Asymmetric gene conversion at inserted segments on yeast mitochondrial DNA

A genome-wide map of mitochondrial DNA recombination in yeast

In eukaryotic cells, the production of cellular energy requires close interplay between nuclear and mitochondrial genomes. The mitochondrial genome is essential in that it encodes several genes involved in oxidative phosphorylation. Each cell contains several mitochondrial genome copies and mitochondrial DNA recombination is a widespread process occurring in plants, fungi, protists, and invertebrates. Saccharomyces cerevisiae has proved to be an excellent model to dissect mitochondrial biology. Several studies have focused on DNA recombination in this organelle, yet mostly relied on reporter genes or artificial systems. However, no complete mitochondrial recombination map has been released for any eukaryote so far. In the present work, we sequenced pools of diploids originating from a cross between two different S. cerevisiae strains to detect recombination events. This strategy allowed us to generate the first genome-wide map of recombination for yeast mitochondrial DNA. We demonstrated that recombination events are enriched in specific hotspots preferentially localized in non-protein-coding regions. Additionally, comparison of the recombination profiles of two different crosses showed that the genetic background affects hotspot localization and recombination rates. Finally, to gain insights into the mechanisms involved in mitochondrial recombination, we assessed the impact of individual depletion of four genes previously associated with this process. Deletion of NTG1 and MGT1 did not substantially influence the recombination landscape, alluding to the potential presence of additional regulatory factors. Our findings also revealed the loss of large mitochondrial DNA regions in the absence of MHR1, suggesting a pivotal role for Mhr1 in mitochondrial genome maintenance during mating. This study provides a comprehensive overview of mitochondrial DNA recombination in yeast and thus paves the way for future mechanistic studies of mitochondrial recombination and genome maintenance.

Relocation of the unusual VAR1 gene from the mitochondrion to the nucleus

The Var1 protein (Var1p) is an essential, stoichiometric component of the yeast mitochondrial small ribosomal subunit, and it is the only major protein product of the mitochondrial genetic system that is not part of an energy transducing complex of the inner membrane. Interestingly, no mutations have been reported that affect the function of Var1p, presumably because loss of a functional mitochondrial translation system leads to an instability of mtDNA. To study the structure, function and synthesis of Var1p, we have engineered yeast strains for the expression of this protein from a nuclear gene, VAR1U, in which 39 nonstandard mitochondrial codons were converted to the universal code. Immunoblot analysis using an epitope-tagged form of Var1Up showed that the nuclear-encoded protein was expressed and imported into the mitochondria. VAR1U was tested for its ability to complement a mutation in mtDNA, PZ206, which disrupts '3-end processing of the VARI mRNA, causing greatly reduced synthesis of Var1p and a respiratory-deficient phenotype. Respiratory growth was restored in PZ206 mutants by transformation with a centromere plasmid carrying VAR1U under ADH1 promoter control, thus proving that VAR1 function can be relocated from the mitochondrion to the nucleus. Moreover, epitope-tagged Var1Up co-sedimented specifically with small ribosomal subunits in high salt sucrose gradients. The relocation of VAR1 from the mitochondrion to the nucleus provides an excellent system for the molecular genetic analysis of structure-function relationships in the unusual Var1 protein.

Mobility of two optional G + C-rich clusters of the var1 gene of yeast mitochondrial DNA

Yeast mtDNA contains two different kinds of mobile optional sequences, two group I introns and a short G + C-rich insertion to some var1 genes. Movement of each element in crosses has been called gene conversion though little is known about the mechanism of G + C cluster conversion. A new allele of the var1 gene found in mtDNA of Saccharomyces capensis is described that permitted a more detailed comparison between intron mobility and G + C cluster conversion. The S. capensis var1 gene lacks the cc+ element present in all S. cerevisiae var 1 genes and the previously described optional a+ element. In crosses with cc+ a- and cc+ a+ S. cerevisiae strains, both clusters were found to be mobile and, in the latter cross, appear to convert independently and only to homologous insertion sites. No evidence for flanking marker coconversion (a hallmark feature of intron conversion) was obtained despite the availability of nearby physical markers on both sides of cluster conversion sites. These data indicate that G + C cluster conversion has only a superficial resemblance to intron mobility; analogies to procaryotic transposition mechanisms are considered.

A mitochondrial intergenic mutation affecting processing of specific yeast mitochondrial transcripts

The mutation in the temperature-conditional mit- mutant h56, mapped previously to the var1 gene region of Saccharomyces cerevisiae mitochondrial DNA, results in a specific inhibition of var1 protein synthesis in cells incubated at the non-permissive temperature, 36 degrees C (1). We have now characterized the mutation present in mutant h56 by DNA sequencing and found it to be an A to T transversion located 109 nucleotides upstream of the var1 reading frame. Two spontaneous revertants of mutant h56 restore the parental strain sequence at residue -109, confirming that this single base change within the 5'-untranslated region of the var1 mRNA is responsible for defective synthesis of the var1 protein. A comparison of var1 transcripts in the parental and mutant strains has shown that the mutation specifically blocks formation of var1 mRNA at 36 degrees C and leads to accumulation of precursor transcripts. Expression of the oli1 gene, co-transcribed with the var1 gene in primary transcripts, is not affected. It is concluded that the mutation in mutant h56 alters the secondary structure of the precursor RNA, inhibiting an endonucleolytic cleavage required to generate the 5' end of var1 mRNA.

In vivo double-strand breaks occur at recombinogenic G + C-rich sequences in the yeast mitochondrial genome

An optional 46-base-pair G + C-rich element (GC cluster) in the coding region of the yeast mitochondrial var1 gene inserts preferentially in crosses into recipient alleles that lack the sequence. Unlike a similar gene conversion event involving the insertion of an optional 1143-base-pair intron, the mitochondrial 21S rRNA gene, which requires the action of a protein encoded by a gene within that intron, conversion of the var1 GC cluster does not require any protein product of the mitochondrial genome. We have detected double-strand breaks in the var1 gene in mitochondrial DNA isolated from unmated haploid rho+ and rho- strains at or near the boundaries of the optional GC cluster, as well as at a conserved copy of that sequence 160 base pairs upstream. No double-strand breaks were detected in the recipient var1 DNA molecules in the vicinity of the optional GC cluster target sequence. This contrasts with 21S rRNA-encoding DNA (rDNA) intron conversion where the recipient, but not the donor DNA, is cleaved at the element insertion site. These results suggest that although the 21S rDNA intron and the var1 GC cluster are preferentially inserted into their respective short alleles, these conversions probably occur by different mechanisms.

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 unusual varl gene of yeast mitochondrial DNA

The var1 gene specifies the only mitochondrial ribosomal protein known to be encoded by yeast mitochondrial DNA. The gene is unusual in that its base composition is nearly 90 percent adenine plus thymine. It and its expression product show a strain-dependent variation in size of up to 7 percent; this variation does not detectably interfere with function. Furthermore, var1 is an expandable gene that participates in a novel recombinational event resembling gene conversion whereby shorter alleles are preferentially converted to longer ones. The remarkable features of var1 indicate that it may have evolved by a mechanism analogous to exon shuffling, although no introns are actually present.

Nonreciprocal exchange between alleles of the yeast mitochondrial 21S rRNA gene: kinetics and the involvement of a double-strand break

A 1.1 kb intron containing an open reading frame (ORF) in one allele (omega+) of the yeast mitochondrial 21S rRNA gene is nearly quantitatively inserted in crosses into a 21S rRNA allele lacking that intron (omega-). We have determined that this nonreciprocal exchange initiates soon after cells fuse to form zygotes and is complete by 10-16 hr after mating. We have discovered a unique in vivo double-strand cut in omega- mitochondrial DNA (mtDNA) at or near the site of intron insertion that is implicated in the process. Markers flanking the intron insertion site are coconverted with frequencies inversely proportional to their distance from that site. There is no net conversion of omega- to omega+ in crosses between petites retaining these alleles, nor do we observe the unique double-strand cut in the mtDNA from zygotes of such crosses. The data suggest that a translation product of the intron ORF is required for the double-strand cut and nonreciprocal recombination at omega.

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.

Expandable var1 gene of yeast mitochondrial DNA: in-frame insertions can explain the strain-specific protein size polymorphisms

The var1 locus of yeast mitochondrial DNA encodes a protein of the small mitochondrial ribosome subunit, denoted var1 protein. The size of var1 protein was previously shown to exhibit a strain-dependent polymorphism, determined by various combinations of at least three genetic elements. We report here that the var1 gene is itself polymorphic and that the six forms of this gene examined here differ by various combinations of three in-frame insertions into the coding region of the smallest allele. These insertions, which appear to be the molecular basis for the genetic elements, could increase the size of var1 protein by 8, 10, 16, 24, or 26 amino acid residues, accounting for the observed protein polymorphisms. Furthermore, we have characterized three additional sources of sequence variation located outside of the coding region but within major transcripts of the var1 gene.

Transcriptional analysis of the Saccharomyces cerevisiae mitochondrial var1 gene: anomalous hybridization of RNA from AT-rich regions

A family of mitochondrial RNAs hybridizes specifically to the var1 region on Saccharomyces cerevisiae mitochondrial DNA (Farrelly et al., J. Biol. Chem. 257:6581-6587, 1982). We constructed a fine-structure transcription map of this region by hybridizing DNA probes containing different portions of the var1 region and some flanking sequences to mitochondrial RNAs isolated from var1-containing petites. We also report the nucleotide sequence of more than 1.2 kilobases of DNA flanking the var1 gene. Our primary findings are: (i) The family of RNAs we detect with homology to var1 DNA is colinear with the var1 gene. Their direction of transcription is olil to cap, as it is for most other mitochondrial genes. (ii) Extensive hybridization anomalies are present, most likely due to the high A-T (A-U) content of the hybridizing species and to the asymmetric distribution of their G-C residues. An important conclusion is that failure to detect transcripts from A-T-rich regions of the yeast mitochondrial genome by standard blot transfer hybridizations cannot be interpreted to mean that such sequences, which are commonly supposed to be spacer DNA, are noncoding or lack direct function in the expression of mitochondrial genes.

Transcriptional analysis of the Saccharomyces cerevisiae mitochondrial var1 gene: anomalous hybridization of RNA from AT-rich regions

A family of mitochondrial RNAs hybridizes specifically to the var1 region on Saccharomyces cerevisiae mitochondrial DNA (Farrelly et al., J. Biol. Chem. 257:6581-6587, 1982). We constructed a fine-structure transcription map of this region by hybridizing DNA probes containing different portions of the var1 region and some flanking sequences to mitochondrial RNAs isolated from var1-containing petites. We also report the nucleotide sequence of more than 1.2 kilobases of DNA flanking the var1 gene. Our primary findings are: (i) The family of RNAs we detect with homology to var1 DNA is colinear with the var1 gene. Their direction of transcription is olil to cap, as it is for most other mitochondrial genes. (ii) Extensive hybridization anomalies are present, most likely due to the high A-T (A-U) content of the hybridizing species and to the asymmetric distribution of their G-C residues. An important conclusion is that failure to detect transcripts from A-T-rich regions of the yeast mitochondrial genome by standard blot transfer hybridizations cannot be interpreted to mean that such sequences, which are commonly supposed to be spacer DNA, are noncoding or lack direct function in the expression of mitochondrial genes.

Mitochondrial genes at Cold Spring Harbor

The flowering dogwood trees and green lawns of Cold Spring Harbor provided the setting for a meeting devoted to Mitochondrial Genes from May 13-17th, 1981. Dedicated to the memory of Boris Ephrussi, who pioneered mitochondrial genetics at a time when the only kinds of genetics were nuclear or unclear, the meeting showed that the study of mtDNA has had impact on many areas of molecular biology including the genetic code and decoding, tRNA function, mechanisms of splicing and molecular evolution. Curiously, as Herschel Roman pointed out in his opening address, Ephrussi took great pains to avoid any mention of mitochondrial DNA in connection with his observations on cytoplasmic inheritance, preferring instead to refer to 'cytoplasmic particles, endowed with genetic continuity' (Ephrussi 1953). This reticence was not shared by participants at the meeting, as the following, brief report will show.

Gene conversion at the var1 locus on yeast mitochondrial DNA

Alleles of the var1 locus on yeast mtDNA determine the apparent size of the mitochondrial translation product, var1 polypeptide. We have analyzed most of the different var1 alleles in our collection, which number at least 15, and have developed procedures and a genetic rationale for determining their origin and predicting their behavior in crosses. The var1 alleles are characterized by two genetically defined segments, designated a and b, which can move from one var1 allele to another by asymmetric gene conversion. We show that the a segment behaves as an entity in recombination; it is either present in or absent from different var1 alleles. The b segment usually, but not always, recombines as an entity; in some cases, only portions of the b segment recombine by gene conversion. Thus, the total number of electrophoretically resolvable var1 species we observe is explained by the assortment of a, b, and partial b segments. Each segment recombines at a characteristic frequency; however, one example is presented which shows that the recipient can modulate the frequency of gene conversion. Finally, we show that, like the 21S rDNA region (omega), there is polarity of gene conversion within var1.

Adrenocorticotropic hormone increases specific proteins of the mitochondrial fraction that are translated inside or outside this organelle in cultured adrenal tumor cells

In addition to its stimulatory effects on steroidogenesis, adrenocorticotropic hormone (ACTH) also has a trophic action on the adrenal cell. This is manifested in part by increases in the levels of key mitochondrial steroidogenic enzymes. The mechanism by which this trophic action of ACTH occurs has been studied in monolayer cultures of mouse adrenal cortical tumor cells. ACTH treatment of these cells stimulates the relative incorporation of amino acids into at least eight specific proteins in mitochondrial preparations. Two of these ACTH-responsive proteins are among the nine major adrenal polypeptides that fulfill the criteria of mitochondrial translation products: (i) their synthesis in intact cells is specifically resistant to inhibition by cycloheximide yet uniquely sensitive to chloramphenicol and (ii) they are synthesized in vitro by isolated mitochondria. The other six ACTH-responsive proteins are within the much larger category of mitochondrial proteins that are synthesized on cytoplasmic ribosomes. One of the proteins synthesized in the cytoplasm electrophoretically comigrates with purified beef adrenodoxin reductase and another with beef adrenodoxin. These findings indicate that ACTH regulates the synthesis (and turnover, or both) of specific mitochondrial proteins that are synthesized inside as well as outside the mitochondria of these adrenal cells.

Isolation and characterization of spontaneously arising auxotrophic and Kanagawa phenomenon-negative mutants of Vibrio parahaemolyticus

As a first step toward developing a system of genetic exchange between Vibrio parahaemolyticus strains, spontaneously arising auxotrophic and Kanagawa phenomenon-negative (KP-) mutants were isolated and characterized. Auxotrophic mutants were selected by nalidixic acid enrichment of parental cultures. Some Cys- and Arg- mutants of a KP+ strain were found to be KP-. Reversion to prototrophy by these strains was not accompanied by a return to the parental KP+ phenotype. Additionally, two prototrophic KP- mutants were isolated. No detectable levels of vibriolysin were found in supernatant extracts of KP- mutants by slide gel immunodiffusion analysis, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, or assay for lethal activity in mice. All Cys-, Arg-, and Pur- mutants tested reverted to a different auxotrophy (phenotypic interconversion) as well as to prototrophy. The possible role of insertion sequence-like elements in vibriolysin production and phenotypic interconversion is discussed.