Cloning and characterization of chloroplast ribosomal protein-encoding genes, rpl16 and rps3, of the marine macro-algae, Gracilaria tenuistipitata

In Gracilaria tenuistipitata, a highly differentiated multicellular member of the marine red algae, Rhodophyta, chloroplast (cp) DNA can be separated as a satellite band from the nuclear DNA in a CsCl gradient. Using a heterologous probe from Chlamydomonas, the ribosomal protein-encoding gene, rpl16, was located on a 4.5-kb EcoRI fragment of cp DNA. The fragment was cloned and a 1365-bp region around rpl16 was sequenced. The gene order around rpl16, 5′ rpl22-rps3-rpl16, is identical to that detected in the chloroplast DNA of liverwort, tobacco and maize. Both the nucleotide sequence and the amino-acid sequence of rpl16 are more conserved than that of rps3. The rpl16 gene contains no intron, a feature which shows more similarity to the unicellular green algae, Chlamydomonas, than the other land plants. Sequences that may form a stable stem-loop structure were detected within the coding sequence of rpl16.     

梅花草属叶绿体基因组进化分析

叶绿体基因组序列变异和基因组成等特征可有效反映植物类群间的系统发育和进化关系。本研究利用Illumina高通量测序平台对梅花草属（Parnassia）及其近缘属5种植物的叶绿体基因组进行测序和组装,同时基于已发表的近缘种叶绿体基因组信息,对梅花草属叶绿体基因组结构特征、序列遗传变异和蛋白编码基因密码子偏好性比对分析。结果显示：梅花草属叶绿体基因组整体结构较为保守,均为四分体结构;梅花草多个基因出现假基因化,而本属其他物种叶绿体基因组成一致,均编码115个基因;与近缘属物种相比,本属所有物种均丢失rpl16基因的内含子;蛋白质编码基因的非同义/同义替代率比值较低,叶绿体基因可能经历纯化选择作用;密码子偏好性聚类结果与蛋白编码序列重建的系统发育关系结果一致。本研究表明选择压力可能在梅花草属叶绿体基因组蛋白编码基因进化过程中发挥作用,有助于进一步理解梅花草属植物的进化和适应机制。     

Chloroplast phylogenomics of unicellular and colonial Volvocales provides perspectives on the evolution of morphological characters

Volvocales forms a species-rich clade with wide morphological variety and is regarded as an ideal model for tracing the evolutionary transitions in multicellularity. The phylogenetic relationships among the colonial volvocine algae and its relatives are important for investigating the origin of multicellularity in the clade Reinhardtinia. Therefore, a robust phylogenetic framework of the unicellular and colonial volvocine algae with broad taxon and gene sampling is essential for illuminating the evolution of multicellularity. Recent chloroplast phylogenomic studies have uncovered five major orders in the Chlorophyceae, but the family-level relationships within Sphaeropleales and Volvocales remain elusive due to the uncertain positions of some incertae sedis taxa. In this study, we contributed six newly sequenced chloroplast genomes in the Volvocales and analyzed a dataset with 91 chlorophycean taxa and 58 protein-coding genes. Conflicting phylogenetic signals were detected among chloroplast genes that resulted in discordant tree topologies among different analyses. We compared the phylogenetic trees inferred from original nucleotide, RY-coding, codon-degenerate, and amino acid datasets, and improved the robustness of phylogenetic inference in the Chlorophyceae by reducing base compositional bias. Our analyses indicate that the unicellular Chlamydomonas and Vitreochlamys are close to or nested within the colonial taxa, and all the incertae sedis taxa are nested within the monophyletic Sphaeropleales s.l. We propose that the colonial taxa in the Reinhardtinia are paraphyletic and multicellularity evolved once in the volvocine green algae and might be lost in Chlamydomonas and Vitreochlamys.     

丝兰属6种植物叶绿体基因组特征分析

为了理清丝兰属（Yucca）叶绿体基因组特征和序列变异情况,进行丝兰属植物叶绿体比较基因组学分析,并构建基于叶绿体基因组的系统发育树。利用高通量测序技术获得无刺龙舌兰（Y. treculeana）叶绿体基因组序列,结合丝兰属现已发表的叶绿体基因组,使用生物信息学方法对6种丝兰属植物叶绿体全基因组进行基本结构、重复序列、边界收缩与扩张以及序列变异分析等在内的比较基因组学研究,并进行系统发育分析。结果表明：6种丝兰属植物叶绿体基因组大小、基因的类型及数目相近,种间基因组结构比较保守;从丝兰属植物叶绿体基因组中检测到多条重复序列,其中SSR位点多是由单核苷酸、双核苷酸和四核苷酸组成,且偏好使用A、T碱基;根据核酸多态性指数π≥0.008,在6种丝兰属植物叶绿体基因组中筛选出了psbK-psbl-trnS-GCU、rpl20-rps12和ccsA-ndhD 3个高变异区域;基于叶绿体全基因组和LSC+SSC区序列构建的系统发育关系基本一致,确定了6种丝兰属植物间的系统发育关系,其中无刺龙舌兰与克雷塔罗丝兰（Y. queretaroensis）的亲缘关系最近。本研究测序获得了无刺龙舌兰叶绿体基因组,揭示了6种丝兰属植物叶绿体基因组特征和序列变异情况,明确了各物种间的亲缘关系,研究结果可为后续丝兰属植物分子标记开发及系统发育研究提供参考。     

Herbarium phylogenomics: Resolving the generic status of the enigmatic Pseudobartsia (Orobanchaceae)

The millions of herbarium specimens in collections around the world provide historical resources for phylogenomics and evolutionary studies. Many rare and endangered species exist only as historical specimens. Here, we report a case study of the monotypic Pseudobartsia yunnanensis D. Y. Hong (=Pseudobartsia glandulosa[Bentham] W. B. Yu & D. Z. Li: Orobanchaceae) known from a single Chinese collection taken in 1940. We obtained genomic data of Pseudobartsia glandulosa using high-throughput short-read sequencing, and then assembled a complete chloroplast genome and nuclear ribosome DNA region in this study. We found that the newly assembled three plastid DNA regions (atpB-rbcL, rpl16, and trnS-G) and nuclear ribosomal internal transcribed spacer (nrITS) of Pseudobartsia glandulosa were more than 99.98% similar to published sequences obtained by target sequencing. Phylogenies of Orobanchaceae using 30 plastomes (including 10 new plastomes), using both supermatrix and multispecies coalescent approaches following a novel plastid phylogenomic workflow, recovered seven recognized tribes and two unranked groups, both of which were proposed as new tribes, that is, Brandisieae and Pterygielleae. Within Pterygielleae, all analyses strongly supported Xizangia D. Y. Hong as the first diverging genus, with Pseudobartsia D. Y. Hong as sister to Pterygiella Oliver + Phtheirospermum Bunge (excluding Phtheirospermum japonicum [Thunberg] Kanitz); this supports reinstatement of Pseudobartsia and Xizangia. Although elements of Buchnereae-Cymbarieae-Orobancheae and Brandisieae-Pterygielleae-Rhinantheae showed incongruence among gene trees, the topology of the supermatrix tree was congruent with the majority of gene trees and functional-group trees. Therefore, most plastid genes are evolving as a linkage group, allowing the supermatrix tree approach to yield internally consistent phylogenies for Orobanchaceae.     

Acyl carrier protein-derived sequence encoded by the chloroplast genome in the marine diatom Cylindrotheca sp. strain N1.

The chloroplast genome of chromophytic and rhodophytic algae differs from the plastid genome of plants and green algae in that it encodes the gene for the small subunit (rbcS) of ribulose 1,5-bisphosphate carboxylase/oxygenase. Hybridization studies indicated that there was a second region of chloroplast DNA from the marine diatom Cylindrotheca sp. strain N1 that strongly hybridized to a previously isolated Cylindrotheca fragment that contained the rbcS gene and flanking sequences. Subsequent determination of the oligonucleotide sequence of this second chloroplast DNA fragment, however, indicated that hybridization was due to identical sequences 3' to the previously cloned Cylindrotheca chloroplast rbcL rbcS genes. Sequences derived from the 5' end of the second chloroplast DNA fragment contained a short open reading frame of 80 amino acids which was found to be highly homologous to bacterial acyl carrier protein and nuclear-encoded acyl carrier protein from plants. Amino acid residues in the environment of Ser-36 of the Escherichia coli protein, which is bound to a 4'-phosphopantetheine moiety, are virtually identical in the Cylindrotheca deduced sequence and all other sources of this protein. Unlike plant acyl carrier-deduced amino acid sequences, there was no leader peptide sequence found for the presumptive Cylindrotheca protein, consistent with the location of this DNA fragment on the chloroplast genome of this organism. DNA encoding the putative acyl carrier protein gene and rbcS thus represent two genes that are chloroplast-encoded in the chromophytic marine diatom Cylindrotheca, a significant departure from the organization of such genes in plants.     

Structure and expression of the ornithine decarboxylase gene of Chlamydomonas reinhardtii

A cDNA was cloned encoding ornithine decarboxylase (ODC) of the unicellular green alga Chlamydomonas reinhardtii. The polypeptide consists of 396 amino acid residues with 35–37% sequence identity to other eukaryotic ODCs. As indicated by the phylogenetic tree calculated by neighbour joining analysis, the Chlamydomonas ODC has the same evolutionary distances to the ODCs of higher plants and mammalians. The Chlamydomonas ODC gene contains three introns of 222, 133, and 129 bp, respectively. As revealed by Northern-blot analyses, expression of the Chlamydomonas ODC gene is neither altered throughout the vegetative cell cycle nor modulated by exogenous polyamines.     

Loss of the rpl32 gene from the chloroplast genome and subsequent acquisition of a preexisting transit peptide within the nuclear gene in Populus

Gene transfer events from organelle genomes (mitochondria and chloroplasts in plants) to the nuclear genome are important processes in the evolution of the eukaryotic cell. It is highly likely that the gene transfer event is still an ongoing process in higher plant mitochondria and chloroplasts. The number and order of genes encoded in the chloroplast genome of higher plants are highly conserved. Recently, several exceptional cases of gene loss from the chloroplast genome have been discovered as the number of complete chloroplast genome sequences has increased. The Populus chloroplast genome has lost the rpl32 gene, while the corresponding the chloroplast rpl32 (cp rpl32) gene has been identified in the nuclear genome. Nuclear genes transferred from the chloroplast genome need to gain a sequence that encodes a transit peptide. Here, we revealed that the nuclear cp rpl32 gene has acquired the exon sequence, which is highly homologous to a transit peptide derived from the chloroplast Cu-Zn superoxide dismutase (cp sod-1) gene. The cp rpl32 gene has acquired the sequence that encodes not only for the transit peptide, but also for the conserved N-terminal portion of the mature SOD protein from the cp sod-1 gene, suggesting the occurrence of DNA sequence duplication. Unlike cp SOD-1, cp RPL32 did not show biased localization in the chloroplasts. This difference may be caused by mutations accumulated in the sequence of the SOD domain on the cp rpl32 gene. We provide new insight into the fate of the inherent sequence derived from a transit peptide.     

Molecular phylogeny and taxonomic revision of Chlamydomonas (Chlorophyta). I. Emendation of Chlamydomonas Ehrenberg and Chloromonas Gobi, and description of Oogamochlamys gen. nov. and Lobochlamys gen. nov

The genus Chlamydomonas (including Chloromonas) is one of the largest green algal genera comprising more than 600 species. To initiate a comprehensive analysis of the phylogeny and systematics of the genus, we determined nuclear-encoded SSU rRNA sequences from 32 strains of Chlamydomonas, Chloromonas and Chlorogonium with emphasis on oogamous taxa and related strains, and incorporated these into global molecular phylogenetic analyses of 132 strains of Chlorophyceae. In addition, we studied the morphology and reproduction of oogamous and related strains by light microscopy. We recognize and designate 18 monophyletic lineages (clades) within the Chlorophyceae, 11 of which are confined to the CW (basal bodies displaced clockwise) subgroup. The majority of clades recognized within the Chlorophyceae do not correspond to any of the traditional classification systems, which are still largely based on the organization level. Strains assigned to Chlamydomonas and Chloromonas were found in seven different clades confirming the polyphyly of the two genera as presently conceived. To initiate the taxonomic revision of Chlamydomonas, C. reinhardtii is proposed as the conserved type of the genus. In consequence, species in clades other than the clade containing C. reinhardtii must be transferred to other genera, a process initiated in this contribution. The oogamous strains studied represent a monophyletic lineage, which is described as Oogamochlamys gen. nov. comprising three species (O. gigantea, O. zimbabwiensis and O. ettlii spec. nov.). The sister clade to Oogamochlamys consists of isogamous strains characterized by chloroplasts with incisions and is described as Lobochlamys gen. nov. with two species (L. culleus and L. segnis). Another clade is characterized by asteroid or perforated, parietal chloroplasts and contains the type species of Chloromonas (C. reticulata). Thus, the polyphyletic Chloromonas (traditionally defined as “Chlamydomonas without pyrenoids”) can be legitimized as a monophyletic genus by restriction to this clade and is here emended on the basis of chloroplast characters (the clade contains strains with or without pyrenoids thus rejecting the character “absence of pyrenoids”).     

Oxygen-exchange studies in Chlamydomonas mutants deficient in photosynthetic electron transport: Evidence for a Photosystem II-dependent oxygen uptake in vivo

Photosynthetic oxygen exchange has been measured using ¹⁸O₂ and the mass-spectrometric technique in two mutant strains of Chlamydomonas reinhardtii deficient in electron transport. In the F15 mutant, deficient in PS I, O₂ was evolved in the light at a constant rate of about 145 nmol O₂/min per mg chlorophyll. At the same time, O₂ uptake was increased in the light by about 28%. O₂ evolution and the light-stimulation of O₂ uptake were inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea. Antimycin A and salicylhydroxamic acid, both inhibitors of mitochondrial respiration, when added together, inhibited dark respiration and also the light-dependent O₂ evolution by about 80%. Similar properties were observed in a mutant strain of Chlamydomonas (F18) lacking the cytochrome b₆-f complex. We conclude from these results that in the absence of active Photosystem I, a permanent electron flow can occur in the light from Photosystem II to molecular O₂. This electron transfer pathway would involve the plastoquinone pool and the mitochondrial electron transport chain. Because O₂ evolution measured in the F15 mutant was severely inhibited by the uncoupler cyanide m-chlorophenylhydrazone, we propose that an energy-dependent reverse electron transfer similar to that of Rhodospirillaceae might occur in the chloroplast of Chlamydomonas.     

青藏高原特有种-藏扇穗茅叶绿体基因组测序及序列分析

藏扇穗茅（Littledalea tibetica）是禾本科（Poaceae）雀麦族（Bromeae）中一个具有重要生态价值的多年生高山特有种,主要分布于青藏高原及其毗邻地区。本文采用基于第二代高通量测序平台的Illumina MiSeq技术,对青藏高原特有种—藏扇穗茅进行了叶绿体基因组测序,首次建立了雀麦族物种的标准测序流程;同时,以其近缘物种—黑麦草（Lolium perenne）的叶绿体基因组序列作为参考,组装获得它的叶绿体基因组序列。结果表明,藏扇穗茅叶绿体基因组序列全长136 852 bp,GC含量为38.5%,呈典型的四段式结构,其中大（LSC）、小（SSC）单拷贝区大小分别为80 970和12 876 bp,反向互补重复区（IR）大小为21 503 bp,共注释得到141个基因,包含95个蛋白编码基因、38个tRNA基因和8个rRNA基因,主要分布于大单拷贝区和小单拷贝区。同时,基于藏扇穗茅和其它30种禾本科植物叶绿体基因全序列构建的系统发育树显示,藏扇穗茅与早熟禾亚科中小麦族植物亲缘关系较近。     

DNA条形码在热带龙脑香科树种鉴定中的应用

龙脑香科植物是东南亚地区重要的热带木材来源树种, 对其开展DNA条形码评估在林业监管及森林资源保护等方面具有非常重要的实际应用价值。通过对龙脑香科植物样品进行rbcL、matK、trnL-trnF和ITS2四个片段的扩增和测序, 结合GenBank下载的数据, 共获得龙脑香科树种14属244种共计899条序列。通过比较4个片段的通用性、序列特征、种内和种间的遗传变异, 基于Best Match (BM)、Best Close Match (BCM)、相似性搜索算法(BLAST)和邻接树(NJ) 4种方法评估DNA条形码对于龙脑香科树种的鉴定能力。结果表明, ITS2在龙脑香科树种中鉴定效率最高, 通过优化的扩增体系能够从该科植物叶片中获得较高质量的ITS2片段; 叶绿体matK片段扩增和测序效率为100%, 且种内及种间遗传变异明显, 鉴定成功率高于其它叶绿体片段, 并据此提出ITS2和matK适合作为龙脑香科树种的DNA条形码。     

水稻叶绿体16S启动子克隆改造、载体构建及转化研究

利用PCR方法从水稻叶绿体基因组DNA中分离16S启动子,并在其下游加入rbcL基因SD序列,以增强该启动子的翻译能力;序列分析表明,除加入的SD序列外,扩增片段与水稻(Oryza sativa)叶绿体基因组DNA序列16S启动子相应区域同源性为100％。将16S启动子与bar基因和gfp基因的融合基因连接,以psbA基因的3′序列为终止子,并以烟草叶绿体trnH—psbA和trnK为同源片段构建了烟草叶绿体表达载体pRl6S。用基因枪转化烟草,转化植株经Southern、Northern检测及后代遗传学分析,发现：16S启动子具有启动活性,融合基因已在烟草叶绿体中稳定整合并遵循母系遗传规律。     

DNA条形码在热带龙脑香科树种鉴定中的应用

龙脑香科植物是东南亚地区重要的热带木材来源树种, 对其开展DNA条形码评估在林业监管及森林资源保护等方面具有非常重要的实际应用价值。通过对龙脑香科植物样品进行rbcL、matK、trnL-trnF和ITS2四个片段的扩增和测序, 结合GenBank下载的数据, 共获得龙脑香科树种14属244种共计899条序列。通过比较4个片段的通用性、序列特征、种内和种间的遗传变异, 基于Best Match (BM)、Best Close Match (BCM)、相似性搜索算法(BLAST)和邻接树(NJ) 4种方法评估DNA条形码对于龙脑香科树种的鉴定能力。结果表明, ITS2在龙脑香科树种中鉴定效率最高, 通过优化的扩增体系能够从该科植物叶片中获得较高质量的ITS2片段; 叶绿体matK片段扩增和测序效率为100%, 且种内及种间遗传变异明显, 鉴定成功率高于其它叶绿体片段, 并据此提出ITS2和matK适合作为龙脑香科树种的DNA条形码。     

水稻叶绿体16S启动子克隆改造、载体构建及转化研究

利用PCR方法从水稻叶绿体基因组DNA中分离16S启动子, 并在其下游加入rbcL基因SD序列,以增强该启动子的翻译能力;序列分析表明, 除加入的SD序列外, 扩增片段与水稻（Oryza sativa）叶绿体基因组DNA序列16S启动子相应区域同源性为100%。将16S启动子与bar基因和gfp基因的融合基因连接,以psbA基因的3′序列为终止子, 并以烟草叶绿体trnH-psbA和trnK为同源片段构建了烟草叶绿体表达载体pR16S。 用基因枪转化烟草, 转化植株经Southern、Northern检测及后代遗传学分析, 发现16S启动子具有启动活性, 融合基因已在烟草叶绿体中稳定整合并遵循母系遗传规律。