Distribution of mitochondrial introns in the species Schizosaccharomyces pombe and the origin of the group II intron in the gene encoding apocytochrome b

Summary The mitochondrial genome size of 26 different Schizosaccharomyces pombe strains varies between 17.6 and 24.6 kilobase pairs due to the presence or absence of introns. One of these is the group II intron in the gene encoding apocytochrome b (cob: intron cobI1 ). Partial DNA sequences of continuous cob genes from six strains (including strain EF1: Trinkl et al. 1985) revealed identical nucleotide sequence in the region where the group II intron is inserted in the mosaic form of the gene. In contrast, analysis of the mosaic cob, gene in strain UCD-Fstl revealed several base pair changes in the exon regions flanking the splice point, compared with the continuous genes and with the mosaic cob gene in strain 50 (Lang et al. 1985). The base pair differences between the exons of the two mosaic cob genes and the identity of exons in all continuous cob genes argue in favour of the two cob introns in strains 50 and UCD-FstI as independent later acquisitions of the genes, rather than loss of the intron from a common mosaic ancestor of all strains.Other introns present in some but not all strain include two group I introns without open reading frame in the gene encoding subunit 1 of cytochrome c oxidase (cox1: introns cox1I2a and cox1I3), and two group I introns with open reading frames in the same gene (introns cox1I1 and cox1I2b).     

Structure and evolution of myxomycete nuclear group I introns: a model for horizontal transfer by intron homing

Summary We have examined five nuclear group I introns, located at three different positions in the large subunit ribosomal RNA (LSU rRNA) gene of the two myxomycete species, Didymium iridis and Physarum polycephalum. Structural models of intron RNAs, including secondary and tertiary interactions, are proposed. This analysis revealed that the Physarum intron 2 contains an unusual core region that lacks the P8 segment, as well as several of the base-triples known to be conserved among group I introns. Structural and evolutionary comparisons suggest that the corresponding introns 1 and 2 were present in a common ancestor of Didymium and Physarum, and that the five introns in LSU rRNA genes of these myxomycetes were acquired in three different events. Evolutionary relationships, inferred from the sequence analysis of several different nuclear group I introns and the ribosomal RNA genes of the intron-harbouring organisms, strongly support horizontal transfer of introns in the course of evolution. We propose a model that may explain how myxomycetes in natural environments obtained their nuclear group I introns.     

Specific elimination of mitochondrial DNA from Chlamydomonas by intercalating dyes

Summary Minute colony mutations in C. reinhardtii are induced with 100% efficiency by intercalating dyes such as acriflavin and ethidium bromide. These mutants form small colonies on petri plates because they undergo only 8–9 mitotic divisions before growth ceases. In liquid media without the dye the mutants show gross alterations in mitochondrial structure and function. Here we demonstrate that induction of minute mutations is accompanied by the specific loss of mitochondrial DNA. We also provide evidence that the transmission of the minute colony phenotype in crosses can be explained in terms of uniparental transmission of mitochondrial DNA by the mt ^– parent.     

The fate of mitochondrial DNAs of mt + and mt − origin in gametes and zygotes of Chlamydomonas

Summary In order to study the mechanism responsible for the uniparental transmission of the mitochondrial genome in crosses between Chlamydomonas reinhardtii and C. smithii, we have analyzed the fate of mitochondrial DNA during gametogenesis, zygospore differentiation and sporulation by hybridization experiments. Both mt ⁺ and mt ^– gametes contain the same amount of mitochondrial DNA and the two parental genomes persist for several days in the zygotes. The DNA of mt ⁺ origin is slowly eliminated during the period of zygote maturation. Light is required for total elimination of mt ⁺ mitochondrial DNA in the zygospores. Using appropriate restriction enzymes, we have been unable to detect methylation of the mitochondrial DNA during gametogenesis or zygospore formation. The possibility that the mt ⁺ mitochondria themselves are specifically eliminated in the course of zygote maturation is discussed.     

Comparative analysis of the mitochondrial genomes of Chlamydomonas eugametos and Chlamydomonas moewusii

Summary We report the cloning and physical mapping of the mitochondrial genome of Chlamydomonas eugametos together with a comparison of the overall sequence structure of this DNA with the mitochondrial genome of Chlamydomonas moewusii, its closely related and interfertile relative. The C. eugametos mitochondrial DNA (mtDNA) has a 24 kb circular map and is thus 2 kb larger than the 22 kb circular mitochondrial genome of C. moewusii. Restriction mapping and heterologous fragment hybridization experiments indicate that the C. eugametos and C. moewusii mtDNAs are colinear. Nine cross-hybridizing restriction fragments common to the C. eugametos and C. moewusii mtDNAs, and spanning the entirety of these genomes, show length differences between homologous fragments which vary from 0.1 to 2.3 kb. A 600 bp subfragment of C. moewusii mtDNA, within one of these conserved fragments, showed no hybridization with the C. eugametos mtDNA. Of the 73 restriction sites identified in the C. eugametos and C. moewusii mtDNAs, five are specific to C. moewusii, eight are specific to C. eugametos and 30 are common to both species. Hybridization experiments with gene probes derived from protein-coding and ribosomal RNA-coding regions of wheat and Chlamydomonas reinhardtii mtDNAs support the view that the small and large subunit ribosomal RNA-coding regions of the C. eugametos and C. moewusii mtDNAs are interrupted and interspersed with each other and with protein-coding regions, as are the ribosomal RNA-coding regions of C. reinhardtii mtDNA; however, the specific arrangement of these coding elements in the C. eugametos and C. moewusii mtDNAs appears different from that of C. reinhardtii mtDNA.     

NRE,the major nitrogen regulatory protein of Penicillium chrysogenum,binds specifically to elements in the intergenic promoter regions of nitrate assimilation and penicillin biosynthetic gene clusters

NRE, the nitrogen regulatory protein of Penicillium chrysogenum, contains a single Cys2/Cys2-type zinc-finger motif followed immediately by a highly basic region. The zinc-finger domain was expressed to Escherichia coli as a fusion protein with -galactosidase. In order to test the putative DNA-binding ability of NRE, the intergenic promoter region of the nitrate reductase/nitrite reductase gene cluster (niiA-niaD) of Penicillium was sequenced. Our results show that NRE is a DNA-binding protein and binds to the intergenic promoter regions of the P. chrysogenum niiA-niaD and acvA-pcbC gene cluster, encoding the first two enzymes in penicillin biosynthesis. Three of the four high-affinity NRE-binding sites contained two GATA core elements. In one of the recognition sites for NRE, one GATA motif was replaced by GATT. The two GATA elements showed all possible orientations, head-to-head, head-to-tail and tail-to-tail, and were separated by between 4 and 27 bp. Missing-contact analysis showed that all three purines in both of the GATA core sequences and the single adenine residue in each of the complementary TATC sequences were involved in the binding of NRE. Moreover, loss of purines in the flanking regions of the GATA elements also affect binding of NRE, as their loss causes reduced affinity.     

Two group I mitochondrial introns in the cob-box and coxI genes require the same MRS1/PET157 nuclear gene product for splicing

Summary We have studied the role of the product of the nuclear gene PET157 in mitochondrial pre-mRNA splicing. Cytoduction experiments show that a mitochondrial genome deleted for the three introns bI3, aI5 and aI6 is able to suppress the pet157-1 mutation: the strain recovers respiratory competency indicating that the product of the PET157 gene is only required for mitochondrial premRNA splicing. Characterization of the high molecular weight pre-mRNAs which accumulate in the pet157 mutant demonstrate that the product of the PET157 gene is required for the excision of two group I introns bI3 and aI6 (corresponding to aI5) located in the cob-box and coxI genes respectively. Furthermore, the pet157 mutant strain accumulates the bI3 maturase in the form of a polypeptide of 50K (p50) previously observed in mitochondrial mutants defective in the excision of bI3. We have shown by restriction analysis and allelism tests that the pet157-1 mutation is allelic to the nuclear mrs1 mutation, previously described as specifically blocking the excision of bI3. Finally, revertants obtained by the deletion of bI3 or aI6 from the mitochondrial DNA were isolated from the MRS1 disrupted allele, confirming the involvment of the product of the MRS1/PET157 gene in the excision of the two introns bI3 and aI6.     

Inheritance of mitochondrial and chloroplast genome markers in backcrosses of Chlamydomonas eugametos x Chlamydomonas moewusii hybrids

Summary Southern blot analysis of AvaI-digested total cellular DNA from the interfertile species Chlamydomonas eugametos and Chlamydomonas moewusii with a coxI mitochondrial gene probe from Chlamydomonas reinhardtii revealed single hybridizing fragments of 5.0 and 3.5 kb, respectively. The transmission of these mitochondrial DNA physical markers along with that of chloroplast genetic markers for resistance to streptomycin and resistance to erythromycin was studied in the fourth backcrosses of F₁ hybrids to one or the other parent. Viability in these backcrosses is high in contrast to the cross C. eugametos x C. moewusii and its reciprocal which are associated with considerable meiotic product lethality. The resulting zygospores were found to transmit the mitochondrial and chloroplast genome markers uniparentally or preferentially from the mating-type-plus parent. Thus the species pair C. eugametos and C. moewusii differs from the pair Chlamydomonas reinhardtii and Chlamydomonas smithii in which mitochondrial genome markers are transmitted uniparentally by the mating-type minus parent, while the chloroplast genome markers are transmitted uniparentally by the opposite parental mating-type (Boynton et al. 1987).     

Physical evidence for recombination of chloroplast dna in hybrid progeny of Chlamydomonas eugametos and C. moewusii

Summary Differences in the restriction endonuclease fragmentation patterns of chloroplast DNA (cpDNA) from C. eugametos and C. moewusii have been used to study the inheritance of these DNAs in interspecific hybrids. Analysis of the cpDNAs from ten randomly selected F₁ hybrids, in each case revealed cpDNA to be recombinant for AvaI and BstEII restriction sites, although fragments characteristic of C. eugametos, the mt+ parent, were typically found in excess of those for C. moewusii, the mt– parent. In backcrosses between an F ₁ mt+ hybrid and C. moewusii mt–, seven randomly selected B₁ hybrids showed cpDNA restriction patterns either identical to or highly similar to that of the mt+ parent. We propose that cpDNA molecules are predominantly transmitted by the mt+ parent in both F₁ and B₁ generations but that selection favors survival of F₁ progeny with recombinant chloroplast genomes which avoid interspecific incompatibilities. On the surface, the inheritance of recombinant cpDNA contrasts with the simultaneous uniparental inheritance of two putative chloroplast markers (sr-2 and er-nM1 ⁺). However, it may be that these two markers are by chance associated with cpDNA sequences of the mt+ parent which were selected in all F₁ hybrids.     

The trans-spliced intron 1 in the psaA gene of the Chlamydomonas chloroplast: a comparative analysis

In the secondary structure model that has been proposed for the trans-spliced intron 1 in the Chlamydomonas reinhardtii psaA gene, a third RNA species (tscA RNA) interacts with the 5 and 3 intron parts flanking the exons to reconstitute a composite structure with several features of group-II introns. To test the validity of this model, we undertook the sequencing and modelling of equivalent introns in the psaA gene from other unicellular green algae belonging to the highly diversified genus Chlamydomonas. Our comparative analysis supports the model reported for the C. reinhardtii psaA intron 1, and also indicates that the 5 end of the tscA RNA and the region downstream from the psaA exon 1 cannot be folded into a structure typical of domain I as described for most group-II introns. It is possible that a fourth RNA species, yet to be discovered, provides the parts of domain I which are apparently missing.     

Intergenomic recombination of mitochondrial genomes in a somatic hybrid plant

Summary Restriction site polymorphisms between two parental mitochondrial (mt) genomes were used to characterize the novel mt genome present in a somatic hybrid plant. A cosmid clone containing mtDNA restriction fragments characteristic of both parental plant lines was identified in a library constructed from mtDNA of progeny of a somatic hybrid plant. Restriction mapping revealed the location of several restriction fragments derived from each of the parental mt genomes on the same cloned region of somatic hybrid mtDNA. This result is direct evidence that intergenomic recombination at the molecular level occurs in homologous regions of two parental mt genomes combined in the same plant cell by protoplast fusion.     

Splicing and evolution of an unusually small group I intron

Introns are common in the rRNA gene loci of fungal genomes, but biochemical studies to investigate splicing are rare. Here, self-splicing of a very small (67 nucleotide) group I intron is demonstrated. The PaSSU intron (located within the rRNA small subunit gene of Phialophora americana) splices in vitro under group I intron conditions. Most group I ribozymes contain pairing regions P1-P10, with a conserved G.U pair at the 5' splice site, and a G at the 3' intron border. The PaSSU intron contains only P1, P7, and P10. While it contains the G.U pair at the 5' splice, a U is found at the 3' end of the intron instead of a G. Phylogenetic analysis places it within subgroup IC1, whose members are found in the nuclear rRNA genes of fungi. The structural elements are similar to those in the centermost regions of other group I introns. Its size can be explained by a single large deletion that removed P2 through much of P9. Part of the original P9 region has assumed the function of P7. Its small size and genealogy makes it an excellent model to study RNA catalysis and evolution.     

Studies on mutants deficient in the photosystem I reaction centers in Chlamydomonas reinhardtii

Summary Genetic analysis of 25 nuclear mutants defective in the chlorophyll-protein complex CP1 was undertaken. The mutants belong to 13 complementation groups scattered throughout the nuclear genome. All these mutants lack the apoprotein of CP1 and, in addition, a specific set of six low molecular weight thylakoid polypeptides. System I particles obtained by treating WT thylakoid membranes with detergent specifically contain those polypeptides which the mutants lack. These observations suggest that a particular sub-structure of the thylakoid membrane associated with the photosystem I activity is missing from all 25 mutants studied, and that this general phenotype can result from mutation at any one of several unlinked Mendelian loci.     

DNA sequence analysis of the 24.5 Kilobase pair cytochrome oxidase subunit I mitochondrial gene from Podospora anserina: a gene with sixteen introns

Summary The DNA sequence of a 26.7 Kilobase pair (10³ base pairs = 1 Kb) region of the mitochondrial genomes of races s and A from Podospora anserina was determined. Within this region, the 24.5 Kb cytochrome oxidase subunit I gene was located and its exon sequences determined by computer analysis comparisons with other fungal genes. The Podospora COI gene was interrupted by two group II introns (one in race s) and fourteen group I introns ranging in size from about 2.2 Kb to 404 bp. Earlier studies on secondary structure analysis, as well as comparison of their open reading frames (ORFs), showed that the two group II introns were closely related. The fourteen group I introns were representatives of three subgroupings (IB, C and a new category, subgroup ID). Two of these group I introns were separated by just a single exon codon. The analysis of all these introns is discussed in comparison with other fungal introns as well as with the known Podospora anserina introns.     

Changes in chloroplast genome composition and recombination during the maturation of zygospores of Chlamydomonas reinhardtii

Summary In crosses of the unicellular green alga Chlamydomonas reinhardtii, the chloroplast genes are normally transmitted exclusively by the maternal parent to zygospore progeny. However, transmission of the paternal chloroplast alleles can be increased markedly by certain pretreatments of the maternal parent prior to mating. As zygospores age prior to induction of meiosis, they display decreased biparental transmission of chloroplast alleles and increased transmission of chloroplast alleles from only the maternal or paternal parent. In this report, chloroplast genome composition of biparental zygospores is shown to change in several ways during zygospore maturation. Allelic ratios of chloroplast genes within biparental zygospore clones become maternally or paternally skewed as the zygospores age, cotransmission of chloroplast alleles is reduced, and recombination increases, resulting in an expansion of genetic map distances between chloroplast markers used in this cross. The recovery of unequal frequencies of zygospore progeny expressing reciprocal recombinant genotypes confirms and extends other reports of the predominance of nonreciprocal recombination in organelle genetic systems.     

Studies on homologous recombination in the green alga Chlamydomonas reinhardtii

The introduction of exogenous DNA into the nuclear genome of Chlamydomonas reinhardtii occurs predominantly via non-homologous (illegitimate) recombination and results in integration at apparently-random loci. Using truncated and modified versions of the C. reinhardtii ARG7 gene in a series of transformation experiments, we demonstrate that homologous recombination between introduced DNA molecules occurs readily in C. reinhardtii, requires a region of homology of no more than 230 bp, and gives rise to intact copies of ARG7 in the nuclear genome. Evidence is presented for homologous recombination between introduced ARG7 DNA and the resident copy of the gene, and for the de-novo synthesis of the ARG7 sequence during transformation.     

The mitochondrial DNA of land plants: peculiarities in phylogenetic perspective

Land plants exhibit a significant evolutionary plasticity in their mitochondrial DNA (mtDNA), which contrasts with the more conservative evolution of their chloroplast genomes. Frequent genomic rearrangements, the incorporation of foreign DNA from the nuclear and chloroplast genomes, an ongoing transfer of genes to the nucleus in recent evolutionary times and the disruption of gene continuity in introns or exons are the hallmarks of plant mtDNA, at least in flowering plants. Peculiarities of gene expression, most notably RNA editing and trans-splicing, are significantly more pronounced in land plant mitochondria than in chloroplasts. At the same time, mtDNA is generally the most slowly evolving of the three plant cell genomes on the sequence level, with unique exceptions in only some plant lineages. The slow sequence evolution and a variable occurrence of introns in plant mtDNA provide an attractive reservoir of phylogenetic information to trace the phylogeny of older land plant clades, which is as yet not fully resolved. This review attempts to summarize the unique aspects of land plant mitochondrial evolution from a phylogenetic perspective.     

Transmission of chloroplast genes in crosses between Chlamydomonas reinhardtii diploids: Correlation with chloroplast nucleoid behavior in young zygotes

Summary In crosses between diploid strains of Chlamydomonas reinhardtii, the mode of chloroplast gene transmission was studied and correlated with the behavior of DAPI-stained chloroplast nucleoids in young tetraploid zygotes. Phenotypically plus (female) diploids with mating-type genotypes of mt ⁺/mt ⁺ or mt ⁺/0 (hemizygote) and phenotypically minus (male) diploids with genotypes of mt ⁺/mt ^– or mt ^–/mt ^– or 0/mt ^– were obtained by either crosses or polyethylene glycol induced somatic fusions between haploid strains. When crosses were made between mt ⁺/mt ⁺ or mt ⁺/0 and mt ^–/mt ^– or 0/mt ^–, the transmission of chloroplast genes occurred mostly from the female parent, indicating a typical maternal inheritance. In these cases the chloroplast nucleoids of one of the two parents disappeared within 2.5 h after mating. In contrast, when female diploids were crossed to mt ⁺/mt ^– male diploids, the chloroplast genes from both parents were transmitted to the progeny at equal frequency. The chloroplast nucleoids derived from the two parents were conserved for at least 2.5 h after mating. It is concluded that the chloroplast genes derived from the heterozygous male (mt ⁺/mt ^–) are protected from the degradation that takes place soon after zygote formation, by virtue of the presence of mt ⁺ gene although this allele is recessive with respect to the phenotypic expression of sexuality in diploids.     

Net synthesis of chloroplast DNA throughout the synchronized vegetative cell-cycle of Chlamydomonas

Summary The accumulation of chloroplast and nuclear DNAs during the 12 h light and 12 h dark synchronized vegetative cell-cycle of Chlamydomonas reinhardtii was monitored by the direct optical quantification of these DNAs in the analytical ultracentrifuge. Net synthesis of nuclear DNA was sharply discontinuous and this synthesis occurred during the first 6 h of the dark period. In contrast, the net synthesis of chloroplast DNA appeared continuous throughout the cell-cycle. The rate of this accumulation, however, was greatest in the dark period.     

Cytological demonstration of chloroplast DNA behavior during gametogenesis and zygote formation in Chlamydomonas reinhardtii

Summary We used the flourescent dye DAPI to visualize nucleoids of chloroplast DNA and follow their behavior through sexual reproduction by counting nucleoids in fixed cells at various stages. Nucleoid number varied greatly among cells at each stage. The mean number of nucleoids per cell was similar in mt ⁺ and mt ^– vegetative cells, and declined similarly during gametogenesis. Longer periods of nitrogen starvation reduced the mean nucleoid number further. Mean nucleoid number declined again in mating pairs, and continued to drop in zygotes up to the latest stage that can be examined (24-h zygotes). The oldest zygotes had means of about 2 to 3 nucleoids in different experiments, significantly fewer than in the mt ⁺ gametes (usually 4 to 5). The quantitative data on nucleoid number, mating efficiency, and germination efficiency allowed us to show that the decrease in nucleoid number is not limited to gametes that do not mate, or to zygotes that do not germinate. These data are consistant with earlier biochemical studies showing loss of chloroplast DNA during gametogenesis in both mating types, and with the degradation of paternal chloroplast DNA detected biochemically and (in non-quantitative studies) by DAPI staining. There may also be some fusion of nucleoids, although if it occurs it is not complete by 24 h of zygote maturation.