Physical mapping of differences in chloroplast DNA of the five wild-type plastomes in Oenothera subsection Euoenothera

Hybrid variegation in the genus Pelargonium

1) The genetical and cytological analysis of crosses between the wild-type form 'Roseum' of Pelargonium zonale (L.) L 'Herit. ex Ait. and the hybrid species Pelargonium zonale hort. 'Stadt Bern'' revealed the occurrence of hybrid variegation in the genus Pelargonium 2) The plastids in the green-white variegated plants were sorted out in the quick apical way characteristic for Pelargonium chimera. Six types of periclinal chimeras could be observed. 3) The DNAs of the two different plastomes can be distinguished by restriction endonuclease analysis with EcoRl and BamHI. 4) The differences in the cleavage patterns allowed a detailed description of the process of sorting out of the two parental plastids types within the variegated hybrids on the level of their plastid DNA. In all cases observed the cleavage pattern of 'Roseum' plastid DNA was found in the green tissue and the pattern of 'Stadt Bern' plastid DNA in the white tissue. 5) From these results we draw the conclusion that there is a disharmony between the F1-hybrid nucleus and the plastome of Stadt Bern', which blocks the normal differentiation of 'Stadt Bern' plastids.

Chloroplast DNA from the fern Osmunda cinnamomea: physical organization, gene localization and comparison to angiosperm

Chloroplast DNA from the fern Osmunda einnamomea was isolated by a sucrose gradient procedure utilizing PEG to stabilize chloroplasts. Analysis with the restriction endonucleases PvuII, Sacl and BstEII indicates a chloroplast genome size of 144 kb. A physical map of the fragments produced by these three enzymes was constructed by filter hybridizations using purified PvuII fragments as hybridization probes. The Osmunda chloroplast genome is circular and contains an inverted repeat 8-13 kb in size.Gene probes from tobacco, corn and spinach were used to map the positions of six genes on the Osmunda chloroplast chromosome. The 16S and 23S ribosomal RNAs are encoded by duplicate genes which lie within the inverted repeat. Genes for the large subunit of ribulose-1,5-bisphosphate carboxylase, a photosystem II polypeptide, and the alpha and beta subunits of chloroplast coupling factor are located in three different segments of the large single copy region.The Osmunda chloroplast genome is remarkably similar in size, conformation, physical organization, and map positions of known genes, to chloroplast DNA from a number of angiosperms. The major difference between chloroplast DNA from this fern and angiosperms is that the inverted repeat is smaller in Osmunda (8-13 kb) than in angiosperms (22-25 kb).

Transfer RNAs and tRNA genes of Vicia faba chloroplasts

Isolated chloroplasts from broad bean and common bean were found to contain a minimum of 31 and 32 tRNA species, respectively. These individual chloroplast tRNAs were (32)P-labeled in vitro and hybridized to DNA fragments obtained upon digestion of broad bean and common bean chloroplast DNAs with various restriction endonucleases. At least 30 tRNA genes were localized on the physical maps of the two chloroplast genomes. Comparison of the broad bean tRNA gene map to that of common bean revealed DNA sequence rearrangements, such as inversions, insertions/ deletions and duplications, within these two members of the Legu minosae family.

Molecular marker systems for Oenothera genetics

The genus Oenothera has an outstanding scientific tradition. It has been a model for studying aspects of chromosome evolution and speciation, including the impact of plastid nuclear co-evolution. A large collection of strains analyzed during a century of experimental work and unique genetic possibilities allow the exchange of genetically definable plastids, individual or multiple chromosomes, and/or entire haploid genomes (Renner complexes) between species. However, molecular genetic approaches for the genus are largely lacking. In this study, we describe the development of efficient PCR-based marker systems for both the nuclear genome and the plastome. They allow distinguishing individual chromosomes, Renner complexes, plastomes, and subplastomes. We demonstrate their application by monitoring interspecific exchanges of genomes, chromosome pairs, and/or plastids during crossing programs, e.g., to produce plastome-genome incompatible hybrids. Using an appropriate partial permanent translocation heterozygous hybrid, linkage group 7 of the molecular map could be assigned to chromosome 9.8 of the classical Oenothera map. Finally, we provide the first direct molecular evidence that homologous recombination and free segregation of chromosomes in permanent translocation heterozygous strains is suppressed.

The complete nucleotide sequences of the five genetically distinct plastid genomes of Oenothera, subsection Oenothera: I. sequence evaluation and plastome evolution

The flowering plant genus Oenothera is uniquely suited for studying molecular mechanisms of speciation. It assembles an intriguing combination of genetic features, including permanent translocation heterozygosity, biparental transmission of plastids, and a general interfertility of well-defined species. This allows an exchange of plastids and nuclei between species often resulting in plastome-genome incompatibility. For evaluation of its molecular determinants we present the complete nucleotide sequences of the five basic, genetically distinguishable plastid chromosomes of subsection Oenothera (=Euoenothera) of the genus, which are associated in distinct combinations with six basic genomes. Sizes of the chromosomes range from 163 365 bp (plastome IV) to 165 728 bp (plastome I), display between 96.3% and 98.6% sequence similarity and encode a total of 113 unique genes. Plastome diversification is caused by an abundance of nucleotide substitutions, small insertions, deletions and repetitions. The five plastomes deviate from the general ancestral design of plastid chromosomes of vascular plants by a subsection-specific 56 kb inversion within the large single-copy segment. This inversion disrupted operon structures and predates the divergence of the subsection presumably 1 My ago. Phylogenetic relationships suggest plastomes I-III in one clade, while plastome IV appears to be closest to the common ancestor.

Chloroplast genome characterization in the red alga Griffithsia pacifica

It has been suggested that cyanobacteria served as the ancestors for rhodophytic algae whose chloroplasts contain chlorophyll a and phycobilins, and that a rodophyte served as the plastid source for chromophytic plants that contain chlorophylls a and c. Although organellar DNA has been used to assess phylogenetic relatedness among terrestrial plants and green algae whose chloroplasts contain chlorophylls a and b, few data are presently available on the molecular profile of plastid DNA in chromophytes or rhodophytes. In this study the chloroplast genome of the rhodophytic, filamentous alga Griffithsia pacifica has been characterized. DNA was purified from isolated chloroplasts using protease k treatment and sodium dodecyl sulfate lysis followed by density centrifugation in Hoechst-33258 dye-CsCl gradients. Single and double restriction enzyme digests demonstrate that the DNA prepared from purified chloroplasts has a genome size of about 178 kilobase pairs (kb). A restriction map of this chloroplast genome demonstrates that it is circular and, unlike the chloroplast DNA (cpDNA) in most other plants, contains only a single ribosomal DNA operon. DNA was also purified from the mitochondria that co-isolated with chloroplasts. Mitochondrial DNA consists of molecules that range in size from 27 to 350 kb based on restriction endonuclease digestion and electron microscopic analysis.

Coordination of nuclear and chloroplast gene expression in plant cells

Plastid proteins are encoded in two genomes, one in the nucleus and the other in the organelle. The expression of genes in these two compartments in coordinated during development and in response to environmental parameters such as light. Two converging approaches reveal features of this coordination: the biochemical analysis of proteins involved in gene expression, and the genetic analysis of mutants affected in plastid function or development. Because the majority of proteins implicated in plastid gene expression are encoded in the nucleus, regulatory processes in the nucleus and in the cytoplasm control plastid gene expression, in particular during development. Many nucleus-encoded factors involved in transcriptional and posttranscriptional steps of plastid gene expression have been characterized. We are also beginning to understand whether and how certain developmental or environmental signals perceived in one compartment may be transduced to the other.

Sequence variation in the putative replication origins of the five genetically distinct basic Euoenothera plastid chromosomes (plastomes)

Approximately 4,200 nucleotides of the 16S/23S rDNA spacer and the 5' region flanking the rrn operon of the plastid chromosomes representing the five basic, phylogenetically related Euoenothera plastomes were sequenced and compared. The sequences that harbor the putative replication origins are almost identical except for a 785-bp intercistronic segment between the genes for the 16S rRNA and trnI. Differences are mainly caused by insertions/deletions and duplications; the predicted potential for formation of quite extensive secondary structure differs among the plastomes. Unexpected intraplastome variation has also been noted. Furthermore, the sequence-based and published genetically deduced plastome pedigrees differ significantly.

Structural analysis of length mutations in a hot-spot region of wheat chloroplast DNAs

The hot-spot region related to length mutations in the chloroplast genome of the wheat group was precisely analyzed at the DNA sequence level. This region, located downstream from the rbcL gene, was highly enriched in A + T, and contained a number of direct and inverted repeats. Many deletions/insertions were observed in the region. In most deletions/insertions of multiple nucleotides, short repeated sequences were found at the mutation points. Furthermore, a pair of short repeated sequences was also observed at the border of the translocated gene. A sequence homologous with ORF512 of tobacco cpDNA was truncated in cpDNAs of the wheat group and found only in the mitochondrial DNA of Ae. crassa, suggesting the inter-organellar translocation of this sequence. Mechanisms that could generate structural alterations of the chloroplast genome in the wheat group are discussed.

Electron microscopic localization of replication origins in Oenothera chloroplast DNA

The origins of chloroplast DNA (cpDNA) replication were mapped in two plastome types of Oenothera in order to determine whether variation in the origin of cpDNA replication could account for the different transmission abilities associated with these plastomes. Two pairs of displacement loop (D-loop) initiation sites were observed on closed circular cpDNA molecules by electron microscopy. Each pair of D-loops was mapped to the inverted repeats of the Oenothera cpDNA by the analysis of restriction fragments. The starting points of the two adjacent D-loops are approximately 4 kb apart, bracketing the 16S rRNA gene. Although there are small DNA length variations near one of the D-loop initiation sites, no apparent differences in the number and the location of replication origins were observed between plastomes with the highest (type I) and lowest (type IV) transmission efficiencies.

Phylogenetic relationships in the stone fruit group of Prunus as revealed by restriction fragment analysis of chloroplast DNA

In order to clarify the genetic relationships among stone fruits, a restriction fragment analysis of chloroplast DNAs (cpDNAs) was applied to cultivated Prunus species, whose genetic diagnoses are difficult because of their heterogeneity and long life span. Chloroplast DNAs (cpDNAs) were extracted from leaves of nine stone fruit accessions covering six species of Prunus. A restriction fragment analysis was conducted by gel electrophoresis after digestion with these endonucleases. The genome sizes of the cpDNAs were about 135-139 kbp, and the fruits were classified into seven chloroplast genome types according to their restriction fragment patterns. Two peach cultivars and nectarine were found to harbor identical plastomes, differing from those of two wild peaches and the European plum. This suggests that two cultivated peaches (P. persica) did not receive the cytoplasm from the wild peaches, P. mira and P. davidiana. Phylogenetic relationships among these types were then estimated based on the shared common fragments among the species.

Distribution of restriction site polymorphism within the chloroplast genome of the genus Glycine, subgenus Soja

Restriction fragment length polymorphisms (RFLPs) have been used to detect intragenic sequence diversity in Glycine subgenus soja chloroplast DNA. The distribution of these RFLPs allow Glycine max and G. soja accessions to be grouped according to cytoplasmic genetic relatedness. DNA clones from mung bean chloroplast DNA were used to locate the RFLPs to specific regions of the chloroplast genome. In the course of the experiments, several previously unobserved RFLPs were also identified. At least six molecular changes were detected, including both restriction site loss or gain and insertion/deletion events. Three of the fragment polymorphisms detected are due to changes in the juncture region between one inverted repeat region and the large single-copy region. Probes detecting polymorphisms in three representative soybean genotypes were used to screen additional cultivars and Plant Introductions. The distribution of RFLP patterns in these accessions were consistent with the patterns of previously described cytoplasmic groupings, with the exception of one accession, which formed a new plastome group.

Assembly of Rubisco from native subunits

Large subunits of ribulosebisphosphate carboxylase/oxygenase (Rubisco) (3-phospho-D-glycerate carboxy-lyase (dimerizing), EC 4.1.1.39) from prokaryotic sources can assemble into intact enzyme either in vitro or in Escherichia coli cells. Large subunits of higher plant Rubisco do not assemble into Rubisco in E. coli cells, nor is it possible to reconstitute higher plant Rubisco from its dissociated subunits in vitro. This behavior represents an obstacle to any practical attempts at engineering the higher plant enzyme, and it suggests that the in vivo assembly mechanism of higher plant Rubisco must be more complex than is commonly expected for oligomeric proteins of organelles. In pea chloroplasts, a binding protein interacts with newly synthesized large subunits, in quantities expected for an intermediate in the assembly process, as judged by Western blotting. Radiotracer-labeled large subunits which interact with this binding protein can be shown to assemble into Rubisco in reactions which lead to changes in the aggregation state of the binding protein. Antibody to this binding protein specifically inhibits the assembly of these subunits into Rubisco. Rubisco synthesis appears to be subject to many types of control: gene dosage, transcription rate, selective translation of message, post-translational degradation and threshold concentration effects have been observed in various organisms' synthesis of Rubisco. The biochemical mechanisms underlying most of these effects have not been elucidated. The post-translational assembly mechanism in particular appears to require further study.

Diversity and evolution of chloroplast DNA in Triticum and Aegilops as revealed by restriction fragment analysis

Restriction fragment analysis of chloroplast (cp) DNAs from 35 wheat (Triticum) and Aegilops species, including their 42 accessions, was carried out with the use of 13 restriction enzymes to clarify variation in their cpDNAs. Fourteen fragment size mutations (deletions/insertions) and 33 recognition site changes were detected among 209 restriction sites sampled. Based on these results, the 42 accessions of wheat-Aegilops could be classified into 16 chloroplast genome types. Most polyploids and their related diploids showed identical restriction fragment patterns, indicating the conservatism of the chloroplast genome during speciation, and maternal lineages of most polyploids were disclosed. This classification of cpDNAs was principally in agreement with that of the plasma types assigned according to phenotypes arising from nucleus-cytoplasm interactions. These mutations detected by restriction fragment analysis were mapped on the physical map of common wheat cpDNA, which was constructed with 13 restriction endonucleases. Length mutations were more frequently observed in some regions than in others: in a 16.0 kilo base pairs (kbp) of DNA region, including rbcL and petA genes, 6 of 14 length mutations were concentrated. This indicates that hot spot regions exist for deletions/insertions in chloroplast genome. On the other hand, 33 recognition site mutations seemed to be distributed equally throughout the genome, except in the inverted repeat region where only one recognition site change was observed. Base substitution rate (p) of cpDNA was similar to that of other plants, such as Brassica, pea and Lycopersicon, showing constant base substitution rates among related taxa and slow evolution of cpDNA compared with animal mitochondrial DNA. Phylogenetic relationships among Triticum and Aegilops species were discussed, based on the present data.

Variation in copy number of a 24-base pair tandem repeat in the chloroplast DNA of Oenothera hookeri strain Johansen

A highly variable region of chloroplast DNA has been analyzed from three isolates of Oenothera hookeri strain Johansen. The variability results from the presence of two, four or seven copies of a discrete 24-base pair tandem repeat in a segment of the chloroplast DNA within the inverted repeat. Alignment of this DNA region with the published tobacco cpDNA sequence shows that in Oenothera, the repeats are insertions within a large unidentified reading frame, with each repeat unit specifying an eight amino acid in-frame addition. A model to explain the frequent alterations in the copy number of this 24-bp unit is proposed: imprecise alignment and recombination between the two large inverted repeats followed by copy correction could result in an amplification or deletion of the 24-bp segments.

Mitochondrial DNA variation in pearl millet and related species

Mitochondrial DNA (mtDNA) restriction endonuclease fragment patterns and patterns of mtDNA hybridized by mitochondrial gene probes were used to study phylogenetic relationships of seven Pennisetum species, including five P. americanum (pearl millet) ecotypes and a reference species from the distantly related genus, Panicum. The restriction patterns of the pearl millet ecotypes were uniform with the exception of the ecotype collected in Ethiopia. The probe hybridization method revealed more variability, with both the Rhodesian and Ethiopian ecotypes differing from the others and from each other. Considerable restriction pattern polymorphism was noted among different species of Pennisetum, and Panicum. Significant relationships were noted of Pennisetum polystachyon to P. pedicellatum and of P. purpureum to P. squamulatum using the restriction pattern method. In addition to those relationships, the hybridization method showed relationships of pearl millet to P. purpureum and to P. squamulatum. The relationships noted between species by the hybridization method agreed more closely to the cytological data than those indicated by the restriction pattern method. Therefore, the hybridization method appeared to be the preferred method for studying species relationships. The mitochondrial genome size of pearl millet was calculated to be 407 kb and the mitochondrial genome sizes of other Pennisetum species ranged from 341 to 486 kb.

Chloroplast DNA differences in the genus Oenothera subsection Munzia: a short direct repeat resembling the lambda chromosomal attachment site occurs as a deletion/insertion within an intron of an NADH-dehydrogenase gene

A small restriction fragment length mutation has been mapped in the large inverted repeats of the chloroplast (cp) DNA of Munzia-Oenothera species (vom Stein and Hachtel 1986). This mutation could be localized within the intron of a reading frame presumably coding for subunit B of an NADH-dehydrogenase (ndhB). Sequence analysis revealed a 24 bp duplication/deletion. The predicted secondary structure of the ndhB-intron is altered by this duplication/deletion. Part of the directly repeated segment shows remarkable similarity to the phage lambda attachment site. Evidence is presented for similar sequences in other plastome regions where deletions/insertions have been found. Furthermore, the locations of the genes for other components of the NADH-dehydrogenase (ndhA, ndhC, ndhD, ndhE, ndhF) were established by heterologous hybridization using gene probes from tobacco cpDNA.

Structural organization and evolution of the plastid genome of Vaucheria sessilis (Xanthophyceae)

The plastid DNAs of 18 Vaucheria sessilis strains from various habitats in western Europe were digested with the restriction endonucleases Eco RI, Sal I, Bam HI and Pvu II. Their restriction patterns showed variable fragment divergencies. Two main groups of plastid genomes were recognized, which were substantiated by morphological features. The differences among the restriction patterns could be attributed to the loss or appearance of restriction sites and to minor size variations caused by deletions/insertions. The Sal I and Bam HI restriction sites which together discriminate six different plastid genomes were mapped on the circular molecule of 124 kilobase paris (kbp). The plastid genomes of several Vaucheria sessilis strains were shown to exist in two inversion isomers caused by intramolecular recombination within the inverted repeat segments.

Insertion/deletion mutations in the Zea chloroplast genome

The chloroplast (cp) genomes of Zea species are distinguished by at least four restriction fragment length (insertion/deletion) mutations. All four mutations occur in the large unique sequence region of the genome. Restriction fragments containing three of these mutations were cloned. The large and small forms of two of the mutated fragments were sequenced. This revealed 80 and 83 bp insertion/deletions. The inserted/deleted segments are not parts of tandem repeats nor were they flanked by direct repeats. Two other insertion/deletion mutations were not sequenced, but their sizes were estimated to be 150 and 250 bp by size fractionation on agarose gels. Use of Tripsacum pilosum and Sorghum bicolor as outgroups suggests that three of the fragment length mutations arose via deletions. The fourth could not be polarized. The three species of section Luxuriantes of Zea were identical to one another for each of the four length mutations, and they were consistently distinguished from the taxa of section Zea by these mutations. These data support the division of Zea into the above named sections.

Beta chloroplast genomes: analysis of Fraction I protein and chloroplast DNA variation

The interrelationships of Beta chloroplast genomes have been investigated on the basis of the analysis of Fraction I protein and chloroplast (ct) DNA. Three groups of the chloroplast genomes could be demonstrated by the difference in isoelectric points of the large subunit of Fraction I protein. Restriction enzyme analysis revealed inter- and intra-specific variations among the ctDNAs, which enabled us to detect seven distinct ctDNA types. In Vulgares and Corollinae species, the observed differences were physically mapped taking advantage of the restriction fragment map available for sugar beet (B. vulgaris) ctDNA. The DNA variations were found to result either from gains or losses of restriction sites or from small deletions/ insertions, and most of them were located in the large single-copy region of the genome. Moreover, the ctDNAs from Patellares species are more diverged from those of other Beta taxa. Our results also indicate that there is a close correlation between the chloroplast genome diversity and the accepted taxonomic classification of the species included in this survey.

Polymorphism and gene arrangement among plastomes of ten Epilobium species

Plastid DNAs of ten different Epilobium species from four continents have been analysed using the restriction endonucleases BamHI, BglI, BglII, EcoRI, PstI, PvuII and SalI. With respect to the position of cleavage sites of those enzymes, each species has a specific plastome. Fragment patterns of different species from the same continent show a higher degree of similarity than those from different continents. Physical maps of the circular plastid DNA molecule have been constructed for each of the ten species by localising the cleavage sites of the enzymes BglI, PvuII and SalI. As in most other higher plants, the plastid DNA of Epilobium is segmentally organized into two inverted repeats separated by a large and a small single copy region. In heterologous hybridization experiments using radioactively labelled gene probes, the positions of structural genes coding for the rRNAs and for seven polypeptides have been determined. In contrast to its closest relative, Oenothera, the gene arrangement of Epilobium plastomes has the same order as in spinach. This indicates that changes in gene arrangement may be genus-specific and not the result of one or several events affecting all members of a plant family.

Location and nucleotide sequence of the pre-apocytochrome f gene on the Oenothera hookeri plastid chromosome (Euoenothera plastome I)

The gene for pre-apocytochrome f has been mapped by blot hybridization on a 2.4 kbp HindIII fragment of the circular plastid chromosome of Oenothera hookeri employing probes from the corresponding spinach gene. The gene is located distal to the gene for the ATP synthase subunit alpha, at the border of the 45 kbp inversion that distinguishes spinach and Oenothera plastid chromosomes. Both genes are transcribed in the same direction. Nucleotide sequence analysis reveals a single open reading frame encoding 318 amino acids of which 285 comprise the mature polypeptide and another 33 residues represent probably a N-terminal signal sequence. The putative pre-sequence is 2 residues shorter than those known from the spinach, wheat and pea protein. The deduced amino acid sequences of f cytochromes from the four plant species show over 80% conservation, maintaining the structural characteristics of the protein.

Cytochrome b-559 genes from Oenothera hookeri and Nicotiana tabacum show a remarkably high degree of conservation as compared to spinach. The enigma of cytochrome b-559: highly conserved genes and proteins but no known function

Recent data suggest that cytochrome b-559, an intrinsic membrane protein of the oxygen-evolving photosystem II in chloroplasts, is a heme cross-linked heteromeric polypeptide unit (Herrmann et al. 1984, FEBS Lett 176:239-244). The genes for this cytochrome, designated psbE and psbF, have been located on the chloroplast chromosome of Oenothera hookeri and Nicotiana tabacum by hybridization with fragments of the corresponding spinach genes, and characterized. In both cases, the nucleotide sequence discloses 2 uninterrupted reading frames of 83 and 39 codons separated by a few nucleotides, as in spinach. The amber translation stop codon of psbE overlaps the putative ribosome-binding site for psbF in all cases. The predicted molecular weights of the proteins are 9.2 and 4.3 kd, respectively. In each of the three plant species, and the direction of transcription is opposite to that of the gene for cytochrome f which is located distal to the b-559 genes. Comparison of the deduced amino acid sequences with those from the corresponding spinach genes shows 97% homology. The ubiquitous presence and remarkably high degree of structural and functional conservation of this gene cluster supports the hypothesis of a heteromeric assembly and an important functional role for cytochrome b-559.

Variation of plastid and mitochondrial DNAs in the genus Hedysarum

Plastid and mitochondrial DNAs from Hedysarum species of the western Mediterranean basin, H. spinosissimum ssp eu-spinosissimum, H. spinosissimum ssp capitatum, H. carnosum, H. coronarium and H. flexuosum, were compared by restriction endonuclease fragment analysis. ctDNA fragment patterns for ssp eu-spinosissimum and ssp capitatum were indistinguishable in different enzyme digests. An identical ctDNA variation was found in Hpa II digests with two Sardinian populations of ssp capitatum. Each of the two subspecies was characterized by specific mt DNA patterns with Pst I, Bam HI, Sma I and EcoRI. No variation was detected in populations of different geographical origins for a given subspecies. H. carnosum, H. coronarium and H. flexuosum generated specific ct and mt DNA patterns. Comparison of mitochondrial fragments indicated: - a strong homology between the two subspecies, - a closer homology among the three other diploids, each being closer to the other two than to H. spinosissimum subspecies - as was also the case for the plastid genomes.

The intergenic region between the Vicia faba chloroplast tRNA(CAALeu) and tRNA(UAALeu) genes contains a partial copy of the split tRNA(UAALeu) gene

A cluster of three tRNA genes located on fragment Bam6a from Vicia faba chloroplast DNA has been sequenced: it contains the genes for tRNA(CAALeu), tRNA(UAALeu) and tRNA(Phe). The two tRNA(Leu) genes are separated by 443 bp and are transcribed divergently from different DNA strands. The intergenic region contains a series of short repeats and a partial copy of the split tRNA(UAALeu) gene which includes 100 bp of the 5' flanking region, 35 bp of the 5'exon and the first 42 bp of the intron. It is possible that some of these duplications occurred upon the rearrangement of the two tRNA(Leu) genes in broad bean (and in pea) or upon the deletion of one copy of the inverted repeat, since in all other higher plant chloroplast genomes studied so far these two tRNA(Leu) genes are located far apart on the genome, one being in the inverted repeat region, the other one in the large single copy region. The tRNA(Phe) and tRNA(UAALeu) are encoded by the same DNA strand, and separated by 110 bp.

A 21 kilobase-pair deletion/addition difference in the inverted repeat sequence of chloroplast DNA from Chlamydomonas eugametos and C. moewusii

Our recent physical mapping of chloroplast DNA (cpDNA) from Chlamydomonas moewusii, a unicellular green alga which is interfertile with Chlamydomonas eugametos, has revealed a two-fold size difference between the inverted repeat sequences of these algae. With a size of 42 kbp, the inverted repeat of C. moewusii is the largest yet identified in any chloroplast genome. Here we have compared the arrangement of conserved sequences within the two algal inverted repeats by hybridizing cloned restriction fragments representing over 90% of these repeats to Southern blots of cpDNA digests from the two algae. We found that the size difference between the two algal inverted repeats is due to the presence of an extra DNA segment of 21 kilobase pairs (kbp) in C. moewusii. Except for this sequence, the C. moewusii inverted repeat is highly homologous to the entire C. eugametos repeat and the arrangement of conserved sequences in the two repeats is identical. Southern hybridizations with specific gene probes revealed that the conserved sequences include the rDNA region and the genes coding for the large subunit of ribulose 1,5 bisphosphate carboxylase-oxygenase (rbcL) and for the '32 kilodalton' thylakoid membrane protein (psbA). With respect to the conserved sequences, the extra 21 kbp DNA segment of C. moewusii lies in the region of psbA, most probably slightly downstream from this gene.

Recombination between chloroplast DNAs does not occur in sexual crosses of Oenothera

Crosses of Oenothera result in the transmission of chloroplasts from both parents to their offspring. In spite of this biparental inheritance, no wild-type recombinants were recovered from crosses between different chloroplast mutants. Since more than 7500 progeny were examined, the results indicate that recombination between the chloroplast DNAs of higher plants must be a very rare event.

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.