Plastid inheritance in Oenothera: organelle genome modifies the extent of biparental plastid transmission

Summary The transmission abilities of four out of the five major plastome types of Oenothera (I–V) were analyzed in a constant nuclear background by assessing both the frequency of biparental inheritance and the extent of variegation in the progeny. Reciprocal crosses were performed between plants carrying one of four wild-type plastomes and plants carrying one of seven white plastid mutants. The frequency of biparental plastid transmission ranged from 0 to 56% depending on the plastid types involved in the crosses. The transmission abilities of the four representative wild-type plastids appear to be in the order of I > III > II > IV in the nuclear background of O. hookeri str. Johansen. In general, variegated seedlings from crosses that produced a higher frequency of biparental plastid transmission also had an increased abundance of tissue containing plastids of paternal origin. Although the transmission abilities of most Oenothera plastid mutants are comparable to the wild-type plastids, three mutant plastids derived from species having different type I plastids show three distinguishable transmission patterns. This study confirms the significant role of the plastome in the process of plastid transmission and possibly in plastid multiplication. However, the hypothesis of differential plastid multiplication rates suggested by earlier studies can explain the results only partially. The initiation of plastid multiplication within the newly formed zygote also seems to be plastome-dependent.     

Plastid inheritance in Epilobium

Summary Interspecific hybrids of various Epilobium species have been produced in order to analyse plastid inheritance using restriction fragment polymorphisms of plastid DNA as markers. This analysis reveals that interspecific hybrids exhibit only the fragment pattern of the maternal plastome. Southern hybridization experiments using cloned species-specific plastid DNA fragments as markers confirm the maternal type of plastid inheritance in Epilobium, while providing at least a tenfold increase of sensitivity to detect restriction polymorphisms. Within the limit of detection even young seedlings contain no plastid DNA from the paternal parent. However, investigations of plastomes of large populations have provided evidence that a very low frequency of paternal plastid transmission can occur. Thus, the mechanism which ensures the elimination of paternal plastids is not 100% efficient. This suggestion is also supported by intraspecific reciprocal crosses between plants carrying mutant white and normal green plastids. While the offspring usually exhibit the maternal plastid type, a few cases indicate an apparent paternal plastid transmission.Abbreviations kbp kilobase pairs - ptDNA plastid DNA     

Cell type determines plastid transmission in tomato intergeneric somatic hybrids

Summary Mesophyll (M)- and suspension culture (S)-derived protoplasts of both Lycopersicon esculentum, tomato, and its wild relative Solanum lycopersicoides were fused as S+M, M+M and S+S combinations, respectively, to resolve the role of parental cell types in determining cpDNA transmission to intergeneric somatic hybrid plants. The mesophyll cpDNA was preferentially transmitted to 96% of the plants, each regenerated from a separate callus, in M+S and S+M fusion combinations. In contrast, for the M+M combination there was an equable distribution of either tomato cpDNA or that of S. lycopersicoides among the 34 hybrid plants. The number of plastids or proplastids in mesophyll or suspension protoplasts was not a factor regulating cpDNA transmission. Mesophyll or suspension protoplasts of both fusion partners had comparable frequencies of either plastid type with a mean of 23. The biased transmission of plastids from the mesophyll parent in somatic hybrid plants of S+M and M+S combinations appears to be due to differential multiplication of plastids, possibly conditioned by an unequal input of the nucleoids found in plastids versus proplastids. In the M+M fusion, plastid and nucleotid input and subsequent plastid multiplication are apparently equal, and when combined with random sorting out leads to an equal distribution of parental cpDNAs in the regenerated somatic hybrid plants. For the S+S combination, 22 somatic hybrid plants have exclusively tomato cpDNA, an outcome that is not readily explained by donor cell input.     

Light and benzylaminopurine induce changes in ultrastructure and gene expression in plastids of Petunia hybrida cell cultures

Summary The regulatory effect of light and the cytokinin 6-benzylaminopurine (BA) on the plastid ultrastructure and plastid DNA gene expression is studied in white and mutant green cell suspension cultures of Petunia hybrida. By electron microscopy we show that both light and 6-benzylaminopurine induce the formation of thylakoid membranes and grana structures in plastids of the green cultures. For membrane formation in plastids of white cultures, light in combination with BA is required. Light and benzylaminopurine also influence the plastid DNA gene expression. By in-organello protein synthesis with isolated plastids we show that light as well as benzylaminopurine affects the synthesis of plastid DNA encoded proteins. A characteristic effect of benzylaminopurine on plastids from white and green cultures is the reduction in the synthesis of the CFI subunits of 55,000 and 57,000 D, and the reduction in the synthesis of large polypeptides with a molecular weight higher than 67,000 D. In contrast to benzylaminopurine, light only affects the DNA gene expression of plastids from white cell cultures, that are in a very early stage of plastid development. Light stimulates the synthesis of polypeptides with a molecular weight of 84,000, 70,000 and 46,000 D which are encoded by cpDNA in these white culture plastids. In green cell cultures both plastids with a etioplast-like phenotype and with a chloroplast like morphology synthesize similar polypeptides, resulting in the same polypeptide pattern. Our results indicate that qualitative differences in plastid DNA gene expression as an effect of light do occur but only in plastids at very early stages of chloroplast development. We observe a gradual reduction in the number of high molecular weight polypeptides at later stages of chloroplast development. This suggests that these large polypeptides are characteristic for plastids at an early developmental stage.Abbreviations LSU of RuBPCase large subunit of Ribulose-1, 5-bisphosphate carboxylase - CF₁ coupling factor of the ATPase complex - LCH chlorophyll a/b protein - BA 6-benzylaminopurine - cpDNA chloroplast DNA     

Non-random plastid segregation in somatic hybrids of Datura innoxia with several other Solanaceous species

Summary A non-random plastid segregation was found in somatic hybrids of Datura innoxia with seven different Solanaceous species. 14 out of 17 examined somatic hybrids showed the plastid features of Datura innoxia. Within the limits of sensitivity of the applied methods, one line could be shown to contain mixed plastids. Since sexual offspring of this line contains only one set of plastids, it is assumed that this is probably a periclinal chimaera due to the plastome, i.e., the plastid mixture is present on a plant rather than a cell level.     

Structure and expression of cytochrome f in an Oenothera plastome mutant

Summary The chloroplast mutant pm7 is one of a number of mutants derived from the plastome mutator (pm) line of Oenothera hookeri, strain Johansen. Immunoblotting showed that this mutant accumulates a protein that is cross-antigenic with cytochrome f, but five kilodaltons larger than the mature wild-type protein. Since cytochrome f is known to be translated on plastid ribosomes as a precursor with an amino-terminal extension, it is proposed that the unprocessed cytochrome f precursor accumulates in pm7. In addition to this precursor-sized cytochrome f protein, some mature-sized cytochrome f was also found in the mutant plastids. The pm7 mutation is inherited in a non-Mendelian fashion; but no alterations in chloroplast DNA restriction patterns, or differences in DNA sequence in the region encoding cytochrome f, were found in a comparison of the wild-type and pm7 chloroplast DNAs. Although the mutant was capable of synthesizing heme, no covalently-bound heme, normally found associated with mature, functional, cytochrome f was detected in the mutant at sizes expected for the presumed precursor, or for mature cytochrome f. These results indicate that the aberrant accumulation of a precursor-sized cytochrome f in pm7 is not due to a lesion directly in the plastid gene encoding cytochrome f, petA, or to a deficiency in the ability of the mutant plastids to synthesize or accumulate heme.     

Paternal plastid inheritance in alfalfa: plastid nucleoid number within generative cells correlates poorly with plastid number and male plastid transmission trength

Summary A previous study on alfalfa determined that the number of plastids/generative cell does not necessarily correlate with male plastid transmission strength in a given genotype. The objectives of the present study were to learn (1) whether plastid nucleoid number/generative cell is comparable to the number of plastids/generative cell, and (2) whether plastid nucleoid number/generative cell correlates with known male plastid transmission behavior in three alfalfa genotypes. Our results, which were based upon 150 generative cells examined by DAPI/epifluorescence microscopy, indicate that the mean plastid nucleoid number/generative cell is much less than the mean number of plastids/generative cell in genotype 7W (60 nucleoids/264 plastids) and genotype 301 (54 nucleoids/165 plastids). In genotype MS-5, mean plastid nucleoid number/generative cell (45) is similar to the mean number of plastids/generative cell (65). The significantly fewer plastid nucleoids/generative cell in MS-5, compared to that of 7W and 301, correlates positively with the relatively poor male plastid transmission strength of this genotype. However, the difference between the mean number of plastid nucleoids/generative cell in 7W and 301 is not significant, yet 301 is a much stronger transmitter of male plastids than is 7W.     

Control of organelle transmission in Chlorophytum

Summary In a study of pollen ultrastructure in Chlorophytum comosum plastids were found to be present and apparently unaltered in both vegetative and generative cells. These ultrastructural data are consistent with the biparental transmission of plastids in this genus. However, mitochondria appear degenerate when compared to leaf mitochondria, exhibiting small myelin-like figures in addition to an abnormal cristae system. Since the plastids are not degenerate in the pollen of this species it appears that the transmission genetics of the mitochondria are determined separately from that of the plastid in higher plants.     

Phylogenetic analysis of plastid origins based on secA sequences

We have generated secA sequence data from a number of photosynthetic prokaryotes and carried out a phylogenetic analysis using secA sequences from prokaryotes, green plants, and red and brown algae. We have studied the substitution patterns that give rise to the apparent phylogenetic structure. We show that the high AT content of the plastid sequences significantly affects the amino-acid composition. We also show that most of the apparent evidence for an edge separating red and brown plastids from green plants within the phylogenetic tree is due to differences in nucleotide composition. The remaining apparent evidence is likely to be due, at least in part, to differences in the distribution of sites free to vary. We discuss the implications of this study for hypotheses of plastid origins. Received: 21 May / 8 September 1998     

Sure facts and open questions about the origin and evolution of photosynthetic plastids.

Some eukaryotic groups carry out photosynthesis thanks to plastids, which are endosymbiotic organelles derived from cyanobacteria. Increasing evidence suggests that the plastids from green plants, red algae, and glaucophytes arose directly from a single common primary symbiotic event between a cyanobacterium and a phagotrophic eukaryotic host. They are therefore known as primary plastids. All other lineages of photosynthetic eukaryotes seem to have acquired their plastids by secondary or tertiary endosymbioses, which are established between eukaryotic algae, already containing plastids, and other eukaryotic hosts. Both primary and secondary symbioses have been followed by extensive plastid genome reduction through gene loss and gene transfer to the host nucleus. All this makes the reconstruction of the evolutionary history of plastids a very complex task, indissoluble from the resolution of the general phylogeny of eukaryotes.     

The peculiar distribution of class I and class II aldolases in diatoms and in red algae

Diatom plastids probably evolved by secondary endocytobiosis from a red alga that was up by a eukaryotic host cell. Apparently, this process increased the complexity of the intracellular distribution of metabolic enzymes. We identified genes encoding fructose-bisphosphate aldolases (FBA) in two centric (Odontella sinensis, Thalassiosira pseudonana) and one pennate (Phaeodactylum tricornutum) diatoms and found that four different aldolases are present in both groups: two plastid targeted class II enzymes (FBAC1 and FBAC2), one cytosolic class II (FBA3) and one cytosolic class I (FBA4) enzyme. The pennate Phaeodactylum possesses an additional plastidic class I enzyme (FBAC5). We verified the classification of the different aldolases in the diatoms by enzymatic characterization of isolated plastids and whole cell extracts. Interestingly, our results imply that in plastids of centric and pennate diatoms mainly either class I or class II aldolases are active. We also identified genes for both class I and class II aldolases in red algal EST databases, thus presenting a fascinating example of the reutilization and recompartmentalization of different aldolase isoenzymes during secondary endocytobiosis but as well demonstrating the limited use of metabolic enzymes as markers for the interpretation of phylogenetic histories in algae. The nucleotide sequences have been deposited at Genbank under the accession numbers AY116588, AY191866 and AY212505     

Lack of a functional plastid tRNACys gene is associated with loss of photosynthesis in a lineage of parasitic plants

Summary We recently reported that the gene for chloroplast tRNA^Cys(GCA) is a pseudogene in the plastid DNA of Epifagus virginiana, a non-photosynthetic parastic flowering plant in the family Orobanchaceae. Since this is the only tRNA^Cys gene in the plastid genome, and since Epifagus appears to possess a functional plastid translational apparatus, it seems probable that nuclear-encoded tRNAs are imported into plastids to effect translation. In this study we have surveyed species closely related to Epifagus to establish how widespread the loss of this tRNA gene has been. We find that Conopholis americana, another non-photosynthetic parasite, lacks the gene altogether, but that seven closely-related photosythetic plants (both parasitic and free-living) maintain an intact chloroplast tRNA^Cys gene. Thus, the tRNA^Cys gene appears to have become non-functional at the same time that photosynthetic ability was lost. This may be because the levels of putatively imported tRNAs are sufficient to meet the demands of plastid gene expression under nonphotosynthetic conditions only.     

Plastid genomes of the Rhodophyta and Chromophyta constitute a distinct lineage which differs from that of the Chlorophyta and have a composite phylogenetic origin,perhaps like that of the Euglenophyta

Summary A phylogenetic tree has been constructed from comparisons of entire 16S rRNA gene sequences from different prokaryotes and from several algal plastids. According to this study, and to previous work on the ribulose-1,5-bisphosphate carboxylase oxygenase (Rubisco) large and small subunit genes, we postulate that: (1) rhodophyte and chromophyte plastid genomes have a common, composite phylogenetic origin which implies at least two different ancestors, a cyanobacterial and a -proteobacterial ancestor; (2) chlorophyte (green algae and land plants) plastids have a cyanobacterial ancestor which probably differs from that of rhodophyte and chromophyte plastids, and in any case constitute a different lineage; (3) euglenophyte plastid genomes also seem to have a composite phylogenetic origin which involves two different lineages.     

rps10, unreported for plastid DNAs,is located on the cyanelle genome of Cyanophora paradoxa and is contranscribed with the str operon genes

Summary rps10, encoding the plastid ribosomal protein S10, is a nuclear gene in higher plants and green algae, and is missing from the large ribosomal protein gene cluster of chlorophyll b-type plastids that contains components of the prokaryotic S10, spc and alpha operons. The cyanelle genome of Cyanophora paradoxa is shown to harbor rps10 as another specific feature of its organization. However, this novel plastid gene is not contiguous with the genes of the S10 operon, but is adjacent to, and cotranscribed with, the str operon, a trait also found in archaebacteria.     

PCR analysis of pulsed-field gel electrophoresis-purified plastid DNA,a sensitive tool to judge the hetero-/homoplastomic status of plastid transformants

The genetic transformation of plastids of higher plants has developed into a powerful approach for both basic research and biotechnology. Due to the high copy number of the plastid genome per plastid and per cell, repeated cycles of shoot regeneration under conditions selective for the modified plastid chromosome are required to obtain transformants entirely lacking wild-type plastid genomes. The presence of promiscuous plastid DNA in nuclear and/or mitochondrial genomes that generally contaminate even gradient-purified plastid fractions reduces the applicability of the highly sensitive PCR approach to monitor the absence of residual wild-type plastid chromosomes in transformed lines. It is therefore difficult, or even impossible, to assess reliably the hetero- or homoplastomic state of plastid transformants in this manner. By analysing wild-type and transplastomic mutants of tobacco, we demonstrate that separation of plastid chromosomes isolated from gradient-purified plastid fractions by pulsed-field gel electrophoresis can overcome the problem of (co)amplification of interfering promiscuous plastid DNA. PCR analyses with primers specific for plastid, mitochondrial and nuclear genes reveal an impressive purity of such plastid DNA fractions at a detection limit of less than one wild-type plastid chromosome copy per ten transplastomic cells.     

Presence of a 16S rRNA pseudogene in the bi-molecular plastid genome of the primitive brown alga Pylaiella littoralis. Evolutionary implications

Summary The plastid genome of the brown alga Pylaiella littoralis (L.) Kjellm. is composed of two different circular DNA molecules: the largest carries two rrn operons, and the smallest, only one copy of both 16S and 23S rDNAs. 16S rDNA copies located on both molecules have been cloned and their nucleotide sequences determined: they are 65% homologous to one another. The expression of these genes was assayed by hybridizing in vivo labelled P. littoralis rRNAs to both clones, and specific oligonucleotides to total RNA from P. littoralis. Results indicate that the 16S rDNA copy located on the small molecule is a pseudogene. Comparisons of the functional gene with other 16S rRNA genes shows that chloroplasts from green plants emerged earlier from the cyanobacterial lineage than Euglena gracilis and Pylaiella littoralis plastids.