Characterization of chloroplast DNA in Chlamydomonas eugametos and C. moewusii and its inheritance in hybrid progeny

Summary The density, molecular weight, and cellular repetition of DNA molecules associated with the -DNA satellite of the interfertile algae Chlamydomonas eugametos and C. moewusii are reported. The similarities between these values and those for the chloroplast DNA (cpDNA) in the related alga Chlamydomonas reinhardtii indicate that these satellites represent cpDNA. The buoyant densities of C. eugametos and C. moewusii cpDNAs are indistinguishable from one another, as are those of their respective nuclear DNAs. These densities differ slightly from the densities of the homologous components of C. reinhardtii whole cell DNA. All three species differ with respect to additional minor satellite DNAs and low molecular weight DNAs of unknown cellular location.Differences in the Aval and Smal restriction endonuclease fragmentation patterns of C. eugametos and C. moewusii cpDNAs were employed to study the inheritance of cpDNA in an F1 hybrid which had inherited a non-Mendelian streptomycin resistance marker (sr-2) from the C. eugametos mating-type plus (mt ⁺) parent and in two homoplasmic mitotic segregants from a B 1 hybrid (F₁ × C. moewusii) which had been initially heteroplasmic for the resistance marker. Although the cpDNA patterns in the F1 hybrid were similar to those of the C. eugametos ml ¹ parent, important differences were noted which suggest that recombination between C. eugametos and C. moewusii cpDNA had occurred. Homoplasmic streptomycin resistant and sensitive mitotic segregants recovered from the B1 hybrid product reveal Aval restriction patterns similar to those of the respective resistant and sensitive parents. These data are consistent with the hypothesis that the sr-2 marker is located in cpDNA and that C. eugametos and C. moewusii cpDNA sequences can coexist in the same chloroplast and, at least sometimes, segregate without extensive recombination. The transmission of low molecular weight DNAs characteristic of C. moewusii but of unknown cellular origin shows no direct correlation with the transmission of the sr-2 marker.     

A group I intron in the chloroplast large subunit rRNA gene of Chlamydomonas eugametos encodes a double-strand endonuclease that cleaves the homing site of this intron

Summary During interspecific crosses between Chlamydomonas eugametos and Chlamydomonas moewusii, an optional group I intron of 955 base pairs (CeLSU· 5) in the C. eugametos chloroplast large subunit rRNA gene undergoes a duplicative transposition event which is associated with frequent co-conversion of flanking cpDNA sequences. In the present study, we show that the basic protein of 218 amino acids encoded by CeLSU· 5 could mediate the phenomenon of intron transposition, also called intron homing. We overexpressed the ORF specifying this protein in E. coli using expression vectors that contain a C. moewusii cpDNA sequence encompassing the intron homing site. The expression product was found to exhibit a double-strand DNA endonuclease activity that is specific for the homing site. This activity was detected in vivo by self-linearization of the expression plasmids.     

Uniparental inheritance of chloroplast DNA sequences in interspecific hybrids of Chlamydomonas

Summary The meiotic transmission of chloroplast DNA (cpDNA) was studied in crosses between two species of Chlamydomonas (C. moewusii and C. eugametos) which have substantial differences in cpDNA restriction patterns. The results provide a direct demonstration that cpDNA can be inherited in a uniparental pattern, paralleling the transmission of a uniparentally inherited antibiotic resistance marker. Thus, cpDNA could carry the uniparental genes of these species, but other extrachromosomal DNAs are not excluded as possible carriers. For example, C. moewusii was found to contain a set of low molecular weight (LMW) DNA species which cannot be detected in C. eugametos. These LMW DNA species are also transmitted uniparentally in the tetrads studied. Uniparentai transmission may not be an exclusive property of cpDNA in Chlamydomonas species.     

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).     

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.     

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.     

Transmission and recombination of chloroplast genes in asexual crosses of Chlamydomonas reinhardii

Summary Chlamydomonas reinhardii diploids homozygous for the plus mating-type (mt ⁺) allele were constructed via polyethylene glycol (PEG)-induced cell fusion to investigate the transmission of chloroplast genes.We used two methods to determine whether the fusion products (PEG diploids) had inherited chloroplast markers uniparentally or biparentally. One method (multiple clone analysis) was found to markedly improve the detection of biparental transmission. With this method the frequency of biparental PEG-induced diploids was comparable to that seen in sexual diploids. Multiple clone analysis also demonstrated that fusion products which showed biparental inheritance were an extremely heterogeneous group.In some crosses, pre-treatment of one parent with isolated flagella from cells of the opposite mating type was used. This pre-treatment has been reported to promote chloroplast gene transmission from the mt ⁺ parent in diploids produced by PEG fusion (Adams 1982). In our crosses flagellar pretreatment had no significant effect on chloroplast gene transmission or recombination frequences. A significant bias was found for the date a cross was performed, but neither parent preferentially transmitted its alleles in all crosses. This indicates the necessity of comparing data from treated and control crosses done on the same day. We conclude from our data that separate hypotheses are not required to explain biparental inheritance in sexual versus PEG-induced diploids. The absence of biased parental allelic ratios with PEG-induced biparental diploid clones underscores their usefulness for the study of biparental gene transmission.Supported by National Institutes of Health Fellowship F32 GM085 34     

Physical mapping of differences between the chloroplast DNAs of the interfertile algae Chlamydomonas eugametos and Chlamydomonas moewusii

Summary The chloroplast genomes from the interfertile green algae Chlamydomonas eugametos and C. moewusii have been compared in their overall sequence organization. Physical mapping of Aval, BstEII and EcoRI restriction sites on the C. moewusii chloroplast genome revealed that this 292 kilobase-pair (kbp) genome is 49 kbp larger than the C. eugametos genome. Heterologous fragment hybridizations indicated the same order of common sequence elements on the two algal genomes. Almost all of the 49 kbp size difference is accounted for by the presence of two large extra sequences in C. moewusii: a 21 kbp sequence in the inverted repeat and a 5.8 kbp sequence in the single copy-region bordering the 16S ribosomal RNA (rRNA) genes. In addition to these two major deletion/addition differences, 42 restriction site and fragment length differences (ranging from 100 to 500 base pairs) were mapped on the two algal genomes. Surprisingly, the greatest density of these differences was found to be confined within the inverted repeat, one of the most conserved regions of land plant chloroplast genomes.     

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.     

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.     

Loss of mt +-derived zygotic chloropiast DNA is associated with a lethal allele in Chlamydomonas monoica

Summary The Chlamydomonas monoica mutant allele mtl-1, is associated with the formation of nonviable zygospores following self-mating of the mutant strain. Furthermore, mtl-1 heterozygote populations show a 50% reduction in germination frequency and no transmission of a chloroplast antibiotic resistance marker carried by the mtl-1 parent. To determine whether the effects on zygospore viability and chloroplast gene transmission resulted from the direct involvement of the mtl-1 locus in the control of mt ⁺-directed uniparental inheritance of chloroplast DNA (cpDNA), we have used the DNA-specific fluorochrome DAPI to follow the fate of cpDNA during the maturation of zygotes. Throughout the first few hours after the initial fusion of gametes, the young zygotes show DAPI-fluorescent nucleoids distributed symmetrically around the region of nuclear fusion, and presumably located within both of the parental chloroplasts. Wild-type and mtl-1 mutant zygotes show similar early staining patterns. As the zygotes age, the staining patterns become asymmetric for the wildtype population, with all of the visible cytoplasmic nucleoids restricted to one side of the zygote. In contrast, mtl-1 homozygotes appear to lose cytoplasmic nucleoids from both sides of the zygote simultaneously and within 24 h are apparently devoid of cpDNA. By introducing a mutation which arrests cell fusion (and prevents plastid fusion), we can show that (1) the asymmetric nucleoid distribution in wildtype zygotes results from the loss of nucleoids from one gamete in each mating event, and (2) the additional loss of cpDNA in mtl-1 homozygotes does not require contact between parental plastids (thus the nuclease responsible for cpDNA degradation is not sequestered within the chloroplast of one gamete). We propose that the mtl-1 mutant strain is defective for a process which normally protects cpDNA of mt ⁺ origin.     

A nuclear mutant of Chlamydomonas that exhibits increased sensitivity to UV irradiation,reduced recombination of nuclear genes,and altered transmission of chloroplast genes

Summary Meiotic progeny of Chlamydomonas reinhardtii normally receive chloroplast genomes only from the mt ⁺ parent. However, exceptional zygotes, which transmit the chloroplast genomes of both parents or, more rarely, only those of the mt ^- parent, arise at a low frequency. Mutations at the mt ⁺-linked mat-3 locus were found previously to elevate the transmission of chloroplast genomes from the mt-parent, resulting in a much higher than normal frequency of exceptional zygotes. In this paper we demonstrate that an ultraviolet-sensitive nuclear mutation mapping at the uvsE1 locus, which is unlinked to mating type, also promotes chloroplast genome transmission from the mt ^- parent. This mutant, which was previously shown to reduce recombination of nuclear genes in meiosis, acts synergistically which the mat3-3 mutation to produce an extremely high frequency of exceptional zygotes. Through the use of restriction fragment length polymorphisms existing in the chloroplast genomes of C. reinhardtii and the interfertile strain C. smithii, we show that chloroplast DNA fragments from the mt ^- parent normally begin to disappear shortly after zygote formation. However, this process appears to be blocked totally in the absence of wild-type uvsE1 and mat-3 gene products. Our findings are consistent with the hypothesis that both gene products contribute to the mechanism responsible for uniparental inheritance of the chloroplast genome from the mt ⁺ parent.     

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.     

Chloroplast gene transmission in Chlamydomonas reinhardtii. A model for its control by the mating-type locus

Summary In sexual crosses of Chlamydomonas reinhardtii, genes residing in the chloroplast (cp) are most often transmitted from the mating-type plus (mt ⁺) parent only. Galloway and Goodenough (1985) proposed a model in which the mt locus (linkage group VI) is a complex region containing several genes involved in the control of both gametic differentiation and cp inheritance. The mt ⁺ locus contains: the sfu locus necessary for sexual fusion between gametes; the upp locus (uniparental plus) which controls cp gene inheritance and also perhaps zygote maturation; and the sad locus which functions in sexual adhesion. The mt ^– locus also contains a sad locus as well as a regulatory element (mid) necessary for the minus dominance in mt ⁺/mt ^– diploid gametes. This model has been extended to include new genetic functions linked to the mt ⁺ or mt ^– locus. In this new system, there is a group of genes (maps for mating-type plus structure), present in both plus and minus strains, controlling some mt ⁺ phenotypical traits as well as the synthesis of an activator of the cp DNA nuclease; two genes contained in the mt ^– locus — one (cge for cp genomic elimination) coding for a nuclease (in an inactive form) located in the chloroplast and another (mid) coding for a repressor of maps; one gene (upp) contained in the mt ⁺ locus, coding for a substance preventing the synthesis or the activity of the nuclease and perhaps also acting on the maps product. The model can be applied to explain the complex dominance/ recessivity relationships observed between the mt ⁺ and mt ^– alleles in heterozygous diploid gametes, the basis for mitotic vs meiotic zygote formation and the differences in transmission observed for these two physiologically distinct zygote classes. Application of the model for prediction of mutant phenotypes and the design of future experiments is also described.     

Extensive sequence rearrangements in the chloroplast genomes of the green algaeChlamydomonas eugametos andChlamydomonas reinhardtii

Summary We have compared the overall sequence organization of chloroplast DNA (cpDNA) from the unicellular green algaeChlamydomonas eugametos andChlamydomonas reinhardtii. Cloned restriction fragments whose locations are known on the chloroplast genome of one or the other alga were hybridized to Southern blots of cpDNA digests from both algae and the positions of hybridization signals were used to align the two algal cpDNA restriction maps. In agreement with the important biological differences reported betweenC. eugametos andC. reinhardtii, we found extensive sequence rearrangements and low overall sequence homology between the two cpDNAs. To explain the striking contrast between our results and the remarkable conservation reported for the sequence and the organization of angiosperm cpDNAs containing inverted repeats, we suggest that the divergence between theC. eugametos andC. reinhardtii chloroplast genomes simply reflects a longer time of separate evolution relative to the angiosperm lineages. However, we cannot exclude the possibility that the algal cpDNAs rearranged faster than angiosperm cpDNAs.     

Detection of chloroplast DNA by using fluorescent monoclonal anti-bromodeoxyuridine antibody and analysis of its fate during zygote formation in Chlamydomonas reinhardtii

Summary A monoclonal anti-bromodeoxyuridine antibody conjugated to fluorescein was used to detect the chloroplast nucleoids after specific incorporation of bromodeoxyuridine (BUdR) into the chloroplast DNA of Chlamydomonas reinhardtii. The incorporation of BUdR was enhanced by simultaneous treatment with fluorodeoxyuridine (FUdR). The method was applied to analyze the fate of chloroplast DNA in zygotes resulting from mating between BUdR-treated gametes (mt ⁺ or mt ^-) and untreated gametes of opposite mating-type. In crosses between wild-type strains, the nucleoids of mt ⁺ origin remained in the large majority of zygotes whereas those of mt ^- origin most often disappeared within the first hours following copulation. In crosses of the type mat-3 mt ⁺xwild-type mt ^- (the mat-3 mutation permits a high transmission of chloroplast genes from the mt ^- parent), the nucleoids of mt ^- origin were generally not eliminated which indicates that the mat-3 mutation prevents the selective destruction of paternal chloroplast DNA in the zygote.     

An optional group I intron between the chloroplast small subunit rRNA genes of Chlamydomonas moewusii and C. eugametos

Summary We report the presence of a 402 by group I intron in the chloroplast small subunit (SSU) rRNA gene of Chlamydomonas moewusii. The intron is inserted within the highly conserved 530 loop, at a site corresponding to positions 531–532 of the E. coli 16rRNA. Residues surrounding the insertion site almost certainly play an important role in ribosomal proofreading function as they proved to be protected by tRNAs in E. coli 16S rRNA (Moazed and Noller 1986; Stern et al. 1986). The C. moewusii intron revealed a secondary structure model which differs substantially from those of the typical subgroup IA and IB introns. This model, however, shows striking similarities with the structures of the C. reinhardtii chloroplast 23S rRNA gene intron (Rochaix et al. 1985), the S. cerevisiae mitochondrial COB3 intron (Holl et al. 1985) and the three introns of phage T4 in the nrdB, td and sunY genes (Shub et al. 1988). The SSU rRNA gene intron is absent from C. eugametos, an alga that is interfertile with C. moewusii. The presence/absence of the intron account for a 390 by restriction fragment length polymorphism between the two algal SSU rRNA genes, a polymorphic locus that is strictly co-inherited with a tightly linked streptomycin resistance mutation (sr-2) in interspecific hybrids between the two algae.     

Chloroplastic genomes of Ginkgo biloba and Chlamydomonas moewusii contain a chlB gene encoding one subunit of a light-independent protochlorophyllide reductase

We have cloned and sequenced a Chlamydomonas moewusii chloroplastic DNA fragment that includes a 563 amino-acid open reading frame (ORF563, chlB) presenting 89% amino-acid homology with ORF513 from Marchantia polymorpha. It is also homologous to ORF510 from Pinus thumbergii but includes two insertions absent in both M. polymorpha and P. thunbergii. The derived polypeptide is 54% similar to the product of bchB from Rhodobacter capsulatus, identified as one subunit of a light-independent NADH-protochlorophyllide reductase. We also isolated and sequenced an homologous chloroplastic gene from the gymnosperm Ginkgo biloba. Northern hybridizations performed on RNA isolated from synchronized Chlamydomonas eugametos cells showed higher expression between the tenth hour of light and the eighth hour of darkness, peaking during the first 2 h of darkness.     

Mutations at three different nuclear loci of Chlamydomonas suppress a defect in chloroplast psbD mRNA accumulation

In the photosynthetic chloroplast mutant PRB2A of Chlamydomonas reinhardtii the psbD mRNA is unstable. Three strains were isolated, in which the underlying site-directed mutation within the psbD 5′ UTR (untranslated region) is suppressed. In all three suppressors, psbD RNA levels and RNA 5′ maturation are restored to a varying extent, suggesting a tight coupling of RNA stabilization and 5′ processing. Expression of the psbA gene is not compromised in these strains. Genetic crosses revealed that the suppressor mutations affect three unlinked nuclear loci, which may encode new factors involved in psbD gene expression. Received: 30 August / 26 October 1999     

Chloroplast gene inheritance studied by somatic fusion in Chlamydomonas reinhardtii

Summary Somatic fusion between strains of Chlamydomonas containing complementing cell-wall and auxotrophic mutations, having the same mating-type (mt) and bearing chloroplast markers, have been performed to study the mode of chloroplast gene inheritance in the fusion products. About one third of the fusion products (mt ⁺/mt ⁺ or mt ^–/mt ^–) transmitted chloroplast markers from both parents (= biparental fusion products). The rest of the population was equally distributed between fusion products transmitting the chloroplast marker of one parent or the other (uniparental fusion products) exclusively. Incubation of the fusion products in the dark for 48 hours, immediately after the fusion, decreases the frequency of biparental fusion products. The results indicate that the general process of elimination of chloroplast alleles is independent of the presence of both mt ⁺ and mt ^– alleles in the cell. In contrast, directional elimination (i.e. preferential elimination of paternal chloroplast alleles) does appear to depend upon heterozygosity at the mt locus. These results are discussed in relation to the models which have been proposed to explain the maternal inheritance of chloroplast genes in Chlamydomonas.