Structural Analysis of rbcL Gene from an Endangered Plant，（Acanthopanax brachypus）

ＳｔｒｕｃｔｕｒａｌＡｎａｌｙｓｉｓｏｆｒｂｃＬＧｅｎｅｆｒｏｍａｎＥｎｄａｎｇｅｒｅｄＰｌａｎｔ,（Ａｃａｎｔｈｏｐａｎａｘｂｒａｃｈｙｐｕｓ）ＹＡＮＨｕａ－ｊｕｎ（严华军）;ＺＨＵＣｈｅｎｇ（朱）;ＷＵＮａｉ－ｈｕ（吴乃虎）（Ｉｎｓｔｉｔｕｔｅｏ...     

Noncoding sequences from the slowly evolving chloroplast inverted repeat in addition to rbcL data do not support gnetalean affinities of angiosperms

We developed PCR primers against highly conserved regions of the rRNA operon located within the inverted repeat of the chloroplast genome and used these to amplify the region spanning from the 3' terminus of the 23S rRNA gene to the 5' terminus of the 5S rRNA gene. The sequence of this roughly 500-bp region, which includes the 4.5S rRNA gene and two chloroplast intergenic transcribed spacer regions (cpITS2 and cpITS3), was determined from 20 angiosperms, 7 gymnosperms, and 16 ferns (21,700 bp). Sequences for the large subunit of ribulose bisphosphate carboxylase/oxygenase (rbcL) from the same or confamilial genera were analyzed in both separate and combined data sets. Due to the low substitution rate in the inverted repeat region, noncoding sequences in the cpITS region are not saturated with substitutions, in contrast to synonymous sites in rbcL, which are shown to evolve roughly six times faster than noncoding cpITS sequences. Several length polymorphisms with very clear phylogenetic distributions were detected in the data set. Results of phylogenetic analyses provide very strong bootstrap support for monophyly of both spermatophytes and angiosperms. No support for a sister group relationship between Gnetales and angiosperms in either cpITS or rbcL data was found. Rather, weak bootstrap support for monophyly of gymnosperms studied and for a basal position for the aquatic angiosperm Nymphaea among angiosperms studied was observed. Noncoding sequences from the inverted repeat region of chloroplast DNA appear suitable for study of land plant evolution.      

Rice mitochondrial genome contains a rearranged chloroplast gene cluster

Summary We have previously reported the isolation and partial sequence analysis of a rice mitochondrial DNA fragment (6.9 kb) which contains a transferred copy of a chloroplast gene cluster coding for the large subunit of ribulose-1,5-bisphosphate carboxylase (rbcL), and subunits of ATPase (atpB and atpE), methionine tRNA (trnM) and valine tRNA (trnV). We have now completely sequenced this 6.9 kb fragment and found it to also contain a sequence homologous to the chloroplast gene coding for the ribosomal protein L2 (rpl2), beginning at a site 430 bp downstream from the termination codon of rbcL. In the chloroplast genome, two copies of rpl2 are located at distances of 20 kb and 40 kb, respectively, from rbcL. We have sequenced these two copies of rice chloroplast rpl2 and found their sequences to be identical. In addition, a 151 bp sequence located upstream of the chloroplast rpl2 coding region is also found in the 3 noncoding region of chloroplast rbcL and other as yet undefined locations in the rice chloroplast genome. Hybridization analysis revealed that this 151 bp repeat sequence identified in rice is also present in several copies in 11 other plant species we have examined. Findings from these studies suggest that the translocation of rpl2 to the rbcL gene cluster found in the rice mitochondrial genome might have occurred through homologous recombination between the 151 bp repeat sequence present in both rpl2 and rbcL.     

Molecular Analysis of the Hot Spot Region Related to Length Mutations in Wheat Chloroplast Dnas. I. Nucleotide Divergence of Genes and Intergenic Spacer Regions Located in the Hot Spot Region

The nucleotide divergence of chloroplast DNAs around the hot spot region related to length mutation in Triticum (wheat) and Aegilops was analyzed. DNA sequences (ca. 4.5 kbp) of three chloroplast genome types of wheat complex were compared with one another and with the corresponding region of other grasses. The sequences region contained rbcL and psaI, two open reading frames, and a pseudogene, rpl23' (pseudogene for ribosomal protein L23) disrupted by AT-rich intergic spacer regions. The evolution of these genes in the closely related wheat complex is characterized by nonbiased nucleotide substitutions in terms of being synonymous/nonsynonymous, having A-T pressure transitions over transversions, and frequent changes at the third codon position, in contrast with the gene evolution among more distant plant groups where biased nucleotide substitutions have frequently occurred. The sequences of these genes had diverged almost in proportion to taxonomic distance. The sequence of the pseudogene rpl23' changed approximately two times faster than that of the coding region. Sequence comparison between the pseudogene and its protein-coding counterpart revealed different degrees of nucleotide homology in wheat, rice and maize, suggesting that the transposition timing of the pseudogene differed and/or that different rates of gene conversion operated on the pseudogene in the cpDNA of the three plant groups in Gramineae. The intergenic spacer regions diverged approximately ten times faster than the genes. The divergence of wheat from barley, and that from rice are estimated based on the nucleotide similarity to be 1.5, 10 and 40 million years, respectively.     

Molecular evolution and phylogeny of the atpB-rbcL spacer of chloroplast DNA in the true mosses.

The nucleotide variation of a noncoding region between the atpB and rbcL genes of the chloroplast genome was used to estimate the phylogeny of 11 species of true mosses (subclass Bryidae). The A+T rich (82.6%) spacer sequence is conserved with 48% of bases showing no variation between the ingroup and outgroup. Rooted at liverworts, Marchantia and Bazzania, the monophyly of true mosses was supported cladistically and statistically. A nonparametric Wilcoxon Signed-Ranks test Ts statistic for testing the taxonomic congruence showed no significant differences between gene trees and organism trees as well as between parsimony trees and neighbor-joining trees. The reconstructed phylogeny based on the atpB-rbcL spacer sequences indicated the validity of the division of acrocarpous and pleurocarpous mosses. The size of the chloroplast spacer in mosses fits into an evolutionary trend of increasing spacer length from liverworts through ferns to seed plants. According to the relative rate tests, the hypothesis of a molecular clock was supported in all species except for Thuidium, which evolved relatively fast. The evolutionary rate of the chloroplast DNA spacer in mosses was estimated to be (1.12 +/- 0.019) x 10(-10) nucleotides per site per year, which is close to the nonsynonymous substitution rates of the rbcL gene in the vascular plants. The constrained molecular evolution (total nucleotide substitutions, K approximately 0.0248) of the chloroplast DNA spacer is consistent with the slow evolution in morphological traits of mosses. Based on the calibrated evolutionary rate, the time of the divergence of true mosses was estimated to have been as early as 220 million years ago.     

Sequences downstream of the translation initiation codon are important determinants of translation efficiency in chloroplasts

The objective of this study was to determine if mRNA sequences downstream of the translation initiation codon are important for translation of plastid mRNAs. We have employed a transgenic approach, measuring accumulation of the neomycin phosphotransferase (NPTII) reporter enzyme translationally fused with 14 N-terminal amino acids encoded in the rbcL or atpB plastid genes. NPTII accumulation from wild-type and mutant rbcL and atpB segments was compared. We report that silent mutations in the rbcL segment reduced NPTII accumulation 35-fold. In contrast, mutations in the atpB mRNA reduced NPTII accumulation only moderately from approximately 7% (w/w) to approximately 4% (w/w) of the total soluble cellular protein, indicating that the importance of sequences downstream of the translation initiation codon are dependent on the individual mRNA. Information provided here will facilitate transgene design for high-level expression of recombinant proteins in chloroplasts by translational fusion with the N-terminal segment of highly expressed plastid genes or by introduction of silent mutations in the N-terminal part of the coding region.     

Amplification of noncoding chloroplast DNA for phylogenetic studies in lycophytes and monilophytes with a comparative example of relative phylogenetic utility from Ophioglossaceae

Noncoding DNA sequences from numerous regions of the chloroplast genome have provided a significant source of characters for phylogenetic studies in seed plants. In lycophytes and monilophytes (leptosporangiate ferns, eusporangiate ferns, Psilotaceae, and Equisetaceae), on the other hand, relatively few noncoding chloroplast DNA regions have been explored. We screened 30 lycophyte and monilophyte species to determine the potential utility of PCR amplification primers for 18 noncoding chloroplast DNA regions that have previously been used in seed plant studies. Of these primer sets eight appear to be nearly universally capable of amplifying lycophyte and monilophyte DNAs, and an additional six are useful in at least some groups. To further explore the application of noncoding chloroplast DNA, we analyzed the relative phylogenetic utility of five cpDNA regions for resolving relationships in Botrychium s.l. (Ophioglossaceae). Previous studies have evaluated both the gene rbcL and the trnL(UAA)-trnF(GAA) intergenic spacer in this group. To these published data we added sequences of the trnS(GCU)-trnG(UUC) intergenic spacer + the trnG(UUC) intron region, the trnS(GGA)-rpS4 intergenic spacer+rpS4 gene, and the rpL16 intron. Both the trnS(GCU)-trnG(UUC) and rpL16 regions are highly variable in angiosperms and the trnS(GGA)-rpS4 region has been widely used in monilophyte phylogenetic studies. Phylogenetic resolution was equivalent across regions, but the strength of support for the phylogenies varied among regions. Of the five sampled regions the trnS(GCU)-trnG(UUC) spacer+trnG(UUC) intron region provided the strongest support for the inferred phylogeny.     

Evaluation of atpB nucleotide sequences for phylogenetic studies of ferns and other pteridophytes

Inferring basal relationships among vascular plants poses a major challenge to plant systematists. The divergence events that describe these relationships occurred long ago and considerable homoplasy has since accrued for both molecular and morphological characters. A potential solution is to examine phylogenetic analyses from multiple data sets. Here I present a new source of phylogenetic data for ferns and other pteridophytes. I sequenced the chloroplast gene atpB from 23 pteridophyte taxa and used maximum parsimony to infer relationships. A 588-bp region of the gene appeared to contain a statistically significant amount of phylogenetic signal and the resulting trees were largely congruent with similar analyses of nucleotide sequences from rbcL. However, a combined analysis of atpB plus rbcL produced a better resolved tree than did either data set alone. In the shortest trees, leptosporangiate ferns formed a monophyletic group. Also, I detected a well-supported clade of Psilotaceae (Psilotum and Tmesipteris) plus Ophioglossaceae (Ophioglossum and Botrychium). The demonstrated utility of atpB suggests that sequences from this gene should play a role in phylogenetic analyses that incorporate data from chloroplast genes, nuclear genes, morphology, and fossil data.     

Natural Hybrids between Ligularia vellerea and L.subspicata (Asteraceae: Senecioneae)

Three types of intermediate morphological individuals were found in the sympatric distribution areas of Ligularia vellerea and Lsubspicata. These intermediate individuals were hypothesized to be the hybrids of these two species based on the detailed comparison of their morphological characters. To test this hypothesis, we compared the DNA sequence of Lvellerea, Lsubspicata and the intermediate individuals by using the internal transcribed spacer region of nuclear ribosomal and atpB rbcL intergenic spacer region of the chloroplast. Direct sequencing of ITS clearly had additives and then cloned sequencing cloned out two kinds of sequences that were identical to those putative parental species, thus these putative hybrids were approved. With different morphological characters among three types, their plastid donors were all Lsubspicata according to the maternal sequences of atpB rbcL.     

Generic realignment in primuloid families of the Ericales s.l.: a phylogenetic analysis based on DNA sequences from three chloroplast genes and morphology

The phylogenetic interrelationships in Primulaceae, Myrsinaceae, and Theophrastaceae were investigated using DNA sequence data from the chloroplast genes atpB, ndhF, and rbcL. The three genes were analyzed separately, together, and in combination with morphology, using parsimony jackknifing. The sequence data are further explored by analyses of first and second codon position only, third positions only, and transversions only. The results show that all codon positions contribute group support to the ndhF tree, whereas third codon positions provide most of the structure in the atpB and rbcL trees. Analyzed separately, transversions in atpB and rbcL have little structure, whereas in ndhF they produce a well-resolved tree. We conclude that the most informative and robust results are obtained from analyses with all codon positions included and that the tree resulting from the combined analysis of all available data provides the best estimate of phylogeny.The results show that Maesa is sister to all other taxa from the three families. Theophrastaceae are well supported, but both Myrsinaceae and Primulaceae are paraphyletic. We conclude that four families should be recognized, Maesaceae, Theophrastaceae, Primulaceae, and Myrsinaceae. For all families to be monophyletic, Samolus was transferred to Theophrastaceae, and Lysimachia, Anagallis, Trientalis, Glaux, Asterolinon, and Pelletiera were moved to the Myrsinaceae together with the genera Coris, Ardisiandra, and Cyclamen.