不同来源中国李（Prunus salicina L.）的多样性与近缘种关系

doi:10.3864/j.issn.0578-1752.2019.03.017

摘要/Abstract

摘要：

目的中国李资源丰富、分布广泛。更好地明晰不同来源中国李栽培品种的多样性、遗传结构差异以及与同域近缘种的关系,将有利于明确中国李驯化扩散历程以及近缘种在栽培驯化过程中的作用,促进中国李地方品种资源的深入挖掘和新品种的选育。方法利用均匀分布于基因组的22对SSR分子标记,采用荧光毛细管电泳检测技术对48份种质进行基因分型,其中包括38份不同来源的中国李种质、10份变异类型或近缘种。通过GenAlEx 6.41软件评估22对SSR引物的多态性,对参试种质按不同来源分析遗传多样性;利用NTSYS-pc 2.1软件构建48份材料的树状聚类分析图;并根据贝叶斯模型的Structure 2.2软件分析不同居群间的遗传结构差异。结果基于48份供试材料的数据,22对SSR引物等位变异范围为3—21个,平均每个位点检测到13.54个;总共检测到298个等位变异,其中有51.8%的等位变异属于稀有等位变异。在不同居群间进行比较,根据平均有效等位变异（Ne）、平均Shannon’s多样性指数（I）、观察杂合度（Ho）和期望杂合度（He）可以看出,南方品种群的多样性最高,其次为东北品种群;而杏李的多样性最低,且明显低于华北品种群。通过分子方差分析,认为中国李的多样性有69%的遗传变异来源于居群内,仅有31%的遗传变异来源于居群间。基于遗传分化系数和Nei’s遗传距离的数据比较,认为不同居群间存在显著的遗传分化,同时不同地理来源种质间存在适当的基因交流。树状聚类分析暗示国外育成品种与我国南方品种群具有较近的亲缘关系;而华北品种群与杏李关系密切;东北品种群与乌苏里李关系紧密。群体结构分析可以将栽培中国李种质资源划分为南方小果脆肉品种群、南方大果品种群（包括国外育成品种）、华北品种群和东北品种群。结论我国南方地区中国李的多样性最为丰富,按东北品种群、国外品种群、华北品种群顺序依次降低。东北品种群为了提高适应性融入了乌苏里李基因;杏李是从华北品种群中高度驯化后的特化类型,且该类型通过无性繁殖保存了其高度杂合性状态。我国南方江浙地区的大果型种质对国外育成品种起着重要作用。

关键词: 中国李, 遗传多样性, 群体结构, 基因流

Abstract:

【Objective】 There are abundant Japanese plums (Prunus salicina L.) germplasm resources in China, which are distributed widely in geography. The better understanding of the diversity, the genetic structure and the relationship between sympatric related species, can be helpful to clarify the process of domestication of the cultivated groups of plum and the role of the related species, also further contribute to the in-depth exploration of local resources and enhance the fruit quality in breeding. 【Method】 The 22 pairs of SSR markers covering the entire genome were used to scan 48 samples, including 38 accessions of P. salicina from different sources and 10 accessions of the variation types or related species, by high-throughput fluorescence capillary electrophoresis platform. The polymorphism of 22 SSR loci and genetic diversity of 48 samples were evaluated via the software GenAlEx 6.41, and the dendrogram of these accessions was constructed by using the NTSYS-pc Version 2.1 program. The STRUCTURE 2.2 software based on Bayesian clustering method was used to analyze the genetic mixture of samples and to perform an assignment test on the studied individuals. 【Result】 The detected alleles of 22 SSR primers ranged from 3 to 21, with an average of 13.54 alleles for each locus. A total of 298 alleles were detected in these accessions, 51.8% of which were rare alleles. The values of average effective allele (Ne), average Shannon's diversity index (I), observation heterozygosity (Ho) and expectation heterozygosity (He) indicated that the diversity was the highest in the southern population, followed by the northeast population, which also indicated that the diversity of the Prunus simonii was lower than that of northern China. The analysis of molecular variance (AMOVA) showed that 69% of the diversity in P. salicina was within the population, and only 31% was among populations. On the basis of the data comparisons of the genetic differentiation coefficient and Nei's genetic distance, the results showed that there were extremely significant genetic differentiation and appropriate genes mixture among different geographical populations. The results of cluster analysis implied that the breeding cultivars abroad were closely related to the local accessions in southern China, and the northern cultivars population was similar with P. simonii, the northeast cultivars population had close relationship with Prunus ussuriensis. The genetic structure analysis indicated that the accessions in P. salicina were divided into four types: northern cultivars population, northeast cultivars population, southern cultivars of small fruit and crisp meat population, and southern cultivars of large fruit population (including foreign breeding cultivars). 【Conclusion】 The diversity of the southern varieties were the most abundant in the P. salicina, followed by that of Northeast China varieties, foreign varieties and Northern varieties. In order to enhance the adaptability, the northeast population might be introgressed with P. ussuriensis. P. simonii might be a special type which was highly domesticated from Chinese plum in Northern China, and it had high heterozygosis owing to asexual reproduction by grafting. The large fruit accessions in Jiangsu and Zhejiang regions played an important role in modern breeding varieties abroad.

Key words: Prunus salicina L., genetic diversity, population structure, gene flow

魏潇,章秋平,刘宁,张玉萍,徐铭,刘硕,张玉君,马小雪,刘威生. 不同来源中国李（Prunus salicina L.）的多样性与近缘种关系[J]. 中国农业科学, 2019, 52(3): 568-578.

WEI Xiao,ZHANG QiuPing,LIU Ning,ZHANG YuPing,XU Ming,LIU Shuo,ZHANG YuJun,MA XiaoXue,LIU WeiSheng. Genetic Diversity of the Prunus salicina L. from Different Sources and Their Related Species[J]. Scientia Agricultura Sinica, 2019, 52(3): 568-578.

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链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2019.03.017

https://www.chinaagrisci.com/CN/Y2019/V52/I3/568

图/表 7

表1

供试材料信息"

居群 Population	编号 Code	种质名称 Accessions	来源 Origin	类群 Group	编号 Code	种质名称 Name	来源 Origin
华北品种（HB） Northern varieties	1	香蕉李 Xiangjiaoli	北京 Beijing		25	连平三华李 Lianpingsanhuali	广东 Guangdong
	2	帅李 Shuaili	山东 Shandong		26	从化三华李 Conghuasanhuali	广东 Guangdong
	3	昌黎晚红 Changliwanhong	河北 Hebei		27	长圹三华李 Changkuangsanhuali	广东 Guangdong
	4	玉皇李 Yuhuangli	甘肃 Gansu		28	上海芙蓉李 Shanghaifurongli	上海 Shanghai
	5	平顶香 Pingdingxiang	山东 Shandong		29	永泰芙蓉李 Yongtaifurongli	福建 Fujian
东北品种（DB） Northeast varieties	6	康什 Kangshi	吉林 Jilin		30	福建芙蓉李 Fujianfurongli	福建 Fujian
	7	奎丰 Kuifeng	东北品种实生 Seedling of northeast varieties		31	福州青奈 Fuzhouqingnai	福建 Fujian
	8	矮甜李Aitianli	黑龙江Heilongjiang		32	银醉李Yinzuili	江苏Jiangsu
	9	黄干核Huangganhe	吉林Jilin		33	天目蜜李Tianmumili	浙江Zhejiang
	10	延吉李Yanjili	吉林Jilin	国外品种（EX） Foreign varieties	34	安哥诺Angeleno	美国USA
	11	矮化李Aihuali	吉林Jilin		35	百班克Baibanke	美国USA
	12	矬李Cuoli	黑龙江Heilongjiang		36	布尔班克Burbank	美国USA
	13	小离核Xiaolihe	吉林Jilin		37	黑宝石Black Diamond	美国USA
	14	小黄李Xiaohuangli	黑龙江Heilongjiang		38	幸运Fortune	美国USA
	15	大叶伏李Dayefuli	辽宁Liaoning	杏李（XL）	39	扁艳Bianyan	山东Shandong
	16	大叶砧木 Dayezhenmu	小黄李实生 Seedling of Xiaohuangli	P. simonii	40	熊岳香扁 Xiongyuexiangbian	辽宁 Liaoning
南方品种（NF） Southern varieties	17	青冬李 Qingdongli	四川 Sichuan		41	昌黎香蕉李 Changlixiangjiaoli	河北 Hebei
	18	红冬李Hongdongli	四川Sichuan		42	黄牛心李Huangniuxinli	不详 Unknown
	19	巴塘李Batangli	四川Sichuan		43	昌黎香扁Changlixiangbian	河北Hebei
	20	庐山李Lushanli	江西 Jiangxi	乌苏里李（WU） P. ussuriensis	44	海底亚克夫 Haidiyakefu	黑龙江Heilongjiang
	21	竹丝李Zhusili	广东Guangdong	乌苏里李（WU） P. ussuriensis	45	乌苏里李 Wusulili	黑龙江Heilongjiang
	22	西瓜李 Xiguali	江西 Jiangxi	樱桃李 P. cerasifera	46	新疆樱桃李 Xinjiangyingtaoli	新疆 Xinjiang
	23	铜盘奈 Tongpannai	广东 Guangdong	美洲李 P. amercana	47	锦西牛心李 Jinxiniuxinli	美国 USA
	24	利源三华李 Liyuansanhuali	广东 Guangdong	普通杏 P. armeniaca	48	金妈妈 Jinmama	甘肃 Gansu

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位点 Locus	连锁群LG	位置Sites	Ao	Ne	I	Ho	He	F	Nm
SSRPACITA5^[17]	G1	13.6	7	3.207	1.429	0.667	0.688	0.031	0.388
EPDCU5100^[18]	G1	14.5	6	3.734	1.406	0.729	0.732	0.004	0.363
PGS1.24^[19]	G1	58.4	19	9.125	2.473	0.667	0.890	0.251	0.374
BPPCT028^[19]	G1	60.7	10	6.055	1.990	0.688	0.835	0.177	0.387
pchgms1^[20]	G1	—	9	4.571	1.730	0.792	0.781	-0.013	0.461
PceGA025^[21]	G1	77.4	21	12.031	2.696	0.500	0.917	0.455	0.412
CPSCT039^[17]	G2	35.1	15	8.678	2.371	0.958	0.885	-0.083	0.449
CPDCT028^[22]	G2	48.6	21	9.521	2.583	0.813	0.895	0.092	0.376
CPDCT016^[23]	G3	28.4	21	11.157	2.656	0.833	0.910	0.085	0.299
CPDCT045^[18]	G3	46.4	14	7.211	2.231	0.833	0.861	0.033	0.519
CPSCT034^[22]	G4	1.8	13	4.347	1.854	0.708	0.770	0.080	0.455
CPPCT030^[23]	G4	16.8	16	7.189	2.273	0.688	0.861	0.201	0.326
CPSCT011^[22]	G5	5.2	19	9.253	2.559	0.667	0.892	0.253	0.529
PGS1.21^[19]	G5	26.7	8	3.050	1.330	0.500	0.672	0.256	0.212
CPSCT004^[23]	G5	30.7	5	3.504	1.399	0.833	0.715	-0.166	1.502
CPDCT027^[18]	G5	—	3	1.889	0.703	0.333	0.471	0.292	0.233
BPPCT025^[21]	G6	56.4	18	5.654	2.176	0.583	0.823	0.291	0.324
BPPCT029^[24]	G6	80.2	16	10.355	2.500	0.708	0.903	0.216	0.426
CPPCT006^[22]	G7	9.5	17	8.727	2.413	0.875	0.885	0.012	0.523
pchcms4^[21]	G7	29.6	7	2.503	1.170	0.500	0.600	0.167	0.313
CPSCT018^[22]	G8	0	19	8.471	2.414	0.750	0.882	0.150	0.382
CPDCT008^[24]	G8	—	14	3.266	1.695	0.458	0.694	0.339	0.158
整体Whole	—	—	298	143.5	2.002	0.686	0.798	0.142	0.428

居群 Population	Ao	Ne	I	Ho	He	F
HB	77	2.743	0.977	0.645	0.527	-0.203
DB	141	4.035	1.509	0.686	0.712	0.024
NF	191	5.141	1.709	0.682	0.736	0.074
EX	83	2.874	1.129	0.718	0.624	-0.165
XL	39	1.773	0.536	0.773	0.386	-1.000

	HB	DB	NF	EX	XL	WU
HB	-	0.590	0.706	0.564	0.190	1.492
DB	0.126	-	0.627	0.627	0.767	0.412
NF	0.146	0.089	-	0.366	0.916	1.313
EX	0.140	0.105	0.068	-	0.779	1.529
XL	0.086	0.189	0.207	0.214	-	1.622
WU	0.288	0.116	0.216	0.256	0.365	-