Investigation on reproductive characteristics of Polygonatum cyrtonema / 中国中药杂志

The study is aimed to investigate the reproductive biology characteristics of Polygonatum cyrtonema, especially including phenology, flower bud differentiation, flowering timing, floral traits, pollen vigor and stigma receptivity. The results showed that P. cyrtonema forms inflorescence before the leaves spread. In the wild, P. cyrtonema is mainly pollinated by insects such as bumblebees, with a seed setting rate of 65.12%. The seed setting rate of indoor single plant isolation or self-pollination enclosed by parchment paper bag is 0, indicating that it is self-incompatible. In Lin'an city, seedlings begin to emerge from mid-March to early April(the temperature is higher than 7.5 ℃), buds begin to emerge from the end of March to mid-April, and then undergo the full bloom stage from mid-to-late April, and the final flowering stage from the end of April to mid-May. The whole flowering period lasts 36 to 45 days. There are obvious differences in the phenology of different provenances. The flowers come into bloom from the base to the top along the aboveground main axis, which usually contain 4-22 inflorescences with(2-) 4-10(-21) flowers per inflorescence. The flowering pe-riod for a single plant is 26-38 days. The single flower lasts about 20-25 days from budding to opening and withers 2 days after pollination, and then the ovary will gradually expand. If unpollinated, it will continue to bloom for 3-5 days and then wither. Flower development period is significantly related to pollen vigor and stigma remittance. The pollen viability is the highest when the flower is fully opened with anthers gathering on the stigma, and the receptivity is the strongest when the stigma protrudes out of the perianth and secretes mucus. The fruits and seeds ripen in October, and proper shading can ensure the smooth development and maturity of the seeds. This study provides a basis for the hybrid breeding and seed production of P. cyrtonema.

Studies on genetic diversity in cultivated populations of Atractylodes macrocephala / 中国中药杂志

<p><b>OBJECTIVE</b>To investigate the genetic diversity of main germplasm of Atractylodes macrocephala in China and the genetic differentiation of the germplasm of A. macrocephala.</p><p><b>METHOD</b>A molecular marker ISSR was used to analyze the genetic diversity of 7 populations of A. macrocephala and a population of A. lancea.</p><p><b>RESULT</b>Twelve primers were used in the PCR amplification of 86 samples of A. macrocephala and 5 samples of A. lancea. Sixty-three bands with sizes ranged from 100 to 2500 bp were generated from 12 primers. Of all the 63 bands, 55 bands were polymorphic among 86 individuals of A. macrocephala, the percentage of polymorphic bands were 87.30% at the species level. The percentage of polymorphic bands (PPL) for a single population ranged from 58.73% to 71.43% (mean, 64.85%). Among the 7 populations, a population from Panan, GM exhibited highest variability (PPL =71.43%; HE = 0.2835; I = 0.4267). A dendrogram constructed by an unweighted pair group method of cluster analysis showed that populations from Panan constructed one branch and separated from other populations. In the AMOVA analysis, low level of genetic differentiation among populations was detected, 90.52% of the variability existed in population.</p><p><b>CONCLUSION</b>The genetic diversity of cultivated A. macrocephala in China is high, which is good for the production of high quality herb medicine.</p>

Species-specific SCAR markers for authentication of Sinocalycanthus chinensis / 浙江大学学报（英文版）（B辑：生物医学和生物技术）

Sinocalycanthus chinensis, an endangered species endemic to China, is cultivated as an ornamental landscape tree in China. However, S. chinensis, Chimonanthus species and Calycanthus floridus are difficult to be distinguished in seedling market because of their similar morphological characters. In this study, ISSR (inter-simple sequence repeats) were applied to detect S. chinensis from its closely related species. A unique 748-bp band was found in all accessions of S. chinensis. SCAR (sequence characterized amplified regions) markers were created by cloning and sequencing the specific band, and designing a pair of primers to amplify the band of 748 bp. Diagnostic PCRs were performed using the primer pair with the total DNAs of S. chinensis, Chimonanthus species and C. floridus as templates, with only S. chinensis being able to be amplified. This amplification is not only rapid (results can be obtained in less than 3 h), but is also easy to perform. Hence it is a feasible method for identifying S. chinensis in seedling market.

Analysis of population genetic structure and molecular identification of Changium smyrnioides and Chuanminshen violaceum with ISSR marker / 中国中药杂志

<p><b>OBJECTIVE</b>To assess the population genetic diversity and genetic structure and screen species-specific bands for identification of Changium smyrnioides and Chuanminshen violaceum.</p><p><b>METHOD</b>Seven wild populations of Changium smyrnioides and one cultivated population of Chuanminshen violaceum were studied by ISSR analysis. The population genetic diversity and population genetic structure were assessed by using POPGENE software.</p><p><b>RESULT</b>A total of 152 ISSR markers were scored, among which 136 (90.8%) were polymorphic. The values of Gst tended to be high (mean Gst = 0.575). The level of genetic divesity of Changium smyrnioides (A = 1.272; P = 27.26%; I = 0.132; H = 0.087) was higher than that of Chuanminshen violaceum (A = 1.217; P = 21.7; I = 0.103; H = 0.067).</p><p><b>CONCLUSION</b>The genetic variation of Changium smyrnioides is high and the majority of genetic variation occur among populations. Substantial genetic divergence is shown by cluster analysis (UPGMA) to befound between Changium smyrnioides and Chuanminshen violaceum at DNA level. In addition, one species-specific marker has been obtained in Chuanminshen violaceum. The phylogenetic relationship of two species has also been discussed.</p>