Isolation, characterization and restriction endonuclease mapping of the Petunia hybrida chloroplast DNA

Stable plastid transformation of petunia

Petunia hybrida is a commercial ornamental plant and is also an important model species for genetic analysis and transgenic research. Here we describe the steps required to isolate stable plastid transformants in P. hybrida using the commercial Pink Wave cultivar. Wave cultivars are popular spreading Petunias sold as ground cover and potted plants. Transgenes introduced into P. hybrida plastids exhibit stable expression over many generations. The development of plastid transformation in P. hybrida provides an enabling technology to bring the benefits of plastid engineering, including maternal inheritance and stable expression of performance-enhancing trait genes, to the important floriculture and horticulture industries.

Analysis of variation in chloroplast DNA sequences

This chapter introduces and reviews methods for analyzing variation in chloroplast DNA, mainly by polymerase chain reaction (PCR) and subsequent revelation of polymorphisms. Sources for chloroplast primers are discussed, as well as methods such as Sanger sequencing, PCR followed by restriction fragment length polymorphism (RFLP), gel electrophoresis, fragment analysis on automated DNA sequencers, denaturing high-performance liquid chromatography (dHPLC), and next-generation sequencing (NGS). A special section deals with peculiarities of chloroplast DNA variation, such as tandem repeats and mini- and microsatellites.

Chloroplast DNAs of Spinacia, Petunia and Spirodela have a similar gene organization

We have located the positions of the genes coding for the α, β and ε subunits of the ATPase complex on Spirodela oligorhiza chloroplast DNA by means of heterologous hybridization with Spinacia cpDNA fragments.The overall cpDNA sequence organization of Petunia hybrida and Spirodela was compared. We hybridized well-characterized, cloned Spirodela cpDNA fragments with size fractionated Petunia cpDNA digested by Sall. It appears that the monocotyledonous Spirodela and the dicotyledonous Petunia cpDNA share a common sequence organization around their entire circumference. These observations, together with data reported in the literature, indicate a strikingly similar genetic organization of the chloroplast genome in widely divergent plants.

Mapping the Chloroplast DNA of Vicia faba

A complete clone bank representing the chloroplast DNA from Vicia faba has been constructed. A total of 15 fragments (10 Pst1, 1 Pst1-EcoR1 and 4 Sal1 fragments) were inserted into the vector pBR322 and transformed into the E. coli strain HB101. The cloned fragments were used as the main tools in constructing the physical map of Vicia faba for the restriction endonucleases Pst1, Kpn1 and Xho1. The identity of the cloned fragments was demonstrated by restriction analysis and blot hybridization. The information generated was used to construct the map. The 16S and 23S rRNA genes and the gene for the large subunit of ribulose-1,5-bisphosphate carboxylase have been positioned on the map using heterologous probes. The orientation of the gene for the large subunit of RuBP carboxylase has also been determined.

Rearrangements in the chloroplast genomes of mung bean and pea

We have mapped all the cleavage sites for the restriction endonucleases BstEII, Kpn I, Pst I, Pvu II, Sac I, Sal I, Sma I, and Xho I on the circular chloroplast chromosomes from mung bean and pea. The mung bean chloroplast genome measures 150 kilobase pairs (kb) in length; it includes two identical sequences of 23 kb that contain the ribosomal genes and are arranged as an inverted repeat separated by single-copy regions of 21 and 83 kb. The pea chloroplast genome is only 120 kb in size, has only one set of ribosomal genes, and does not possess any detectable repeated sequences. The mung bean inverted repeat structure is common to all other nonleguminous higher plant chloroplast genomes studied, whereas the pea structure has been found only in the closely related legume Vicia faba. We conclude from these data that loss of one copy of the inverted repeat sequence has occurred only rarely during the evolution of the Angiosperms, and in the case of the legumes after the divergence of the mung bean line from the pea-Vicia line. We present hybridization data indicating that rearrangements that change the linear order of homologous sequences within the chloroplast genome have been quite frequent during the course of legume evolution.

Chloroplast DNA evolution and phylogenetic relationships in Lycopersicon

Chloroplast DNA was purified from 12 accessions that represent most of the species diversity in the genus Lycopersicon (family Solanaceae) and from 3 closely related species in the genus Solanum. Fragment patterns produced by digestion of these DNAs with 25 different restriction endonucleases were analyzed by agarose gel electrophoresis. In all 15 DNAs, a total of only 39 restriction site mutations were detected among 484 restriction sites surveyed, representing 2,800 base pairs of sequence information. This low rate of base sequence change is paralleled by an extremely low rate of convergent change in restriction sites; only 1 of the 39 mutations appears to have occurred independently in two different lineages. Parsimony analysis of shared mutations has allowed the construction of a maternal phylogeny for the 15 accessions. This phylogeny is generally consistent with relationships based on morphology and crossability but provides more detailed resolution at several places. All accessions within Lycopersicon form a coherent group, with two of the three species of Solanum as outside reference points. Chloroplast DNA analysis places S. pennellii firmly within Lycopersicon, confirming recent studies that have removed it from Solanum. Red-orange fruit color is shown to be a monophyletic trait in three species of Lycopersicon, including the cultivated tomato, L. esculentum. Analysis of six accessions within L. peruvianum reveals a limited amount of intraspecific polymorphism which, however, encompasses all the variation observed in L. chilense and L. chmielewskii. It is suggested that these latter two accessions be relegated to positions within the L. peruvianum complex.

Complete cloning of the chloroplast genome of safflower in lambda EMBL3 and mapping of 23S and 16S rRNA genes

A recombinant DNA library was constructed from partial BamHI or MboI digests of safflower (Carthamus tinctorius L.) chloroplast DNA, in the BamHI site of lambda EMBL3. Seventeen lambda recombinants, selected by chromosome walking, were found to contain overlapping fragments of the entire chloroplast genome. These clones were mapped using single and double digests of BamHI, EcoRI and HindIII. cDNAs synthesized from isolated 16S and 23S chloroplast rRNAs were used to map the ribosomal RNA genes relative to physical maps of the above restriction enzymes. The mapped positions of the rRNA genes for the safflower chloroplast DNA are in good agreement with previously published data for tobacco, spinach and several other higher plants.

Transcriptional and post-transcriptional regulation of chloroplast gene expression in Petunia hybrida

To study the control of differential gene expression during plastid biogenesis in Petunia hybrida, we have investigated the in vivo translation and transcription of the rbc L gene, coding for the large subunit of ribulose bisphosphate carboxylase (LSU), and the psa A gene, coding for P700 chlorophyll-a apoprotein (AP700). Differential expression of these plastid-encoded genes was studied in two developmentally different plastid systems, proplastid-like organelles from the green cell suspension AK2401 and mature chloroplasts from green leaves. In vivo translation of rbc L and psa A transcripts was analysed using specific antibodies. Specific transcript levels were analysed using internal fragments of the rbc L and psa A genes. A standardization procedure was used so that a direct correlation could be made between the amount of products and gene copy number. In Petunia hybrida the amount of LSU polypeptides present in both plastid types does not correspond to the amount of specific mRNA for the gene. Although the rbc L transcripts are present in both plastid types, the LSU protein is only present in green leaf plastids and not in cell culture plastids. In vitro translation of isolated rbc L transcripts give similar results, thereby suggesting that differences in the primary structure of the transcripts are responsible for the observed discrepancy. In contrast to this, the amount of AP700 polypeptides does correspond to the amount of the psa A transcripts. Therefore, our results indicate that the expression of chloroplast genes during plastid biogenesis takes place on at least two different levels: expression of the rbc L gene is regulated post-transcriptionally while expression of the psa A gene is regulated at the transcriptional level.

Genetic analyses of Oryza species by molecular markers for chloroplast genomes

Relationships in a wide range of Oryza species (13 species) were analyzed using the large subunits (LS) of Fraction I protein (Rubisco) and the Bam HI restriction patterns of chloroplast DNA (ctDNA) as molecular markers. Four types of LS were detected by isoelectrofocusing with and without S-carboxymethylation. The close relation between AA and CCDD genome species was suggested by analyses of LS and ctDNA. Intraspecific variation in O. latifolia was detected at the levels of both LS and ctDNA. The LS of the BB, BBCC, and CC genomes and FF (O. brachyantha) were not distinguishable, although the native Rubisco of the latter was slightly different from those of the first three. It was also shown that O. australiensis, the only EE genome species, might have evolved differently than the other Oryza species.

Isolation and physicochemical characterization of mitochondrial DNA from cultured cells ofPetunia hybrida

Mitochondrial DNA ofPetunia hybrida was purified from cell suspension cultures. Up to 50% of the DNA could be isolated as supercoiled DNA molecules by CsCl-ethidium bromide density gradient centrifugation. The DNA purified from DNase-treated mitochondria bands at a single buoyant density of 1.760 gcm(-3) in neutral density gradients and runs on agarose gels as a single band with an apparent molecular weight exceeding 30 megadaltons (Md). Summing of the restriction endonuclease fragment lengths indicates a mitochondrial genome size of at least 190 Md. Electron microscopic analysis reveals the presence of a heterogeneous population of circular DNA molecules, up to 60 Md in size. Small circular DNA molecules, ranging in size from 2-30 Md are present, but unlike in cultured cells of other plant species they do not form discrete size classes and furthermore, they constitute less than 5% of the total DNA content of the mitochondria. The restriction endonuclease patterns of mitochondrial DNA do not qualitatively alter upon prolonged culture periods (up to at least two years).

Chloroplast biosystematics: chloroplast DNA as a molecular probe

The classification of plants has traditionally been dependent upon the comparative analysis of morphological and biochemical data. In this paper the use of molecular probe analysis of chloroplast DNA (ctDNA) is used to expand the data base used in taxonomic studies. Chloroplast DNA size, homogeneity, the global arrangement of ctDNA structure, gene content, gene cluster array and gene sequence determination are discussed as useful criteria in the analysis of phylogenetic relationships.

Physical mapping of plastid DNA variation among eleven Nicotiana species

Plastid DNA of seven American and four Australian species of the genus Nicotiana was examined by restriction endonuclease analysis using the enzymes Sal I, Bgl I, Pst I, Kpn I, Xho I, Pvu II and Eco RI. These endonucleases collectively distinguish more than 120 sites on N. tabacum plastid DNA. The DNAs of all ten species exhibited restriction patterns distinguishable from those of N. tabacum for at least one of the enzymes used. All distinctive sites were physically mapped taking advantage of the restriction cleavage site map available for plastid DNA from Nicotiana tabacum (Seyer et al. 1981). This map was extended for the restriction endonucleases Pst I and Kpn I. In spite of variation in detail, the overall fragment order was found to be the same for plastid DNA from the eleven Nicotiana species. Most of the DNA changes resulted from small insertions/deletions and, possibly, inversions. They are located within seven regions scattered along the plastid chromosome. The divergence pattern of the Nicotiana plastid chromosomes was strikingly similar to that found in the genus Oenothera subsection Euoenothera (Gordon et al. 1982). The possible role of replication as a factor in the evolution of divergence patterns is discussed. The restriction patterns of plastid DNA from species within a continent resembled each other with one exception in each instance. The American species N. repanda showed patterns similar to those of most Australian species, and those of the Australian species N. debneyi resembled those of most American species.

In vitro expression and characterization of the translation start site of the psbA gene product (QB protein) from higher plants

The psbA gene from higher plants, which codes for the atrazine herbicide binding protein of photosystem II (QB protein), has been recently sequenced by various laboratories. From these data there are two potential translation sites, one yielding a protein of 38,500 kd and another a protein of 34,500 kd. In the present study, cloned psbA gene sequences from maize, tobacco, and pea have been expressed in a highly defined E. coli in vitro transcription/translation system. In order to determine the start site of translation, we also have employed a simplified E. coli system designed to synthesize the first di- or tripeptide of the gene product. From these results, it is clear that the first ATG of the longest open reading frame of the psbA gene, that begins fMet-Thr, is not recognized in vitro. Instead, the next downstream Met at position 37 is the initiation site, since the expected dipeptide fMet-Ile is synthesized from all psbA clones. These data are in accord with the in vivo results that the gene product is a precursor protein of 34,500 kd.

Cloning of Petunia hybrida chloroplast DNA sequences capable of autonomous replication in yeast

Sequences from Petunia hybrida chloroplast DNA which have the property to promote autonomous replication in Saccharomyces cerevisiae were cloned in vector YIp5. Seven cloned chloroplast DNA fragments are localized at one of two different sites on the chloroplast genome. One site, arsA was mapped on a 1.8 Kb fragment at position 27.0-28.8 Kb on the P. hybrida chloroplast genome. The plasmids containing this arsA are stable both in yeast and E. coli. The other site, arsB, was shown to be very unstable and is located either in the small single copy region close to the inverted repeat or just in the inverted repeat. The functioning of these sequences as a possible origin of replication in vivo is discussed.

Nicotiana chloroplast genome : 6. Deletion and hot spot - a proposed origin of the inverted repeats

A physical map containing six restriction sites of the Nicotiana tabacum chloroplast genome, together with the BamHI maps of N. tabacum, N. otophora and N. knightiana, and the SmaI maps of N. acuminata, N. plumbaginifolia, N. langsdorffii, N. otophora, N. tabacum, N. tomentosiformis and N. knightiana was constructed. In Nicotiana chloroplast genomes, the most frequently observed variations are point mutations. Deletions are also detected. Most of the observed changes are confined to one area of the large single copy region, which is designated as the "hot spot". Based on the evidence obtained from Nicotiana chloroplast genomes, an origin of the inverted repeats in this genus is proposed. We suggest that the inverted repeats represent a vestige of what were once two identical, complete chloroplast genomes joined together in a head-to-head and tail-to-tail fashion, and that deletions generated the current chloroplast genome organization.

Chloroplast DNA evolution and the origin of amphidiploid Brassica species

The origin and evolution of a hybrid species complex in the genus Brassica (cabbage, turnip, mustard, rapeseed oil) has been explored through mutational analysis of the maternally inherited chloroplast genome. A detailed chloroplast DNA phylogeny enables identification of the maternal parent for most of the amphidiploids examined and permits quantitative resolution of the relative time of hybridization as well as the relative divergence of the diploid parents. Contradictory chloroplast and nuclear phylogenies obtained for two accessions of the amphidiploid B. napus (rapeseed oil) lead to the hypothesis that introgressive hybridization has also figured in their recent evolution.

Plastid gene expression in a yellow-green leaf mutant of Petunia hybrida

We have analyzed the morphology and gene expression in plastids of a yellow-green leaf mutant of Petunia hybrida (E 5059). Under normal light intensities (20,000 lx), yellow-green leaves develop with a typical proplastid morphology (few membranes, incomplete stacking). When such plants are grown under low light intensities (3,000 lx), the newly formed leaves are green. The plastids in these green leaves have a wild-type like chloroplast morphology (thylakoids and grana structure). Pre-existing green leaves remain green in 20,000 lx, indicating that chlorophyll is not degraded. An analysis of polypeptides synthesized in isolated plastids from the yellow-green and green leaves of this mutant plant shows several differences. In the yellow-green leaf plastids only a very small amount of the large subunit of ribulose-1,5-bisphosphate carboxylase (RuBPCase) is present, while in green plastids this polypeptide is present in much higher amounts. Hybridization experiments indicated that in plastids from the yellow-green leaves the mRNA coding for the large subunit polypeptide is present in much lower amounts than in plastids from the 3,000 lx green leaves of this mutant or in chloroplasts from wild type plants. These results indicate regulation at the mRNA level. Furthermore, in yellow-green leaf plastids eleven polypeptides are present with high molecular wieght (higher than 67,000 d). Five of them are synthesized by the yellow-green leaf plastid itself. Such high molecular weight polypeptides are also synthesized by proplastids isolated from white petunia cell suspension cultures, but are not synthesized by 3,000 lx green leaf plastids, or by isolated normal leaf chloroplasts. These results indicate that the synthesis of these polypeptides is specific for the proplastid stage of chloroplast biogenesis.

Restriction endonuclease analysis of chloroplast DNA in interspecies somatic Hybrids of Petunia

Restriction endonuclease cleavage pattern analysis of chloroplast DNA (cpDNA) of three different interspecific somatic hybrid plants revealed that the cytoplasms of the hybrids contained only cpDNA of P. parodii. The somatic hybrid plants analysed were those between P. parodii (wild type) + P. hybrida (wild type); P. parodii (wild type)+P. inflata (cytoplasmic albino mutant); P. parodii (wild type) + P. parviflora (nuclear albino mutant). The presence of only P. parodii chloroplasts in the somatic hybrid of P. parodii + P. inflata is possibly due to the stringent selection used for somatic hybrid production. However, in the case of the two other somatic hybrids P. parodii + P. hybrida and P. parodii + P. parviflora it was not possible to determine whether the presence of only P. parodii chloroplasts in these somatic hybrid plants was due to the nature of the selection schemes used or simply occurred by chance. The relevance of such somatic hybrid material for the study of genomic-cytoplasmic interaction is discussed, as well as the use of restriction endonuclease fragment patterns for the analysis of taxonomic and evolutionary inter-relationships in the genus Petunia.

Chloroplast DNA rearrangements are more frequent when a large inverted repeat sequence is lost

We examined the arrangement of sequences common to seven angiosperm chloroplast genomes. The chloroplast DNAs of spinach, petunia and cucumber are essentially colinear. They share with the corn chloroplast genome a large inversion of approximately 50 kb relative to the genomes of three legumes--mung bean, pea and broad bean. There is one additional rearrangement, a second, smaller inversion within the 50 kb inversion, which is specific to the corn genome. These two changes are the only detectable rearrangements that have occurred during the evolution of the species examined (corn, spinach, petunia, cucumber and mung bean) whose chloroplast genomes contain a large inverted repeat sequence of 22-25 kb. In contrast, we find extensive sequence rearrangements in comparing the pea and broad bean genomes, both of which have deleted one entire segment of the inverted repeat, and also in comparing each of these to the mung bean genome. Thus there is a relatively stable arrangement of sequences in those genomes with the inverted repeat and a much more dynamic arrangement in those that have lost it. We discuss several explanations for this correlation, including the possibility that the inverted repeat may play a direct role in maintaining a conserved arrangement of chloroplast DNA sequences.

Physical and gene mapping of chloroplast DNA from Atriplex triangularis and Cucumis sativa

A rapid and simple method for constructing restriction maps of large DNAs (100-200 kb) is presented. The utility of this method is illustrated by mapping the Sal I, Sac I, and Hpa I sites of the 152 kb Atriplex triangularis chloroplast genome, and the Sal I and Pvu II sites of the 155 kb Cucumis sativa chloroplast genome. These two chloroplast DNAs are very similar in organization; both feature the near-universal chloroplast DNA inverted repeat sequence of 22-25 kb. The positions of four different genes have been localized on these chloroplast DNAs. In both genomes the 16S and 23S ribosomal RNAs are encoded by duplicate genes situated at one end of the inverted repeat, while genes for the large subunit of ribulose-1,5-bisphosphate carboxylase and a 32 kilodalton photosystem II polypeptide are separated by 55 kb of DNA within the large single copy region. The physical and genetic organization of these DNAs is compared to that of spinach chloroplast DNA.

Conservation of sequence arrangement among higher plant chloroplast DNAs: molecular cross hybridization among the Solanaceae and between Nicotiana and Spinacia

Isolated, nick-translated Pvu II fragments of Nicotiana tabacum chloroplast DNA produce specific intra- and intergeneric hybridization signals with chloroplast DNA digests from several representatives of the Solanaceae. These data, along with similarities in restriction enzyme patterns, permit construction of physical maps for Nicotiana line 92 (a cytoplasmic substitution line), Atropa belladonna and Petunia parodii. Plastid-DNA map differences among the Solanaceae are shown to result from single base-pair substitutions as well as local deletions or insertions. Several of these differences of Nicotiana tabacum chloroplast DNA fragments to a chloroplast DNA digest of Spinacia oleracea defines a sequential arrangement of fragments for spinach DNA which is very similar to its published physical map. This is achieved although chloroplast-DNA restriction enzyme patterns from the two organisms are grossly dissimilar. Alignment differences which have been revealed involve the edges of the inverted repeat region where certain single copy stretches in tobacco have been duplicated in spinach.

A restriction map of the ribosomal RNA genes and the short single-copy DNA sequence of the pearl millet chloroplast genome

The chloroplast rDNA genes of pearl millet (Pennisetum americanum) have been cloned and physically mapped. The chloroplast genome of the pearl millet contains two identical rRNA genes located on DNA sequences that are inverted with respect to one another and separated by 12 kb of single-copy DNA. The rRNA genes were positioned on a restriction endonuclease map by using as hybridization probes specific cloned rDNA sequences from the chloroplast DNA of the alga Euglena gracilis. The 16S and 23S rRNA genes were shown to be approx. 2 kb from one another, and the 5S RNA gene is immediately adjacent to the 23S tRNA gene.

Cloning and mapping of the chloroplast DNA sequences for two messenger RNAs from mustard (Sinapis alba L.)

Restriction fragments of chloroplast (cp)DNA from mustard leaves were cloned in E. coli using pBR 322 as the vehicle. Cloned fragments containing the structural sequences for two polypeptides of 56,000 and 35,000 daltons were selected by a mRNA hybridization-translation procedure. The cloned mustard genes are structurally related to chloroplast genes from maize. They hybridize to the maize mRNAs for the large subunit of ribulosebisphosphate carboxylase and for the 34,500 dalton precursor to a membrane protein. The coding sequence on mustard cpDNA for the 56,000 dalton polypeptide is colinear with a 1,500 base pair transcript, and the sequence for the 35,000 dalton polypeptide is colinear with a 1,220 base pair transcript.