Chloroplast DNA variation between species of Triticum and Aegilops. Location of the variation on the chloroplast genome and its relevance to the inheritance and classification of the cytoplasm

Comparative and phylogenetic analysis of the complete chloroplast genomes of ten Pittosporum species from East Asia

Pittosporum (Pittosporaceae) is famous as the ornamental and medical values, which is distributed tropical and subtropical regions of Eastern Hemisphere. The few phylogenetic studies have included samples from the Pacific Island, but the phylogenetic relationships of Asian species has not been studied. Here, the complete chloroplast (cp) genomes of ten Pittosporum species from East Asia were first sequenced and compared with those of the published species of this genus. Our results indicated that cp genomes of these species had a typical and conserved quadripartite structure. 131 genes were identical in order and orientation and no changes of inverted repeat (IR) occurred. However, the comparative analysis of cp genomes suggested that sequence divergence mainly appeared in non-coding or intergenic regions, in which several divergence hotspots were identified. By contrast, protein-coding genes showed the lowest variance under strong purifying selection. Phylogenetic analysis based on the cp genome sequences showed that the tested Pittosporum species were clustered into two major clades, in which the Asian species formed Clade I and the remaining species from Australia and New Zealand formed Clade II with high support values, which was consistent with the results of ITS data with low support values. These results suggested that cp genome is a robust phylogenetic indicator for deep nodes in the phylogeny of Pittosporum. Meanwhile, these results will provide the valuable information to better understand the phylogeny and biogeography of Pittosporum.

rbcL and matK earn two thumbs up as the core DNA barcode for ferns

BACKGROUND

DNA barcoding will revolutionize our understanding of fern ecology, most especially because the accurate identification of the independent but cryptic gametophyte phase of the fern's life history--an endeavor previously impossible--will finally be feasible. In this study, we assess the discriminatory power of the core plant DNA barcode (rbcL and matK), as well as alternatively proposed fern barcodes (trnH-psbA and trnL-F), across all major fern lineages. We also present plastid barcode data for two genera in the hyperdiverse polypod clade--Deparia (Woodsiaceae) and the Cheilanthes marginata group (currently being segregated as a new genus of Pteridaceae)--to further evaluate the resolving power of these loci.

PRINCIPAL FINDINGS

Our results clearly demonstrate the value of matK data, previously unavailable in ferns because of difficulties in amplification due to a major rearrangement of the plastid genome. With its high sequence variation, matK complements rbcL to provide a two-locus barcode with strong resolving power. With sequence variation comparable to matK, trnL-F appears to be a suitable alternative barcode region in ferns, and perhaps should be added to the core barcode region if universal primer development for matK fails. In contrast, trnH-psbA shows dramatically reduced sequence variation for the majority of ferns. This is likely due to the translocation of this segment of the plastid genome into the inverted repeat regions, which are known to have a highly constrained substitution rate.

CONCLUSIONS

Our study provides the first endorsement of the two-locus barcode (rbcL+matK) in ferns, and favors trnL-F over trnH-psbA as a potential back-up locus. Future work should focus on gathering more fern matK sequence data to facilitate universal primer development.

Polymerase chain reaction-single strand conformational polymorphism analysis of intra- and interspecific variations in organellar DNA regions of Aegilops mutica and related species

In order to study the phylogeny of Aegilops mutica in the genera of Triticum and Aegilops, variations in chloroplast and mitochondrial DNA regions were investigated by polymerase chain reaction-single strand conformational polymorphism (PCR-SSCP) analysis. Nine lines, each of Ae. mutica and Ae. speltoides, were studied together with nine other Triticum and Aegilops species, including T. aestivum. By analyzing 9.7-kb chloroplast and 13.1-kb mitochondrial DNA regions, a total of 268 bands were detected, of which 176 (65.7%) showed variation within and/or between species. The level of intraspecific variation of Ae. mutica was lower than that of Ae. speltoides. The low level of the intraspecific variation of Ae. mutica was contrary to the expectation from previous studies on morphological and cytolo-gical characters. In the phylogenetic trees based on SSCP, Ae. mutica, Ae. speltoides and the other four species of the section Sitopsis (the subsection Emarginata) were separated into three different clusters. In addition, T. aestivum was included in the cluster of Ae. speltoides in the phylogenetic trees. This result suggests that Ae. speltoides is the cytoplasmic donor of common wheat.

The mitochondrial atpA/atp9 co-transcript in wheat and triticale: RNA processing depends on the nuclear genotype

The gene region coding for subunits alpha and 9 of the mitochondrial ATP synthase exhibit an identical DNA sequence in wheat, rye, and the intergeneric hybrid triticale (xTriticosecale Wittmack). However, co-transcripts containing both genes show different sizes depending on the nuclear genotype. To investigate nuclear-mitochondrial interactions leading to this variation, we performed a comparative transcript analysis with various lines carrying defined nuclear and cytoplasmic genotypes. Northern analyses showed that all wheat lines investigated possess a single atpA/atp9 mRNA of 2.6kb, whereas in rye and five independent triticale lines an additional transcript of 2.35kb appeared. Primer-extension and RNase-protection analyses indicate that the co-transcripts of this gene have staggered 5' termini in some lines, whereas the 3' termini seem to be similar in wheat, rye, and triticale. Transcription is initiated at position -338/-339 upstream of the atpA gene in all lines investigated, giving rise to a 2.6-kb mRNA. In rye and triticale, staggered 5' termini were observed closer to the translational start. The DNA sequences upstream of these termini exhibit homology to plant mitochondrial-processing sites, therefore the proximal 5' ends are most probably generated by RNA processing. As the processing event occurs more frequently in triticale carrying the Triticum timopheevi cytoplasm, trans-acting factors from rye are likely to interact with other cytoplasmic factors resulting in the observed RNA modification. Most interestingly, the T. timopheevi cytoplasm inducing male sterility in alloplasmic wheat, fails to generate the CMS phenotype in triticale. The data support our hypothesis that nuclear factors affect mitochondrial gene expression and thus control sexual fertility in wheat and triticale.

Phylogenetic analysis of organellar DNA sequences in the Andropogoneae: Saccharinae

To study the phylogenetics of sugarcane (Saccharum officinarum L.) and its relatives we sequenced four loci on cytoplasmic genomes (two chloroplast and two mitochondrial) and analyzed mitochondrial RFLPs generated using probes for COXI, COXII, COXIII, Cob, 18S+5S, 26S, ATPase 6, ATPase 9, and ATPase α (D'Hont et al. 1993). Approximately 650 bp of DNA in the intergenic spacer region between rbcL and atpB and approximately 150 bp from the chloroplast 16S rDNA through the intergenic spacer region tRNA(val) gene were sequenced. In the mitochondrial genome, part of the 18S rRNA gene and approximately 150 bp from the 18S gene 3' end, through an intergenic spacer region, to the 5S rRNA gene were sequenced. No polymorphisms were observed between maize, sorghum, and 'Saccharum complex' members for the mitochondrial 18S internal region or for the intergenic tRNA(val) chloroplast locus. Two polymorphisms (insertion-deletion events, indels) were observed within the 18S-5S mitochondrial locus, which separated the accessions into three groups: one containing all of the Erianthus, Eccoilopus, Imperata, Sorghum, and 1 Miscanthus species; a second containing Saccharum species, Narenga porphyrocoma, Sclerostachya fusca, and 1 presumably hybrid Miscanthus sp. from New Guinea; and a third containing maize. Eighteen accessions were sequenced for the intergenic region between rbcL and atpB, which was the most polymorphic of the regions studied and contained 52 site mutations and 52 indels, across all taxa. Within the Saccharum complex, at most 7 site mutations and 16 indels were informative. The maternal lineage of Erianthus/Eccoilopus was nearly as divergent from the remaining Saccharum complex members as it was from sorghum, in agreement with a previous study. Sequences from the rbcL-atpB spacer were aligned with GENBANK sequences for wheat, rice, barley, and maize, which were used as outgroups in phylogenetic analyses. To determine whether limited intra-complex variability was caused by under sampling of taxa, we used seven restriction enzymes to digest the PCR-amplified rbcL-atpB spacer of an additional 36 accessions within the Saccharum complex. This analysis revealed ten restriction sites (none informative) and eight length variants (four informative). The small amount of variation present in the organellar DNAs of this polyploid complex suggests that either the complex is very young or that rates of evolution between the Saccharum complex and outgroup taxa are different. Other phylogenetic information will be required to resolve systematic relationships within the complex. Finally, no variation was observed in commercial sugarcane varieties, implying a world-wide cytoplasmic monoculture for this crop.

Phylogenetic analysis of chloroplast restriction enzyme site mutations in the Saccharinae Griseb. subtribe of the Andropogoneae Dumort. tribe

Chloroplast (cp) DNA from 32 genotypes representing eight genera and 19 species from the Andropogoneae tribe was analyzed using 15 restriction enzymes and Southern hybridization with 12 cpDNA probes that span the complete rice chloroplast genome. Six of the genera, Saccharum, Miscanthus, Erianthus, Narenga, Eccoilopus, and Sclerostachya, are part of the Saccharinae subtribe, whereas the other two, Zea and Sorghum, were used as outgroups. Narenga, Miscanthus, Erianthus, and Sclerostachya are presumed to have been involved in the evolution of Saccharum officinarum ("noble" or high sucrose sugarcane) via S. spontaneum and S. robustum. Southern hybridization with the rice cpDNA probes surveyed approximately 3% of the S. officinarum 'Black Cheribon' genome and yielded 62 restriction site mutations (18 informative) that were analyzed using cladistic parsimony and maximum likelihood. These site mutations placed the 32 genotypes into nine different chloroplast groups; seven from within the Saccharinae subtribe and the two outgroups (maize and Sorghum). Phylogenetic inferrence under various assumptions showed that the maternal lineages of Narenga, Miscanthus, Sclerostachya, and Saccharum formed a monophyletic group. This group displayed little variation. On the other hand, 5 of 6 Erianthus species and Eccoilopus longisetosus formed a separate group. The 'Old World' Erianthus/Eccoilopus chloroplast was very different from that of the rest of the 'Saccharum complex' members and was slightly more related to that of Sorghum bicolor. Placement of these Erianthus/Eccoilopus genotypes was, therefore, in conflict with analyses based on morphology. Surprisingly, Erianthus trinii, a New World species, had the same restriction sites as did one Miscanthus sinensis. One Miscanthus sp. from New Guinea that has a very high chromosome number (2n=192) had the same restriction sites as the majority of the Saccharum genus, suggesting that introgression between these genera occurs in the wild. The Saccharum genus was separated into two clades by single site mutation: one containing S. spontaneum, and the other containing all of the remaining Saccharum species and all 8 commerical hybrids (from various regions of the world). A physical map of the chloroplast of Saccharum officinarum 'Black Cheribon' was constructed using 5 restriction enzymes.

Restriction fragment patterns of chloroplast and mitochondrial DNA of Dasypyvum villosum (L.) candargy and wheats

To elucidate the phylogenetic relationships and cytoplasmic types, restriction endonuclease fragment patterns of chloroplast (cp) and mitochondrial (mt) DNAs isolated from two different accessions of Dasypyrum villosum (L.) candargy were compared with those of tetraploid wheat (Triticum durum Desf., PI265007), hexaploid wheat (Triticum aestivum L., cv Chinese Spring), Aegilops longissimum (S. and M., in Muschli) Bowden and Hordeum vulgare L. T. aestivum and T. durum had identical restriction patterns for their cp and mtDNAs in digestions with four different enzymes. Likewise, no differences were found between the restriction fragment patterns of two accessions of D. villosum. But, there were distinct differences in chloroplast and mitochondrial DNA restriction fragment patterns between D. villosum and tetraploid and hexaploid wheats. A. longissimum (G609) showed a similar pattern to those wheats for PstI digestion of cpDNA. Organellar DNA from Hordeum vulgare (cv Himalaya) showed a distinctly different restriction pattern from those of wheat and D. villosum. These results suggest that D. villosum is unlikely to be the donor of cytoplasm to wheats, and its cytoplasmic organelles were also different from those of A. longissimum.

Differences between, and possible origins of, the cytoplasms found in fertile and male-sterile onions (Allium cepa L.)

The DNA of the organellar genomes of Allium cepa has been examined to detect restriction fragment length polymorphisms. Differences can be shown between both the chloroplastal and mitochondrial genomes of the N and cms-S cytoplasms in their restriction fragment profiles. Southern blot analysis of the mtDNA profiles using probes containing defined mitochondrial genes also detected polymorphisms. No differences can be shown between the organellar genomes of the N and cms-T onions by either of these techniques. These data indicate different origins for the two sterility-conferring cytoplasms, suggesting autoplasmic and alloplasmic origins for the cms-T and cms-S cytoplasms, respectively. No evidence of the presence of virus-like particles was found in any of the cytoplasms.

Variability and uniformity of mitochondrial DNA in populations of putative diploid ancestors of common wheat

By using restriction endonuclease digestion patterns, the degree of intraspecific polymorphism of mitochondrial DNA in four diploid species of wheat and Aegilops, Ae. speltoides, Ae. longissima, Ae. squarrosa, and Triticum monococcum, was assessed. The outbreeding Ae. speltoides was found to possess the highest degree of variability, the mean number of nucleotide substitutions among conspecific individuals being 0.027 substitutions per nucleotide site. A very low degree of mtDNA variation was detected among Ae. longissima accessions, with most of the enzyme-probe combinations exhibiting uniform hybridization patterns. The mean number of substitutions among Ae. longissima individuals was 0.001 substitutions per nucleotide site. The domesticated diploid wheat T. monococcum var. monococcum and its conspecific variant T. monococcum var. boeoticum seem to lack mitochondrial DNA variability altogether. Thus, the restriction fragment pattern can be used as a characteristic identifier of the T. monococcum cytoplasmic genome. Similarly, Ae. squarrosa accessions were found to be genetically uniform. A higher degree of variation among accessions is observed when noncoding sequences are used as probes then when adjacent coding regions are used. Thus, while noncoding regions may contain regulatory functions, they are subject to less stringent functional constraints than protein-coding regions. Intraspecific variation in mitochondrial DNA correlates perfectly with the nuclear variability detected by using protein electrophoretic characters. This correlation indicates that both types of variation are selectively neutral and are affected only by the effective population size.

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.

Chloroplast DNA variation in diploid and polyploid species of Bromus (Poaceae) subgenera Festucaria and Ceratochloa

Chloroplast DNA (cpDNA) restriction endonuclease patterns are used to examine phylogenetic relationships between Bromus subgenera Festucaria and Ceratochloa. Festucaria is considered monophyletic based on the L genome, while Ceratochloa encompasses two species complexes: the B. catharticus complex, which evolved by combining three different genomes, and the B. carinatus complex, which is thought to have originated from hybridization between polyploid species of B. catharticus and diploid members of Festucaria. All species of subgenus Ceratochloa (hexaploids and octoploids) were identical in chloroplast DNA sequences. Similarly, polyploid species of subgenus Festucaria, except for B. auleticus, were identical in cpDNA sequences. In contrast, diploid species of subgenus Festucaria showed various degrees of nucleotide sequence divergence. Species of subgenus Ceratochloa appeared monophyletic and phylogenetically closely related to the diploid B. anomalus and B. auleticus of subgenus Festucaria. The remaining diploid and polyploid species of subgenus Festucaria appeared in a distinct grouping. The study suggests that the B. catharticus complex must have been the maternal parent in the proposed hybrid origin of B. carinatus complex. Although there is no direct evidence for the paternal parent of the latter complex, the cpDNA study shows the complex to be phylogenetically very related to the diploid B. anomalus of subgenus Festucaria.

Inheritance of plastids in interspecific hybrids of blue spruce and white spruce

Chloroplast DNA (cpDNA) was purified from blue spruce (Picea pungens Engelm.) and white spruce [P. glauca (Moench) Voss], and was digested with several different restriction endonucleases. Restriction fragment length polymorphisms (RFLPs) were identified that differentiated the cpDNA of both species. Intraspecific conservation of the RFLPs that differentiated each species was confirmed by examining trees from across the natural range of each species. Ten F1 hybrids were examined, and the cpDNA from each showed the banding pattern of the paternal species. Cloned Petunia cpDNA containing part of the rbcL gene hybridized to polymorphic bands, while a cloned maize mtDNA probe of the coxII gene failed to hybridize to any band.

Evidence for cytoplasmic control of in vitro microspore embryogenesis in the anther culture of wheat (Triticum aestivum L.)

Anthers were cultured from two sets of seven lines of hexaploid wheat (Triticum aestivum L.) with different cytoplasms, the euplasmic nucleus donors, 'Siete Cerros 66' and 'Penjamo 62', as well as their six alloplasmic lines derived from wild relative species of the genera Triticum and Aegilops. Significant cytoplasmic and nuclear effects but no cytoplasmic-nuclear interaction were found for embryogenic anther response, with the best performance of 'Penjamo 62' in Ae. kotschyi cytoplasm. Plant regeneration was not affected significantly by the cytoplasmic background of the lines cultured. The possible genetic implications of the observed cytoplasmic and nuclear influences on the in vitro haploid induction of wheat are discussed.

Autopolyploidy in Dactylis glomerata L.: further evidence from studies of chloroplast DNA variation

Chloroplast DNA variation has been used to examine some of the maternal lineages involved in the evolution of the intraspecific polyploid complex, Dactylis glomerata L. Diploid (2x) and tetraploid (4x) individuals were collected from natural populations of the subspecies glomerata (4x), marina (4x) and lusitanica (2x), as well as from sympatric 2x/4x populations of the Galician type. Digestion of their ctDNA with 11 restriction endonucleases revealed enough variation to characterise three ctDNA variants, designated MBMK, MBmK and mBMK. The distribution of these ctDNA variants reflects different stages in their spread among the populations. The MBMK ctDNA variant predominated at both ploidy levels in subspecies glomerata, lusitanica and marina, and in recent tetraploid Galician/glomerata hybrids. The MBmK variant was detected in a single tetraploid individual and probably results from a relatively recent mutation. Fixation of the mBMK minority variant in the diploid and tetraploid Galician populations adds to the evidence concerning the possible origin of the Galician tetraploids. It means that the Galician diploids were maternal ancestors of the tetraploids. This result complements evidence from earlier studies based on morphology or biochemical markers, and reduces the likelihood that the tetraploids arose by hybridisation between an ancient Galician diploid and an alien tetraploid. It is, however, consistent with a true autopolyploid origin of the tetraploids.

Alloplasmic male sterility in AD allotetraploid Gossypium hirsutum upon replacement of its resident A cytoplasm with that of D species G. harknessii

Alloplasmic male sterile (cms) and restoration-of-fertility (Rf) lines of the AD allotetraploid Gossypium hirsutum were earlier derived from the presumed introgression of the cytoplasm of the D species G. harknessii. To confirm that this happened and address its significance, cytoplasms of the maternal progenitor, backcross intermediates, derived breeding lines, related A, D, and F species, and a synthetic AD tetraploid were examined by agarose and polyacrylamide gel electrophoresis of 140 restriction enzyme fragments of chloroplast DNA. Length mutations of 10-50 nucleotides predominate over site loss/gain mutations. Chloroplast DNA is maternally inherited and that of G. harknessii has been maintained in the cms lines for at least 13 successive generations without detectable alteration. Chloroplast DNA divergence is consistent with current nuclear genome classification and shows that the A progenitor was the maternal parent of the AD tetraploids. As predicted from incompatability models of cms, the degree of male sterility in alloplasmic Gossypium tetraploids is correlated with the extent of evolutionary divergence of their cytoplasms. It is suggested that the A genome in the AD tetraploids dominates those nuclear-cytoplasm interactions reflected by male fertility.

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.

Origin of chloroplast DNA diversity in the Andean potatoes

Wide chloroplast DNA (ctDNA) diversity has been reported in the Andean cultivated tetraploid potato, Solanum tuberosum ssp. andigena. Andean diploid potatoes were analyzed in this study to elucidate the origin of the diverse ctDNA variation of the cultivated tetraploids. The ctDNA types of 58 cultivated diploid potatoes (S. stenotomum, S. goniocalyx and S. phureja), 35 accessions of S. sparsipilum, a diploid weed species, and 40 accessions of the wild or weed species, S. chacoense, were determined based on ctDNA restriction fragment patterns of BamHI, HindIII and PvuII. Several different ctDNA types were found in the cultivated potatoes as well as in weed and wild potato species; thus, intraspecific ctDNA variation may be common in both wild and cultivated potato species and perhaps in the higher plant kingdom as a whole. The ctDNA variation range of cultivated diploid potatoes was similar to that of the tetraploid potatoes, suggesting that the ctDNA diversity of the tetraploid potato could have been introduced from cultivated diploid potatoes. This provided further evidence that the Andean cultivated tetraploid potato, ssp. andigena, could have arisen many times from the cultivated diploid populations. The diverse but conserved ctDNA variation noted in the Andean potatoes may have occurred in the early stage of species differentiation of South American tuber-bearing Solanums.

PHYLOGENETIC IMPLICATIONS OF CHLOROPLAST DNA RESTRICTION SITE VARIATION IN THE MUTISIEAE (ASTERACEAE)

Phylogenetic relationships among 13 species in the tribe Mutisieae and a single species from each of three other tribes in the Asteraceae were assessed by chloroplast DNA restriction site mapping. Initially, 211 restriction site mutations were detected among 16 species using 10 restriction enzymes. Examination of 12 of these species using nine more enzymes revealed 179 additional restriction site mutations. Phylogenetic analyses of restriction site mutations were performed using both Dolio and Wagner parsimony, and the resulting monophyletic groups were statistically tested by the bootstrap method. The phylogenetic trees confirm an ancient evolutionary split in the Asteraceae that was previously suggested by the distribution of a chloroplast DNA inversion. The subtribe Barnadesiinae of the tribe Mutisieae is shown to be the ancestral group within the Asteraceae. The molecular phylogenies also confirm the paraphyly of the Mutisieae and provide statistical support for the monophyly of three of its four currently recognized subtribes (Barnadesiinae, Mutisiinae, and Nassauviinae). The fourth subtribe, Gochnatiinae, is shown to be paraphyletic. Within the subtribes, several closely related generic pairs are identified. Chloroplast DNA sequence divergence among genera of the Asteraceae ranges between 0.7 and 5.4%, which is relatively low in comparison to other angiosperm groups. This suggests that the Asteraceae is either a relatively young family or that its chloroplast DNA has evolved at a slower rate than in other families.

Common features of three inversions in wheat chloroplast DNA

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.

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.

Comparative restriction endonuclease analysis and molecular cloning of plastid DNAs from wild species and cultivated varieties of the genus Beta (L.)

A phyletic tree of the genus Beta has been constructed based on EcoRI and PstI plastid DNA restriction patterns of eight species from three sections of the genus. In contrast to the remarkable morphological variability of the varieties of B. vulgaris the restriction patterns of the plastid DNA of this species were found to be almost identical. The comparison of plastic DNAs of B. vulgaris crassa fertile and sterile lines with 13 different restriction enzymes revealed only a single fragment polymorphism in the HindIII patterns. Hybridization analyses in the plastidal rDNA region revealed an interesting loss of an EcoRI restriction site in all cultivated B. vulgaris varieties in contrast to wild species. The results of the construction of clone banks for SalI and BamHI fragments of plastid DNA from fertile B. vulgaris crassa are reported and difficulties in the cloning of specific fragments are discussed.

Chloroplast DNA variation in the grass tribe Festuceae

Six grasses, Hordeum sativum, Dactylis glomerata, Festuca arundinacea, F. pratensis, F. rubra and Lolium multiflorum were subjected to chloroplast DNA analysis based on restriction endonuclease digestion fragments and end labeling with (35)S nucleotides. This method is compared with others in general use. The results indicate that Lolium multiflorum is closely affiliated with Festuca pratensis and F. arundinacea; in fact much closer than F. rubra is to any of them.

Parental genome expression in synthetic wheats (Triticum turgidum sp. × T. tauschii sp.) revealed by two-dimensional electrophoresis of seedling proteins

Two-dimensional gel electrophoresis was conducted on etiolated seedling proteins from two distinct amphiploids (ABD1, ABD2) and their parental lines (AB1, D1 and AB2, D2), AB1 and AB2 being used as female. On the amphiploid patterns were found all the parental spots except 8 D spots of which 3 are cytoplasmically encoded. One exceptional polypeptide observed in ABD1 was present neither in AB1 nor D1. The patterns fromt the amphiploids very closely resemble the co-electrophoresis done with 1/3 D protein extract and 2/3 AB protein extract. Thus it is very likely that for most gene products revealed the genomes act independently of each other.

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.

Mitochondrial DNA diversity in the genera of Triticum and Aegilops revealed by southern blot hybridization

Southern blot hybridization of total DNA to defined mitochondrial DNA sequences provides a sensitive assay for mtDNA variation in the genera of Triticum and Aegilops. A clear distinction between cytoplasms of tetraploid species sharing the "AG" haploid genome is reported for the first time. The Sitopsis section of the genus Aegilops showed the most extensive intra- and inter-specific variation, whereas no variation could be detected among the cytoplasms of polyploid Triticum species (wheats) sharing the AB haploid genome. Extensive cytoplasmic intraspecific diversity was revealed in Ae. speltoides.

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.

The molecular basis of genetic diversity among cytoplasms of Triticum and Aegilops : 5. Mitochondrial genome diversity among Aegilops species having identical chloroplast genomes

Restriction fragment patterns of mtDNA isolated from the cytoplasm of three groups of Aegilops species (or accessions) which are known to carry the identical chloroplast genome but distinctly different cytoplasmic genomes (plasmons) have been analysed using five restriction endonucleases. Two to four different mitochondrial genomes are found in each group, between which the percent common restriction fragments amounts to 86-97%, whereas the same parameter obtained between mitochondrial genomes of the different groups ranges from 34 to 42%. Mitochondrial genome diversity is far more extensive than the chloroplast genome diversity, and the former provides a useful key for the phylogenetic relationships between cytoplasms of closely related species or even different accessions of the same species. The mitochondrial and chloroplast genome differentiation most certainly accounts for the plasmon variability known in this genus.

The specific activity of ribulose-1,5-bisphosphate carboxylase in relation to genotype in wheat

The specific activity of ribulose-1,5-bisphosphate carboxylase (RuBPCase; EC 4.1.1.39) in crude extracts of leaves from euploid, amphiploid and alloplasmic lines of wheat fell into high or low categories (3.75 or 2.70 μmol·mg(-1)·min(-1), 30°C). For the alloplasmic lines, where the same hexaploid nuclear genome was substituted into different cytoplasms, the specific activity of RuBPCase was consistent with the type of cytoplasm (high for the B and S cytoplasms and low for the A and D cytoplasms). There was no evidence from the euploid and amphiploid lines that small subunits encoded in different nuclear genomes influenced the specific activity. High specific activity was conferred by possession of the chloroplast genome of the B-type cytoplasm which encodes the large subunit of RuBPCase. All lines with a cytoplasm derived from the Sitopsis section of wheat, with the exception of Aegilops longissima and A. speltoides 18940, had RuBPCase with high specific activity. In contrast with the euploid lines of A. longissima, the alloplasmic line containing A. longissima cytoplasm from a different source had RuBPCase with high specific activity. The difference in specific activity found here in-vitro was not apparent in-vivo when leaf gas exchange was measured.

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.

Copy numbers of chloroplast and nuclear genomes are proportional in mature mesophyll cells of Triticum and Aegilops species

The possibility of estimating the proportion of chloroplast DNA (ctDNA) and nuclear DNA (nDNA) in nucleic-acid extracts by selective digestion with the methylation-sensitive restriction enzyme PstI, was tested using leaf extracts from Spinacia oleracea and Triticum aestivum. Values of ctDNA as percentage nDNA were estimated to be 14.58%±0.56 (SE) in S. oleracea leaves and 4.97%±0.36 (SE) in T. aestivum leaves. These estimates agree well with those already reported for the same type of leaf material. Selective digestion and quantitative dot-blot hybridisation were used to determine ctDNA as percentage nDNA in expanded leaf tissue from species of Triticum and Aegilops representing three levels of nuclear ploidy and six types of cytoplasm. No significant differences in leaf ctDNA content were detected: in the diploids the leaf ctDNA percentage ranged between 3.8% and 5.1%, and in the polyploids between 3.5% and 4.9%. Consequently, nuclear ploidy and nDNA amount were proportional to ctDNA amount (r(19)=0.935, P>0.01) and hence to ctDNA copy number in the mature mesophyll cells of these species. There was a slight increase in ctDNA copy numbers per chloroplast at higher ploidy levels. The balance between numbers of nuclear and chloroplast genomes is discussed in relation to polyploidisation and to the nuclear control of ctDNA replication.