Nucleotide sequence of soybean chloroplast DNA regions which contain the psb A and trn H genes and cover the ends of the large single copy region and one end of the inverted repeats.

The soybean chloroplast psb A gene (photosystem II thylakoid membrane protein of Mr 32 000, lysine-free) and the trn H gene (tRNAHisGUG), which both map in the large single copy region adjacent to one of the inverted repeat structures (IR1), have been sequenced including flanking regions. The psb A gene shows in its structural part 92% sequence homology with the corresponding genes of spinach and N. debneyi and contains also an open reading frame for 353 aminoacids. The aminoacid sequence of a potential primary translation product (calculated Mr, 38 904, no lysine) diverges from that of spinach and N. debneyi in only two positions in the C-terminal part. The trn H gene has the same polarity as the psb A gene and the coding region is located at the very end of the large single copy region. The deduced sequence of the soybean chloroplast tRNAHisGUG is identical with that of Zea mays chloroplasts. Both ends of the large single copy region were sequenced including a small segment of the adjacent IR1 and IR2.     

The enigma of the gene coding for ribosomal protein S12 in the chloroplasts of Nicotiana.

A 2.9 kbp region from within the inverted repeat of Nicotiana chloroplast DNA hybridized with a chloroplast DNA fragment from Euglena containing the complete rps12 gene coding for ribosomal protein S12. Nucleotide sequencing within this region revealed the existance of two rps12 coding stretches interrupted by 540 bp having class II intron structure. Joining and decoding the exon regions produced a sequence of 85 amino acids colinear and 81% homologous to the S12 protein of Euglena chloroplasts and E. coli, starting from amino acid residue 38 to the stop codon. Immediately upstream of codon 38, conserved intron sequences were located. However, the 5' 37 codon of Nicotiana chloroplast rps12 could not be identified by electron microscopy of RNA-DNA hybrids within a DNA region extending 4000 bp upstream of codon 38, nor by computer search of a completely sequenced region extending for more than 9000 bp upstream of this codon. In E. coli, alteration in rps12 codons 42 or 87 causes streptomycin resistance. However, the nucleotide sequence of the identified rps12 exons in two Nicotiana chloroplast mutants resistant to streptomycin were found to be identical to that of wild type.     

Chloroplast mRNA 3'' end processing requires a nuclear-encoded RNA-binding protein.

The protein coding regions of plastid mRNAs in higher plants are generally flanked by 3' inverted repeat sequences. In spinach chloroplast mRNAs, these inverted repeat sequences can fold into stem-loop structures and serve as signals for the correct processing of the mature mRNA 3' ends. The inverted repeat sequences are also required to stabilize 5' upstream mRNA segments, and interact with chloroplast protein in vitro. To dissect the molecular components involved in chloroplast mRNA 3' end processing and stability, a spinach chloroplast protein extract containing mRNA 3' end processing activity was fractionated by FPLC and RNA affinity chromatography. The purified fraction consisted of several proteins and was capable of processing the 3' ends of the psbA, rbcL, petD and rps14 mRNAs. This protein fraction was enriched for a 28 kd RNA-binding protein (28RNP) which interacts with both the precursor and mature 3' ends of the four mRNAs. Using specific antibodies to this protein, the poly(A) RNA-derived cDNA for the 28RNP was cloned and sequenced. The predicted amino acid sequence for the 28RNP reveals two conserved RNA-binding domains, including the consensus sequences RNP-CS1 and CS2, and a novel acidic and glycine-rich N-terminal domain. The accumulation of the nuclear-encoded 28RNP mRNA and protein are developmentally regulated in spinach cotyledons, leaves, root and stem, and are enhanced during light-dependent chloroplast development. The general correlation between accumulation of the 28RNP and plastid mRNA during development, together with the result that depletion of the 28RNP from the chloroplast protein extract interferes with the correct 3' end processing of several chloroplast mRNAs, suggests that the 28RNP is required for plastid mRNA 3' end processing and/or stability.     

Mapping of genes on the chloroplast DNA of Spirodela oligorhiza

With the use of spinach chloroplast RNAs as probes, we have mapped the rRNA genes and a number of protein genes on the chloroplast DNA (cpDNA) of the duckweed Spirodela oligorhiz. For a more precise mapping of these genes we had to extend the previously determined [14] restriction endonuclease map of the duckweed cpDNA with the cleavage sites for the restriction endonucleases Sma I and Bgl I. The physical map indicates that duckweed cpDNA contains two inverted repeat regions (18 Md) separated by two single copy regions with a size of 19 Md and 67 Md, respectively.By hybridization with spinach chloroplast rRNAs it could be shown that each of the two repeat units contains one set of rRNA genes in the order: 16S rRNA gene — spacer — 23S rRNA gene — 5S rRNA gene.A spinach chloroplast mRNA preparation (14S RNA), which is predominantly translated into a 32 Kilodalton (Kd) protein [9], hybridized strongly to a DNA fragment in the large single copy region, immediately outside one of the inverted repeats. With another mRNA preparation (18S), which mainly directs the in vitro synthesis of a 55 Kd protein [9], hybridization was observed with two DNA regions, located between 211° and 233° and between 137° and 170°, respectively. Finally, with a spinach chloroplast genomic probe for the large subunit of ribulose 1,5-bisphosphate carboxylase [17], hybridization was found with a DNA fragment located between 137° and 158° on the map.     

A method for determining the presence of inverted repeats in the chloroplast genome of higher plants]

A plasmid containing fragments of rp12 and rps19 genes from the chloroplast genome of Arabidopsis thaliana was developed. The presence of inverted repeats in the chloroplast DNA of A. thaliana and Vicia sativa, and their absence from two species of Fabaceae family (Lathyrus sativus, Lens esculenta) were shown with the help of this plasmid.     

Complete structure of the chloroplast genome of a legume, Lotus japonicus.

The nucleotide sequence of the entire chloroplast genome (150,519 bp) of a legume, Lotus japonicus, has been determined. The circular double-stranded DNA contains a pair of inverted repeats of 25,156 bp which are separated by a small and a large single copy region of 18,271 bp and 81,936 bp, respectively. A total of 84 predicted protein-coding genes including 7 genes duplicated in the inverted repeat regions, 4 ribosomal RNA genes and 37 tRNA genes (30 gene species) representing 20 amino acids species were assigned on the genome based on similarity to genes previously identified in other chloroplasts. All the predicted genes were conserved among dicot plants except that rpl22, a gene encoding chloroplast ribosomal protein CL22, was missing in L. japonicus. Inversion of a 51-kb segment spanning rbcL to rpsl6 (positions 5161-56,176) in the large single copy region was observed in the chloroplast genome of L. japonicus. The sequence data and gene information are available on our World Wide Web database at http://www.kazusa.or.jp/en/plant/database.html.     

ORGANIZATION OF THE CHLOROPLAST GENOME OF THE FRESHWATER CENTRIC DIATOM CYCLOTELLA MENEGHINIANA1

We constructed a complete physical map and a partial gene map of the chloroplast genome of Cyclotella meneghiniana Kützing clone 1020-1a (Bacillariophyceae). The 128-kb circular molecule contains a 17-kb inverted repeat, which divides the genome into single copy regions of65 kb and 29 kb. This is the largest genome and inverted repeat found in any diatom examined to date. In addition to the 16S and 23S ribosomal RNA genes, the inverted repeat contains both the ndhD gene (as yet unexamined in other diatoms) and the psbA gene (located similarly in one of two other examined diatoms). The Cyclotella chloroplast genome exists as two equimolar populations of inversion isomers that differ in the relative orientation of their single copy sequences. This inversion heterogeneity presumably results from intramolecular recombination within the inverted repeat. For the first time, we map the ndhD, psaC, rpofi, rpoCl, and rpoC2 genes to the chloroplast genome of a chlorophyll c-containing alga. While the Cyclotella chloroplast genome retains some prokaryotic and land plant gene clusters and operons, it contains a highly rearranged gene order in the large and small single copy regions compared to all other examined diatom, algal, and land plant chloroplast genomes.     

Sequence organization of repetitive elements in the flanking regions of the chloroplast ribosomal unit of Chlamydomonas reinhardii.

The flanking regions and the end of the chloroplast ribosomal unit of Chlamydomonas reinhardii have been sequenced. The upstream region of the ribosomal unit contains three open reading frames coding for 111, 117 and 124 amino acids, respectively. The latter polypeptide is partially related to the ribosomal protein L16 of E. coli. Two of the open reading frames overlap each other and are oriented in opposite direction. The region between these open reading frames and the 5' end of the 16S rRNA gene contains numerous short direct and inverted repeats which can be folded into large stem-loop structures. Sequence elements that resemble prokaryotic promoters are found in the same region. Several of the repeated elements are distributed throughout the non-coding regions of the chloroplast inverted repeat. Sequence comparison between the 5S rRNA and its gene does not reveal any significant sequence heterogeneity between the chloroplast 5S rRNA genes.     

Complete Sequence of the Duckweed (<Emphasis Type="Italic">Lemna minor</Emphasis>) Chloroplast Genome: Structural Organization and Phylogenetic Relationships to Other Angiosperms

The complete nucleotide sequence of the duckweed (Lemna minor) chloroplast genome (cpDNA) was determined. The cpDNA is a circular molecule of 165,955 bp containing a pair of 31,223-bp inverted repeat regions (IRs), which are separated by small and large single-copy regions of 89,906 and 13,603 bp, respectively. The entire gene pool and relative positions of 112 genes (78 protein-encoding genes, 30 tRNA genes, and 4 rRNA genes) are almost identical to those of Amborella trichopoda cpDNA; the minor difference is the absence of infA and ycf15 genes in the duckweed cpDNA. The inverted repeat is expanded to include ycf1 and rps15 genes; this pattern is unique and does not occur in any other sequenced cpDNA of land plants. As in basal angiosperms and eudicots, but not in other monocots, the borders between IRs and a large single-copy region are located upstream of rps19 and downstream of trnH, so that trnH is not included in IRs. The model of rearrangements of the chloroplast genome during the evolution of monocots is proposed as the result of the comparison of cpDNA structures in duckweed and other monocots. The phylogenetic analyses of 61 protein-coding genes from 38 plastid genome sequences provided strong support for the monophyly of monocots and position of Lemna as the next diverging lineage of monocots after Acorales. Our analyses also provided support for Amborella as a sister to all other angiosperms, but in the bayesian phylogeny inference based on the first two codon positions Amborella united with Nymphaeales.     

蕨类植物叶绿体rps12基因的分子进化研究

以68种蕨类植物和2种石松类植物的rps12基因为对象,在系统发育背景下,结合最大似然法,使用HyPhy和PAML软件对该基因进行进化速率和适应性进化研究。结果显示:位于IR区的外显子2~3,其替换率明显降低,rps12基因编码序列的替换率也随之降低,且rps12基因密码子第3位的GC含量明显升高;在蕨类植物的进化过程中,3′-rps12更倾向定位于IR区,以保持较低的替换率;rps12基因编码的123个氨基酸位点中,共检测到4个正选择位点和116个负选择位点。研究结果表明基因序列进入到IR区后,显示出降低的替换率;强烈的负选择压力表明RPS12蛋白的高度保守性以及rps12基因的功能和结构已经趋于稳定。     

The complete nucleotide sequence of the coffee (Coffea arabica L.) chloroplast genome: organization and implications for biotechnology and phylogenetic relationships amongst angiosperms

The chloroplast genome sequence of Coffea arabica L., the first sequenced member of the fourth largest family of angiosperms, Rubiaceae, is reported. The genome is 155 189 bp in length, including a pair of inverted repeats of 25 943 bp. Of the 130 genes present, 112 are distinct and 18 are duplicated in the inverted repeat. The coding region comprises 79 protein genes, 29 transfer RNA genes, four ribosomal RNA genes and 18 genes containing introns (three with three exons). Repeat analysis revealed five direct and three inverted repeats of 30 bp or longer with a sequence identity of 90% or more. Comparisons of the coffee chloroplast genome with sequenced genomes of the closely related family Solanaceae indicated that coffee has a portion of rps19 duplicated in the inverted repeat and an intact copy of infA . Furthermore, whole-genome comparisons identified large indels (> 500 bp) in several intergenic spacer regions and introns in the Solanaceae, including trnE (UUC)– trnT (GGU) spacer, ycf4 – cemA spacer, trnI (GAU) intron and rrn5 – trnR (ACG) spacer. Phylogenetic analyses based on the DNA sequences of 61 protein-coding genes for 35 taxa, performed using both maximum parsimony and maximum likelihood methods, strongly supported the monophyly of several major clades of angiosperms, including monocots, eudicots, rosids, asterids, eurosids II, and euasterids I and II. Coffea (Rubiaceae, Gentianales) is only the second order sampled from the euasterid I clade. The availability of the complete chloroplast genome of coffee provides regulatory and intergenic spacer sequences for utilization in chloroplast genetic engineering to improve this important crop.     

Complete Chloroplast Genome Sequence of <Emphasis Type="Italic">Glycine max</Emphasis> and Comparative Analyses with other Legume Genomes

Lack of complete chloroplast genome sequences is still one of the major limitations to extending chloroplast genetic engineering technology to useful crops. Therefore, we sequenced the soybean chloroplast genome and compared it to the other completely sequenced legumes, Lotus and Medicago. The chloroplast genome of Glycine is 152,218 basepairs (bp) in length, including a pair of inverted repeats of 25,574 bp of identical sequence separated by a small single copy region of 17,895 bp and a large single copy region of 83,175 bp. The genome contains 111 unique genes, and 19 of these are duplicated in the inverted repeat (IR). Comparisons of Glycine, Lotus and Medicago confirm the organization of legume chloroplast genomes based on previous studies. Gene content of the three legumes is nearly identical. The rpl22 gene is missing from all three legumes, and Medicago is missing rps16 and one copy of the IR. Gene order in Glycine, Lotus, and Medicago differs from the usual gene order for angiosperm chloroplast genomes by the presence of a single, large inversion of 51 kilobases (kb). Detailed analyses of repeated sequences indicate that many of the Glycine repeats that are located in the intergenic spacer regions and introns occur in the same location in the other legumes and in Arabidopsis, suggesting that they may play some functional role. The presence of small repeats of psbA and rbcL in legumes that have lost one copy of the IR indicate that this loss has only occurred once during the evolutionary history of legumes.     

Chloroplast DNA in Pinus monticola

Summary Restriction sites on the chloroplast genome of Pinus monticola have been mapped, and the gene for the large subunit of ribulose bisphosphate carboxylase/oxygenase, the genes for the photosystem II polypeptides psbA, psbD and psbC, and the 16S and 23S ribosomal RNA genes have been located. The genome lacks the large inverted repeat characteristic of most angiosperms. The gene order is similar to that found in P. radiata. The presence of dispersed repeated sequences is likely. Two structural features, lack of a large inverted repeat and the presence of dispersed repeats, may confer a degree of variability on the genome which will prove useful in studies of population structure.     

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

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