[1]REN L J,GUO X,LIU S N,et al.Intraspecific variation in Phragmites australis:Clinal adaption of functional traits and phenotypic plasticity vary with latitude of origin[J].Journal of Ecology,2020,108(6):2531-2543.[2]于文英,高燕,逄玉娟,等.山东银莲花叶片形态结构对异质生境和海拔变化的响应[J].生态学报,2019,39(12):4413-4420.[3]ISHIKAWA T,SEGA Y,KITAJIMA J.Water-soluble constituents of Glehnia littoralis fruit[J].Chemical & Pharmaceutical Bulletin,2001,49(5):584-588.[4]WANG A,ZHANG P,LIU X,et al.Genetic structure and diversity of Glehnia littoralis,an endangered medicinal plant in China[J].Biochemical Systematics and Ecology,2016,66:265-271.[5]国家林业和草原局.国家重点保护野生植物名录[EB/OL].(2023-09-09)[2021-08-07].http://www.forestry.gov.cn/c/www/gkml/11057.jhtml.[6]JING Y,ZHANG R,MA Y,et al.Structural elucidation,anti-radical and immunomodulatory activities of polysaccharides from the roots of Glehnia littoralis[J].Natural Product Research,2022,36(18):4624-4629.[7]ZHANG S,CHENG F,YANG L,et al.Chemical constituents from Glehnia littoralis and their chemotaxonomic significance[J].Natural Product Research,2020,34(19):2822-2827.[8]李丽霞,逄玉娟,高燕,等.不同种源野生北沙参种子表型及萌发特性的研究[J].种子,2021,40(6):101-106.[9]SHAO C Y,WANG G Y,DING X,et al.Physiological and biochemical characteristics of cold stratification to overcome morphophysiological dormancy in Glehnia littoralis seed[J].Seed Science and Technology,2021,49(1):19-24.[10]YEOM M S,NGUYEN T K L,CHO J S,et al.Improving germination rate of coastal Glehnia by cold stratification and pericarp removal[J].Agronomy,2021,11(5):944.[11]HONG S J,PARK N I,HWANG D K,et al.Comparison of yield and metabolites according to the types of hilling materials utilized during Glehnia littoralis sprout vegetable cultivation[J].Food Science and Biotechnology,2022,31(6):669-679.[12]TAMURA Y,KUBO N,OHSAKO T.Genetic diversity among Japanese local populations of an edible and medicinal coastal plant Glehnia littoralis F.Schmidt ex Miq[J].Genetic Resources and Crop Evolution,2022,69(1):85-97.[13]YAN M,WANG H,LIU S,et al.Cloning and bioinformatics analysis of the GlROP6 gene in Glehnia littoralis[J].Phyton-International Journal of Experimental Botany,2021,90(4):1293-1300.[14]杨贺雨,卫海燕,桑满杰,等.华中五味子叶表型可塑性及环境因子对叶表型的影响[J].植物学报,2016,51(3):322-334.[15]CHEN P Y,WELSH C,HAMANN A.Geographic variation in growth response of douglas-fir to interannual climate variability and projected climate change[J].Global Change Biology,2010,16(12):3374-3385.[16]黎有有,唐源江,李菁,等.蛇足石杉的形态学及不同光照处理下气孔特征的研究[J].植物研究,2009,29(4):411-416.[17]SIMES R,RODRIGUES A,FERREIRA-DIAS S,et al.Chemical composition of cuticular waxes and pigments and morphology of leaves of Quercus suber trees of different provenance[J].Plants (Basel),2020,9(9):1165.[18]de VILLEMEREUIL P,MOUTERDE M,GAGGIOTTI O E,et al.Patterns of phenotypic plasticity and local adaptation in the wide elevation range of the alpine plant Arabis alpina[J].Journal of Ecology,2018,106(5):1952-1971.[19]董华,陈红.基于叶片表型性状的疑似‘蜂糖李’种质遗传差异分析[J].北方园艺,2022(15):25-33.[20]WANG D,FAHAD S,SAUD S,et al.Morphological acclimation to agronomic manipulation in leaf dispersion and orientation to promote ‘Ideotype’ breeding:Evidence from 3D visual modeling of ‘super’ rice (Oryza sativa L.)[J].Plant Physiology and Biochemistry,2019,135:499-510.[21]HAO N,CAO J,WANG C,et al.Understanding the molecular mechanism of leaf morphogenesis in vegetable crops conduces to breeding process[J].Frontiers in Plant Science,2022,13:971453.[22]STRUIK P C,DRIEVER S M.Intriguing correlations between leaf architecture and intrinsic water-use efficiency enable selective breeding to mitigate climate challenges[J].Plant,Cell & Environment,2022,45(6):1607-1611.[23]王常顺,汪诗平.植物叶片性状对气候变化的响应研究进展[J].植物生态学报,2015,39(2):206-216.[24]WANG Z,HUANG H,WANG H,et al.Leaf water content contributes to global leaf trait relationships[J].Nature Communications,2022,13(1):5525.