Distribution and evolutionary significance of mitochondrial plasmids in Neurospora spp

Fungal mitochondrial genomes and genetic polymorphisms

Mitochondria are the powerhouses of eukaryotic cells, responsible for ATP generation and playing a role in a diversity of cellular and organismal functions. Different from the majority of other intracellular membrane structures, mitochondria contain their own genetic materials that are capable of independent replication and inheritance. In this mini-review, we provide brief summaries of fungal mitochondrial genome structure, size, gene content, inheritance, and genetic variation. We pay special attention to the relative genetic polymorphisms of the mitochondrial vs nuclear genomes at the population level within individual fungal species. Among the 20 species/groups of species reviewed here, there is a range of variation among genes and species in the relative nuclear and mitochondrial genetic polymorphisms. Interestingly, most (15/20) showed a greater genetic diversity for nuclear genes and genomes than for mitochondrial genes and genomes, with the remaining five showing similar or slower nuclear genome genetic variations. This fungal pattern is different from the dominant pattern in animals, but more similar to that in plants. At present, the mechanisms for the variations among fungal species and the overall low level of mitochondrial sequence polymorphisms are not known. The increasing availability of population genomic data should help us reveal the potential genetic and ecological factors responsible for the observed variations.

Natural Variation of the Circadian Clock in Neurospora

Most living organisms on earth experience daily and expected changes from the rotation of the earth. For an organism, the ability to predict and prepare for incoming stresses or resources is a very important skill for survival. This cellular process of measuring daily time of the day is collectively called the circadian clock. Because of its fundamental role in survival in nature, there is a great interest in studying the natural variation of the circadian clock. However, characterizing the genetic and molecular mechanisms underlying natural variation of circadian clocks remains a challenging task. In this chapter, we will summarize the progress in studying natural variation of the circadian clock in the successful eukaryotic model Neurospora, which led to discovering many design principles of the molecular mechanisms of the eukaryotic circadian clock. Despite the success of the system in revealing the molecular mechanisms of the circadian clock, Neurospora has not been utilized to extensively study natural variation. We will review the challenges that hindered the natural variation studies in Neurospora, and how they were overcome. We will also review the advantages of Neurospora for natural variation studies. Since Neurospora is the model fungal species for circadian study, it represents over 5 million species of fungi on earth. These fungi play important roles in ecosystems on earth, and as such Neurospora could serve as an important model for understanding the ecological role of natural variation in fungal circadian clocks.

RANDOM-FRAGMENT HYBRIDIZATION ANALYSIS OF EVOLUTION IN THE GENUS NEUROSPORA: THE STATUS OF FOUR-SPORED STRAINS

A random-fragment hybridization method employing nuclear DNA has been developed to explore phylogenetic relationships in the genus Neurospora. Four cloned fragments and repetitive rDNA sequences were examined for restriction-fragment polymorphisms among 14 strains representing four species. The findings demonstrate that variation among randomly selected nuclear fragments can be employed to group related taxa with a higher degree of resolution than has been obtained with other DNA hybridization methods, isozyme electrophoresis, or restriction analysis of repetitive DNA. Based on our analysis of cloned fragments, we conclude that four-spored, secondarily-homothallic strains collected worldwide represent a monophyletic group. Trees constructed on the basis of restriction-fragment cataloging and coarse-structure restriction-site maps are for the most part consistent with the present mating-based species concept. We are encouraged that this method will provide an additional important experimental tool for evolutionary studies.

Phylogenetic and biological species diversity within the Neurospora tetrasperma complex

The objective of this study was to explore the evolutionary history of the morphologically recognized filamentous ascomycete Neurospora tetrasperma, and to reveal the genetic and reproductive relationships among its individuals and populations. We applied both phylogenetic and biological species recognition to a collection of strains representing the geographic and genetic diversity of N. tetrasperma. First, we were able to confirm a monophyletic origin of N. tetrasperma. Furthermore, we found nine phylogenetic species within the morphospecies. When using the traditional broad biological species recognition all investigated strains of N. tetrasperma constituted a single biological species. In contrast, when using a quantitative measurement of the reproductive success, incorporating characters such as viability and fertility of offspring, we found a high congruence between the phylogenetic and biological species recognition. Taken together, phylogenetically and biologically defined groups of individuals exist in N. tetrasperma, and these should be taken into account in future studies of its life history traits.

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.

Perspective: transposable elements, parasitic DNA, and genome evolution

The nature of the role played by mobile elements in host genome evolution is reassessed considering numerous recent developments in many areas of biology. It is argued that easy popular appellations such as "selfish DNA" and "junk DNA" may be either inaccurate or misleading and that a more enlightened view of the transposable element-host relationship encompasses a continuum from extreme parasitism to mutualism. Transposable elements are potent, broad spectrum, endogenous mutators that are subject to the influence of chance as well as selection at several levels of biological organization. Of particular interest are transposable element traits that early evolve neutrally at the host level but at a later stage of evolution are co-opted for new host functions.

Divergence of a linear and a circular plasmid in disjunct natural isolates of the fungus Neurospora

It is known from DNA hybridization and other studies that Neurospora plasmids are widely distributed across species of this genus. However few comparisons have been performed of the structure of apparently identical plasmids in widely differing geographical and biological locations. We compare pairs of circular and linear mitochondrial plasmids from distant geographical locations. The circular plasmids (LaBelle and Harbin-1) were from different ecotypes of N. intermedia and the linear plasmids (maranhar and Harbin-3) were from different species (N. crassa and N. intermedia). The structures are highly similar at the sequence level showing that they are closely related. Most of the differences are outside the presumptive genes (coding for polymerases). Furthermore, most of the proposed functional motifs have been retained. Sequence divergence is compatible with a distribution model by vertical descent from a common ancestor, but horizontal transmission cannot be ruled out.

Natural plasmids of filamentous fungi

Among eukaryotes, plasmids have been found in fungi and plants but not in animals. Most plasmids are mitochondrial. In filamentous fungi, plasmids are commonly encountered in isolates from natural populations. Individual populations may show a predominance of one type, but some plasmids have a global distribution, often crossing species boundaries. Surveys have shown that strains can contain more than one type of plasmid and that different types appear to be distributed independently. In crosses, plasmids are generally inherited maternally. Horizontal transmission is by cell contact. Circular plasmids are common only in Neurospora spp., but linear plasmids have been found in many fungi. Circular plasmids have one open reading frame (ORF) coding for a DNA polymerase or a reverse transcriptase. Linear plasmids generally have two ORFs, coding for presumptive DNA and RNA polymerases with amino acid motifs showing homology to viral polymerases. Plasmids often attain a high copy number, in excess of that of mitochondrial DNA. Linear plasmids have a protein attached to their 5' end, and this is presumed to act as a replication primer. Most plasmids are neutral passengers, but several linear plasmids integrate into mitochondrial DNA, causing death of the host culture. Inferred amino acid sequences of linear plasmid ORFs have been used to plot phylogenetic trees, which show a fair concordance with conventional trees. The circular Neurospora plasmids have replication systems that seem to be evolutionary intermediates between the RNA and the DNA worlds.

Recombination between heterologous linear and circular mitochondrial plasmids in the fungus Neurospora

A strain of Neurospora intermedia from China contains five prominent extragenomic mitochondrial plasmids: three linear elements called zhisi plasmids, and two circular plasmids, Harbin-1 and -2. In one subculture, levels of four plasmids (all three zhisis and Harbin-1) fell to undetectable values and two novel linear plasmids appeared, Harbin-L and -L2, as well as a new small circular plasmid, Harbin-0.9. Cross-hybridization of restriction fragments and DNA sequencing showed that the Harbin-L plasmid was composed of parts of the circular Harbin-1 plasmid and of one of the linear zhisi plasmids. A model is presented in which the Harbin-1 and zhisi plasmids are present within the same mitochondrion, and crossovers at two separate 7 bp sites of sequence identity effectively insert part of the circular Harbin-1 DNA into a zhisi linear plasmid, simultaneously deleting part of the zhisi element. The small plasmid Harbin-0.9 is a fragment of the Har-1 plasmid, and seems to be another product of the recombination process that created Har-L. Recombination of this type could have contributed to the wide array of mitochondrial plasmids found in natural populations of Neurospora.

Sexuality of mitochondria: fusion, recombination, and plasmids

Mitochondrial fusion, recombination, and mobile genetic elements, which are essential for mitochondrial sexuality, are well established in various organisms. The recombination of mitochondrial DNA (mtDNA) depends upon fusion between parental mitochondria, and between their mtDNA-containing areas (mt-nuclei), to allow pairing between the parental mtDNAs. Such mitochondrial fusion followed by recombination may be called "mitochondrial sex." We have identified a novel mitochondrial plasmid named mF. This plasmid is apparently responsible for promoting mitochondrial fusion and crosses over with mtDNA in successive sexual crosses with mF- strains. Only in mF+ strains carrying the mF plasmid did small spherical mitochondria fuse which subsequently underwent fusion between the mt-nuclei that contained the mtDNA derived from individual mitochondria. Several successive mitochondrial divisions followed, accompanied by mt-nuclear divisions. The resulting mitochondria contained recombinant mtDNA with the mF plasmid. Such features remind us also of the bacterial conjugative plasmids such as F plasmid. Therefore, in the final part of this chapter, we discuss the origin of sex and its relationship to the sexuality of mitochondria.

A kalilo-like linear plasmid in Louisiana field isolates of the pseudohomothallic fungus Neurospora tetrasperma

Two Louisiana strains of Neurospora tetrasperma contain a linear plasmid (LA-kalDNA) with a restriction map identical to the Hawaiian Neurospora intermedia senescence plasmid, kalDNA, but with termini 100 nucleotide pairs shorter. One of these strains also bore a circular plasmid similar to the Hawaiian circular plasmid Hanalei-2. One species probably acquired both plasmids from the other by horizontal transfer, at a time sufficiently distant for sequence divergence to take place. Many LA-kalDNA-bearing derivative strains senesced, but this plasmid does not guarantee senescence. Furthermore, LA-kalDNA does not insert into mtDNA. One senescent strain showed no LA-kalDNA. The plasmids are effectively transmitted via the pseudohomothallic sexual cycle. Single mating-type derivatives transmit plasmids maternally.

Distribution of seven homology groups of mitochondrial plasmids in Neurospora: evidence for widespread mobility between species in nature

A survey of mitochondrial DNAs from over 225 Neurospora and related fungal isolates from around the world uncovered three new homology groups of mitochondrial plasmids, two divergent subgroups of the Fiji plasmid family, and extended previous data about plasmid distribution patterns. Newly-discovered circular plasmids, Java and MB1, and the linear Moorea plasmids, were found in relatively-few isolates. A large proportion of isolates (51%) were found to have these or previously-discovered plasmids in the Varkud, kalilo, LaBelle, or Fiji families. Plasmids in most families were found in isolates worldwide and distributed nearly randomly with respect to species. As many as three types of plasmids were found in single isolates, and plasmids typically were found alone or in pairs in a random, independent pattern. The regional clustering of some plasmids was independent of species, providing a strong argument that horizontal transfer of plasmids occurs frequently in nature. Some plasmid families were much more diverse than others. The Fiji plasmids are a superfamily composed of distinct subgroups defined by degrees of cross-hybridization. Between some subgroups there were large regions of non-homology.

Plasmid suppressors active in the sexual cycle of Neurospora intermedia

We have discovered that, in certain crosses of natural isolates of Neurospora intermedia, linear and circular mitochondrial plasmids of the maternal parent are not transmitted to the progeny. This contrasts with the maternal transmission of organellar genetic elements generally observed in crosses between laboratory strains and between other natural isolates. Formally, failure of plasmid transmission is a type of plasmid suppression. The present cases represent the first report of plasmid suppressors in natural populations of fungi. Strains used as female parents can transmit or not transmit plasmids depending on the strain used as male parent. Males that act to suppress in one cross fail to suppress in others. Therefore, the suppression of plasmids depends on a strain-specific interaction and is not determined exclusively by the males. Since suppression is a specific interaction we inferred that it must be genetically based and tested this hypothesis by seeking segregation of suppressed and nonsuppressed phenotypes in octads. Segregation of the original full suppression of all plasmids was indeed observed in each of the three sets of testcrosses examined. The interaction type of suppression must be initiated in ascogenous tissue during the sexual cycle. It is a nonautonomous type of suppression, affecting all descendent cells. In any one case of suppression, either one, several, or all plasmids can be lost. Both linear and circular plasmids can be eliminated by the same suppressor genotype. In addition, several strains were found to contain suppressors that act after ascospore delineation. This autonomous type of suppression has been observed previously in laboratory strains, but not in natural isolates. All the cases of plasmid suppression identified in this study involved a range of apparently neutral circular and linear plasmids. Using one senescent Kalilo strain of N. intermedia, we did not detect any case of suppression of the senescence-determining linear plasmid kalDNA.

Two Neurospora mitochondrial plasmids encode DNA polymerases containing motifs characteristic of family B DNA polymerases but lack the sequence Asp-Thr-Asp

We have determined the DNA sequence of the mitochondrial plasmid from Neurospora intermedia strain Fiji N6-6. The plasmid contains a 1278-codon open reading frame that is 49% identical to the open reading frame of the mitochondrial plasmid from the LaBelle strain of N. intermedia, which is known to encode a DNA-dependent DNA polymerase. The results of polymerase assays and photolabeling studies, the high degree of identity with the LaBelle plasmid polymerase, and the observation that the Fiji polymerase activity in a reaction utilizing endogenous template is not affected by removal of RNA suggest that the Fiji plasmid also encodes a DNA-dependent DNA polymerase. Comparison of regions of amino acids that are highly conserved in the two plasmid polymerases to family B polymerases reveals good correlates for the three major polymerase motifs and suggests that previously identified motifs characteristic of reverse transcriptase found in the LaBelle sequence are not significant. The polymerases encoded by the Fiji and LaBelle plasmids are unusual in that the amino acid sequence Asp-Thr-Asp, which forms the core of the third motif in family B polymerases, is not present in either Fiji or LaBelle. A version of the motif containing Thr-Thr-Asp exists in both sequences.

Plasmid diversity in senescent and nonsenescent strains of Neurospora

A sample of 171 natural isolates of Neurospora crassa and Neurospora intermedia was tested for senescence. Of these, 28 strains senesced within the duration of the experiment. These senescent strains, together with a selection of nonsenescent strains, were examined for the presence of mitochondrial plasmids. This was done by digesting mitochondrial DNA preparations with proteinase K, and running these samples on agarose gels. Most of the strains examined, both senescent and nonsenescent, contained plasmids, many of them new. Some new plasmids were linear, as inferred from their resistance to 5' exonuclease and sensitivity to 3' exonuclease. New circular plasmids were also found. Some strains carry several plasmids, and mixtures of circular and linear elements were common. A cross-homology study was performed on a sample of plasmid-bearing strains, and several cases of apparent relatedness were found, some between strains from distant geographical locations. Linear plasmids homologous to the maranhar linear senescence plasmid were quite common. A new member of the LaBelle circular plasmid homology group was found. In the sample tested for homology, no strains contained elements related to the kalilo linear senescence plasmid. The relationship of the new plasmids to senescence is not known. In addition to plasmid monomers, several different types of derivatives were found. The kalilo linear plasmid was found to occur in linear and circular forms of low mobility, presumed to be giant concatamers, and, in some strains, variant sibling structures and ladders of short derivatives were found. Circular plasmids also gave rise to extensive ladders on electrophoresis, probably representing different relaxation states and head-to-tail concatameric series. Some such forms migrated more slowly than mitochondrial DNA. One unique type of plasmid modification observed was a pair of linear elements that had apparently arisen de novo which showed homology to a circular plasmid.

Evidence that a 1.6 kilobase region of Neurospora mtDNA was derived by insertion of part of the LaBelle mitochondrial plasmid

The LaBelle mitochondrial plasmid hybridizes to a small region of the mtDNA of different Neurospora species. Here, we show that the region of homology encompasses 1385 bp of plasmid sequence and 1649 bp of mtDNA sequence. Several findings--that the region of homology is not found in the mtDNAs of other organisms, that it includes the C-terminus of the ORF encoding the plasmid DNA polymerase, and that the ORF sequence in the mtDNA is interrupted by insertions--suggest that the region was part of the plasmid that integrated into mtDNA prior to the divergence of Neurospora species. Since the LaBelle plasmid has been found in only one Neurospora strain, we infer that the plasmid was lost subsequently from most strains. The LaBelle plasmid is transcribed by the host Neurospora mitochondrial RNA polymerase and the major promoter is located upstream of the long ORF, within the region of homology to mtDNA. A promoter used for the transcription of the mitochondrial small rRNA is found at a corresponding position in Neurospora mtDNA and may have been acquired via integration of the plasmid sequence. Our results provide evidence that an autonomous infectious element may contribute to sequences that functionally constitute an organism's mtDNA.

Linear, non-mitochondrial plasmids of Alternaria alternata

Three plasmids, with sizes of 7.0 kbp, 6.8 kbp, and 5.0 kbp and designated pAal-1, pAal-2 and pAal-3 respectively, have been found in a tentoxin-producing isolate of Alternaria alternata. Exonuclease digestions show these plasmids to be linear with blocked 5' ends. Plasmid pAal-1 does not hybridize to nuclear DNA, mitochondrial DNA, or double-stranded RNA from a mycovirus found in the isolate, but does hybridize weakly to a series of linear DNAs which are not visible on gels and may include pAal-2 and pAal-3. Cellular fractionation shows that, unlike other linear fungal plasmids, these plasmids are not localized in the mitochondria. Plasmids have not been found in other tentoxin-producing isolates and there is no evidence that these plasmids have any effect on the production of tentoxin.

Characterization of circular mitochondrial plasmids in three Pythium species

Four circular plasmids, with a monomer size ranging from 3.2 to 4.94 kb, have been identified in isolates of P. aphanidermatum (two different plasmids), P. torulosum, and an unidentified echinulate isolate. The mitochondrial location has been confirmed for three of the plasmids. Each fungal isolate contained a single plasmid, present in both monomeric and oligomeric forms; plasmid monomers were present as open circles and as supercoiled forms. Restriction maps of the plasmids were dissimilar. Hybridization studies using cloned plasmids revealed no DNA sequence similarity among the different plasmids or between the plasmids and the nuclear or mitochondrial genome of the isolates from which they were recovered. Hybridization of labeled plasmid DNA to Northern transfers of mitochondrial RNA for two isolates indicate that what appears to be the predominant RNA transcript is unit length in size. For three isolates, the plasmid was retained following subculturing and was present in all asexual and sexual single-spore progeny evaluated. For one isolate of P. aphanidermatum the plasmid was unstable and was lost during subculturing.

The LaBelle mitochondrial plasmid of Neurospora intermedia encodes a novel DNA polymerase that may be derived from a reverse transcriptase

The LaBelle-1b strain of Neurospora intermedia contains a 4.1-kb closed-circular mitochondrial plasmid DNA, which encodes a single long open reading frame of 1,151 amino acids reported to have sequence similarity to reverse transcriptases. Here, we show that the LaBelle strain contains a novel DNA polymerase activity that is highly specific for the endogenous LaBelle plasmid DNA in nucleoprotein particles and can be distinguished from the mitochondrial DNA polymerase by several characteristics. Photolabeling experiments indicate that the LaBelle-specific DNA polymerase activity is associated with a polypeptide of 120 kDa, which is in good agreement with the size predicted for the protein encoded by the LaBelle plasmid open reading frame (132 kDa). This 120-kDa polypeptide is found only in the LaBelle strain that contains the mitochondrial plasmid, and it cosegregates with mitochondria in sexual crosses, suggesting that it is encoded by the plasmid. The LaBelle-specific DNA polymerase efficiently uses the artificial DNA substrates, poly(dA)-oligo(dT) and poly(dC)-oligo(dG), but despite its reported sequence similarity to reverse transcriptases, it has very low activity with analogous RNA substrates, poly(rA)-oligo(dT), poly(rC)-oligo(dG), or poly(rCm)-oligo(dG). Considered together with the previous sequence comparisons, our results suggest that the LaBelle plasmid encodes a novel DNA polymerase, which was derived from a protein that was at one time a reverse transcriptase but lost its ability to use RNA templates. This DNA polymerase now presumably functions in replication of the plasmid. Our results constitute the first biochemical evidence for a DNA polymerase activity associated with a mitochondrial plasmid. Further, they may provide insight into the evolution of DNA polymerases from reverse transcriptases, as presumably occurred in the course of evolution following the transition from the so-called RNA world to the present DNA world.

The LaBelle mitochondrial plasmid of Neurospora intermedia encodes a novel DNA polymerase that may be derived from a reverse transcriptase

The LaBelle-1b strain of Neurospora intermedia contains a 4.1-kb closed-circular mitochondrial plasmid DNA, which encodes a single long open reading frame of 1,151 amino acids reported to have sequence similarity to reverse transcriptases. Here, we show that the LaBelle strain contains a novel DNA polymerase activity that is highly specific for the endogenous LaBelle plasmid DNA in nucleoprotein particles and can be distinguished from the mitochondrial DNA polymerase by several characteristics. Photolabeling experiments indicate that the LaBelle-specific DNA polymerase activity is associated with a polypeptide of 120 kDa, which is in good agreement with the size predicted for the protein encoded by the LaBelle plasmid open reading frame (132 kDa). This 120-kDa polypeptide is found only in the LaBelle strain that contains the mitochondrial plasmid, and it cosegregates with mitochondria in sexual crosses, suggesting that it is encoded by the plasmid. The LaBelle-specific DNA polymerase efficiently uses the artificial DNA substrates, poly(dA)-oligo(dT) and poly(dC)-oligo(dG), but despite its reported sequence similarity to reverse transcriptases, it has very low activity with analogous RNA substrates, poly(rA)-oligo(dT), poly(rC)-oligo(dG), or poly(rCm)-oligo(dG). Considered together with the previous sequence comparisons, our results suggest that the LaBelle plasmid encodes a novel DNA polymerase, which was derived from a protein that was at one time a reverse transcriptase but lost its ability to use RNA templates. This DNA polymerase now presumably functions in replication of the plasmid. Our results constitute the first biochemical evidence for a DNA polymerase activity associated with a mitochondrial plasmid. Further, they may provide insight into the evolution of DNA polymerases from reverse transcriptases, as presumably occurred in the course of evolution following the transition from the so-called RNA world to the present DNA world.

Characterization of a novel plasmid-like element in Neurospora crassa derived mostly from the mitochondrial DNA

We have identified a plasmid-like element within mitochondria of Neurospora crassa strain stp-B1. It is derived from the EcoRI-4 and EcoRI-6 regions of the mitochondrial DNA, and an additional 124 bp DNA segment of unknown origin. The plasmid DNA consists of an oligomeric series of circular molecules of monomer length 2.2 kbp. The abundance of the plasmid suggests its autonomous replication and the presence of an efficient origin of replication. An unusually large number of palindromes capable of forming secondary structures are present in the plasmid. Such a palindrome, located near sequences reminiscent of mammalian and fungal mtDNA origins of replication, may define the replication origin of the plasmid. This putative origin might also represent the replication origin of the wild-type mtDNA.

A site-specific self-cleavage reaction performed by a novel RNA in Neurospora mitochondria

We describe a novel DNA and RNA found in the mitochondria of the Varkud-1c natural isolate of Neurospora. The majority of the RNA, termed VSRNA, is an 881 nucleotide single-stranded circular molecule complementary to one strand of a low copy, double-stranded circular DNA, VSDNA. VSRNA combines some features of the human hepatitis delta virus, group I introns, retroelements, and plant viral satellite RNAs. VSRNA synthesized in vitro performs a self-cleavage reaction whose products terminate with a 5' hydroxyl and a 2',3' cyclic phosphate. This reaction may be involved in the natural processing pathway of multimeric VSRNA in vivo. VSRNA lacks a hammer-head structure or substantial sequence similarity to any other self-cleaving RNA, suggesting that the RNA structure involved in cleavage may be different from those in previously characterized catalytic RNAs.

Independent transfer of mitochondrial chromosomes and plasmids during unstable vegetative fusion in Neurospora

The sporadic distribution of similar introns in organelle, nuclear ribosomal RNA and bacteriophage genes suggests that at least some of these introns are mobile genetic elements. Some plasmids in fungal mitochondria contain intron-like sequences and, like introns, they have scattered distributions within and among species. The occurrence and evolutionary importance of such horizontal transfer of DNA, not only between fungi, but among a wide range of organisms have been matters of much discussion. Here, we report experimental evidence for transfer of Neurospora mitochondrial plasmids from one mitochondrial genotype to another at high frequency during unstable vegetative cell fusion. Exchange of mitochondrial and nuclear genomes can also occur. These observations suggest that vegetative fusion may have a more important role in the mitochondrial genetic structure of natural populations than is generally thought, and may provide an explanation for the distribution of certain plasmids and possibly other mobile genetic elements.

Independent transfer of mitochondrial plasmids in Neurospora crassa

In the ascomycete fungus Neurospora, the distribution of homologous mitochondrial plasmid DNAs in different species and among mitochondrial types of N. crassa suggests that these molecules have moved between lineages of clonally propagated mtDNA. Here we report direct evidence for independent inheritance of mitochondrial plasmids by sexual reproduction which may help explain the distribution of these molecules among mitochondrial lineages.

The mitochondrial plasmid from Neurospora intermedia strain Labelle-1b contains a long open reading frame with blocks of amino acids characteristic of reverse transcriptases and related proteins

We have determined the DNA sequence of the 4070 base pair mitochondrial plasmid from the Labelle-1b strain of Neurospora intermedia. Analysis of the sequence revealed that the plasmid contains a long open reading frame (ORF) that could encode a protein of up to 1151 amino acids. Codon usage in the long ORF shows no clear relationship to Neurospora mitochondrial genes, nuclear genes, nor to the ORF of a different Neurospora mitochondrial plasmid. The long ORF contains regions of similarity to yeast mitochondrial RNA polymerase as well as blocks of amino acids that are characteristic of reverse transcriptases and the ORFs of certain group II mtDNA introns (Michel and Lang, (1985) Nature 316,641). The plasmid gives rise to specific transcripts, some of which may be unit length, and which carry the information for expression of the long ORF. The genetic organization and content of the plasmid suggest that it is related to mobile genetic elements.

Nucleotide sequence of the Varkud mitochondrial plasmid of Neurospora and synthesis of a hybrid transcript with a 5' leader derived from mitochondrial RNA

The Mauriceville and Varkud mitochondrial plasmids of Neurospora are closely related, closed circular DNAs (3.6 and 3.7 kb, respectively; 1 kb = 10(3) bases or base-pairs), whose characteristics suggest relationships to mitochondrial DNA introns and retrotransposons. Here, we characterized the structure of the Varkud plasmid, determined its complete nucleotide sequence and mapped its major transcripts. The Mauriceville and Varkud plasmids have more than 97% positional identity. Both plasmids contain a 710 amino acid open reading frame that encodes a reverse transcriptase-like protein. The amino acid sequence of this open reading frame is strongly conserved between the two plasmids (701/710 amino acids) as expected for a functionally important protein. Both plasmids have a 0.4 kb region that contains five PstI palindromes and a direct repeat of approximately 160 base-pairs. Comparison of sequences in this region suggests that the Varkud plasmid has diverged less from a common ancestor than has the Mauriceville plasmid. Two major transcripts of the Varkud plasmid were detected by Northern hybridization experiments: a full-length linear RNA of 3.7 kb and an additional prominent transcript of 4.9 kb, 1.2 kb longer than monomer plasmid. Remarkably, we find that the 4.9 kb transcript is a hybrid RNA consisting of the full-length 3.7 kb Varkud plasmid transcript plus a 5' leader of 1.2 kb that is derived from the 5' end of the mitochondrial small rRNA. This and other findings suggest that the Varkud plasmid, like certain RNA viruses, has a mechanism for joining heterologous RNAs to the 5' end of its major transcript, and that, under some circumstances, nucleotide sequences in mitochondria may be recombined at the RNA level.

Two linear plasmids in mitochondria of Fusarium solani f. sp. cucurbitae

Two linear plasmid-like DNAs designated pFSC1 (9.2 kbp) and pFSC2 (8.3 kbp) were found in an isolate of the plant pathogenic fungus Fusarium solani f. sp. cucurbitae race 1. The plasmids were maternally inherited and copurified with mitochondrial DNA obtained from a mitochondria-enriched cell fraction suggesting that they are located in mitochondria. The plasmids did not share extensive sequence similarity. No homology was detected between either plasmid and the nuclear or mitochondrial genome when cloned plasmids were used as probes in Southern hybridization analyses. The fungus was cured of plasmids by ethidium bromide treatment. Compared to the plasmid-containing isolate, plasmid-cured derivatives had reduced pathogenicity on a susceptible plant host, Cucurbita maxima "Pink Banana."

An evolutionary comparison of homologous mitochondrial plasmid DNAs from three Neurospora species

We have discovered a mitochondrial DNA plasmid in N. crassa 516 (Roanoke, LA) which is homologous to those previously described from N. intermedia 435 (Fiji) and N. tetrasperma 2510 (Hanalei, HA). Subsequent analysis by DNA-DNA hybridization showed that 6 of 14 other Louisiana N. crassa isolates possessed plasmids homologous to these three plasmids, but at lower copy number. Plasmids from the three named strains were studied to examine possible plasmid diversity within each isolate, the extent of the homology between the plasmids, and the possibility that these plasmids could be inherited separately from their host mitochondria. Comparison of cloned plasmids and covalently closed circular mitochondrial DNA showed that only one plasmid line was present in each of the three intensively studied isolates. DNA-DNA hybridization and restriction endonuclease site mapping showed that the mitochondrial plasmids from the three species were very similar; most of the variation was due to presumed nucleotide substitutions. Plasmids judged identical by our analysis were found in different species. The distribution of the homologous plasmids in nature and the presence of these identical plasmids in different species, suggested that these plasmids could be transmitted between isolates independently of their host mitochondria.