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《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:

2024年10

Page:

119-125

Research Field:

Publishing date:

Info

Title:

Research Progress on Germplasm Resources of Hemerocallis citrina Baroni

Author(s):

JIA Minlong1; CAO Dongmei1; LI Sen1; LI Wei2; WU Zhiqiang2; 3; XING Guoming1

(1.College of Horticulture,Shanxi Agricultural University,Taiyuan,Shanxi 030801；Shenzhen Institute of Agricultural Genomics,Chinese Academy of Agricultural Sciences,Shenzhen,Guangdong 518120；3.Kunpeng Modern Agriculture Research Institute in Foshan,Foshan，Guangdong 528200)

Keywords:

Hemerocallis citrina Baroni; germplasm resources; classification; functional substances; functional genes

PACS:

S 644.3

DOI:

10.11937/bfyy.20233697

Abstract:

Hemerocallis citrina Baroni is a characteristic vegetable and functional food with a large planting area and consumption,and high economic value in China.It is listed as one of the four major vegetarian delicacies.With the continuous extension and development of the Hemerocallis citrina industry,many studies on yellow flower have gradually been carried out,such as germplasm resource evaluation,cultivation technology research and development,medicinal value,genomics,transcriptome,metabolome,functional genes,functional substances,etc.,in order to provide reference for the comprehensive development of the Hemerocallis citrina industry.However,due to the fact that molecular biology,especially the combination of multiple omics,is still in its developmental stage in the study of Hemerocallis citrina,there is still a lot of room for exploration in specific traits or phylogenetic aspects of Hemerocallis citrina.This study systematically summarized the research progress of Hemerocallis citrina in germplasm resources,molecular biology,genomics,and functional substances,discusses the limitations and possible solutions in current research on Hemerocallis citrina,and looked forward to its future research development direction.

References:

［1］刘永庆,沈美娟.黄花菜品种资源研究［J］.园艺学报,1990,17(1):45-50,83.［2］任毅,高亦珂,朱琳,等.萱草属种质资源多样性研究进展［J］.北方园艺,2016(16):188-193.［3］DAHLGREN R M T,CLIFFORD H T,YEO P F.The Families of the monocotyledons:Structure,evolution,and taxonomy［M］.Berlin,Heidelberg:Springer Berlin Heidelberg,1985.［4］何琦,高亦珂,高淑滢.萱草育种研究进展［J］.黑龙江农业科学,2011(3):137-140.［5］周默.上海应用技术大学国家萱草种质资源库 囊括现代萱草类型 突出资源多样性［J］.中国花卉园艺,2020(23):16-17.［6］颉敏昌.庆阳市黄花菜品种资源及栽培技术［J］.甘肃农业科技,2012(1):53-55.［7］郑家祯,李和平,赖正锋,等.国内菜用黄花菜种质资源遗传多样性分析［J］.福建农业学报,2018,33(10):1030-1038.［8］CHUNG M G,KANG S S.Morphometric analysis of the genus Hemerocallis L.(Liliaceae) in Korea［J］.Journal of Plant Research,1994,107(2):165-175.［9］高阳,侯非凡,熊雄,等.基于候选基因开发gSSR标记加密黄花菜和萱草种间遗传图谱［J］.江苏农业学报,2021,37(1):139-149.［10］KAWANO S,NOGUCHI J.Biosystematic studies on the genus Hemerocallis：I.Introgressive hybridization between H.citrina v.vespertina and H.fulva sensu lato［J］.University of Toyama Faculty of Education,1973,(6)：111-137.［11］肖雪.四川萱草属植物细胞学及繁育学研究［D］.雅安:四川农业大学,2008.［12］张超,段九菊,曹冬梅,等.太行山野生萱草染色体数鉴定与核型分析［J］.山西农业科学,2013,41(8):767-770.［13］SAITO H,MIZUNASHI K,TANAKA S,et al.Ploidy estimation in Hemerocallis species and cultivars by flow cytometry［J］.Scientia Horticulturae,2003,97(2):185-192.［14］李永平,贾民隆,梁峥,等.3种萱草属植物染色体核型分析［J］.山西农业科学,2020,48(1):32-34,86.［15］刘新星,欧巧明,罗俊杰,等.食用黄花菜SSR标记开发及指纹图谱库构建［J］.食品与发酵工业,2022,48(12):188-195.［16］于晓英,吴铁明,彭尽晖,等.萱草种质资源扩增片段长度多态性鉴别与分类的研究Ⅱ.5个萱草材料的AFLP分析［J］.湖南农业大学学报(自然科学版),2002,28(1):76-77.［17］TOMKINS J P,WOOD T C,BARNES L S,et al.Evaluation of genetic variation in the daylily (Hemerocallis spp.) using AFLP markers［J］.Theoretical and Applied Genetics,2001,102(4):489-496.［18］洪亚辉,张文,彭克勤,等.黄花菜不同品种的RAPD分析［J］.湖南农业大学学报(自然科学版),2003,29(6):496-499.［19］刘长命,李彩云,张姣.秦岭南麓萱草属植物种质资源遗传多样性的RAPD分析［J/OL］.分子植物育种,(2021-12-01)［2023-10-26］.https://kns.cnki.net/kns8s/defaultresult/index?crossids.［20］常涛.‘大同黄花’ב摇篮曲’F1群体花色遗传及QTL定位分析［D］.太谷:山西农业大学,2020.［21］公菲菲,李森,杜崴,等.黄花菜生物钟基因HcLHY的克隆及时空表达分析［J］.河北农业大学学报,2020,43(3):37-44.［22］杜崴,李森,公菲菲,等.光照处理对‘大同黄花’开花节律及光周期关键基因〖STBX〗HcCOL14〖STBZ〗表达特性的影响［J］.河北农业大学学报,2020,43(5):46-53.［23］冀芳芳,李森,史青青,等.萱草属种质遗传多样性分析及初级核心种质库的构建［J］.河北农业大学学报,2018,41(2):55-61.［24］李森,程宵婧,侯非凡,等.黄花菜八氢番茄红素脱氢酶基因HcPDS的克隆及VIGS转化表达验证［J］.河北农业大学学报,2021,44(1):25-32.［25］QING Z,LIU J,YI X,et al.The chromosome-level Hemerocallis citrina Borani genome provides new insights into the rutin biosynthesis and the lack of colchicine［J］.Horticulture Research,2021,8:89.［26］HIROTA S K,YASUMOTO A A,NITTA K,et al.Evolutionary history of Hemerocallis in Japan inferred from chloroplast and nuclear phylogenies and levels of interspecific gene flow［J］.Molecular Phylogenetics and Evolution,2021,164:107264.［27］ZHANG K,WANG Y,ZHANG X,et al.Deciphering the mitochondrial genome of Hemerocallis citrina (Asphodelaceae) using a combined assembly and comparative genomic strategy［J］.Frontiers in Plant Science,2022,13:1051221.［28］郭瑞,寇永丽.不同产区黄花菜中蛋白质含量差异性比较及不同加工工艺的影响［J］.当代农机,2022(5):79-80.［29］张清云,李明,安钰,等.不同杀青温度及制干方式对黄花菜营养成分的影响研究［J］.宁夏农林科技,2018,59(6):3-4,21.［30］敬美莲,伍卫红,米健国,等.不同品种黄花菜中黄酮类化合物的提取工艺及抗氧化活性研究［J］.广东化工,2022,49（14）:16-18.［31］曹熙,杨大伟.黄花菜多酚类化合物的鉴定及漂烫与贮藏对其稳定性的影响研究［J］.核农学报,2021,35(12):2787-2798.［32］WU W T,MONG M C,YANG Y C,et al.Aqueous and ethanol extracts of daylily flower (Hemerocallis fulva L.) protect HUVE cells against high glucose［J］.Journal of Food Science,2018,83(5):1463-1469.［33］HSU Y W,TSAI C F,CHEN W K,et al.Determination of lutein and Zeaxanthin and antioxidant capacity of supercritical carbon dioxide extract from daylily (Hemerocallis disticha)［J］.Food Chemistry,2011,129(4):1813-1818.［34］张宁,武永福.黄花菜粗多糖梯度乙醇提取工艺及其抗氧化活性研究［J］.中国食物与营养,2014,20(11):60-62.［35］LI X K,CUI J L,QIN X M,et al.Metabolic and transcriptional regulatory mechanisms of differential carbohydrates formation from flower buds to flowers of Hemerocallis citrina［J］.Scientia Horticulturae,2023,308:111553.［36］宋卓琴,段九菊,梁峥,等.抽薹期不同施氮量对黄花菜生长、光合特性及产量的影响［J］.北方园艺,2023(13)：8-14.

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Last Update: 2024-06-13