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.     

Maternal transmission of mitochondrial DNA in interspecific hybrids of Populus

Summary Restriction fragment analysis was conducted to investigate the mode of inheritance of mitochondrial (mt) DNA in F₁ progeny of two P. deltoides x P. deltoides, three P. deltoides x P. nigra, and two P. deltoides x P. maximowiczii controlled crosses, and in Populus x canadensis by using 16 restriction endonucleases and two heterologous probes of cloned mtDNA fragments of maize. Five restriction fragment length polymorphisms (RFLPs) of mtDNA differentiated P. deltoides from P. nigra, whereas three RFLPs of mtDNA separated P. deltoides from P. maximowiczii. In all cases, F₁ progeny of P. deltoides x P. nigra, and P. deltoides x P. maximowiczii, crosses had mtDNA restriction fragments of only their maternal P. deltoides parents. P. x canadensis had mtDNA restriction fragments of only P. deltoides. F₁ progeny of intraspecific P. deltoides crosses also had the same mtDNA fragments as their maternal parent. The results clearly demonstrate uniparental-maternal inheritance of the mitochondrial genome in F₁ interspecific hybrids of P. deltoides with P. nigra and P. maximowiczii.     

Mitochondrial genetics of Coprinus: Recombination of mitochondrial genomes

Summary The formation of the sexual mycelium or dikaryon in the basidiomycete Coprinus cinereus involves exchange and migration of nuclei without accompanying exchange of mitochondria. The dikaryotic growth which appears around the periphery of mated monokaryons has exclusively the mitochondrial genome of the recipient cells. Recombination of mitochondrial genomes is not, however, precluded during dikaryosis. Using monokaryons with different mitochondrial gene mutations, [acu-10] causing cytochrome aa ₃ deficiency and[cap-1.1] conferring resistance to chloramphenicol, it was shown that recombinant mitochondria arise in the zone of contact of mated monokaryons.     

High-frequency inter-parental recombination between mitochondrial genomes of rice cybrids

Analyzing more than 100 independent rice cybrids, we found evidence for inter-molecular recombination between parental mitochondrial genomes occurring at high frequency soon after protoplast fusion. The structure of the region around the atp6 gene showed extensive polymorphism among Indica (MTC-5A), Japonica (Nipponbare), and wild abortive (IR58024A) mitochondrial genomes. Recombination between the mitochondrial genomes of IR58024A and MTC-5A around the atp6 gene was detected by Southern-blot analysis of cybrid plants. Such recombinant mitochondrial molecules were also cloned from IR58024A/Nipponbare cybrid callus. PCR analysis around the atp6 gene demonstrated that inter-parental recombination occurs in practically all cybrid calli within 2 weeks after protoplast fusion. At this point, parental and recombinant mitochondrial genomes coexisted within the callus. Over the course of further cultivation, however, mitochondrial genome diversity decreased as parental and/or recombinant genomes segregated out.     

An ameiotic mutant of Coprinus cinereus halted prior to pre-meiotic S-phase

Summary Five Coprinus cinereus monokaryons were isolated which bore a dominant mutation designated Mar. Dikaryons formed by mating Mar-bearing monokaryons with normal monokaryons produced aborted fruiting bodies in which the basidia never underwent karyogamy. The Mar mutation probably prevented pre-meiotic DNA replication; extracts of Mar-bearing dikaryons harvested at a stage equivalent to pre-meiotiv S-phase caused little net DNA synthesis in DNA polymerase assays. There was no marked incorporation of 32p into DNA (and low incorporation of 32p into RNA) of cap tissue from Mar-bearing fruiting bodies at a stage equivalent to pre-meiotic S-phase. The aborted fruiting bodies were similar to those resulting on normal cultures following treatment prior to S-phase with cycloheximide, or continuous light at 35 °C. In contrast to normal C. cinereus monokaryons, no Mar-bearing monokaryon formed fruiting bodies when subjected to nutritional stress.     

Linear mitochondrial genome organization in vivo in the genus Pythium

Pulsed-field gel electrophoresis (PFGE) of isolates of Pythium oligandrum with linear mitochondrial genomes revealed a distinct band in ethidium bromide-stained gels similar in size to values estimated by restriction mapping of mitochondrial DNA (mtDNA). Southern analysis confirmed that these bands were mtDNA and indicated that linear genomes were present in unit-length size as well as multimers. Isolates of this species with circular mtDNA restriction maps also had low levels of linear mono- and multimers. visualized by Southern analysis of PFGE gels. Examination of 17 additional species revealed similar results; three species had distinct linear mtDNA bands in ethidium bromide-stained gels while the remainder had linear mono- and multi-mers in lower amounts detected only by Southern analysis. Sequence analysis of an isolate of P. oligandrum with a primarily circular mitochondrial genomic map and a low amount of linear molecules revealed that the small unique region of the circular map (which corresponded to the terminal region of linear genomes) was flanked by palindromic intrastrand complementary sequences separated by a unique 194-bp sequence. Sequences with similarity to ATPase9 coding regions from other organisms were located adjacent to this region. Sequences with similarity to mitochondrial origins of replication and autonomously replicating sequences were also located in this region: their potential involvement in the generation of linear molecules is discussed.     

Mitochondrial DNA rearrangements associated with mF plasmid integration and plasmodial longevity in Physarum polycephalum

Plasmodial cultures of Physarum polycephalum have defined life spans and undergo a reproducible decline (senescence) before losing the ability to be subcultured. Studies of the mtDNA of a long-lived Physarum strain, which does not undergo senescence, revealed a 7.9-kb insertion in its mtDNA. This insertion is derived from a mitochondrial plasmid which enhances mitochondrial fusion and mtDNA recombination. Four different recombination events are required to convert the parental mtDNA to the form found in the long-lived strain. An additional recombination event, which deletes a 2.4-kb region of the insert from the long-lived strain, has been identified in the mtDNA of a normally senescing strain. These observations imply a mitochondrial involvement in the process of plasmodial senescence and implicate a region of the DNA derived from the mitochondrial plasmid as being necessary for plasmodial longevity. Received: 11 August / 18 November 1997     

Evolution of linear mitochondrial DNA in three known lineages of Polytomella

Although DNA sequences of linear mitochondrial genomes are available for a wide variety of species, sequence and conformational data from the extreme ends of these molecules (i.e., the telomeres) are limited. Data on the telomeres is important because it can provide insights into how linear genomes overcome the end-replication problem. This study explores the evolution of linear mitochondrial DNAs (mtDNAs) in the green-algal genus Polytomella (Chlorophyceae, Chlorophyta), the members of which are non-photosynthetic. Earlier works analyzed the linear and linear-fragmented mitochondrial genomes of Polytomella capuana and Polytomella parva. Here we present the mtDNA sequence for Polytomella strain SAG 63-10 [also known as Polytomella piriformis (Pringsheim 1963)], which is the only known representative of a mostly unexplored Polytomella lineage. We show that the P. piriformis mtDNA is made up of two linear fragments of 13 and 3 kb. The telomeric sequences of the large and small fragments are terminally inverted, and appear to end in vitro with either closed (hairpin-loop) or open (nicked-loop) structures as also shown here for P. parva and shown earlier for P. capuana. The structure of the P. piriformis mtDNA is more similar to that of P. parva, which is also fragmented, than to that of P. capuana, which is contained in a single chromosome. Phylogenetic analyses reveal high substitution rates in the mtDNA of all three Polytomella species relative to other chlamydomonadalean algae. These elevated rates could be the result of a greater number of vegetative cell divisions and/or small population sizes in Polytomella species as compared with other chlamydomonadalean algae.     

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     

The mitochondrial plasmid of the true slime mold <Emphasis Type="Italic">Physarum polycephalum</Emphasis> bypasses uniparental inheritance by promoting mitochondrial fusion

Mitochondrial DNA (mtDNA) is inherited maternally in most eukaryotes. Linear mitochondrial plasmids in higher plants and fungi are also transmitted from the maternal parent to the progeny. However, mF, which is a mitochondrial linear plasmid of Physarum polycephalum, evades uniparental mitochondrial inheritance. We examined 36 myxamoebal strains of Physarum and isolated three novel mF⁺ strains (JE8, TU111, NG111) that harbored free mF plasmids. These strains were mated with the mF^– strain KM88. Of the three mF^– × mF⁺ crosses, only KM88 × JE8 displayed complete uniparental inheritance. However, in KM88 × TU111 and KM88 × NG111, the mtDNA of KM88 and mF of TU111 and NG111 were inherited by the plasmodia and showed recombination. For example, although the mtDNA of TU111 was eliminated, the mF of TU111 persisted and became inserted into the mtDNA of KM88, such that recombinant mtDNA represented 80% of the total mtDNA. The parental mitochondria fused to yield giant mitochondria with two or more mitochondrial nucleoids. The mF appears to exchange mitochondria from the recipient (paternal) to the donor (maternal) by promoting mitochondrial fusion.The first two authors have equally contributed to this work     

Mitochondrial inheritance in haploid × non-haploid crosses in Cryptococcus neoformans

In the basidiomycetous yeast Cryptococcus neoformans, fusants and meiotic progeny from haploid–haploid (HH) crosses between strains of mating type a (MAT a) and mating type alpha (MATα) typically inherit mitochondrial DNA (mtDNA) from the MAT a parent. In this study, we investigated the mtDNA inheritance pattern in haploid × non-haploid crosses. A total of 420 meiotic progeny and 173 fusants were obtained from five crosses and analyzed for two polymorphic mitochondrial markers. The percentage of meiotic progeny and fusants inheriting mtDNA from MATα or MATα/α parents ranged from 8 to 50%. The leakage was significantly greater than those observed in HH crosses, indicating that mtDNA inheritance is not uniparental in haploid × non-haploid crosses in C. neoformans. In addition, mtDNA leakage in the fusants, but not the meiotic progeny, of the MATα/α × MAT a cross was significantly higher than that in the MAT a/a × MATα cross, suggesting that the diploid parents with different mating types contribute differently in determining fusant mtDNA genotype in these crosses. Flow cytometry analysis revealed that meiotic progeny population of each cross was of mixed ploidy while the ploidy level of the selected fusants ranged from diploid to triploid.     

Mitochondrial DNAs of the fungus Armillaria ostoyae: restriction map and length variation

A restriction-enzyme-site map is presented for the 147-kb mtDNA of North American Armillaria ostoyae. The locations of five structural genes, atp6, atp8, coxI, coxIII, and cob, along with the location and orientation of the large and small ribosomal RNA genes, were determined through Southern hybridizations with cloned genes from other fungal mtDNAs. Based on this map, the variation in mtDNA suggested geographic structure at two different levels. On a large geographic scale, 17 mtDNA types from North America were distinct, with respect to both size and restriction maps, from three mtDNA types from Europe. At the local scale, identical mtDNA types were evident among several different genetic individuals located no more than 1 km apart at a site in Michigan. No mtDNA type occurred more than once among genetic individuals from different regions of North America, although the occurrence of similar mtDNAs in isolates from distant regions suggested that this may occur at a low frequency with large sample sizes. Among the North American mtDNA types, analysis of discrete length variants was inconsistent with the hypothesis that the mtDNA of A. ostoyae evolves as a clonal lineage in which each length mutation represents a unique event. The two remaining hypotheses, that similar mutational events have occurred independently and that genetic exchange and recombination occurs among mtDNAs in natural populations of this species, remain to be tested.     

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.     

Analysis of Heteroplasmic Variants in the Cardiac Mitochondrial Genome of Individuals with Down Syndrome

Individuals with Down syndrome (DS, trisomy 21) exhibit a pro‐oxidative cellular environment as well as mitochondrial dysfunction. Increased oxidative stress may damage the mitochondrial DNA (mtDNA). The coexistence of mtDNA variants in a cell or tissue (i.e., heteroplasmy) may contribute to mitochondrial dysfunction. Given the evidence on mitochondrial dysfunction and the relatively high incidence of multiorganic disorders associated with DS, we hypothesized that cardiac tissue from subjects with DS may exhibit higher frequencies of mtDNA variants in comparison to cardiac tissue from donors without DS. This study documents the analysis of mtDNA variants in heart tissue samples from donors with (n = 12) and without DS (n = 33) using massively parallel sequencing. Contrary to the original hypothesis, the study's findings suggest that the cardiac mitochondrial genomes from individuals with and without DS exhibit many similarities in terms of (1) total number of mtDNA variants per sample, (2) the frequency of mtDNA variants, (3) the type of mtDNA variants, and (4) the patterns of distribution of mtDNA variants. In both groups of samples, the mtDNA control region showed significantly more heteroplasmic variants in comparison to the number of variants in protein‐ and RNA‐coding genes (P < 1.00×10^?4, ANOVA).     

Reaching for the ring: the study of mitochondrial genome structure

The linear molecules that comprise most of the mitochondrial DNA (mtDNA) isolated from most organisms result from the artifactual degradation of circular genomes that exist within mitochondria. This view has been adopted by most investigators and is based on DNA fragment mapping data as well as analogy to the genomesized circular mtDNA molecules obtained in high yield from animals. The alternative view that linear molecules actually represent the major form of DNA within mitochondria is supported by two observations: (1) over a 1000-fold range of genome size among fungi and plants we find the same size distribution of linear mtDNA molecules, and (2) linear mtDNA molecules much larger than genome size can be found for some fungi and plants. The circles that represent only a small fraction of the mtDNA obtained from most eukaryotes could be optional sequence forms unimportant for mitochondrial function; they may also participate in mtDNA replication. The circles might result from incidental recombination events between directly repeated sequences within or between tandemly arrayed genome units on linear mtDNA molecules.     

Physical and genetic map of the mitochondrial genome of Cryphonectria parasitica Ep155

 In the chestnut-blight fungus, Cryphonectria parasitica, a cytoplasmically transmissible (infectious) form of hypovirulence is associated with mitochondrial DNA (mtDNA) mutations that cause respiratory deficiencies. To facilitate the characterization of such mutations, a restriction map including the probable location of 13 genes was constructed for a relatively well-characterized virulent strain of the fungus, Ep155. The physical map is based on the order of all fragments generated by cleavage of the mtDNA by the PstI restriction endonuclease and includes some of the cleavage sites for HindIII, EcoRI, and XbaI. It was constructed from hybridization patterns of cloned mtDNA fragments with Southern blots of mtDNA digested with the four restriction enzymes. On this map, the probable locations of genes commonly found in the mitochondrial genomes of ascomycetes were determined by low-stringency hybridization of cloned Neurospora crassa mitochondrial gene probes to Southern blots of C. parasitica mtDNA. The data indicate that the mtDNA of strain Ep155 is a circular molecule of approximately 157 kbp and ranks among the largest mitochondrial chromosomes observed so far in fungi. The mtDNAs of 11 different C. parasitica isolates range in size from 135 to 157 kbp and in relatedness from 68 to 100 percent, as estimated from restriction-fragment polymorphisms. In addition to the typical mtDNA, the mitochondria of some isolates of the fungus contain double-stranded DNA plasmids consisting of nucleotide sequences not represented in the mtDNA of Ep155. Received: 19 September 1995/4 January 1996     

Mitochondrial characterisation of two Spanish populations from the Vera and Bejar valleys (Central Spain)

This survey reports the mitochondrial data of two Spanish populations living in the Vera and Bejar valleys, on the opposite slopes of the Sierra de Gredos (Central Spain), which crosses Spain east to west. The aim of the study was to characterise the mitochondrial genetic pool of the Vera and Bejar populations to investigate a putative mitogenetic differentiation between them, evidence that would support the role of the Sierra de Gredos as a genetic barrier in their micro-evolutionary histories. Blood samples of 137 people (66 from Vera and 71 from Bejar) were collected and mtDNA hypervariable regions I and II (HVR-I and HVR-II) were dissected along with several mtDNA-coding region SNPs. The main European mitochondrial lineages have been found both in Vera and in Bejar, together with the typical African haplogroups L (in Vera) and U6 (in Bejar). F_ST value and the 95% credible regions calculated for haplogroup frequencies do not reveal genetic differentiation among the populations. Vera and Bejar contain an expected mitochondrial variability within them, but they do not seem to be genetically different from each other, leading us to conclude that the Sierra de Gredos is not a significant genetic barrier in their maternal genetic history.     

Evolutionary changes in the structures of the cox2 and atp6 loci in the mitochondrial genome of soybean involving recombination across small interspersed sequences

Mitochondrial DNA (mtDNA) fragments that contained cox2 or atp6 loci were cloned from three accessions of wild soybean (Glycine soja) in order to understand the evolutionary changes of mitochondrial genomes in the genus Glycine subgenus Soja. Cox2 was cloned as a single configuration, while atp6 was cloned as either one or two configurations from each accession. Structural variations were detected in the 5′ upstream region of cox2 and in both the 5′ upstream and 3′ downstream regions of atp6. These variations appeared to be the results of recombination events. A comparison of the mtDNA fragments previously cloned from a cultivated soybean (G. max) and a wild soybean revealed various sites of recombination, as well as various combinations of the 5′ and 3′ regions, at the cox2 and atp6 loci. Some of the cloned fragments were found to contain a set of repeated sequences, namely 299-bp and 23-bp repeats in the 5′ region of cox2 or atp6, which were interspersed in the mitochondrial genome in the subgenus Soja. Recombination events involving the 299-bp or 23-bp repeated sequences were shown to account for the generation of structural variations in the 5′ regions of these loci. Received: 21 March / 4 August 1998     

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.