Characteristic and Phylogenetic Analysis of the Complete Chloroplast Genomes of Three Medicinal Plants of Schisandraceae

Schisandra chinensis, which has a high development value, has long been used as medicine. Its mature fruits (called Wuweizi in Chinese) have long been used in the famous traditional Chinese medicine (TCM) recorded in the “Chinese Pharmacopoeia.” Chloroplasts (CP) are the highly conserved primitive organelles in plants, which can serve as the foundation for plant classification and identification. This study introduced the structures of the CP genomes of three Schisandraceae species and analyzed their phylogenetic relationships. Comparative analyses on the three complete chloroplast genomes can provide us with useful knowledge to identify the three plants. In this study, approximately 5 g fresh leaves were harvested for chloroplast DNA isolation according to the improved extraction method. A total of three chloroplast DNAs were extracted. Afterwards, the chloroplast genomes were reconstructed using denovo combined with reference-guided assemblies. General characteristics of the chloroplast genome and genome comparison with three Schisandraceae species was analyzed by corresponding software. The total sizes of complete chloroplast genomes of S. chinensis, S. sphenanthera, and Kadsura coccinea were 146875 bp, 146842 bp, and 145399 bp, respectively. Altogether, 124 genes were annotated, including 82 protein-coding genes, 34 tRNAs, and 8 rRNAs of all 3 species. In SSR analysis, only S. chinensis was annotated to hexanucleotides. Moreover, comparative analysis of chloroplast Schisandraceae genome sequences revealed that the gene order and gene content were slightly different among Schisandraceae species. Finally, phylogenetic trees were reconstructed, based on the genome-wide SNPs of 38 species. The method can be used to identify and differentially analyze Schisandraceae plants and offer useful information for phylogenetics as well as further studies on traditional medicinal plants.

Complex Analyses of Short Inverted Repeats in All Sequenced Chloroplast DNAs

Chloroplasts are key organelles in the management of oxygen in algae and plants and are therefore crucial for all living beings that consume oxygen. Chloroplasts typically contain a circular DNA molecule with nucleus-independent replication and heredity. Using “palindrome analyser” we performed complete analyses of short inverted repeats (S-IRs) in all chloroplast DNAs (cpDNAs) available from the NCBI genome database. Our results provide basic parameters of cpDNAs including comparative information on localization, frequency, and differences in S-IR presence. In a total of 2,565 cpDNA sequences available, the average frequency of S-IRs in cpDNA genomes is 45 S-IRs/per kbp, significantly higher than that found in mitochondrial DNA sequences. The frequency of S-IRs in cpDNAs generally decreased with S-IR length, but not for S-IRs 15, 22, 24, or 27 bp long, which are significantly more abundant than S-IRs with other lengths. These results point to the importance of specific S-IRs in cpDNA genomes. Moreover, comparison by Levenshtein distance of S-IR similarities showed that a limited number of S-IR sequences are shared in the majority of cpDNAs. S-IRs are not located randomly in cpDNAs, but are length-dependently enriched in specific locations, including the repeat region, stem, introns, and tRNA regions. The highest enrichment was found for 12 bp and longer S-IRs in the stem-loop region followed by 12 bp and longer S-IRs located before the repeat region. On the other hand, S-IRs are relatively rare in rRNA sequences and around introns. These data show nonrandom and conserved arrangements of S-IRs in chloroplast genomes.

Sequencing and annotation of the chloroplast DNAs and identification of polymorphisms distinguishing normal male-fertile and male-sterile cytoplasms of onion

Male-sterile (S) cytoplasm of onion is an alien cytoplasm introgressed into onion in antiquity and is widely used for hybrid seed production. Owing to the biennial generation time of onion, classical crossing takes at least 4 years to classify cytoplasms as S or normal (N) male-fertile. Molecular markers in the organellar DNAs that distinguish N and S cytoplasms are useful to reduce the time required to classify onion cytoplasms. In this research, we completed next-generation sequencing of the chloroplast DNAs of N- and S-cytoplasmic onions; we assembled and annotated the genomes in addition to identifying polymorphisms that distinguish these cytoplasms. The sizes (153 538 and 153 355 base pairs) and GC contents (36.8%) were very similar for the chloroplast DNAs of N and S cytoplasms, respectively, as expected given their close phylogenetic relationship. The size difference was primarily due to small indels in intergenic regions and a deletion in the accD gene of N-cytoplasmic onion. The structures of the onion chloroplast DNAs were similar to those of most land plants with large and small single copy regions separated by inverted repeats. Twenty-eight single nucleotide polymorphisms, two polymorphic restriction-enzyme sites, and one indel distributed across 20 chloroplast genes in the large and small single copy regions were selected and validated using diverse onion populations previously classified as N or S cytoplasmic using restriction fragment length polymorphisms. Although cytoplasmic male sterility is likely associated with the mitochondrial DNA, maternal transmission of the mitochondrial and chloroplast DNAs allows for polymorphisms in either genome to be useful for classifying onion cytoplasms to aid the development of hybrid onion cultivars.

Molecular analysis of the complete set of length mutations found in the plastomes of Triticum–Aegilops species

Precise location and nature of each of 14 length mutations detected among chloroplast DNAs of Triticum–Aegilops species by RFLP analysis were determined at the nucleotide sequence level. Each mutation was compared with at least three non-mutated wild-type plastomes as standards. These 14 length mutations were classified into 4 duplications and 10 deletions. One duplication occurred in the small single-copy region close to the border of the inverted repeat, and the remaining 13 length mutations took place in the large single-copy region. All length mutations occurred in the intergenic regions, suggesting that these length mutations do not affect plastid gene expression. Saltatory replication was the cause of all duplications, whereas intramolecular recombination mediated by short direct repeats played a substantial role in the deletions. Recurrent occurrences of certain deletion events were found in some AT-rich regions, which constituted hot spots for deletion. Out of four hypervariable regions detected among the grass plastomes, two (downstream of rbcL and a tRNA gene accumulated region) were still active after differentiation of Triticum and Aegilops complex.Key words: insertions–deletions, plastome, Triticum–Aegilops, deletion hot spots, molecular mechanism.