The orir to ori+ mutation in spontaneous yeast petites is accompanied by a drastic change in mitochondrial genome replication

The orir petite mutants of Saccharomyces cerevisiae show a very low level of suppressivity (5-12%; suppressivity is the percentage of diploid petites issued from a cross of the parental haploid petite with a wild-type cell), indicating a poor replication efficiency of their mitochondrial genome. The latter is made up of repeat units containing two inverted ori sequences and arranged as tandem pairs in inverted orientation relative to their nearest neighbors. After subcloning orir petites or crossing with wild-type cells a large number of ori+ petites are found in the progeny. In contrast to the orir petites, from which they are derived, these ori+ petites are characterized by high suppressivity levels (approx. 90%) and contain mitochondrial genomes made up of tandem repeat units containing single ori sequences. The structural changes underlying the orir to ori+ mutation are therefore accompanied by a dramatic increase in suppressivity, indicating that the elimination of inverted ori sequences causes a drastic change from very poor to very good replicative efficiency in the mitochondrial genome. Finally, crosses of ori0 petites with wild-type cells were also studied; the results obtained have clarified the reasons for the high frequency of petites having genomes similar to those of orir petites after mutagenesis with ethidium bromide.     

Temperature can reversibly modify the structure and the functional efficiency of ori sequences of the yeast mitochondrial genome

We have compared the suppressibility of three isonuclear spontaneous, cytoplasmic petite mutants of Saccharomyces cerevisiae, as measured at three temperatures, 23 degrees C, 28 degrees C and 33 degrees C. The three petites have mitochondrial genomes made up of repeat units which are about 400 bp in size, and carry an origin of replication, ori1. This ori sequence is intact in petite Z1, whereas it lacks GC cluster A in petite 26 and cluster A plus some contiguous nucleotides in petite 14. These deletions lead to the impossibility to form a stem-and-loop structure of the ori sequence, the 'A-B fold', which involves two GC clusters, A and B, and the nucleotides in between. Instead, a 'replacement fold', only involving AT base pairs, is feasible. In petites 14 and 26, suppressivity decreases when the temperature is raised from 28 degrees C to 33 degrees C, and increases when the temperature is lowered from 28 degrees C to 23 degrees C. In contrast, no changes are seen in petite Z1. These temperature effects correlate with the stability of the 'A-B fold' and the instability of the 'replacement folds'. Since suppressibility measures the replicative competitiveness of the petite genome relative to the wild-type genome, these results indicate that an environmental parameter, temperature, can reversibly affect the structure and the functional efficiency of ori sequences in vivo. The evolutionary implications of these findings are discussed.     

A region of extreme instability in the mitochondrial genome of yeast.

About half of the spontaneous petite mutants produced by wild-type Saccharomyces cerevisiae strain B (as well as by several other strains) have the same defective mitochondrial genome. Its repeat unit is a segment, 2200 base pairs (bp) long, which derives from an excision between the origins of replication ori 2 and ori 7 of the wild-type genome, and contains a hybrid ori 2-ori 7 sequence. The spontaneous petites carrying this defective ori.h genome are supersuppressive , i.e., they very rapidly compete out the wild-type genome in crosses. The main reasons for the exceptional frequency of ori.h petites are an extremely high excision frequency, due to the extended homology between the two tandemly oriented ori sequences 265 bp long and the short distance separating them. Such an excision frequency is very strongly increased in petite genomes encompassing the ori 2-ori 7 region, because of their higher concentration in these ori sequences.     

Excision sequences in the mitochondrial genome of yeast

We report an analysis of the sequences used in the excision of the mitochondrial genomes of 22 spontaneous and ten ethidium bromide (EtBr)-induced Saccharomyces cerevisiae petite mutants. In all cases, excision sequences were found to be perfect direct repeats, often flanked on one or both sides by regions of patchy homology. Sequences used in the excision of the genomes of spontaneous petites were always located in the AT spacers and GC clusters of intergenic regions of the genome; the GC clusters corresponded to ori and ori^s sequences, namely to canonical and surrogate origins of DNA replication, respectively. In the case of the ethidium bromide-induced petites, excision sequences were found not only in intergenic sequences, but also in the introns and exons of mitochondrial genes.     

Regions flanking ori sequences affect the replication efficiency of the mitochondrial genome of ori+ petite mutants from yeast

The mitochondrial genomes of progenies from 26 crosses between 17 cytoplasmic, spontaneous, suppressive, ori+ petite mutants of Saccharomyces cerevisiae have been studied by electrophoresis of restriction fragments. Only parental genomes (or occasionally, genomes derived from them by secondary excisions) were found in the progenies of the almost 500 diploids investigated; no evidence for illegitimate, site-specific mitochondrial recombination was detected. One of the parental genomes was always found to be predominate over the other one, although to different extents in different crosses. This predominance appears to be due to a higher replication efficiency, which is correlated with a greater density of ori sequences on the mitochondrial genome (and with a shorter repeat unit size of the latter). Exceptions to the 'repeat-unit-size rule' were found, however, even when the parental mitochondrial genomes carried the same ori sequence. This indicates that noncoding, intergenic sequences outside ori sequences also play a role in modulating replication efficiency. Since in different petites such sequences differ in primary structure, size, and position relative to ori sequences, this modulation is likely to take place through an indirect effect on DNA and nucleoid structure.     

Preferential recombination between GC clusters in yeast mitochondrial DNA.

Yeast mitochondrial DNA molecules have long, AT-rich intergenic spacers punctuated by short GC clusters. GC-rich elements have previously been characterized by others as preferred sites for intramolecular recombination leading to the formation of subgenomic petite molecules. In the present study we show that GC clusters are favored sites for intermolecular recombination between a petite and the wild-type grande genome. The petite studied retains 6.5 kb of mitochondrial DNA reiterated tandemly to form molecules consisting of repeated units. Genetic selection for integration of tandem 6.5 kb repeats of the petite into the grande genome yielded a novel recombination event. One of two crossovers in a double exchange event occurred as expected in the 6.5 kb of matching sequence between the genomes, whereas the second exchange involved a 44 bp GC cluster in the petite and another 44 bp GC cluster in the grande genome 700 bp proximal to the region of homology. Creation of a mitochondrial DNA molecule with a repetitive region led to secondary recombination events that generated a family of molecules with zero to several petite units. The finding that 44 bp GC clusters are preferred as sites for intermolecular exchange adds to the data on petite excision implicating these elements as recombinational hotspots in the yeast mitochondrial genome.     

The GC clusters of the mitochondrial genome of yeast and their evolutionary origin

We have studied the primary and secondary structures, the location and the orientation of the 196 GC clusters present in the 90% of the mitochondrial genome of Saccharomyces cerevisiae which have already been sequenced. The vast majority of GC clusters is located in intergenic sequences (including ori sequences, intergenic open reading frames and the gene varl which probably arose from an intergenic spacer) and in intronic closed reading frames (CRF's); most of them can be folded into stem-and-loop systems; both orientations are equally frequent. The primary structures of GC clusters permit to group them into eight families, seven of which are related to the family formed by clusters A, B and C of the ori sequences. On the basis of the present work, we propose that the latter derive from a primitive ori sequence (probably made of only a monomeric cluster C and its flanking sequences r* and r) through (i) a series of duplication inversions generating clusters A and B; and (ii) an expansion process producing the AT stretches of ori sequences. Most GC clusters apparently originated from primary clusters also derived from the primitive ori sequence in the course of its evolution towards the present ori sequences. Finally, we propose that the function of GC clusters is predominantly, or entirely, associated with the structure and organization of the mitochondrial genome of yeast and, indirectly, with the regulation of its expression.     

The nucleotide sequence of the mitochondrial DNA genome of an abundant petite mutant of Saccharomyces cerevisiae carrying the ori1 replication origin

We have determined the 903 bp nucleotide sequence of the mitochondrial DNA genome of a Saccharomyces cerevisiae petite mutant BB5. This petite, containing the 265 nucleotide ori1 region, is representative of a class of petites arising at exceptionally high frequency within the population of spontaneous petites derived from a particular mit- strain Mb12. The DNA sequences of both the ori1 region and the flanking intergenic regions have been compared to those of the corresponding regions of mtDNA in a previously reported petite strain, a1/1R/1 of Bernardi's laboratory, that has a similar (880 bp) repeat unit. The BB5 petite genome carries a canonical ori1 sequence that is identical in both petite mtDNAs, but the flanking intergenic sequences show significant differences between the two petite strains. The divergence is considered to arise from differences in the sequences flanking ori1 in the respective parent strains.     

The mitochondrial genomes of spontaneous orir petite mutants of yeast have rearranged repeat units organized as inverted tandem dimers

We have investigated the structure and organization of the mitochondrial genomes of two related orir (ori-rearranged) spontaneous petite mutants of Saccharomyces cerevisiae. In these mutant genomes every repeat unit contains an inverted terminal duplication harboring a second (inverted) ori sequence, and tandem pairs of repeat units alternate with tandem pairs in inverted orientation. We have shown that orir genomes are organized as the genomes with inverted repeat units of ethidium bromide (EtBr)-induced petites, and we have clarified the mechanism by which such mutant mitochondrial genomes arise.     

Replication and preferential inheritance of hypersuppressive petite mitochondrial DNA

Wild-type yeast mitochondrial DNA (mtDNA) is inherited biparentally, whereas mtDNA of hypersuppressive petite mutants is inherited uniparentally in crosses to strains with wild-type mtDNA. Genomes of hypersuppressive petites contain a conserved ori sequence that includes a promoter, but it is unclear whether the ori confers a segregation or replication advantage. Fluorescent in situ hybridization analysis of wild-type and petite mtDNAs in crosses reveals no preferential segregation of hypersuppressive petite mtDNA to first zygotic buds. We identify single-stranded DNA circles and RNA-primed DNA replication intermediates in hypersuppressive petite mtDNA that are absent from non-hypersuppressive petites. Mutating the promoter blocks hypersuppressiveness in crosses to wild-type strains and eliminates the distinctive replication intermediates. We propose that promoter-dependent RNA-primed replication accounts for the uniparental inheritance of hypersuppressive petite mtDNA.     

The AT spacers and the var1 genes from the mitochondrial genomes of Saccharomyces cerevisiae and Torulopsis glabrata: evolutionary origin and mechanism of formation

Intergenic sequences represent 63% of the mitochondrial 'long' (85 kb) genome of Saccharomyces cerevisiae. They comprise 170-200 AT spacers that correspond to 47% of the genome and are separated from each other by GC clusters, ORFs, ori sequences, as well as by protein-coding genes. Intergenic AT spacers have an average size of 190 bp, and a GC level of 5%; they are formed by short (20-30 nt on the average) A/T stretches separated by C/G mono- to trinucleotides. An analysis of the primary structures of all intergenic AT spacers already sequenced (32 kb; 80% of the total) has shown that they are characterized by an extremely high level of short sequence repetitiveness and by a characteristic sequence pattern; the frequencies of A/T isostichs conspicuously deviate from statistical expectations, and exponentially decrease when their (AT + TA)/(AA + TT) ratio, R, decreases. A situation basically identical was found in the AT spacers of the mitochondrial genome (19 kb) of Torulopsis glabrata. The sequence features of the AT spacers indicate that they were built in evolution by an expansion process mainly involving rounds of duplication, inversion and translocation events which affected an initial oligodeoxynucleotide (endowed with a particular R ratio) and the sequences derived from it. In turn, the initial oligodeoxynucleotide appears to have arisen from an ancestral promoter-replicator sequence which was at the origin of the nonanucleotide promoters present in the mitochondrial genomes of several yeasts. Common sequence patterns indicate that the AT spacers so formed gave rise to the var1 gene (by linking and phasing of short ORFs), to the DNA stretches corresponding to the untranslated mRNA sequences and to the central stretches of ori sequences from S. cerevisiae.     

Inheritance and organisation of the mitochondrial genome differ between two Saccharomyces yeasts

Petite-positive Saccharomyces yeasts can be roughly divided into the sensu stricto, including Saccharomyces cerevisiae, and sensu lato group, including Saccharomyces castellii; the latter was recently studied for transmission and the organisation of its mitochondrial genome. S. castellii mitochondrial molecules (mtDNA) carrying point mutations, which confer antibiotic resistance, behaved in genetic crosses as the corresponding point mutants of S. cerevisiae. While S. castellii generated spontaneous petite mutants in a similar way as S. cerevisiae, the petites exhibited a different inheritance pattern. In crosses with the wild type strains a majority of S. castellii petites was neutral, and the suppressivity in suppressive petites was never over 50%. The two yeasts also differ in organisation of their mtDNA molecules. The 25,753 bp sequence of S. castellii mtDNA was determined and the coding potential of both yeasts is similar. However, the S. castellii intergenic sequences are much shorter and do not contain sequences homologous to the S. cerevisiae biologically active intergenic sequences, as ori/rep/tra, which are responsible for the hyper-suppressive petite phenotype found in S. cerevisiae. The structure of one suppressive S. castellii mutant, CA38, was also determined. Apparently, a short direct intergenic repeat was involved in the generation of this petite mtDNA molecule.     

Biogenesis of mitochondria: XLI. Physical mapping of mitochondrial genetic markers in yeast

This paper describes the physical mapping of five antibiotic resistance markers on the mitochondrial genome of Saccharomyces cerevisiae. The physical separations between markers were derived from studies involving a series of stable spontaneous petite strains which were isolated and characterized for the loss or retention of combinations of the five resistance markers. DNA-DNA hybridization using ³²P-labelled grande mitochondrial DNA was employed to determine the fraction of grande mitochondrial DNA sequences retained by each of the defined petite strains.One petite clone retaining four of the markers in a segment comprising 36% of the grande genome was then chosen as a reference petite. The sequence homology between the mitochondrial DNA of this petite and that of the other petites was measured by DNA-DNA hybridization. For each petite, the total length of its genome derived by hybridization with grande mitochondrial DNA and the fraction of the grande genome retained in common with the reference petite, together with the genetic markers retained in common, were used to position the DNA segment of each petite relative to the reference petite genome. At the same time the relative physical location of the five markers on a circular genome was established. On the basis of the grande mitochondrial genome being defined as 100 units of DNA, the positions of the markers were determined to bo as follows, measuring from one end of the reference petite genome. chloramphenicol (cap1) ~ 0 units erythromycin (ery1) 0 to 15 units oligomycin (oli1) 18 to 19 units mikamycin (mik1) 22 to 25 units paromomycin (par1) 61 to 73 unitsThe general problems of mapping mitochondrial genetic markers by hybridizations involving petite mitochondrial DNA are discussed. Two very important features of petite genomes which could invalidate the interpretation of DNA-DNA hybridization experiments between petite mitochondrial DNAs are the possible presence in the reference petite of differentially amplified DNA sequences, and/or “new” sequences which are not present in the parent grande genome. A general procedure, which overcomes errors of interpretation arising from these two features is described.     

Genome nucleotide composition shapes variation in simple sequence repeats

Simple sequence repeats (SSRs) or microsatellites are a common component of genomes but vary greatly across species in their abundance. We tested the hypothesis that this variation is due in part to AT/GC content of genomes, with genomes biased toward either high AT or high CG generating more short random repeats that are long enough to enhance expansion through slippage during replication. To test this hypothesis, we identified repeats with perfect tandem iterations of 1-6 bp from 25 protists with complete or near-complete genome sequences. As expected, the density and the frequency are highly related to genome AT content, with excellent fits to quadratic regressions with minima near a 50% AT content and rising toward both extremes. Within species, the same trends hold, except the limited variation in AT content within each species places each mainly on the descending (GC rich), middle, or ascending (AT rich) part of the curve. The base usages of repeat motifs are also significantly correlated with genome nucleotide compositions: Percentages of AT-rich motifs rise with the increase of genome AT content but vice versa for GC-rich subgroups. Amino acid homopolymer repeats also show the expected quadratic relationship, with higher abundance in species with AT content biased in either direction. Our results show that genome nucleotide composition explains up to half of the variance in the abundance and motif constitution of SSRs.     

双翅目昆虫线粒体基因组结构特点及其测序通用引物的设计和应用

研究双翅目昆虫线粒体基因组的结构特点, 并设计其测序的通用引物, 为今后双翅目昆虫线粒体基因组的研究提供参考和依据。利用比较基因组学和生物信息学方法, 分析了已经完全测序的26个双翅目昆虫线粒体基因组的结构特点、 碱基组成和保守区, 并据此设计了双翅目昆虫基因组测序的通用引物。结果表明： 双翅目昆虫线粒体基因组长14 503~19 517 bp, 其结构保守, 含有37个编码基因, 包括13个蛋白质编码基因, 22个tRNA编码基因和2个rRNA编码基因, 此外还包含一段长度差异很大的非编码区(AT富含区)。基因组内基因排列次序稳定, 除个别基因外, 其余都与黑腹果蝇Drosophila melanogaster基因排列次序一致。基因组的碱基组成不均衡, AT含量在72.59%~85.15%之间, 碱基使用存在偏向性, 偏好使用AC碱基。全基因组的核苷酸和氨基酸序列保守, 共鉴定了11个保守区。在保守区内共设计了26对双翅目线粒体基因组测序通用引物, 扩增的目标片段都在1 200 bp以内。将该套通用引物用于葱蝇Delia antiqua线粒体全基因组测序, 结果证明其高效、 合用。