The complete chloroplast genome of Phyllostachys heteroclada f. solida (Poaceae)

Zhuo

et al. 2022

Genes

Dendrocalamus farinosus is one of the essential bamboo species mainly used for food and timber in the southwestern region of China. In this study, the complete chloroplast (cp) genome of D. farinosus is sequenced, assembled, and the phylogenetic relationship analyzed. The cp genome has a circular and quadripartite structure, has a total length of 139,499 bp and contains 132 genes: 89 protein-coding genes, eight rRNAs and 35 tRNAs. The repeat analyses showed that three types of repeats (palindromic, forward and reverse) are present in the genome. A total of 51 simple sequence repeats are identified in the cp genome. The comparative analysis between different species belonging to Dendrocalamus revealed that although the cp genomes are conserved, many differences exist between the genomes. The analysis shows that the non-coding regions were more divergent than the coding regions, and the inverted repeat regions are more conserved than the single-copy regions. Moreover, these results also indicate that rpoC2 may be used to distinguish between different bamboo species. Phylogenetic analysis results supported that D. farinosus was closely related to D. latiflorus. Furthermore, these bamboo species’ geographical distribution and rhizome types indicate two evolutionary pathways: one is from the tropics to the alpine zone, and the other is from the tropics to the warm temperate zone. Our study will be helpful in the determination of the cp genome sequences of D. farinosus, and provides new molecular data to understand the Bambusoideae evolution.

Section: Resultsmentioning

confidence: 99%

“…heteroclada , Ph. nidularia , T. siamensis , etc., and also in other species such as Abutilon fruticosum and Catha edulis [ 19 , 20 , 21 , 22 , 24 , 25 ]. The trnK-UUU gene also has the longest intron in the cp genome of other species (A. fruticosum and C. edulis) [ 24 , 25 ].…”

Section: Resultsmentioning

confidence: 99%

Complete Chloroplast Genome Features of Dendrocalamusfarinosus and Its Comparison and Evolutionary Analysis with Other Bambusoideae Species

Pei

Zhuo

et al. 2022

Genes

The complete chloroplast genome sequence of Phyllostachys incarnata Wen, 1982

Liu

Mitochondrial DNA Part B

et al. 2023

Phyllostachys incarnata Wen, 1982 is one of the important material and edible bamboo specie of high quality in China. We reported the complete chloroplast(cp) genome of P. incarnata in this study. The cp genome of P. incarnata (GenBank accession number: OL457160) was a typical tetrad structure with a full length of 139,689 bp, comprising a pair of inverted repeated (IR) regions (21,798 bp) separated by a large single-copy (LSC) region (83,221 bp) and a small single-copy (SSC) region (12,872 bp). And the cp genome contained 136 genes, including 90 protein-coding genes, 38 tRNA genes, and 8 rRNA genes. Phylogenetic analysis based on 19 cp genomes suggested that P. incarnata was relatively close to P. glauca among the species analyzed.

Complete Chloroplast Genome of Bamboo Species Pleioblastus ovatoauritus and Comparative Analysis of Pleioblastus from China and Japan

Peng,

Wang,

Shen

et al. 2023

Forests

Pleioblastus ovatoauritus T.H.Wen ex W.Y.Zhang is bamboo species published in 2018, originated from and existing in southeastern China. The chloroplast genome of Pl. ovatoauritus was obtained using a high-throughput sequencing platform. The chloroplast genome is up to 139,708 bp in length and displays a typical quadripartite structure with one large single-copy region, one small single-copy region, and two inverted repeat regions. There are 82 protein-coding genes, 8 rRNA genes, and 39 tRNA genes in the plastome genome. However, the interspecific relationship of Pleioblastus species originated from China and Japan has not been revealed explicitly. To understand their relationship, data from four Chinese species and four Japanese species were selected to investigate the distinctions between their genome structures, codon usage patterns, and SSR sites. We moved forward to examine the sequence divergence and polymorphic sites between the eight species. Phylogenetic trees were then plotted using the maximum likelihood method based on different parts of the sequences. Obvious difference found in the JLB boundary and a split in the phylograms contributed to our decision to split Pleioblastus species of China and Japan into different clades. Moreover, taxonomy using the subgenera concept in Flora Reipublicae Popularis Sinicae proved untenable. Nine SSR primers for Pleioblastus genus were then developed from cp genomes, aimed at facilitating identification and germplasm investigation.