²⁺-dependent nuclease in the isolated mitochondria was detected at least 8 h after mixing of two strains. The timing and localization of the Mn²⁺-dependent DNase activity matched the selective digestion of mtDNA.     

Gender-associated mitochondrial DNA heteroplasmy in the venerid clam Tapes philippinarum (Mollusca Bivalvia)

This paper provides evidence of a gender-associated mitochondrial DNA (mtDNA) heteroplasmy in the clam Tapes philippinarum. The pattern of tissue distribution of the two observed mtDNA types (referred to as M and F) parallels that of the doubly uniparental inheritance system of Mytilus. The mitochondrial genetic features of the clam are related to a different rate of evolution of the M- and F-type mtDNAs. Since clams are known to be phylogenetically very distant from mussels, the present findings support the hypothesis that the mechanism producing gender-associated heteroplasmy should be considered an ancestral character in the Bivalvia. Received: 2 August 2000 / Accepted: 3 December 2000     

Moving pictures and pulsed-field gel electrophoresis show only linear mitochondrial DNA molecules from yeasts with linear-mapping and circular-mapping mitochondrial genomes

  The mobility of mitochondrial DNA (mtDNA) in pulsed-field gel electrophoresis (PFGE) and its appearance in moving pictures from fluorescence microscopy were used to investigate the mitochondrial genome structure for five Pichia and Williopsis strains of yeast. An apocytochrome b-gene hybridization probe identified only linear mtDNA molecules for each strain when total cellular DNA was fractionated by PFGE. Most of the mass of DNA isolated from mitochondria for one linear-mapping and one circular-mapping mitochondrial genome was found in linear molecules much larger than the genome size of 50 kb; some molecules were as long as 1500 kb, but only a trace amount of apparently circular mtDNA was found for the strain with the circular-mapping genome. Probes for both the apocytochrome-b and mitochondrial small rRNA subunit genes hybridized strongly to mtDNA of approximately 50–100 kb, but weakly to the larger DNA from mitochondria of these two strains. For the four linear-mapping strains, PFGE revealed two or three distinct bands of linear mtDNA, larger than the genome size, within a smear of approximately 50–100 kb, but a smear without bands was found for the circular-mapping strain. Received: 28 June 1995 / 15 January 1996     

The fate of mitochondrial DNAs of mt + and mt − origin in gametes and zygotes of Chlamydomonas

Summary In order to study the mechanism responsible for the uniparental transmission of the mitochondrial genome in crosses between Chlamydomonas reinhardtii and C. smithii, we have analyzed the fate of mitochondrial DNA during gametogenesis, zygospore differentiation and sporulation by hybridization experiments. Both mt ⁺ and mt ^– gametes contain the same amount of mitochondrial DNA and the two parental genomes persist for several days in the zygotes. The DNA of mt ⁺ origin is slowly eliminated during the period of zygote maturation. Light is required for total elimination of mt ⁺ mitochondrial DNA in the zygospores. Using appropriate restriction enzymes, we have been unable to detect methylation of the mitochondrial DNA during gametogenesis or zygospore formation. The possibility that the mt ⁺ mitochondria themselves are specifically eliminated in the course of zygote maturation is discussed.     

Cryptococcus neoformans mitochondrial genomes from serotype A and D strains do not influence virulence

Cryptococcus neoformans is an encapsulated pathogenic yeast producing meningoencephalitis. Two primary strains in genetic studies, serotype A H99 and serotype D JEC21, possess dramatic differences in virulence. Since it has been shown that mitochondrial gene expression is prominent at the site of the infection and there are significant differences between mitochondrial gene structure and regulation between the serotype A and D strains, this study used AD hybrids to move serotype A and D mitochondria under different genomic influences. When the serotype D MATa strain is involved in the mating crosses, there is uniparental transmission of mitochondrial DNA, but with the serotype A MATa strain, mitochondrial DNA can be inherited from either parent and recombination in the mitochondrial genome may also occur. In virulence studies between serotype A and D strains, it was found that the primary genetic control of the virulence composite for growth in the central nervous system is encoded in the nuclear DNA and not through mitochondrial DNA.     

Rapid disappearance of one parental mitochondrial genotype after isogamous mating in the myxomycete Physarum polycephalum

Summary Five haploid amoebal strains of the myxomycete Physarum polycephalum, each with a distinct mitochondrial genotype, were crossed in all pairwise combinations. The mitochondrial genotype in the diploid plasmodia resulting from these isogamous matings were found to be transmitted uniparentally. This uniparental inheritance could be arranged in a dominant hierarchical order. Time-course analysis of the presence of mitochondrial genotypes in the zygotes and young developing plasmodial genotypes is virtually completed during the first two nuclear cycles in the zygote/differentiating plasmodium. To our knowledge this is the first report indicating an active mechanism involving the degradation of mitochondrial genomes in sexual crosses.     

Maternal inheritance of mitochondrial DNA in sexual crosses of Pythium sylvaticumm

Summary Fifty single oospore progeny from crosses between opposite mating types of Pythium sylvaticum that contained polymorphisms in mitochondrial DNA (mtDNA) for HindIII restriction sites were analyzed for patterns of mitochondrial inheritance. All progeny retained the morphological form of the oogonial parental type; the antheridial form or recombinant forms of parental mtDNA were not detected. With the techniques used, other forms of mtDNA would have been detected it they had comprised 8% or more of the mitochondrial population.     

Complex terminal structure of a linear mitochondrial plasmid from Physarum polycephalum: three terminal inverted repeats and an ORF encoding DNA polymerase

The mitochondria of Physarum polycephalum have a linear plasmid (mF) which promotes mitochondrial fusion. To determine the terminal structure of the mF plasmid, restriction fragments derived from its ends were cloned and sequenced. The sequences showed that the mF plasmid has three kinds of terminal inverted repeats (TIRs). The most characteristic feature is a 144-bp repeating unit which exists between a 205-bp TIR at the extreme ends of the plasmid and another 591-bp TIR. All of the clones showed at least one of these 144-bp repeating units. The GC content of the 205-bp TIR (49%) was higher than those of the other TIRs and of another sequenced region (23%). This TIR can form three thermodynamically-stable hairpin structures based on complex internal palindromic components. Moreover, in the right terminal region of the mF plasmid, there is an open reading frame (ORF) which covers the entire 591-bp TIR and most of one of the 144-bp repeating units. This ORF encodes a 547-amino-acid polypeptide, ORF-547, and shows extensive homology with the polymerization domain of the putative DNA polymerases of linear mitochondrial plasmids from other sources.     

Transfer of paternal mitochondrial DNA during fertilization of honeybee (Apis mellifera L.) eggs

Strict maternal inheritance of mitochondrial (mt) DNA is believed to be the rule in most eukaryotic organisms because of exclusion of paternal mitochondria from the egg cytoplasm during fertilization. In honeybees, polyspermic fertilization occurs, and many spermatozoa, including their mitochondria-rich flagellum, can completely penetrate the egg, thus allowing for a possibly high paternal leakage. In order to identify paternal mtDNA in honeybee eggs, restriction fragment length polymorphisms (RFLP) of different subspecies were used. Total DNA extracts of different developmental stages of an Apis mellifera carnica x Apis mellifera capensis hybrid brood were tested with a radioactively-labelled diagnostic mtDNA probe. Densitograms of autoradiographs indicated that the male contribution represents up to 27% of the total mitochondrial DNA in the fertilized eggs 12 h after oviposition. In subsequent developmental stages the portion of paternal mtDNA slowly decreased until hatching of the larvae when only traces were found. Although rapid disintegration of paternal mtDNA does not occur, the initially high paternal mitochondrial contribution is not maintained in the adult animal.     

A circular mitochondrial plasmid incites hypovirulence in some strains of Cryphonectria parasitica

In the chestnut-blight fungus Cryphonectria parasitica, a plasmid, pCRY1, occurs in the mitochondria of several strains isolated at various locations in the northeastern United States and Canada. The monomer of this plasmid is a 4.2-kb circular double-stranded DNA that has no detectable sequence homology with the 160–kb mitochondrial DNA of Ep155, a standard virulent laboratory strain of C. parasitica. The circular nature and oligomeric characteristics of the plasmid were deduced from the heterogeneous size of plasmid DNA molecules as detected by one- and two-dimensional gel-electrophoresis, the nature and alignment of restriction fragments, and the lack of detectable termini in the nucleotide sequence. The cytoplasmic location of the plasmid was deduced from its co-purification with mitochondria, uniparental (maternal) transmission in sexual crosses, dissociation from the nuclei of the donor strain during its horizontal transfer between vegetatively compatible strains through hyphal anastomoses, and mitochondrial codon usage (UGA=Try). The pCRY1 plasmid contains a long open reading frame that is transcribed and potentially encodes a unique 1214 amino-acid, B-family DNA polymerase similar to those encoded by the LaBelle and Fiji circular mitochondrial plasmids of Neurospora. In this subgroup of proteins, the DTD motif characteristic of B-family DNA polymerases is replaced by TTD. Amino-acid motifs related to those that are characteristic of the 3′→5′ exonuclease domains of B-family DNA polymerases have been located in the amino-terminal portion of the proteins. A comparison of isogenic plasmid-free and plasmid-containing cultures indicates that pCRY1 is an infectious agent that effects a reduction in the pathogenicity of some, but not all, strains of C. parasitica. Received: 12 August / 9 December 1999     

Elimination of mitochondrial mutations by sexual reproduction: two Podospora anserina mitochondrial mutants yield only wild-type progeny when mated

In order to understand the transmission of mitochondrial mutations in sexual crosses of Podospora, we attempted to create compatible strains with defined mitochondrial mutations. A previously characterized mutant, Mn19, with a bipartite mitochondrial genome, served as the fertilizing parent in a cross with a mitochondrial deletion mutant, αΔ5. Characterization of the deletion mutant is reported here. All six of the monokaryotic progeny isolated had neither parental defect but instead appeared to have inherited wild-type mitochondrial DNA. One of the progeny had a mitochondrial plasmid derived from intramolecular recombination between an 11-bp repeated mitochondrial sequence. Subsequent analysis using the polymerase chain reaction (PCR) identified rare undeleted wild-type mtDNA sequences in the maternal parent. The uniform inheritance of wild-type mitochondrial DNA suggests either an aggressive repair mechanism or else selective amplification and transmission of rare wild-type mtDNA molecules. Received: 12 December 1995 / 6 May 1996     

A new senescence-inducing mitochondrial linear plasmid in field-isolated Neurospora crassa strains from India

Summary Several field-collected strains of Neurospora crassa from the vicinity or Aarey, Bombay, India, are prone to precocious senescence and death. Analysis of one strain, Aarely-1e, demonstrated that the genetic determinants for the predisposition to senescence are maternally inherited. The senescence-prone strains contain a 7-kb, linear, mitochondrial DNA plasmid, maranhar, which is not present in long-lived isolates from the same geographical location. The maranhar plasmid has inverted terminal repeats with protein covalently bound at the 5 termini. Molecular hybridization experiments have demonstrated no substantial DNA sequence homology between the plasmid and the normal mitochondrial (mtDNA) and nuclear genomes of long-lived strains of N. crassa. Integrated maranhar sequences were detected in the mtDNAs of two cultures derived from Aarey-1e, and mtDNAs with the insertion sequences accumulated during subculturing. Nucleotide sequence analysis of cloned fragments of the two insertion sequences demonstrates that that they are flanked by long inverted repeats of mtDNA. The senescence syndrome of the maranhar strains, and the mode of integration of the plasmid, are reminiscent of those seen in the kalilo strains of N. intermedia. Nonetheless, there is no detectable nucleotide sequence homology between the maranhar and kalilo plasmids.     

Specific elimination of mitochondrial DNA from Chlamydomonas by intercalating dyes

Summary Minute colony mutations in C. reinhardtii are induced with 100% efficiency by intercalating dyes such as acriflavin and ethidium bromide. These mutants form small colonies on petri plates because they undergo only 8–9 mitotic divisions before growth ceases. In liquid media without the dye the mutants show gross alterations in mitochondrial structure and function. Here we demonstrate that induction of minute mutations is accompanied by the specific loss of mitochondrial DNA. We also provide evidence that the transmission of the minute colony phenotype in crosses can be explained in terms of uniparental transmission of mitochondrial DNA by the mt ^– parent.