DNA barcoding sequence analysis of Amomum tsao-ko germplasm resources in Yunnan Province
10.7501/j.issn.0253-2670.2019.24.025
- VernacularTitle: 云南草果种质资源DNA条形码序列分析
- Author:
Yi-Fan HU
1
Author Information
1. College of Agronomy and Biotechnology, Yunnan Agricultural University
- Publication Type:Journal Article
- Keywords:
Amomun tsao-ko Crevost et Lemaire;
DNA barcoding;
Genetic diversity;
Genetic relationship;
ITS sequence;
MatK sequence;
PsbA-trnH sequence;
Ycf1 sequence
- From:
Chinese Traditional and Herbal Drugs
2019;50(24):6091-6097
- CountryChina
- Language:Chinese
-
Abstract:
Objective: To screen and evaluate DNA barcoding of Amomun tsao-ko populations in Yunnan. Methods: ITS, psbA-trnH, matK, rbcL, and ycf1 sequences were screened and evaluated using A. tsao-ko as samples. The samples of A. tsao-ko population were amplified and sequenced. The sequences were spliced with Genestar, and then processed with Mega for data processing. And A. tsao-ko diversity and identification were analyzed and discussed. Results: The length of the amplified fragments of primers ITS5 and ITS4 was approximately 520 bp; The length of the amplified fragments of the primers rbcLa-F and rbcLa-R was approximately 498 bp; The length of the amplified fragments of the primers ycf1-bF and ycf1-bR was approximately 800 bp; The length of the amplified fragments of the primers psbA-trnH-1F and psbA-trnH-1R was approximately 400 bp; The length of the amplified fragments of the primers matK-2F and matK-2R was approximately 470 bp. The success rate of amplification and sequencing was high, and most of the results were available. By analyzing the amplification results of ITS, psbA-trnH, matK and ycf1 sequences of A. tsao-ko, A. tsao-ko and other Amomum genus plants can be clearly distinguished; All samples of the ITS sequence were divided into MG5 white flower A. tsao-ko population and other populations; All samples of the psbA-trnH sequence were divided into MG5 white flower A. tsao-ko population, MG6 yellow flower A. tsao-ko population and other populations; All samples of the matK sequence were divided into MG6 A. tsao-ko population and other populations. The MG5 white flower A. tsao-ko sample failed to be amplified; All samples of the ycf1 sequence were divided into the MG6 yellow flower A. tsao-ko population and other populations, and the MG5 white flower A. tsao-ko population was clustered with the other 22 A. tsao-ko populations; The amplification of rbcL sequence was consistent for all samples. Conclusion: The ITS, matK, psbA-trnH and ycf1 sequences can accurately distinguish A. tsao-ko from other plants of Amomum genus; The sequence site variations were found in matK, psbA-trnH and ycf1 sequences of MG6. This research has contributed to the selection and breeding of A. tsao-ko varieties. ITS and psbA-trnHsequences can distinguish yellow flower and white flower of A. tsao-ko; There is no variation in the rbcL sequence of all samples of white and yellow flowers of A. tsao-ko, and Amomum tsao-ko and other plants of Amomum genus cannot be identified with the rbcL sequence, which can be discarded.
