Chloroplast DNA differences between two species of Oenothera subsection Munzia: location in the chloroplast genome and relevance to possible interactions between nuclear and plastid genomes

Summary The chloroplast DNAs (cpDNAs) of Oenothera berteriana and Oe. odorata (subsection Munzia) were examined by restriction endonuclease analysis with Sal I, Pvu II, Kpn I, Pst I, Hind III, and Bam HI. The fragment patterns show that these cpDNAs have all 133 restriction sites in common as well as a lot of individual bands. Nevertheless the cpDNAs of the two species can be distinguished by distinct differences in size between a small number of fragments. The 42 cleavage sites produced by Sal I, Pvu II and Kpn I were mapped on the circular cpDNAs. This was achieved by an approach which combined experimental and mathematical procedures. The overall serial order of the fragments was found to be the same for both cpDNAs. The size differences of individual fragments in the Sal I, Pvu II and Kpn I patterns between Oe. berteriana and Oe. odorata cpDNA are located within five regions scattered along the plastid chromosome. Two of these regions have been localized in the larger and one in the smaller of the two single-copy parts of the cpDNA molecule. The remaining two overlap the borders between the large single-copy and each of the duplicated parts of the molecule. The positions of distinct restriction sites are altered among the two Oenothera plastome DNAs by 0.02–0.4 MDa (30–600 base pairs). These alterations probably result from insertions/deletions.Abbreviations cpDNA chloroplast, plastid DNA - Oe. Oenothera - MDa Megadalton - rRNA, rDNA ribosomal RNA, DNA Dedicated to Professor Berthold Schwemmle, Tübingen, on the occasion of his 60th birthday     

Gene rearrangements in Chlamydomonas chloroplast DNAs are accounted for by inversions and by the expansion/contraction of the inverted repeat

To gain insight into the mutational events responsible for the extensive variation of chloroplast DNA (cpDNA) within the green algal genus Chlamydomonas, we have investigated the chloroplast gene organization of Chlamydomonas pitschmannii, a close relative of the interfertile species C. eugametos and C. moewusii whose cpDNAs have been well characterized. At 187 kb, the circular cpDNA of C. pitschmannii is the smallest Chlamydomonas cpDNA yet reported; it is 56 and 105 kb smaller than those of its C. eugametos and C. moewusii counterparts, respectively. Despite this substantial size difference, the arrangement of 77 genes on the C. pitschmannii cpDNA displays only three noticeable differences from the organization of the corresponding genes on the collinear C. eugametos and C. moewusii cpDNAs. These changes in gene order are accounted for by the expansion/contraction of the inverted repeat and one or two inversions in a single-copy region. In land plant cpDNAs, these kinds of events are also responsible for gene rearrangements. The large size difference between the C. pitschmannii and C. eugametos/C. moewusii cpDNAs is mainly attributed to multiple events of deletions/additions as opposed to the usually observed expansion/contraction of the inverted repeat in land plant cpDNAs. We also found that the mitochondrial genome of C. pitschmannii is a circular DNA molecule of 16.5 kb which is 5.5 and 7.5 kb smaller than its C. moewusii and C. eugametos counterparts, respectively.     

Highly rearranged and size‐variable chloroplast genomes in conifers II clade (cupressophytes): evolution towards shorter intergenic spacers

Although conifers are of immense ecological and economic value, bioengineering of their chloroplasts remains undeveloped. Understanding the chloroplast genomic organization of conifers can facilitate their bioengineering. Members of the conifer II clade (or cupressophytes) are highly diverse in both morphologic features and chloroplast genomic organization. We compared six cupressophyte chloroplast genomes (cpDNAs) that represent four of the five cupressophyte families, including three genomes that are first reported here (Agathis dammara, Calocedrus formosana and Nageia nagi). The six cupressophyte cpDNAs have lost a pair of large inverted repeats (IRs) and vary greatly in size, organization and tRNA copies. We demonstrate that cupressophyte cpDNAs have evolved towards reduced size, largely due to shrunken intergenic spacers. In cupressophytes, cpDNA rearrangements are capable of extending intergenic spacers, and synonymous mutations are negatively associated with the size and frequency of rearrangements. The variable cpDNA sizes of cupressophytes may have been shaped by mutational burden and genomic rearrangements. On the basis of cpDNA organization, our analyses revealed that in gymnosperms, cpDNA rearrangements are phylogenetically informative, which supports the ‘gnepines’ clade. In addition, removal of a specific IR influences the minimal rearrangements required for the gnepines and cupressophyte clades, whereby Pinaceae favours the removal of IRB but cupressophytes exclusion of IRA. This result strongly suggests that different IR copies have been lost from conifers I and II. Our data help understand the complexity and evolution of cupressophyte cpDNAs.     

Oenothera chloroplast DNA polymorphisms associated with plastome mutator activity

Summary Oenothera plants homozygous for a recessive allele at the plastome mutator (pm) locus show non-Mendelian mutation frequencies that are 1000-fold higher than spontaneous levels. Chloroplast DNA (cpDNA) was isolated from nine mutants and two green isolates of the plastome mutator line. cpDNA restriction patterns were compared to cpDNA from a representative of the progenitor Johansen strain, and cpDNAs from all eleven plastome mutator lines show changes of fragment mobility due to deletion events at five discrete regions of the plastome. Most of the mutants have cpDNA restriction patterns identical to that of one of the green isolates from the plastome mutator line, and therefore, most of the differences in fragment length are probably not responsible for the mutant phenotypes. In contrast to the plastome mutator line, cpDNA from several populations of a closely related wild-type Oenothera species have few restriction fragment length polymorphisms. This suggests that both mutation frequencies and site-specific cpDNA deletions are elevated in the plastome mutator line, and implicates a defect in the cpDNA repair or replication machinery.     

Chloroplast DNA variability in the genus Helianthus: restriction analysis and S1 nuclease mapping of DNA-DNA heteroduplexes

Chloroplast DNA (cpDNA) from 36 wild species of the genus Helianthus has been analysed with three restriction endonucleases (Bam HI, Hind III and Sst I). Out of the 71 restriction sites described on the reference cpDNA (sunflower cpDNA), three insertions/deletions and seven site modifications were detected during the survey of the other cpDNAs.Since restriction mapping showed only a very limited fraction of the DNA variability, we chose to adapt the S1 nuclease mapping technique to detect fine variations between chloroplast genomes. For this purpose, DNA-DNA heteroduplexes obtained between sunflower and wild-species DNAs were digested by S1 nuclease and the resulting mismatches were detected by classical endonuclease restriction and hybridization methods. The S1 nuclease mapping results were confirmed by sequencing one S1 nuclease-sensitive region detected between cultivated sunflower and two perennial wild-type species.As a result of these analyses, it appeared that the combination of restriction mapping and S1 nuclease mapping might be helpful to differentiate taxonomically close cytoplasms.     

Sequence variation of non-coding regions of chloroplast DNA of soybean and related wild species and its implications for the evolution of different chloroplast haplotypes

Soybean chloroplast DNAs (cpDNAs) are classified into three types (I, II and III) based on RFLP profiles. Type I is mainly observed in cultivated soybean (Glycine max), while type II and type III are frequently found in both cultivated and wild soybean (Glycine soja), although type III is predominant in wild soybean. In order to evaluate the diversity of cpDNA and to determine the phylogenetic relationship among different chloroplast types, we sequenced nine non-coding regions of cpDNA for seven cultivated and 12 wild soybean accessions with different cpDNA types. Eleven single-base substitutions and a deletion of five bases were detected in a total of 3849 bases identified. Five mutations distinguished the accessions with types I and II from those with type III, and seven were found in the accessions with type III, independently of their taxa. Four species of the subgenus Glycine shared bases that were identical to those with types I and II at two of the five mutation sites and shared bases that were identical to those with type III at the remaining three sites. Therefore, the different cpDNA types may not have originated monophyletically, but rather may have differentiated from a common ancestor in different evolutionary directions. A neighbor-joining tree resulting from the sequence data revealed that the subgenus Soja connected with Glycine microphylla which formed a distinct clade from Clycine clandestina and the tetraploid cytotypes of Glycine tabacina and Glycine tomentella. Several informative length mutations of 54 to 202 bases, due to insertions or deletions, were also detected among the species of the genus Glycine. Received: 16 December 1999 / Accepted: 12 February 2000     

Chloroplast and mitochondrial DNA composition of triploid and tetraploid somatic hybrids between Lycopersicon esculentum and Solanum tuberosum

The chloroplast (cp) DNA type and mitochondrial (mt) DNA composition of 17 somatic hybrids between a cytoplasmic albino tomato and monoploid potato (A7-hybrids) and 18 somatic hybrids between a nitrate reductase-deficient tomato and monoploid potato (C7-hybrids) were analyzed. Thirteen A7-hybrids and 9 C7-hybrids were triploids (with one potato genome); the other hybrids were tetraploid. As expected, all A7-hybrids contained potato cpDNA. Of the C7-hybrids 7 had tomato cpDNA, 10 had potato cpDNA and 1 hybrid contained both tomato and potato cpDNA. The mtDNA composition of the hybrids was analyzed by hybridization of Southern blots with four mtDNA-specific probes. The mtDNAs in the hybrids had segregated independently from the cpDNAs. Nuclear DNA composition (i.e. one or two potato genomes) did not influence the chloroplast type in the C7-hybrids, nor the mtDNA composition of A7- or C7-hybrids. From the cosegregation of specific mtDNA fragments we inferred that both tomato and potato mtDNAs probably have a coxII gene closely linked to 18S+5S rRNA genes. In tomato, atpA, and in potato, atp6 seems to be linked to these mtDNA genes.     

CHLOROPLAST DNA SYSTEMATICS OF LILIOID MONOCOTS: RESOURCES,FEASIBILITY, AND AN EXAMPLE FROM THE ORCHIDACEAE

Although chloroplast DNA (cpDNA) analysis has been widely and successfully applied to systematic and evolutionary problems in a wide variety of dicots, its use in monocots has thus far been limited to the Poaceae. The cpDNAs of grasses are significantly altered in arrangement relative to the genomes of most vascular plants, and thus the available clone banks of grasses are not particularly useful in studying variation in the cpDNA of other monocots. In this report, we present mapping studies demonstrating that cpDNAs of four lilioid monocots (Allium cepa, Alliaceae; Asparagus sprengeri, Asparagaceae; Narcissus × hybridus, Amaryllidaceae; and Oncidium excavatum, Orchidaceae), which, while varying in size over as much as 18 kilobase pairs, conform to the genome arrangement typical of most vascular plants. A nearly complete (99.2%) clone bank was constructed from restriction fragments of the chloroplast genome of Oncidium excavatum; this bank should be useful in cpDNA analysis among the monocots and is available upon request. As an example of the utility of filter hybridization using this clone bank to detect systematically useful variation, we present a Wagner parsimony analysis of restriction site data from the controversial genus Trichocentrum and several sections of Oncidium, popularly known as the “mule ear” and “rat tail oncidiums.” Because of their vastly different floral morphology, the species of Trichocentrum have never been placed in Oncidium, although several authors have recently suggested a close relationship to this vegetatively modified group. The analysis of cpDNA presented here supports this affinity; in fact, it places Trichocentrum as a derivative of the mule ear oncidiums.     

High transmission of paternal plastid DNA in alfalfa plants demonstrated by restriction fragment polymorphic analysis

Summary A high frequency of paternal plastid transmission occurred in progeny from crosses among normal green alfalfa plants. Plastid transmission was analyzed by hybridization of radiolabeled alfalfa plastid DNA (cpDNA) probes to Southern blots of restriction digests of the progeny DNA. Each probe revealed a specific polymorphism differentiating the parental plastid genomes. Of 212 progeny, 34 were heteroplastidic, with their cpDNAs ranging from predominantly paternal to predominantly maternal. Regrowth of shoots from heteroplasmic plants following removal of top growth revealed the persistence of mixed plastids in a given plant. However, different shoots within a green heteroplasmic plant exhibited paternal, maternal, or mixed cpDNAs. Evidence of maternal nuclear genomic influence on the frequency of paternal plastid transmission was observed in some reciprocal crosses. A few tetraploid F₁ progeny were obtained from tetraploid (2n=4x=32) Medicago sativa ssp. sativa x diploid (2n=2x=16) M. sativa ssp. falcata crosses, and resulted from unreduced gametes. Here more than the maternal genome alone apparently functioned in controlling plastid transmission. Considering all crosses, only 5 of 212 progeny cpDNAs lacked evidence of a definitive paternal plastid fragment.Contribution No. 89-524-J from the Kansas Agricultural Experiment Station, Kansas State University, Manhattan     

Independent segregation of the plastid genome and cytoplasmic male sterility in Petunia somatic hybrids

Summary The chloroplast genomes of three sets of Petunia somatic hybrids were analyzed to examine the relationship between chloroplast DNA (cpDNA) composition and cytoplasmic male sterility (CMS). Chloroplast genomes of somatic hybrid plants were identified either by restriction and electrophoresis of purified cpDNAs or by hybridization of total DNA digests with cloned cpDNA probes that distinguish the parental genomes.The chloroplast genomes of a set of seven somatic hybrids derived from the fusion of Petunia CMS line 2423 and fertile line 3699 were analyzed. All seven plants were fertile, and all exhibited the cpDNA restriction pattern of the sterile cytoplasm. Similarly, four fertile somatic hybrids derived from the fusion of CMS line 3688 and fertile line 3677 were found to contain the CMS chloroplast genome. The cpDNA compositions of four fertile and two sterile somatic hybrids derived from the fusion of CMS line 3688 and fertile line 3704 were determined by restriction analysis of purified cpDNAs; all six plants exhibited the cpDNA restriction pattern of line 3704. Thus the CMS phenotype segregates independently of the chloroplast genome in Petunia somatic hybrids, indicating that CMS in Petunia is not specified by the chloroplast genome.     

Variability of chloroplast DNA and nuclear ribosomal DNA in cassava (Manihot esculenta Crantz) and its wild relatives

Chloroplast DNA (cp) and nuclear ribosomal DNA (rDNA) variation was investigated in 45 accessions of cultivated and wild Manihot species. Ten independent mutations, 8 point mutations and 2 length mutations were identified, using eight restriction enzymes and 12 heterologous cpDNA probes from mungbean. Restriction fragment length polymorphism analysis defined nine distinct chloroplast types, three of which were found among the cultivated accessions and six among the wild species. Cladistic analysis of the cpDNA data using parsimony yielded a hypothetical phylogeny of lineages among the cpDNAs of cassava and its wild relatives that is congruent with morphological evolutionary differentiation in the genus. The results of our survey of cpDNA, together with rDNA restriction site change at the intergenic spacer region and rDNA repeat unit length variation (using rDNA cloned fragments from taro as probe), suggest that cassava might have arisen from the domestication of wild tuberous accessions of some Manihot species, followed by intensive selection. M. esculenta subspp flabellifolia is probably a wild progenitor. Introgressive hybridization with wild forms and pressures to adapt to the widely varying climates and topography in which cassava is found might have enhanced the crop's present day variability.     

木芙蓉三个品种及近缘种的叶绿体基因组比较分析

木芙蓉(Hibiscus mutabilis)栽培历史悠久,是原产中国的古老园林树种和药用植物。为了探讨木芙蓉品种及近缘种的进化特征,厘清木芙蓉品种间及其与近缘种间的亲缘关系,以及探究木芙蓉叶绿体基因组(chloroplast DNA, cpDNA)的遗传方式,该文选择了一个杂交组合中的3个木芙蓉栽培品种(‘单瓣白’‘金秋颂’‘牡丹粉’),用高通量测序平台Illumina NovaSeq对其cpDNA进行首次测序。经组装注释后得到3条完整的cpDNA序列,结合该团队已经完成的近缘种台湾芙蓉(H.taiwanensis)和来自基因库的木槿、朱槿的cpDNA,对木槿属4种及木芙蓉种下的3个品种进行了cpDNA组成和结构特征的比较分析,并完成了其系统发育树重建。结果表明：(1)‘单瓣白’‘金秋颂’‘牡丹粉’的cpDNA序列长度分别为160 880、160 879、160 920 bp,基因数目均为130个,其中蛋白编码基因85个、核糖体RNA 8个和转运RNA 37个。(2)比较分析结果显示,木芙蓉的种下3个品种及其近缘种台湾芙蓉在cpDNA上高度保守,反向重复区(IR)均为26 300 b...     

CHLOROPLAST DNA RESTRICTION SITE VARIATION AND THE PHYLOGENY OF COREOPSIS SECTION COREOPSIS (ASTERACEAE)

Restriction site variation in chloroplast DNAs (cpDNAs) of Coreopsis section Coreopsis was employed to assess divergence and phylogenetic relationships among the nine species of the section. A total of fourteen restriction site mutations and one length mutation was detected. Cladistic analysis of the cpDNA data produced a phylogeny that is different in several respects from previous hypotheses. CpDNA mutations divide the section into two groups, with the two perennial species C. auriculata and C. pubescens lacking any derived restriction site changes. The other seven species are united by five synapomorphic restriction site mutations and the one length mutation. These seven species fall into three unresolved clades consisting of 1) the remaining three perennial species, C. grandiflora, C. intermedia, and C. lanceolata; 2) three annual species, C. basalis, C. nuecensoides, and C. nuecensis; and 3) the remaining annual, C. wrightii. The cpDNA data suggest that, although the perennial habit is primitive within the section, the annual species of section Coreopsis have likely not originated from an extant perennial species. The estimated proportion of nucleotide differences per site (given as 100p) for the cpDNAs of species in the section ranges from 0.00 to 0.20, which is comparable to or lower than values reported for other congeneric species. The low level of cpDNA divergence is concordant with other data, including cross compatibility, interfertility and allozymes, in suggesting that species of the section are not highly divergent genetically.     

Physical map and gene localization on sunflower (Helianthus annuus) chloroplast DNA: evidence for an inversion of a 23.5-kbp segment in the large single copy region

As a first step in the study of chloroplast genome variability in the genus Helianthus, a physical restriction map of sunflower (Helianthus annuus) chloroplast DNA (cpDNA) has been constructed using restriction endonucleases BamH I, Hind III, Pst I, Pvu II and Sac. I. Sunflower circular DNA contains an inverted repeat structure with the two copies (23 kbp each) separated by a large (86 kbp) and a small (20 kbp) single copy region. Its total length is therefore about 152 kbp. Sunflower cpDNA is essentially colinear with that of tobacco with the exception of an inversion of a 23.5-kbp segment in the large single copy region. Gene localization on the sunflower cpDNA and comparison of the gene map with that from tobacco chloroplasts have revealed that the endpoints of the inversion are located between the trnT and trnE genes on the one hand, and between the trnG and trnS genes on the other hand.Analysis of BamH I restriction fragment patterns of H. annuus, H. occidentalis ssp. plantagineus, H. grossesseratus, H. decapetalus, H. giganteus, H. maximiliani and H. tuberosus cpDNAs suggests that structural variations are present in the genus Helianthus.     

Chloroplast DNA phylogeny of Lens (Leguminosae): origin and diversity of the cultivated lentil

A restriction-site analysis of chloroplast DNA (cpDNA) variation in Lens was conducted to: (1) assess the levels of variation in Lens culinaris ssp. culinaris (the domesticated lentil), (2) identify the wild progenitor of the domesticated lentil, and (3) construct a cpDNA phylogeny of the genus. We analyzed 399 restriction sites in 114 cultivated accessions and 11 wild accessions. All but three accessions of the cultivar had identical cpDNAs. Two accessions exhibited a single shared restriction-site loss, and a small insertion was observed in the cpDNA of a third accession. We detected 19 restriction-site mutations and two length mutations among accessions of the wild taxa. Three of the four accessions of L. culinaris ssp. orientalis were identical to the cultivars at every restriction site, clearly identifying ssp. orientalis as the progenitor of the cultivated lentil. Because of its limited cpDNA diversity, we conclude that either the cultivated lentil has passed through a genetic bottleneck during domestication and lost most of its cytoplasmic variability or else was domesticated from an ancestor that was naturally depauperate in cpDNA restriction-site variation. However, because we had access to only a small number of populations of the wild taxa, the levels of variation present in ssp. orientalis can only be estimated, and the extent of such a domestication bottleneck, if applicable, cannot be evaluated. The cpDNA-based phylogeny portrays Lens as quite distinct from its putative closest relative, Vicia montbretii. L. culinaris ssp. odemensis is the sister of L. nigricans; L. culinaris is therefore paraphyletic given the current taxonomic placement of ssp. odemensis. Lens nigricans ssp. nigricans is by far the most divergent taxon of the genus, exhibiting ten autapomorphic restriction-site mutations.     

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

Summary 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.Contributions no. 45 and no. 490 from the Kihara Institute for Biological Research, Yokohama City University and the Laboratory of Genetics, Faculty of Agriculture, Kyoto University, respectively.     

Chloroplast DNA evidence for non-random selection of females in an outcrossed population of soybeans [Glycine max (L.)]

Summary Restriction fragment length polymorphisms (RFLPs) were used to assess chloroplast DNA (cpDNA) variation in a population of soybeans subjected to continuous cycles of forced outcrossing. This population was derived by crossing 39 female lines with four male-sterile (Ms₂ms₂) maintainer lines and advancing each generation by selecting only outcrossed seed borne on male-sterile (ms₂ms₂) plants. Analysis of the original 39 female lines revealed three groups based on cpDNA RFLPs. These three groups had been previously documented in soybeans, and the distribution of these groups among the female parents of this population was similar to that observed in germ plasm surveys of soybean. Thirty-four of the female parents had group I cpDNA, 3 had group II, and 2 had group III. Plants collected from this population after seven cycles of outcrossing were scored for four morphological traits (flower color, pubescence color, seed color, and pubescence type) known to be controlled by alleles at single nuclear loci. The frequencies of the phenotypes observed in this study indicated that the population underwent random mating with respect to flower and pubescence color, but deviated from random mating at the other two loci. Analysis of 158 of these same plants collected from the population after seven cycles of outcrossing revealed no individuals with group II or group III cpDNAs. The fixation of the group I cpDNA marker in this outcrossing population was judged to result primarily from selection against individuals in the population with the rare cpDNAs.Published as Paper no. 9640, Journal Series, Nebraska Agric Res Div Project no. 12-187. This research was supported in part by the University of Nebraska-Lincoln Research Council and NIH Biomedical Research Support Grant # RR-07055     

Phylogenetic relationships of turfgrasses as revealed by restriction fragment analysis of chloroplast DNA

Chloroplast DNAs (cpDNAs) were analyzed in order to clarify the phylogenetic relationships among turfgrasses. Physical maps of cpDNAs from Agrostis stolonifera and Zoysia japonica, which are representative species of cool (C3 type) and warm (C4 type) season turfgrasses, respectively, were constructed with four restriction enzymes, i.e., PstI, SalI, SacI, and XhoI. The genome structures of these cpDNAs were found to be similar to each other in terms of genome size and gene orders, showing thereby a similarity to other grass cpDNAs. CpDNAs of 5 species of cool season turfgrasses and 6 species of warm season turfgrasses as well as four species of cereals, distributed among 14 genera of Gramineae, were digested with PstI, XhoI, and BamHI, and their restriction fragment patterns were compared. Their genome sizes were estimated to be 135–140 kbp. Each species showed characteristic RFLP patterns. On the basis of the frequency of commonly shared fragments, a dendrogram showing the phylogenetic relationships among their cpDNAs was constructed. This dendrogram shows that turfgrasses can be divided into three major groups; these correspond to the subfamilies. Cool and warm season turfgrasses are clearly distinguishable from each other, and the latter can be further classified into two subgroups that correspond to Eragrostoideae and Panicoideae. Our classification of turfgrasses and cereals by RFLP analysis of cpDNA agreed in principal with their conventional taxonomy, except for the location of Festuca and Lolium.Contribution no. 101 from the Kihara Institute for Biological Research, Yokohama City University, Yokohama 232, Japan     

Transfer of chloroplast genomic DNA to mitochondrial genome occurred at least 300 MYA

With the completion of the first gymnosperm mitochondrial genome (mtDNA) from Cycas taitungensis and the availability of more mtDNA taxa in the past 5 years, we have conducted a systematic analysis of DNA transfer from chloroplast genomes (cpDNAs) to mtDNAs (mtpts) in 11 plants, including 2 algae, 1 liverwort, 1 moss, 1 gymnosperm, 3 monocots, and 3 eudicots. By using shared gene order and boundaries between different mtpts as the criterion, the timing of cpDNA transfer during plant evolution was estimated from the phylogenetic tree reconstructed independently from concatenated protein-coding genes of 11 available mtDNAs. Several interesting findings emerged. First, frequent DNA transfer from cpDNA to mtDNA occurred at least as far back as the common ancestor of extant gymnosperms and angiosperms, about 300 MYA. The oldest mtpt is trnV(uac)-trnM(cau)-atpE-atpB-rbcL. Three other mtpts--psaA-psaB, rps19-trnH(gug)-rpl2-rpl23, and psbE-psbF--were dated to the common ancestor of extant angiosperms, at least 150 MYA. However, all protein-coding genes of mtpts have degenerated since their first transfer. Therefore, mtpts contribute nothing to the functioning of mtDNA but junk sequences. We discovered that the cpDNA transfers have occurred randomly at any positions of the cpDNAs. We provide strong evidence that the cp-derived tRNA-trnM(cau) is the only mtpt (1 out of 3 cp-derived tRNA shared by seed plants) truly transferred from cpDNA to mtDNA since the time of the common ancestor of extant gymnosperms and angiosperms. Our observations support the proposition of Richly and Leister (2004) that "primary insertions of organellar DNAs are large and then diverge and fragment over evolutionary time."     

Extensive gene rearrangements in the chloroplast DNAs of Chlamydomonas species featuring multiple dispersed repeats

We have constructed a physical and gene map for the chloroplast DNA (cpDNA) of the unicellular green alga Chlamydomonas gelatinosa, a close relative of Chlamydomonas reinhardtii. At 285 kb, the C. gelatinosa cpDNA is 89 kb larger than its C. reinhardtii counterpart. The alterations in the order of 77 genes on the cpDNAs of these green algae are attributable to nine inversions and one event of expansion/contraction of the inverted repeat. These rearrangements are much more extensive than those previously reported between the cpDNAs of the closely related Chlamydomonas moewusii and Chlamydomonas pitschmannii. Because the divergence level of the C. gelatinosa and C. reinhardtii chloroplast-encoded large subunit rRNA gene sequences is equivalent to that of the corresponding C. moewusii and C. pitschmannii sequences, our results may suggest that, in the same period of time, there have been more numerous rearrangements in the lineage comprising C. gelatinosa and C. reinhardtii than in the lineage comprising C. moewusii and C. pitschmannii. Alternatively, given that substitution rates in chloroplast genes are not necessarily uniform across lineages, the extensive rearrangements between the C. gelatinosa and C. reinhardtii cpDNAs may reflect a longer divergence period for this pair of Chlamydomonas species compared to that for the C. moewusii/C. pitschmannii pair. We have also found that, like its C. reinhardtii homologue but unlike its C. moewusii and C. pitschmannii counterparts, the C. gelatinosa cpDNA features a large number of dispersed repeated sequences that are readily detectable by Southern blot hybridization with homologous fragment probes. Assuming that the two pairs of closely related Chlamydomonas species diverged at about the same time, these data suggest that the susceptibility of Chlamydomonas cpDNAs to rearrangements is correlated with the abundance of repeated sequences. Preliminary characterization of a 345-bp C. gelatinosa cpDNA region containing a repeated sequence by both DNA sequencing and Southern blot analysis has revealed no sequence homology between this region and the cpDNAs of C. reinhardtii and other Chlamydomonas species.