Deep genomic analysis of Coelastrella saipanensis (Scenedesmaceae,Chlorophyta): comparative chloroplast genomics of Scenedesmaceae

Many species belonging to the coccoid green algae genus Coelastrella are considered potential candidates for the large-scale production of natural pigments and biofuels. However, little is known about the structural, functional and molecular aspects of the chloroplast genomes (cpDNAs) of this genus. In the present study, the complete sequence of the cpDNA of strain FACHB-2138, which was further identified as Coelastrella saipanensis Hanagata based on morphological and molecular analyses, was elucidated. The 196 140 bp cpDNA sequence that was assembled as a circular map was found to possess the typical quadripartite structure. The two identical copies of 11 897 bp inverted repeat (IR) sequences were separated from one another by single copy regions. The large single copy region (LSC) was 104 949 bp, whereas the small single copy region (SSC) was 67 397 bp. The cpDNA encoded a total of 96 unique genes, which included 67 protein-coding genes, three rRNA genes and 26 tRNA genes. A total of 19 group I introns were annotated in this genome. Comparative analyses with three species from the family Scenedesmaceae showed C. saipanensis had a slightly expanded genome, higher GC content and less skewed distribution of its genes between the two DNA strands than that of the other three species. The cpDNA data deduced from the present study helps to expand our present understanding of plant systematics and phylogenetic reconstruction, and identify the possible biotechnological applications of the species belonging to the studied taxa.     

The complete chloroplast genome sequence of the endangered species Syringa pinnatifolia (Oleaceae)

Syringa pinnatifolia is an endangered endemic species in China with important ornamental and medicinal value, and it needs urgent protection. Here, we report the complete chloroplast (cp) genome structure of S. pinnatifolia and its evolution is inferred through comparative studies with related species. The S. pinnatifolia cp genome was 155 326 bp and contained a large single copy region (LSC) of 86 167 bp and a small single copy region (SSC) of 17 775 bp, as well as a pair of inverted repeat regions (IRs) of 25 692 bp. A total of 113 unique genes were annotated, including 79 protein‐coding genes, 30 tRNA genes and four rRNA genes. The GC content of the S. pinnatifolia cp genome was 37.9%, and the corresponding values in the LSC, SSC and IR regions were 36.0, 32.1, 43.2% respectively. Repetitive sequences analysis revealed that the S. pinnatifolia cp genome contained 38 repeats. Microsatellite marker detection analysis identified 253 simple sequence repeats (SSRs), which provides opportunities for future studies of the population genetics and phylogenetic relationships of Syringa. Phylogenetic analysis of 29 selected cp genomes revealed that S. pinnatifolia is closely related to Syringa vulgaris and all 27 Lamiales species formed a clade separate from the two outgroup species. This newly characterized S. pinnatifolia chloroplast genome will provide a useful genomic resource of phylogenetic inference and the development of more genetic markers for species discrimination and population studies in the genus Syringa.     

The complete chloroplast genome of Myriophyllum spicatum reveals a 4‐kb inversion and new insights regarding plastome evolution in Haloragaceae

Myriophyllum, among the most species‐rich genera of aquatic angiosperms with ca. 68 species, is an extensively distributed hydrophyte lineage in the cosmopolitan family Haloragaceae. The chloroplast (cp) genome is useful in the study of genetic evolution, phylogenetic analysis, and molecular dating of controversial taxa. Here, we sequenced and assembled the whole chloroplast genome of Myriophyllum spicatum L. and compared it to other species in the order Saxifragales. The complete chloroplast genome sequence of M. spicatum is 158,858 bp long and displays a quadripartite structure with two inverted repeats (IR) separating the large single copy (LSC) region from the small single copy (SSC) region. Based on sequence identification and the phylogenetic analysis, a 4‐kb phylogenetically informative inversion between trnE‐trnC in Myriophyllum was determined, and we have placed this inversion on a lineage specific to Myriophyllum and its close relatives. The divergence time estimation suggested that the trnE‐trnC inversion possibly occurred between the upper Cretaceous (72.54 MYA) and middle Eocene (47.28 MYA) before the divergence of Myriophyllum from its most recent common ancestor. The unique 4‐kb inversion might be caused by an occurrence of nonrandom recombination associated with climate changes around the K‐Pg boundary, making it interesting for future evolutionary investigations.     

沙冬青属植物叶绿体基因组对比和系统发育分析

该研究以沙冬青和矮沙冬青叶绿体基因组为研究对象,比较分析其基因组结构和系统发育关系。结果显示: (1)沙冬青和矮沙冬青的叶绿体基因组具有典型的四段式结构,全长为153 935 bp和154 140 bp,其中大单拷贝区(LSC)分别为83 891 bp和84 126 bp,小单拷贝区(SSC)分别为18 022 bp和18 014 bp,以及长度各自为26 011 bp和26 000 bp的成对反向重复区(IRs);沙冬青和矮沙冬青均注释130个基因,包括85个蛋白编码基因(PCGs),37个转运RNA(tRNA)以及8个核糖体RNA(rRNA)。(2)沙冬青和矮沙冬青的叶绿体基因组中分别检测出26和15个回文重复序列,39和50个串联重复序列,23和34个散在重复序列。同时都鉴定出96个SSRs位点,包括74和73个单核苷酸重复,5和6个二核苷酸重复,以及各有17个复合SSR位点;边界分析显示两者IR区相似,但仍有一定差异。(3)通过近邻结合法(NJ)对沙冬青和矮沙冬青在内的17种蝶形花亚科以及2种云实亚科植物的叶绿体基因组构建的系统发育树显示,沙冬青和矮沙冬青以较高的支持率聚为一个独立分枝。该研究结果为沙冬青属的种间鉴别、SSR分子标记开发、保育工作、种群动态以及进一步研究坡塔里族的演化过程奠定了理论基础。     

阳春砂叶绿体全基因组解析及系统发育研究

以姜科(Zingiberaceae)豆蔻属(Amomum Roxb.)阳春砂(Amomum villosum)为试材,利用Illumina Hiseq 4000测序平台对阳春砂叶绿体基因组进行测序,通过生物信息学分析方法进行序列组装、注释和特征分析,以揭示阳春砂与其他姜科植物的进化关系及其在系统发育中的地位,为豆蔻属植物的物种鉴定提供理论依据。结果表明:(1)阳春砂叶绿体基因组全长164 069 bp,GC含量为36.1%,包括1对29 959 bp的反向重复区(IR)、一个大单拷贝区(LSC;88 798 bp)和一个小单拷贝区(SSC;15 353 bp);共注释得到133个基因,包括8个rRNA基因、38个tRNA基因和87个蛋白编码基因。(2)在阳春砂基因组中共检测到157个SSR位点,大部分SSR均由A和T组成;豆蔻属物种在基因组大小、IR边界区高度保守,核酸变异主要发生在LSC和SSC区。(3)最大似然法(Maximum Likelihood, ML)聚类分析显示,阳春砂与同属的爪哇白豆蔻(Amomum compactum)和白豆蔻(Amomum kravanh)亲缘关系最近,并且与山姜属(Alpinia Roxb.)也有较近的亲缘关系。     

A chloroplast DNA hypervariable region in eucalypts

Eucalypt chloroplast DNA (cpDNA) provides useful markers for phylogenetic and population research including gene flow and maternity studies. All cpDNA studies in Eucalyptus to date have been based on the RFLP technique, which requires relatively large amounts of clean DNA. The objective of this study was to develop PCR-based cpDNA markers for Eucalyptus. The chloroplast genome of Eucalyptus, like that of most angiosperms, possesses inverted repeats (IR). The two junctions between the IRs and the large single copy (LSC) regions are defined as J_LA andJ_LB. The region surrounding the J_LA junction was sequenced from 26 Eucalyptus DNA samples (21 of E. globulus, plus 5 other species), andtheJ_LB region was sequenced using 5 of these samples. The samples were chosen to represent all major haplotypes identified in previous cpDNA RFLP studies. The J_LA products were 150–210 bp in size, while those fromJ_LB were approximately 500 bp in size. Eighteen mutations were scored in total. Extensive variation was found in the IR within the intergenic spacer between rpl2 and the IR/LSC junctions. Many of these characters were complex indels. One sample of E. globulus possessed a relatively large (38 bp) insertion which caused displacement of the IR/LSC junctions. This is the first report of intraspecific variation in the position of IR/LSC junctions; interspecific variation was also found. The LSC region near J_LB had a low rate of mutation and none were informative. The LSC region near J_LA possessed 2 informative mutations. The variation revealed from these sequences reflects the differentiation previously uncovered in an extensive RLFP analysis on the same samples. These results suggest that the J_LA region will provide very useful cpDNA polymorphisms for future studies in Eucalyptus. Received: 20 March 1999 / Accepted: 16 December 1999     

虎杖叶绿体基因组结构与变异分析

虎杖(Reynoutria japonica Houtt.)为蓼科(Polygonaceae)蓼族(Polygoneae)虎杖属(Reynoutria Houtt.)植物,是一种传统的中草药,具有利湿退黄、清热解毒、散瘀止痛、止咳化痰的功效。本研究采取高通量测序技术获得5个虎杖品种的叶绿体全基因组序列,并与NCBI已公布的蓼族何首乌(Fallopia multiflora)和金线草(Antenoron filiforme)等植物的叶绿体全基因组序列进行了基因组学和系统发育分析。通过基因组学分析发现,5种虎杖的叶绿体基因组大小有163 376 bp和163 371 bp两种情况,并呈现出典型的环状四分体结构,85 784 bp的一条较长的单拷贝区(large single-copy region,LSC),18 616 bp的一条较短的单拷贝区(small single-copy region,SSC),还有两条长度一致的反向重复区,分别为IRa区和IRb区相间隔分布。通过注释得到161个基因,其中蛋白编码基因106个,rRNA编码基因10个,tRNA编码基因45个。总GC含量为36.7...     

The complete plastome of Panax stipuleanatus: Comparative and phylogenetic analyses of the genus Panax (Araliaceae)

Panax stipuleanatus (Araliaceae) is an endangered and medicinally important plant endemic to China. However, phylogenetic relationships within the genus Panax have remained unclear. In this study, we sequenced the complete plastome of P. stipuleanatus and included previously reported Panax plastomes to better understand the relationships between species and plastome evolution within the genus Panax. The plastome of P. stipuleanatus is 156,069 base pairs (bp) in length, consisting of a pair of inverted repeats (IRs, each 25,887 bp) that divide the plastome into a large single copy region (LSC, 86,126 bp) and a small single copy region (SSC, 8169 bp). The plastome contains 114 unigenes (80 protein-coding genes, 30 tRNA genes, and 4 rRNA genes). Comparative analyses indicated that the plastome gene content and order, as well as the expansion/contraction of the IR regions, are all highly conserved within Panax. No significant positive selection in the plastid protein-coding genes was observed across the eight Panax species, suggesting the Panax plastomes may have undergone a strong purifying selection. Our phylogenomic analyses resulted in a phylogeny with high resolution and supports for Panax. Nine proteincoding genes and 10 non-coding regions presented high sequence divergence, which could be useful for identifying different Panax species.     

Characterization of the Complete Chloroplast Genome of Apple (Malus × domestica,Rosaceae)*

Apple (Malus × domestica) is one of the most important temperate fruits. To better understand the molecular basis of this species, we characterized the complete chloroplast (cp) genome sequence downloaded from Genome Database for Rosaceae. The cp genome of apple is a circular molecule of 160068bp in length with a typical quadripartite structure of two inverted repeats (IRs) of 26352bp, separated by a small single copy region of 19180bp (SSC) and a large single copy region (LSC) of 88184bp. A total of 135 predicted genes (115 unique genes, and another 20 genes were duplicated in the IR) were identified, including 81 protein coding genes, four rRNA genes and 30 tRNA genes. Three genes of ycf15, ycf68 and infA contain several internal stop codons, which were interpreted as pseudogenes. The genome structure, gene order, GC content and codon usage of apple are similar to the typical angiosperm cp genomes. Thirty repeat regions (≥30bp) were detected, twenty one of which are tandem, six are forward and three are inverted repeats. Two hundred thirty seven simple sequence repeat (SSR) loci were revealed and most of them are composed of A or T, contributing to a distinct bias in base composition. Additionally, average 10000bp non coding region contains 24 SSR sites, while protein coding region contains five SSR sites, indicating an uneven distribution of SSRs. The complete cp genome sequence of apple reported in this paper will facilitate the future studies of its population genetics, phylogenetics and chloroplast genetic engineering.     

Total duplication of the small single copy region in the angiosperm plastome: Rearrangement and inverted repeat instability in Asarum

Premise of the Study

As more plastomes are assembled, it is evident that rearrangements, losses, intergenic spacer expansion and contraction, and syntenic breaks within otherwise functioning plastids are more common than was thought previously, and such changes have developed independently in disparate lineages. However, to date, the magnoliids remain characterized by their highly conserved plastid genomes (plastomes).

Methods

Illumina HiSeq and MiSeq platforms were used to sequence the plastomes of Saruma henryi and those of representative species from each of the six taxonomic sections of Asarum. Sequenced plastomes were compared in a phylogenetic context provided by maximum likelihood and parsimony inferences made using an additional 18 publicly available plastomes from early‐diverging angiosperm lineages.

Key Results

In contrast to previously published magnoliid plastomes and the newly sequenced Saruma henryi plastome published here, Asarum plastomes have undergone extensive disruption and contain extremely lengthy AT‐repeat regions. The entirety of the small single copy region (SSC) of A. canadense and A. sieboldii var. sieboldii has been incorporated into the inverted repeat regions (IR), and the SSC of A. delavayi is only 14 bp long. All sampled Asarum plastomes share an inversion of a large portion of the large single copy region (LSC) such that trnE‐UUC is adjacent to the LSC‐IR boundary.

Conclusions

Plastome divergence in Asarum appears to be consistent with trends seen in highly rearranged plastomes of the monocots and eudicots. We propose that plastome instability in Asarum is due to repetitive motifs that serve as recombinatory substrates and reduce genome stability.     

The complete chloroplast genome sequence of the Chinese endemic species Sorbus setschwanensis (Rosaceae) and its phylogenetic analysis

Sorbus setschwanensis Koehne is a pinnate-leaved Sorbus s.str. species endemic to China with narrow distribution and intriguing phylogeny that needs wider attention. In this paper, the complete chloroplast (cp) genome of S. setschwanensis is reported, and its phylogenetic position is analyzed. The complete cp genome of S. setschwanensis is 160 064 bp in size with 36.50% GC content. It has a typical quadripartite structure including a pair of inverted repeat regions (IRs) of 26 378 bp that separates a large single copy (LSC) region of 86 013 bp and a small single copy (SSC) region of 19 295 bp. The cp genome encodes 108 genes, comprising 76 protein-coding genes, 28 tRNA genes and 4 rRNA genes. Additionally, 52 simple sequence repeats (SSRs) and 43 dispersed repeats were identified. Comparison of the whole cp genome with those of other Sorbus species showed an overall high degree of sequence similarity, but there are six highly variable regions (trnR-atpA, petN-psbM, ndhC-trnV, trnE-trnT, trnT-trnL and rpl32-trnL) located in intergenic spacers that may be useful as molecular markers in future population genetic and phylogenetic studies in the genus. Phylogenetic analyses based on 108 coding genes from 25 species in Rosaceae revealed that S. setschwanensis is nested within Sorbus sect. Sorbus together with other pinnately leaved species, but does not form a sister lineage to S. rufopilosa belonging to the same series Multijugae. Thus, the systematic position of S. setschwanensis and relationships with other species in the genus needs to be further studied.     

The First Complete Chloroplast Genome Sequences in Actinidiaceae: Genome Structure and Comparative Analysis

Actinidia chinensis is an important economic plant belonging to the basal lineage of the asterids. Availability of a complete Actinidia chloroplast genome sequence is crucial to understanding phylogenetic relationships among major lineages of angiosperms and facilitates kiwifruit genetic improvement. We report here the complete nucleotide sequences of the chloroplast genomes for Actinidia chinensis and A. chinensis var deliciosa obtained through de novo assembly of Illumina paired-end reads produced by total DNA sequencing. The total genome size ranges from 155,446 to 157,557 bp, with an inverted repeat (IR) of 24,013 to 24,391 bp, a large single copy region (LSC) of 87,984 to 88,337 bp and a small single copy region (SSC) of 20,332 to 20,336 bp. The genome encodes 113 different genes, including 79 unique protein-coding genes, 30 tRNA genes and 4 ribosomal RNA genes, with 16 duplicated in the inverted repeats, and a tRNA gene (trnfM-CAU) duplicated once in the LSC region. Comparisons of IR boundaries among four asterid species showed that IR/LSC borders were extended into the 5’ portion of the psbA gene and IR contraction occurred in Actinidia. The clap gene has been lost from the chloroplast genome in Actinidia, and may have been transferred to the nucleus during chloroplast evolution. Twenty-seven polymorphic simple sequence repeat (SSR) loci were identified in the Actinidia chloroplast genome. Maximum parsimony analyses of a 72-gene, 16 taxa angiosperm dataset strongly support the placement of Actinidiaceae in Ericales within the basal asterids.     

Complete chloroplast genome sequence of Magnolia grandiflora and comparative analysis with related species

Magnolia grandiflora is an important medicinal,ornamental and horticultural plant species.The chloroplast(cp) genome of M.grandiflora was sequenced using a 454 sequencing platform and the genome structure was compared with other related species.The complete cp genome of M.grandiflora was 159623 bp in length and contained a pair of inverted repeats(IR) of 26563 bp separated by large and small single copy(LSC,SSC) regions of 87757 and 18740 bp,respectively.A total of 129 genes were successfully annotated,18 of which included introns.The identity,number and GC content of M.grandiflora cp genes were similar to those of other Magnoliaceae species genomes.Analysis revealed 218 simple sequence repeat(SSR) loci,most composed of A or T,contributing to a bias in base composition.The types and abundances of repeat units in Magnoliaceae species were relatively conserved and these loci will be useful for developing M.grandiflora cp genome vectors.In addition,results indicated that the cp genome size in Magnoliaceae species and the position of the IR border were closely related to the length of the ycf1 gene.Phylogenetic analyses based on 66 shared genes from 30 species using maximum parsimony(MP) and maximum likelihood(ML) methods provided strong support for the phylogenetic position of Magnolia.The availability of the complete cp genome sequence of M.grandiflora provides valuable information for breeding of desirable varieties,cp genetic engineering,developing useful molecular markers and phylogenetic analyses in Magnoliaceae.     

The complete chloroplast genome of Origanum vulgare L. (Lamiaceae)

Oregano (Origanum vulgare L., Lamiaceae) is a medicinal and aromatic plant maybe best known for flavouring pizza. New applications e.g. as natural antioxidants for food are emerging due to the plants' high antibacterial and antioxidant activity. The complete chloroplast (cp) genome of Origanum vulgare (GenBank/EBML/DDBJ accession number: JX880022) consists of 151,935 bp and includes a pair of inverted repeats (IR) of 25,527 bp separated by one small and one large single copy region (SSC and LSC) of 17,745 and 83,136 bp, respectively.     

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.     

Complete sequence and organization of the cucumber (Cucumis sativus L. cv. Baekmibaekdadagi) chloroplast genome

The nucleotide sequence of the cucumber (Cucumis sativus L. cv. Baekmibaekdadagi) chloroplast genome was completed (DQ119058). The circular double-stranded DNA, consisting of 155,527 bp, contained a pair of inverted repeat regions (IRa and IRb) of 25,187 bp each, which were separated by small and large single copy regions of 86,879 and 18,274 bp, respectively. The presence and relative positions of 113 genes (76 peptide-encoding genes, 30 tRNA genes, four rRNA genes, and three conserved open reading frames) were identified. The major portion (55.76%) of the C. sativus chloroplast genome consisted of gene-coding regions (49.13% protein coding and 6.63% RNA regions; 27.81% LSC, 9.46% SSC and 18.49% IR regions), while intergenic spacers (including 20 introns) made up 44.24%. The overall G-C content of C. sativus chloroplast genome was 36.95%. Sixteen genes contained one intron, while two genes had two introns. The expansion/contraction manner of IR at IRb/LSC and IR/SSC border in Cucumis was similar to that of Lotus and Arabidopsis, and the manner at IRa/LSC was similar to Lotus and Nicotiana. In total, 56 simple sequence repeats (more than 10 bases) were identified in the C. sativus chloroplast genome.     

The complete chloroplast DNA sequence of the green alga Oltmannsiellopsis viridis reveals a distinctive quadripartite architecture in the chloroplast genome of early diverging ulvophytes

Background  

The phylum Chlorophyta contains the majority of the green algae and is divided into four classes. The basal position of the Prasinophyceae has been well documented, but the divergence order of the Ulvophyceae, Trebouxiophyceae and Chlorophyceae is currently debated. The four complete chloroplast DNA (cpDNA) sequences presently available for representatives of these classes have revealed extensive variability in overall structure, gene content, intron composition and gene order. The chloroplast genome of Pseudendoclonium (Ulvophyceae), in particular, is characterized by an atypical quadripartite architecture that deviates from the ancestral type by a large inverted repeat (IR) featuring an inverted rRNA operon and a small single-copy (SSC) region containing 14 genes normally found in the large single-copy (LSC) region. To gain insights into the nature of the events that led to the reorganization of the chloroplast genome in the Ulvophyceae, we have determined the complete cpDNA sequence of Oltmannsiellopsis viridis, a representative of a distinct, early diverging lineage.