«Previous Article|Table of Contents|Next Article»

¡¶±±·½Ô°ÒÕ¡·[ISSN:1001-0009/CN:23-1247/S]

Issue:

2023Äê24

Page:

110-117

Research Field:

Publishing date:

Info

Title:

Analysis of the Adaptability of Leaves Phenotypic Characteristics of Glehnia littoralis From Different Provenances

Author(s):

ZHANG Xin1; WU Shangman2; AN Kang1; ZHOU Chunxia1; MOU Jinpeng3; BIAN Fuhua1

(1.College of Life Science£¬Yantai University£¬Yantai£¬Shandong 264005£»2.College of Life Science£¬Xinjiang Agricultural University£¬Urumqi£¬Xinjiang 830052£»3.Yantai Forest Resources Monitoring and Protection Service Center£¬Yantai£¬Shandong 265199)

Keywords:

Glehnia littoralis; germplasm resources; leaf phenotypes; adaptability

PACS:

R 282.2

DOI:

10.11937/bfyy.20231339

Abstract:

Perennial Glehnia littoralis plants from eight different provenances of Shandong Province£¬Liaoning Province and Inner Mongolia£¬cultivated heterogeneously under the same environment£¬were used as test materials.The morphological characteristics£¬microstructure and chlorophyll content of the leaves of them were determined£¬and significant difference analysis£¬systematic cluster analysis£¬and principal component analysis combined with affiliation function were performed to reveal the adaptability of the leaves phenotypic characteristics of different germplasm sources of G.littoralis.The results showed that the leaf phenotypes of different germplasm resources of G.littoralis had been changed due to long-term artificial selection.And the leaf area and petiole length of the cultivated G.littoralis were significantly larger than those of the wild G.littoralis.The photosynthetic structure and chlorophyll content of the wild germplasm resources were better than those of the cultivated germplasm resources£¬and had a stronger ability to adapt to the wild environment of strong light£¬drought£¬salinity and wind on the beach£¬which was the result of natural selection.At the squared Euclidean distance of 10£¬the cluster analysis divided the eight germplasm resources into three groups£¬with the cultivated germplasm resources Laiyang and Chifeng clustered into one group£¬the wild germplasm resources Qingrendao£¬Tianhengdao£¬Haiyang£¬Rizhao and Jinshitan clustered into one group£¬and the wild germplasm Baxiandao clustered into one group alone£¬with the advantages of photosynthetic structure such as thick leaves and thick leaf flesh tissue.The comprehensive evaluation of the affiliation function showed that the cultivated germplasm Chifeng had the highest comprehensive score of leaf phenotype.

References:

£Û1£ÝREN L J£¬GUO X£¬LIU S N£¬et al.Intraspecific variation in Phragmites australis£ºClinal adaption of functional traits and phenotypic plasticity vary with latitude of origin£ÛJ£Ý.Journal of Ecology£¬2020£¬108(6)£º2531-2543.£Û2£ÝÓÚÎÄÓ¢£¬¸ßÑ࣬åÌÓñ¾ê£¬µÈ.ɽ¶«ÒøÁ«»¨Ò¶Æ¬ÐÎ̬½á¹¹¶ÔÒìÖÊÉú¾³ºÍº£°Î±ä»¯µÄÏìÓ¦£ÛJ£Ý.Éú̬ѧ±¨£¬2019£¬39(12)£º4413-4420.£Û3£ÝISHIKAWA T£¬SEGA Y£¬KITAJIMA J.Water-soluble constituents of Glehnia littoralis fruit£ÛJ£Ý.Chemical & Pharmaceutical Bulletin£¬2001£¬49(5)£º584-588.£Û4£ÝWANG A£¬ZHANG P£¬LIU X£¬et al.Genetic structure and diversity of Glehnia littoralis£¬an endangered medicinal plant in China£ÛJ£Ý.Biochemical Systematics and Ecology£¬2016£¬66£º265-271.£Û5£Ý¹ú¼ÒÁÖÒµºÍ²ÝÔ­¾Ö.¹ú¼ÒÖص㱣»¤Ò°ÉúÖ²ÎïÃû¼£ÛEB/OL£Ý.(2023-09-09)£Û2021-08-07£Ý.http://www.forestry.gov.cn/c/www/gkml/11057.jhtml.£Û6£ÝJING Y£¬ZHANG R£¬MA Y£¬et al.Structural elucidation£¬anti-radical and immunomodulatory activities of polysaccharides from the roots of Glehnia littoralis£ÛJ£Ý.Natural Product Research,2022£¬36(18)£º4624-4629.£Û7£ÝZHANG S£¬CHENG F£¬YANG L£¬et al.Chemical constituents from Glehnia littoralis and their chemotaxonomic significance£ÛJ£Ý.Natural Product Research£¬2020£¬34(19)£º2822-2827.£Û8£ÝÀîÀöϼ£¬åÌÓñ¾ê£¬¸ßÑ࣬µÈ.²»Í¬ÖÖÔ´Ò°Éú±±É³²ÎÖÖ×Ó±íÐͼ°ÃÈ·¢ÌØÐÔµÄÑо¿£ÛJ£Ý.ÖÖ×Ó£¬2021£¬40(6)£º101-106.£Û9£ÝSHAO C Y£¬WANG G Y£¬DING X£¬et al.Physiological and biochemical characteristics of cold stratification to overcome morphophysiological dormancy in Glehnia littoralis seed£ÛJ£Ý.Seed Science and Technology£¬2021£¬49(1)£º19-24.£Û10£ÝYEOM M S£¬NGUYEN T K L£¬CHO J S£¬et al.Improving germination rate of coastal Glehnia by cold stratification and pericarp removal£ÛJ£Ý.Agronomy£¬2021£¬11(5):944.£Û11£ÝHONG 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£ÛJ£Ý.Food Science and Biotechnology£¬2022£¬31(6)£º669-679.£Û12£ÝTAMURA Y£¬KUBO N£¬OHSAKO T.Genetic diversity among Japanese local populations of an edible and medicinal coastal plant Glehnia littoralis F.Schmidt ex Miq£ÛJ£Ý.Genetic Resources and Crop Evolution£¬2022£¬69(1)£º85-97.£Û13£ÝYAN M£¬WANG H£¬LIU S£¬et al.Cloning and bioinformatics analysis of the GlROP6 gene in Glehnia littoralis£ÛJ£Ý.Phyton-International Journal of Experimental Botany£¬2021£¬90(4)£º1293-1300.£Û14£ÝÑîºØÓ꣬ÎÀº£Ñ࣬ɣÂú½Ü£¬µÈ.»ªÖÐÎåζ×ÓÒ¶±íÐÍ¿ÉËÜÐÔ¼°»·¾³Òò×Ó¶ÔÒ¶±íÐ͵ÄÓ°Ïì£ÛJ£Ý.Ö²Îïѧ±¨£¬2016£¬51(3)£º322-334.£Û15£ÝCHEN P Y£¬WELSH C£¬HAMANN A.Geographic variation in growth response of douglas-fir to interannual climate variability and projected climate change£ÛJ£Ý.Global Change Biology£¬2010£¬16(12)£º3374-3385.£Û16£ÝÀèÓÐÓУ¬ÌÆÔ´½­£¬Àîݼ£¬µÈ.Éß×ãʯɼµÄÐÎ̬ѧ¼°²»Í¬¹âÕÕ´¦ÀíÏÂÆø¿×ÌØÕ÷µÄÑо¿£ÛJ£Ý.Ö²ÎïÑо¿£¬2009£¬29(4)£º411-416.£Û17£ÝSIM¦[ES 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£ÛJ£Ý.Plants (Basel)£¬2020£¬9(9)£º1165.£Û18£Ýde 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£ÛJ£Ý.Journal of Ecology£¬2018£¬106(5)£º1952-1971.£Û19£Ý¶­»ª£¬³Âºì.»ùÓÚҶƬ±íÐÍÐÔ×´µÄÒÉËÆ¡®·äÌÇÀÖÖÖÊÒÅ´«²îÒì·ÖÎö£ÛJ£Ý.±±·½Ô°ÒÕ£¬2022(15)£º25-33.£Û20£ÝWANG D£¬FAHAD S£¬SAUD S£¬et al.Morphological acclimation to agronomic manipulation in leaf dispersion and orientation to promote ¡®Ideotype¡¯ breeding£ºEvidence from 3D visual modeling of ¡®super¡¯ rice (Oryza sativa L.)£ÛJ£Ý.Plant Physiology and Biochemistry£¬2019£¬135£º499-510.£Û21£ÝHAO N£¬CAO J£¬WANG C£¬et al.Understanding the molecular mechanism of leaf morphogenesis in vegetable crops conduces to breeding process£ÛJ£Ý.Frontiers in Plant Science£¬2022£¬13£º971453.£Û22£ÝSTRUIK P C£¬DRIEVER S M.Intriguing correlations between leaf architecture and intrinsic water-use efficiency enable selective breeding to mitigate climate challenges£ÛJ£Ý.Plant,Cell & Environment£¬2022£¬45(6)£º1607-1611.£Û23£ÝÍõ³£Ë³£¬Íôʫƽ.Ö²ÎïҶƬÐÔ×´¶ÔÆøºò±ä»¯µÄÏìÓ¦Ñо¿½øÕ¹£ÛJ£Ý.Ö²ÎïÉú̬ѧ±¨£¬2015£¬39(2)£º206-216.£Û24£ÝWANG Z£¬HUANG H£¬WANG H£¬et al.Leaf water content contributes to global leaf trait relationships£ÛJ£Ý.Nature Communications£¬2022£¬13(1)£º5525.

Memo

Memo:

-

Common functions

Last Update: 2024-01-11