Restriction map and clone bank of tomato plastid DNA

Summary Tomato plastid DNA has been isolated from leaf chloroplasts andPst1 fragments cloned in the plasmid vector pUC8. Recombinant plasmids containing all but the largestPst1 fragment were identified by colony hybridisation. A restriction map of the plastid DNA for four restriction endonucleases was generated by digestion of the clonedPst1 fragments and by hybridisation to Southern blots. The plastid DNA is a circular molecule of 156.6–159.4 kbp with a large inverted repeat, and shows high conservation of restriction sites with plastid DNA from tobacco andPetunia.     

Restriction and gene maps of plastid DNA from Capsicum annuum

Summary Chloroplasts and chromoplasts were isolated from green and red fruits, respectively, of the bell pepper, Capsicum annuum var. Emerald giant. A comparison of the restriction patterns of DNAs isolated from these plastids was made using single and double digests by SacI, PvuII, PstI, and SalI and found to be indistinguishable. It is inferred therefore that the conversion of chloroplasts to chromoplasts in Capsicum annuum does not involve any large rearrangements of the plastid chromosome. A restriction map of Capsicum annuum plastid DNA was constructed using the same restriction enzymes in single digests and in all possible pair combinations. Overlapping restriction fragments were identified by digesting each product of a single digest with each of the other three enzymes. The resulting restriction map is similar to that of chloroplast DNA from other members of the Solanaceae with respect to most restriction sites. The genome size corresponds to 143 kbp. The locations of 24 genes, coding for ribosomal RNAs and for proteins of Photosystem I (PSI), Photosystem II (PSII), ATP synthase, cytochromes, the large subunit of ribulose-1,5-bisphosphate carboxylase-oxygenase (E.C. 4.1.1.29) (RuBPC), and ribosomal proteins were determined by probing Southern blots of Capsicum chloroplast DNA with probes of genes from spinach and tobacco. The gene locations are completely conserved with respect to those of other members of the Solanaceae and the majority of higher land plants.Abbreviations and notations atpA, atpB, atpE, and atpF genes for the , , , and I subunit, respectively, of ATP synthase - cpDNA chloroplast DNA - petA, petB, petD genes for cytochrome f, cytochrome b ₆, and subunit IV of cytochrome b ₆/f complex, respectively - psaA, psaB, psaC genes for the P₇₀₀ apoproteins - psbA gene for Q_B - psbB and psbC genes for the 51-kDa and 44-kDa proteins, respectively, of PSII - psbD gene for the Q_B-like polypeptide of PSII - psbE gene for cytochrome b ₅₅₉ - rbcL gene for the large subunit of RuBPC - rpl2 gene for ribosomal protein L2 - rpoA gene for the subunit of RNA polymerase - rps11, rps12 and rps19 genes for ribosomal proteins S11, S12, and S19, respectively - rps19 open reading frame for a protein with N terminus similar to that of S19 - RuBPC ribulose-1,5-bisphosphate carboxylase-oxygenase (E.C. 4.1.1.29) - trnH gene for histidine transfer RNA - URF39 and URF509 unidentified reading frames for polypeptides of 39 and 509 amino acids, respectively Gene names follow the convention of Hallick and Bottomley (1983)     

Points of rearrangements between plastid chromosomes: location of protein coding regions on broad bean chloroplast DNA

Summary By using genes from spinach and tobacco chloroplast DNA as probes we have localized 22 protein genes on a refined map of Vicia faba (broad bean) chloroplast DNA. The genes are rbcL, rpoA, psaA,B, psbA–E, atpA,B,E,FH,I, pet-A,B,D, and the ribosomal protein genes rp12, rps7, rps12, and rps19. In addition, we mapped sequences homologous to a conserved open reading frame previously found in an intron of a trnK gene. The results were used to map the relative positions of rearrangements that distinguish the broad bean and spinach plastid DNAs. By hybridization with small probes several regions on both DNAs with sequence homology to more than one chromosomal position were found. Intermediate segments are rearranged in broad bean relative to spinach. A spinach chloroplast DNA fragment that functions as an autonomously replicating sequence in yeast is shown to be missing in broad bean chloroplast DNA. This ars is located at a position in spinach DNA which has been a target for rearrangement in the broad bean chromosome. These results can be interpreted by assuming that the DNAs contain short repeat sequences at some conserved positions. We suggest a model for chloroplast DNA divergence assuming that short repeats exist which are the substrate for a recombination system. The few rearrangements between chloroplast chromosomes from a variety of plants may be explained as the result of selection against short repeats.Abbreviations Kbp 10³ base-pairs - IR large inverted repeat unit     

Cultivar variability for the presence of plastid DNA in pollen of Pisum sativum L.: implications for plastid transmission

Summary The mode of plastid transmission in the garden pea (Pisum sativum L.) was analyzed cytologically using the DNA-fluorochrome 4,6-diamidino-2-phenylindole (DAPI) in conjunction with epifluorescence microscopy. The reproductive cells of mature pollen obtained from 12 inbred lines and cv Early Alaska were examined for the presence or absence of DAPI-stained plastid DNA aggregates. Plastid DNA was detected in all 13 pea lines examined, although there was variability with regard to the percentage of pollen graines showing plastid DNA aggregates of generative cells (ranging from 3% in accession 82-12r to 65% in accession 82-14n). These cytological results may indicate genetic variability for plastic DNA inheritance in the garden pea. This paper is dedicated to the memory of Gerald A. Marx     

Genes for components of the chloroplast translational apparatus are conserved in the reduced 73-kb plastid DNA of the nonphotosynthetic euglenoid flagellate Astasia longa

The colourless, nonphotosynthetic protist Astasia longa is phylogenetically related to Euglena gracilis. The 73-kb plastid DNA (ptDNA) of A. longa is about half the size of most chloroplast DNAs (cpDNAs). More than 38 kb of the Astasia ptDNA sequence has been determined. No genes for photosynthetic function have been found except for rbcL. Identified genes include rpoB, tufA, and genes coding for three rRNAs, 17 tRNAs, and 13 ribosomal proteins. Not only is the nucleotide sequence of these genes highly conserved between A. longa and E. gracilis, but a number of these genes are clustered in a similar fashion and have introns in the same positions in both species. The results further support the idea that photosynthetic genes normally encoded in cpDNA have been preferentially lost in Astasia, but that the chloroplast genes coding for components of the plastid translational apparatus have been maintained. This apparatus might be needed for the expression of rbcL and also for that of still unidentified nonphotosynthetic genes of Astasia ptDNA.These sequence data will appear in the EMBL/Gen Bank/DDBJ nucleotide sequence data base under accession numbers X75651, X75652 and X75653     

Localisation of genes for components of photosystem II in chloroplast DNA from pea and wheat

Summary The genes for three components of photosystem II have been localised in chloroplast DNA from pea and wheat by hybridisation with gene-internal sequences from spinach chloroplast DNA. In both pea and wheat, the gene for the 51 kDa polypeptide is located close to the genes for cytochrome b-563 and the 15 kDa polypeptide of the cytochrome b-f complex. The genes for the D2 and 44 kDa polypeptides are located close together, approximately 55 kbp from the gene for the 51 kDa polypeptide, in both pea and wheat chloroplast DNA. The location and orientation of the genes for the D2 and 44 kDa polypeptides in wheat chloroplast DNA indicate that the rearrangement of the wheat genome with respect to the spinach genome is the result of at least two inversions.     

Deleted forms of plastid DNA in albino plants from cereal anther culture

Summary Wheat and barley albino plants derived from anther culture contain plastid genomes which have suffered deletion. DNA molecules of the size of unit genomes exist in these plants. In some cases these may be linear genomes. In all cases a region near the T8 fragment of barley or the corresponding region of the wheat plastid genome has been retained. This region may therefore represent sequences sufficient for replication.     

Localization of chloroplast ribosomal protein genes on Spirodela oligorhiza chloroplast DNA

Summary Three chloroplast ribosomal protein genes have been located on Spirodela chloroplast DNA. (1) rps14 was physically mapped at the central region of the large single copy region by heterologous hybridization with the corresponding gene of Marchantia chloroplast DNA. (2) Chloroplast ribosomal protein C-S23 was detected by immunoprecipitation with a polyspecific antiserum against 30S chloroplast ribosomal proteins among the in vitro translation products of mRNAs selected by Spirodela Pstl-D chloroplast DNA fragment. (3) We have previously reported that Spirodela BamHI-G chloroplast DNA fragment encodes a 14–15 kD 50S chloroplast ribosomal protein (Posno et al. 1985 Curr Genet 9 : 211–219). Here we show that the homologous Spinacia chloroplast DNA fragment Sa1I-9 additionally directs the synthesis of another 50S chloroplast ribosomal protein in a DNA dependent E. coli cellfree system. This was confirmed by molecular weight determination, immunoprecipitation and competition immunoprecipitation experiments. mRNA selection experiments revealed that this additional chloroplast ribosomal protein gene is present on Spirodela chloroplast DNA as well, but is not expressed in the E. coli cellfree system. The identity of this 50S chloroplast ribosomal protein could not be established unambiguously, since two-dimensional gel analysis revealed that this protein comigrated, depending on the experiment, with C-L11 (26 kD) or with C-L24 (17 kD).Abbreviations (k) bp (kilo)basepairs - cp chloroplast - IR inverted repeat - kD kilodalton - LSCR large single copy region - Mw molecular weight - r-protein ribosomal protein - RuBPCase ribulose-1,5-bisphosphate carboxylase - SDS sodium dodecyl sulphate - SSCR small single copy region     

Evidence for tissue-specific cytosine-methylation of plastid DNA from Zea mays

Summary Total DNA isolated from leaves, etiolated seedlings, roots, endosperm or embryos of Zea mays was digested separately with each of the restriction enzymes HpaII, MspI and HhaI, and the resulting fragment patterns, which were specific for the plastid rRNA operon, were analyzed by Southern hybridization. While most of the fragment patterns were consistent with previously established physical maps, the partial resistance shown by one HpaII site and one HhaI site, both of which reside in the 16S/23S rDNA spacer region, was observed in DNA isolated from embryo, root tissue and endosperm. The partially resistant HpaII site was susceptible to cleavage with restriction enzyme MspI. From this and from the known inhibition of restriction enzyme Hhal at methylated HhaI sites, we conclude that the partial resistance of the two sites is caused by C-specific methylation of plastid DNA in the respective tissues. The tissue specificity of this DNA methylation is likely to reflect a differential expression of plastome encoded genes.     

Physical maps of the two circular plastid DNA molecules of the brown algaPylaiella littoralis (L.) Kjellm

Summary Two circular molecules of different sizes, both belonging to the chloroplast DNA of the brown algaPylaiella littoralis, have been observed by electron microscopy (Dalmon et al. 1983). Clone banks representing 86% of the small chloroplast circular DNA molecule (58 kbp) and 69% of the large circular DNA molecule (133 kbp) have been established and used as tools in the construction of physical maps. Two rDNA operons have been mapped in a very small inverted repeat on the large circular molecule. One 16S rRNA pseudogene and one split 23S rRNA gene have been mapped on the small DNA molecule, far apart from each other. Using heterologous probes, genes for ten different proteins have also been located on these maps. Their arrangement on the large molecule is different from that found in higher plants and algae. Probes fromrbcL, psbA andrps19 genes hybridize to several separated fragments. Two of them (psbA andrps19) hybridize to both types of molecules.     

A circular 73 kb DNA from the colourless flagellate Astasia longa that resembles the chloroplast DNA of Euglena: restriction and gene map

Summary A 73 kbp circular DNA was isolated from the colourless euglenoid flagellate Astasia longa. Restriction sites of 12 restriction endonucleases were mapped on this DNA. Southern hybridization using plastid gene probes from Euglena, spinach and tobacco revealed sequence homologies to the genes coding for 16S and 23S ribosomal RNAs, elongation factor Tu (tufA) and the large subunit of ribulose-1,5-bisphosphate carboxylase (rbcL). The locations of these sequences on the restriction map were determined. Sequences homologous to chloroplast genes psaA, psbA, psbD, psbE and atpA are not present. The ribosomal RNA genes are organized in three tandem repeats, each containing one 23S and one 16S rRNA gene. In addition, there is one extra 16S rRNA gene. These results indicate the presence of a truncated form of a plastid DNA in Astasia.     

The rice psb-A chloroplast gene has a standard location

Summary The chloroplast DNA-encoded gene psbA codes for the 32 kD protein of photosystem II. It has been mapped in several monocots to a location in the large single copy segment very near to the end of one of the inverted repeats present in the chloroplast genome of most land plants. The psbA gene of rice has been located much further from the inverted repeat, suggesting that rice differs from related species in the location of this gene. Indirect evidence reported here suggests that this gene actually maps to the usual cereal location, at least in the seven varieties tested, which include representatives of three subspecies.     

DNA markers define plastid haplotypes in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

To identify genetic markers in the Arabidopsis thaliana plastid genome (ptDNA), we amplified and sequenced the rpl2-psbA and rbcL-accD regions in 26 ecotypes. The two regions contained eight polymorphic sites including five insertions and/or deletions (indels) involving changes in the length of A or T mononucleotide repeats and three base substitutions. The 27 alleles defined 15 plastid haplotypes, providing a practical set of ptDNA markers for the Columbia, Landsberg erecta and Wassilewskija ecotypes that are commonly used in genetic studies and also for the C24 and RLD ecotypes that are the most amenable for cell culture manipulations.     

Common features of three inversions in wheat chloroplast DNA

Summary We have determined the DNA sequences of regions involved in two of the three inversions known to have occurred during the evolution of wheat chloroplast DNA. This establishes the extent of the second largest of the three inversions. Examination of these sequences suggests that although short repeated sequences are present, the endpoints of the second and third inversions are not associated with repeated sequences as long as those associated with the first inversion. However the endpoints of all three inversions are all adjacent to at least one tRNA gene, and there is evidence that three of the tRNA genes have been subjected to partial duplication, possibly at the time of inversion. This suggests that tRNA genes might be involved with rearrangements of chloroplast DNA, as has also been postulated for mitochondrial DNA.     

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.     

Molecular analysis of mitochondrial DNA from tomato cell suspension cultures

Summary Mitochondrial DNA (mtDNA) from Lycopersicon esculentum was purified from cell suspension cultures. The DNA, isolated from mitochondria purified by two successive sucrose density gradients, was uncontaminated with nuclear DNA or DNA from proplastids. The total molecular weights of BamHI, BglI, and BglII fragments indicate a mitochondrial genome size of at least 270 kb. Cross hybridization between tomato mtDNA and cloned spinach plastid genes revealed some homology. In hybridization experiments using cloned mitochondrial rRNA genes and BamHI digested total mtDNA the presence of recombination repeats is demonstrated.     

Physical mapping of genes for chloroplast DNA encoded subunit polypeptides of the ATPsynthase complex from Petunia hybrida

Summary Escherichia coli minicells harbouring the cloned restriction fragment Sall S9 from P. hybrida chloroplast DNA synthesize the beta and epsilon polypeptide subunits of the CF₁ component of the chloroplast ATPsynthase complex. The polypeptides were identified by molecular weight determination and immunoprecipitation. The position of the atpB and the atpE gene, encoding respectively the beta and epsilon subunit, on the Sall S9 fragment was determined in more detail by studying polypeptide synthesis directed by subclones of the S9 fragment in E. coli minicells. The atpB and atpE genes are located close to the rbcL gene, the distance between the rbcL gene and atpB gene being approximately 770 bp. Analysis of the expression of subclones of the S9 fragment in E. coli minicells also revealed that the atpE gene can be transcribed and translated independently of the expression of the atpB gene.The location of the genes coding for the alpha subunit (atpA gene) and the proteolipid subunit III of CF₀ (atpH) of the ATPsynthase complex on the physical map of P. hybrida cpDNA was determined by hybridization of restriction enzyme digests of petunia cpDNA with cloned cpDNA fragments from Spirodela and wheat, containing internal parts of respectively the atpA and the atpH gene. The two genes map close together within a region of 5.2 kbp on the physical map of P. hybrida cpDNA. The distance between the atpA gene and the atpB and atpE genes is approximately 42 kbp.Abbreviations cpDNA chloroplast DNA - rbcL gene coding for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase - CF₁ coupling factor, extrinsic part of the chloroplast ATPsynthase complex - kbp kilo base pairs     

Plastid DNA from Pyrenomonas salina (Cryptophyceae): physical map,genes, and evolutionary implications

Summary Cryptomonads are thought to have arisen from a symbiotic association between a eukaryotic flagellated host and a eukaryotic algal symbiont, presumably related to red algae. As organellar DNAs have proven to be useful tools in elucidating phylogenetic relationships, the plastid (pt) DNA of the cryptomonad alga Pyrenomonas salina has been characterized in some detail. A restriction map of the circular 127 kb ptDNA from Pyrenomonas salina was established. An inverted repeat (IR) region of about 5 kb separates two single-copy regions of 15 and 102 kb, respectively. It contains the genes for the small and large subunit of rRNA. Ten protein genes, coding for the large subunit of ribulose-1,5-bisphosphate carboxylase, the 47 kDa, 43 kDa and 32 kDa proteins of photosystem II, the ribosomal proteins L2, S7 and S11, the elongation factor Tu, as well as the - and -subunits of ATP synthase, have been localized on the restriction map either by hybridization of heterologous gene probes or by sequence homologies. The gene for the plastidal small subunit (SSUr) RNA has been sequenced and compared to homologous SSU regions from the cyanobacterium Anacystis nidulans and plastids from rhodophytes, chromophytes, euglenoids, chlorophytes, and land plants. A phylogenetic tree constructed with the neighborliness method and indicating a relationship of cryptomonad plastids with those of red algae is presented.