Unidirectional gene conversion associated with two insertions in neurospora crassa mitochondrial DNA

Uniparental inheritance and replacement of mitochondrial DNA in Neurospora tetrasperma

This study tested mechanisms proposed for maternal uniparental mitochondrial inheritance in Neurospora: (1) exclusion of conidial mitochondria by the specialized female reproductive structure, trichogyne, due to mating locus heterokaryon incompatibility and (2) mitochondrial input bias favoring the larger trichogyne over the smaller conidium. These mechanisms were tested by determining the modes of mitochondrial DNA (mtDNA) inheritance and transmission in the absence of mating locus heterokaryon incompatibility following crosses of uninucleate strains of Neurospora tetrasperma with trichogyne (trichogyne inoculated by conidia) and without trichogyne (hyphal fusion). Maternal uniparental mitochondrial inheritance was observed in 136 single ascospore progeny following both mating with and without trichogyne using mtDNA restriction fragment length polymorphisms to distinguish parental types. This suggests that maternal mitochondrial inheritance following hyphal fusions is due to some mechanism other than those that implicate the trichogyne. Following hyphal fusion, mutually exclusive nuclear migration permitted investigation of reciprocal interactions. Regardless of which strain accepted nuclei following seven replicate hyphal fusion matings, acceptor mtDNA was the only type detected in 34 hyphal plug and tip samples taken from the contact and acceptor zones. No intracellular mtDNA mixtures were detected. Surprisingly, 3 days following hyphal fusion, acceptor mtDNA replaced donor mtDNA throughout the entire colony. To our knowledge, this is the first report of complete mitochondrial replacement during mating in a filamentous fungus.

Identification of a family of bacteriophage T4 genes encoding proteins similar to those present in group I introns of fungi and phage

The bacteriophage T4 segA gene lies in a genetically unmapped region between the gene beta gt (beta-glucosyltransferase) and uvsX (recombination protein) and encodes a protein of 221 amino acids. We have found that the first 100 amino acids of the SegA protein are highly similar to the N termini of four other predicted T4 proteins, also of unknown function. Together these five proteins, SegA-E (similar to endonucleases of group I introns), contain regions of similarity to the endonuclease I-Tev I, which is encoded by the mobile group I intron of the T4 td gene, and to putative endonucleases of group I introns present in the mitochondria of Neurospora crassa, Podospora anserina, and Saccharomyces douglasii. Intron-encoded endonucleases are required for the movement (homing) of the intron DNA into an intronless gene, cutting at or near the site of intron insertion. Our in vitro assays indicate that SegA, like I-Tev I, is a Mg(2+)-dependent DNA endonuclease that has preferred sites for cutting. Unlike the I-Tev I gene, however, there is no evidence that segA (or the other seg genes) resides within introns. Thus, it is possible that segA encodes an endonuclease that is involved in the movement of the endonuclease-encoding DNA rather than in the homing of an intron.

Alteration of the cytochrome c oxidase subunit 2 gene in the [exn-5] mutant of Neurospora crassa

The maternally inherited [exn-5] mutant of Neurospora crassa is characterized by its slow-growth rate and deficiency of cytochrome aa3 relative to wild-type strains. We have determined the DNA sequence of the COXI and COXII genes of the mutant, which encode subunits 1 and 2 of cytochrome c oxidase, respectively. No changes in the DNA sequence of the COXI gene relative to the corresponding wild-type gene were found. In the region of the COXII gene we found two alterations, one a C to T transition eight base pairs upstream of the coding sequence and the second within the coding sequence for subunit 2 affecting amino acid 27 of the precursor polypeptide (amino acid 15 of the mature polypeptide). The altered codon in [exn-5] specifies an isoleucine residue rather than the wild-type threonine residue. The corresponding position in subunit 2 sequences of all other organisms examined is conserved either as a threonine or a serine residue. Thus, we consider it likely that the mutation directly affecting the coding sequence of the polypeptide is responsible for the [exn-5] phenotype. Analysis of serially passaged heterokaryons constructed between wild-type and [exn-5] shows that both mutations segregate with the [exn-5] phenotype. Examination of mitochondrial translation products in [exn-5] revealed a deficiency of subunit 2, as well as the presence of a polypeptide that corresponds to a previously described precursor of subunit 1 that accumulates in a COXI mutant of N. crassa, [mi-3]. We propose possible relationships between [exn-5], [mi-3], and the nuclear su-1[mi-3] allele, which suppresses both mutations.

Behavior of the [mi-3] mutation and conversion of polymorphic mtDNA markers in heterokaryons of Neurospora crassa

We have examined the behavior of the [mi-3] mitochondrial mutation and two physical mtDNA markers in heterokaryotic cultures of Neurospora crassa. Previous workers showed that a 1.2-kilobase insertion in the larger polymorphic form of EcoRI-5 restriction fragment is a site of high frequency and rapid unidirectional gene conversion. We have confirmed this observation and determined by DNA sequence analysis that the insertion in the EcoRI-5 fragment corresponds precisely to an optional intron that contains a long open reading frame in the ND1 gene. Thus, the conversion of the short, intron-lacking, form of EcoRI-5 to the longer, intron-containing, form may be analogous to the unidirectional gene conversion events catalyzed by intron-encoded proteins in other organisms. The resolution of two polymorphic forms of the mtDNA EcoRI-9 restriction fragment in our heterokaryons differs from that observed previously and suggests that this locus is not a site of gene conversion in our heterokaryon pair. The size polymorphism of the EcoRI-9 fragments is due to a tandemly reiterated 78-base-pair sequence which occurs two times in the short form and three times in the long form. One copy of the repeat unit and 66 base pairs following it have been duplicated from the ND2 gene which is located about 30 kilobases distant on the mtDNA. In contrast to the [poky] mitochondrial mutant, which was completely dominant over wild-type mitochondria in heterokaryons, the [mi-3] mutant was recovered in only seven of twenty heterokaryons after ten cycles of conidiation and subculturing. The resolution of the [mi-3] or wild-type phenotype in heterokaryons may depend solely on random factors such as allele input frequency, drift, and segregation rather than specific dominant or suppressive effects.

Group I introns as mobile genetic elements: facts and mechanistic speculations--a review

Group I introns form a structural and functional group of introns with widespread but irregular distribution among very diverse organisms and genetic systems. Evidence is now accumulating that several group I introns are mobile genetic elements with properties similar to those originally described for the omega system of Saccharomyces cerevisiae: mobile group I introns encode sequence-specific double-strand (ds) endoDNases, which recognize and cleave intronless genes to insert a copy of the intron by a ds-break repair mechanism. This mechanism results in: the efficient propagation of group I introns into their cognate sites; their maintenance at the site against spontaneous loss; and, perhaps, their transposition to different sites. The spontaneous loss of group I introns occurs with low frequency by an RNA-mediated mechanism. This mechanism eliminates introns defective for mobility and/or for RNA splicing. Mechanisms of intron acquisition and intron loss must create an equilibrium, which explains the irregular distribution of group I introns in various genetic systems. Furthermore, the observed distribution also predicts that horizontal transfer of intron sequences must occur between unrelated species, using vectors yet to be discovered.

A mobile group I intron in the nuclear rDNA of Physarum polycephalum

We have shown that a strain-specific group I intron (intron 3) in the nuclear extrachromosomal rDNA or Physarum polycephalum is a mobile element. Shortly after mating of amoebae from intron-lacking and intron-containing strains, intron 3 transposes in a site-specific manner into all available recipient molecules. The transposition appears to occur by gene conversion, as evidence by the co-conversion of adjacent sequences and by double strand breakage observed in some of the recipient rDNA molecules. We infer that the double strand break is induced by an endonuclease encoded by intron 3, since in vitro transcription and translation of the cloned intron leads to the synthesis of an enzymatically active, site-specific nuclease. This is the first demonstration of the transposition of a nuclear intron in an experimental setting, and provides a rare example of a protein encoded by an RNA polymerase I transcript.

A latent intron-encoded maturase is also an endonuclease needed for intron mobility

Some yeast mitochondrial introns encode proteins that promote either splicing (maturases) or intron propagation via gene conversion (the fit1 endonuclease). We surveyed introns in the coxl gene for their ability to engage in gene conversion and found that the group I intron, al4 alpha, was efficiently transmitted to genes lacking it. An endonucleolytic cleavage is detectable in recipient DNA molecules near the site of intron insertion in vivo and in vitro. Conversion is dependent on an intact al4 alpha open reading frame. This intron product is a latent maturase, but these data show that it is also a potent endonuclease involved in recombination. Dual function proteins that cleave DNA and facilitate RNA splicing may have played a pivotal role in the propagation and tolerance of introns.

Mitochondrial DNAs of Suillus: three fold size change in molecules that share a common gene order

We constructed restriction-site and gene maps for mitochondrial DNAs from seven isolates of five species of Suillus (Boletaceae, Basidiomycotina). Each mitochondrial genome exists as a single circular chromosome, ranging in size from 36 to 121 kb. Comparisons within species and between two closely related species revealed that insertions and deletions are the major form of genome change, whereas most restriction sites are conserved. Among more distantly related species, size and restriction-site differences were too great to allow precise alignments of maps, but small clusters of putatively homologous restriction sites were found. Two mitochondrial gene orders exist in the five species. These orders differ only by the relative positions of the genes for ATPase subunit 9 and the small ribosomal RNA and are interconvertible by a single transposition. One of the two gene arrangements is shared by four species whose mitochondrial DNAs span the entire size range of 36 to 121 kb. The conservation of gene order in molecules that vary over three-fold in size and share few restriction sites demonstrates a low frequency of rearrangements relative to insertions, deletions, and base substitutions.

Inversions and recombinations in mitochondrial DNA of the (SG-1) cytoplasmic mutant in two Neurospora species

The mitochondrial DNAs of [SG-1] cytoplasmically-mutant and wild-type strains of Neurospora crassa and Neurospora sitophila were examined by comparative restriction endonuclease analyses. The mtDNA of N. sitophila wild type of Whitehouse differs from type II mtDNA of N. crassa by insertions of 3.3 kb in EcoRI-9, and 1.2 kb in EcoRI-3, and a deletion of 1.1 kb in EcoRI-5. These DNA heteromorphisms provided convenient markers for tracing N. crassa [SG-1] mtDNA during and after its transfer into N. sitophila. The [SG-1] cytoplasmic mutant in both N. crassa and N. sitophila has a distinctive inversion that connects the fragment EcoRI-4 with HindIII-10a. The [SG-1] mtDNA from N. crassa remained essentially intact after it was transferred by crosses into N. sitophila. In each species, a unique second inversion occurred in the [SG-1] mtDNA after the transfer was made. In N. sitophila, polar recombination in heteroplasmons between [SG-1] and wild-type preferentially yields strains with mtDNAs that contain the maximum possible number of insertions in the cob and co-1 loci of the EcoRI-3 region of the mitochondrial chromosome.

The [poky] mutant of Neurospora contains a 4-base-pair deletion at the 5' end of the mitochondrial small rRNA

[ poky ] and other group I extranuclear mutants of Neurospora crassa are characterized by gross deficiencies of mitochondrial small ribosomal subunits and small (19S) rRNA. Blot-hybridization and other experiments suggest that the 19S rRNA (2.0 kilobases) is synthesized via precursors that contain 5'-end extensions. The ratio of precursors to mature rRNA is higher in [ poky ] and other group I mutants than in wild type, indicating that the defect involves impaired processing and/or instability of 19S rRNA. [ poky ] and other group I mutants contain a 4-base-pair deletion in the coding sequence for the mitochondrial small rRNA, just downstream from what would normally be the 5' end of the rRNA. This deletion apparently results in synthesis of aberrant 19S rRNAs that are missing 38-45 nucleotides from their 5' ends. We propose that the 4-base-pair deletion is the primary defect in [ poky ] and other group I extranuclear mutants.

Deletion mutants of Neurospora crassa mitochondrial DNA and their relationship to the "stop-start" growth phenotype

"Stoppers" are a class of Neurospora crassa extranuclear mutants characterized by gross deficiencies of cytochromes b and aa3 and an unusual growth phenotype which involves irregular periods of growth andnongrowth. In the present work, mtDNAs from all four stopper mutants were found to contain deletions or insertions detectable by restriction enzyme analysis. [stp] mtDNA consists predominantly of defective molecules which retain a 16-megadalton segment (EcoRI-1, -4, and -6) of wild-type mtDNA (40 megadaltons). The other stopper mutants show smaller alterations: [stp A18t]-618, a 0.35-kilobase deletion in EcoRI-7b; [stp B2]-651, a 4-kilobase insertion in EcoRI-2; and [stp A]-574, a 5-kilobase deletion in EcoRI-2 and -10. Based on these results, we propose that "stop-start" growth results from competition between certain defective mtDNAs which have a tendency to predominate and low concentrations of less defective mtDNA species which must be retained to sustain growth. Three additional extranuclear mutants ("nonstoppers") have also been found to contain deletions in mtDNA. Remarkably, the defective mtDNA species in two of these mutants ([poky]H1-10 and [SG-3]-551) retain different sizes (18 and 13 megadlatons, respectively) of the same region retained in [stp] mtDNA (i.e., EcoRI-1, -4, and -6). The findings suggest that production of defective mtDNAs in Neurospora is nonrandom with a preferred mechanism leading to retention of this segment. It may be significant that the retained segment contains both mitochondrial rRNA genes and most mitochondrial tRNA genes. These deletion mutants may provide a tool for genetic mapping of Neurospora mtDNA.