黄麻SSR标记与纤维产量性状的相关性

doi:10.3724/SP.J.1006.2020.04035

Abstract

Abstract:

Simple sequence repeat (SSR) markers correlated to fiber yield traits would be a beneficial tool for molecular marker-assisted breeding in jute. In this study, 397 SSR markers were screened from 311 jute germplasms by the phenotype identification from 2016 to 2018 and 116 pairs of primers. The correlation analysis between SSR markers and fiber yield related traits by SPSS revealed that the range of the coefficient of variation related to 9 fiber traits was from 13.05% to 76.78%, indicating a comprehensive genetic variation. The correlation analysis of the agronomic traits showed that there were significantly correlations among these traits. The average correlation coefficient between branch height and nodes of main stem was the highest (r = 0.931), followed by the correlation coefficients (r = 0.781) of fresh bark weight per plant and fresh stem weight per plant and the coefficients (r = 0.779) of dry bark weight and fresh bark weight per plant. Analysis of variance (ANOVA) showed that the traits of main stem nodes, number of branches, plant height and branch height were relatively stable in different years with the higher broad heritability capacity. Furthermore, the SSR markers associated with fiber yield related traits were identified by Pearson correlation method. Stepwise regression analysis among each trait associated SSR markers indicated that there were six markers associated significantly with fiber yield related traits, and phenotypic variation explained by each SSR marker varied from 3.9% to 22.5%. These results will accelerate the development of molecular design breeding in jute.

Key words: jute, fiber yield, agronomic traits, SSR, correlation, regression analysis

Li-Lan ZHANG, Lie-Mei ZHANG, Huan-Ying NIU, Yi XU, Yu LI, Jian-Min QI, Ai-Fen TAO, Ping-Ping FANG, Li-Wu ZHANG. Correlation between SSR markers and fiber yield related traits in jute (Corchorus spp.)[J].Acta Agronomica Sinica, 2020, 46(12): 1905-1913.

Figures/Tables 6

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References 31

[1]	Zhang L W, Ibrahim A K, Niyitanga S, Zhang L M, Qi J M . Jute (Corchorus spp.) Breeding. Advances in Plant Breeding Strategies: Industrial and Food Crops, 2019. pp 85-113.
[2]	粟建光, 戴志刚, 杨泽茂, 唐蜻, 谢冬微, 陈基权, 许英, 徐建堂, 张利国, 龚友才, 宋宪友, 程超华, 邓灿辉 . 麻类作物特色资源的创新与利用. 植物遗传资源学报, 2019,20:11-19.
	Su J G, Dai Z G, Yang Z M, Tang Q, Xie D W, Chen J Q, Xu Y, Xu J T, Zhang L G, Gong Y C, Song X Y, Cheng C H, Deng C H . Innovation and utilization of characteristic germplasm for bast fiber crops. J Plant Genet Resour, 2019,20:11-19 (in Chinese with English abstract).
[3]	Mondal S, Hadapad A B, Hande P A, Badigannavar A M . Identification of quantitative trait loci for bruchid ( Caryedon serratus Olivier) resistance components in cultivated groundnut(Arachis hypogaea L.). Mol Breed, 2014,33:961-973. doi: 10.1007/s11032-013-0011-1
[4]	Crouzillat D, Phillips W, Fritz P J, Pétiard V . Quantitative trait loci analysis in Theobroma cacao using molecular markers. Inheritance of polygenic resistance to Phytophthora palmivora in two related cacao populations. Euphytica, 2000,114:25-36. doi: 10.1023/A:1003994212394
[5]	Banerjee S, Das M, Mir R R, Kundu A, Topdar N, Sarkar D, Sinha M K, Balyan H S, Gupta P K . Assessment of genetic diversity and population structure in a selected germplasm collection of 292 jute genotypes by microsatellite (SSR) markers. Mol Plant Breed, 2012,3:11-25.
[6]	Liu S, Liu H, Wu A, Hou Y, An Y, Wei C . Construction of fingerprinting for tea plant ( Camellia sinensis) accessions using new genomic SSR markers. Mol Breed, 2017,37:93. doi: 10.1007/s11032-017-0692-y
[7]	Dachapak S, Somta P, Poonchaivilaisak S, Yimram T, Srinives P . Genetic diversity and structure of the zombi pea [Vigna vexillata(L.) A. Rich] gene pool based on SSR marker analysis. Genetica, 2017,145:189-200. doi: 10.1007/s10709-017-9957-y pmid: 28233217
[8]	Satya P, Chakraborty A, Jana S, Majumdar S, Karan M, Sarkar D, Datta S, Mitra J, Kar C, Karmakar P, Singh N . Identification of genic SSRs in jute ( Corchorus capsularis, Malvaceae) and development of markers for phenylpropanoid biosynthesis genes and regulatory genes. Plant Breed, 2017,136:784-797. doi: 10.1111/pbr.2017.136.issue-5
[9]	Tao A, Huang L, Wu G, Afshar R K, Qi J, Xu J, Fang P, Lin L, Zhang L, Lin P . High-density genetic map construction and QTLs identification for plant height in white jute ( Corchorus capsularis L.) using specific locus amplified fragment (SLAF) sequencing. BMC Genomics, 2017,18:355. doi: 10.1186/s12864-017-3712-8 pmid: 28482802
[10]	Lou Y, Hu L, Chen L, Sun X, Yang Y, Liu H, Xu Q . Association analysis of simple sequence repeat (SSR) markers with agronomic traits in tall fescue ( Festuca arundinacea Schreb.). PLoS One, 2015,10:e0133054. doi: 10.1371/journal.pone.0133054 pmid: 26186338
[11]	Prabhu D A, Ray J D, Singh S K, Valerio H V, Smith J R, Purcell L C, King A, Fritschi F B . Genome-wide association analysis of diverse soybean genotypes reveals novel markers for nitrogen traits. Plant Genome, 2015,8:1-15.
[12]	Islam M S, Saito J A, Emdad E M, Ahmed B, Islam M M, Halim A, Hossen Q M, Hossain M Z, Ahmed R, Hossain M S, Kabir S M, Khan M S, Khan M M, Hasan R, Aktar N, Honi U, Islam R, Rashid M M, Wan X, Hou S, Haque T, Azam M S, Moosa M M, Elias S M, Hasan A M, Mahmood N, Shafiuddin M, Shahid S, Shommu N S, Jahan S, Roy S, Chowdhury A, Akhand A I, Nisho G M, Uddin K S, Rabeya T, Hoque S M, Snigdha A R, Mortoza S, Matin S A, Islam M K, Lashkar M Z, Zaman M, Yuryev A, Uddin M K, Rahman M S, Haque M S, Alam M M, Khan H, Alam M . Comparative genomics of two jute species and insight into fibre biogenesis. Nat Plants, 2017,3:16223. doi: 10.1038/nplants.2016.223 pmid: 28134914
[13]	姚嘉瑜, 张立武, 赵捷, 徐益, 祁建民, 张列梅 . 黄麻全基因组SSR鉴定与特征分析. 作物学报, 2019,45:14-21.
	Yao J Y, Zhang L W, Zhao J, Xu Y, Qi J M, Zhang L M . Evaluation and characteristic analysis of SSRs from the whole genome of jute ( Corchorus capsularis). Acta Agron Sin, 2019,45:14-21 (in Chinese with English abstract).
[14]	张彬, 李金秀, 王震, 冯浩, 李金榜 . 小麦主要农艺性状的相关性及聚类分析. 作物杂志, 2018, ( 3):57-60.
	Zhang B, Li J X, Wang Z, Feng H, Li J B . Correlation and cluster analysis of agronomic traits in wheat lines. Crops, 2018, ( 3):57-60 (in Chinese with English abstract).
[15]	殷冬梅, 李拴柱, 崔党群 . 花生主要农艺性状的相关性及聚类分析. 中国油料作物学报, 2010,32:212-216.
	Yin D M, Li S Z, Cui D Q . Agronomic character and cluster analysis of peanut cultivar. Chin J Oil Crop Sci, 2010,32:212-216 (in Chinese with English abstract).
[16]	Ghosh R K, Sreewongchai T, Nakasathien S, Phumichai C . Phenotypic variation and the relationships among jute ( Corchorus species) genotypes using morpho-agronomic traits and multivariate analysis. Aust J Crop Sci, 2013,7:830.
[17]	Zhang L W, Yuan M H, Tao A F, Xu J T, Lin L H, Fang P P, Qi J M . Genetic structure and relationship analysis of an association population in jute ( Corchorus spp.) evaluated by SSR markers. PLoS One, 2015,10:e0128195. doi: 10.1371/journal.pone.0128195 pmid: 26035301
[18]	张立武, 袁民航, 何雄威, 刘星, 方平平, 林荔辉, 陶爱芬, 徐建堂, 祁建民 . GenBank数据库中黄麻EST-SSR标记的开发及其通用性评价. 作物学报, 2014,40:1213-1219. doi: 10.3724/SP.J.1006.2014.01213
	Zhang L W, Yuan M H, He X W, Liu X, Fang P P, Lin L H, Tao A F, Xu J T, Qi J M . Development and universality evaluation of EST-SSR markers from GenBank in jute. Acta Agron Sin, 2014,40:1213-1219 (in Chinese with English abstract).
[19]	Zhang L L, Gao Z Z, Wan X B, Xu Y, Zhang L M, Tao A F, Fang P P, Qi J M, Zhang L W . Development of novel small indel markers in jute ( Corchorus spp.). Trop Plant Biol, 2017,10:169-176. doi: 10.1007/s12042-017-9193-8
[20]	粟建光 . 黄麻种质资源描述规范和数据标准. 北京: 中国农业出版社, 2005. pp 7-27.
	Su J G. Descriptors and Data Standard for Jute (Corchorus olitorius L. & Corchorus capsularis L.). Beijing: China Agriculture Press, 2005. pp 7-27(in Chinese).
[21]	Kraakman A T, Wageningen A J, Niks R E, Stam P . Linkage disequilibrium mapping of yield and yield stability in modern spring barley cultivars. Genetics, 2004,168:435-446. doi: 10.1534/genetics.104.026831 pmid: 15454555
[22]	杨洛淼, 孙健, 赵宏伟, 王敬国, 刘化龙, 邹德堂 . 不同年份冷水胁迫下水稻抽穗期和产量性状的QTL分析. 中国农业科学, 2016,49:3489-3503. doi: 10.3864/j.issn.0578-1752.2016.18.003
	Yang L M, Sun J, Zhao H W, Wang J G, Liu H L, Zou D T . QTL analysis of heading date and yield traits in japonica rice under cold water stress in different years. Sci Agric Sin, 2016,49:3489-3503 (in Chinese with English abstract).
[23]	Karrakman A T, Nikes R E, Berg P M, Stam P, Eeuwijk F A . Linkage disequilibrium mapping of yield and yield stability in modern spring barley cultivars. Genetics, 2004,168:435-446. doi: 10.1534/genetics.104.026831 pmid: 15454555
[24]	司二静, 张宇, 汪军成, 孟亚雄, 李葆春, 马小乐, 尚勋武, 王化俊 . 大麦农艺性状与SSR标记的关联分析. 作物学报, 2015,41:1064-1072. doi: 10.3724/SP.J.1006.2015.01064
	Si R J, Zhang Y, Wang J C, Meng Y X, Li B C, Ma X L, Shang X W, Wang H J . Association analysis between SSR markers and agronomic traits in barley. Acta Agron Sin, 2015,41:1064-1072 (in Chinese with English abstract).
[25]	Zhao J L, Wang H W, Zhang X C, Du X Y, Li A F, Kong L R . Association analysis of grain traits with SSR markers between Aegilops tauschii and hexaploid wheat(Triticum aestivum L.). J Integr Agric, 2015,14:1936-1948. doi: 10.1016/S2095-3119(15)61070-X
[26]	Abbasi Z, Majidi M M, Arzani A, Rajabi A, Mashayekhi P, Bocianowski J . Association of SSR markers and morpho- physiological traits associated with salinity tolerance in sugar beet ( Beta vulgaris L.). Euphytica, 2015,205:785-797. doi: 10.1007/s10681-015-1408-1
[27]	Fan C, Xing Y, Mao H, Lu T, Han B, Xu C, Li X, Zhang Q . GS3, a major QTL for grain length and weight and minor QTL for grain width and thickness in rice, encodes a putative transmembrane protein. Theor Appl Genet, 2006,112:1164-1171. doi: 10.1007/s00122-006-0218-1
[28]	Yue B, Xue W Y, Luo L J, Xing Y Z . QTL analysis for flag leaf characteristics and their relationships with yield and yield traits in rice. Acta Genet Sin, 2006,33:824-832. doi: 10.1016/S0379-4172(06)60116-9 pmid: 16980129
[29]	祁建民, 卢浩然, 郑云雨, 王英娇 . 黄麻数量性状遗传关系分析. 作物学报, 1991,17:145-150.
	Qi J M, Lu H R, Zheng Y Y, Wang Y J . Analysis on the genetic relationship of quantitative characters in jute ( Corchorus capsularis L.). Acta Agron Sin, 1991,17:145-150 (in Chinese with English abstract).
[30]	周金超, 杨鑫雷, 崔顺立, 侯名语, 陈焕英, 穆国俊, 刘立峰 . 花生SSR标记与农艺性状的相关性. 作物学报, 2014,40:1197-1204. doi: 10.3724/SP.J.1006.2014.01197
	Zhou J C, Yang X L, Cui S L, Hou M Y, Chen H Y, Mu G J, Liu L F . Correlation between SSR markers and agronomic traits in peanut ( Arachis hypogaea L.). Acta Agron Sin, 2014,40:1197-1204 (in Chinese with English abstract).
[31]	李丹阳, 刘凯歌, 卢济明, 杨鑫雷, 崔顺立, 穆国俊, 陈焕英, 刘立峰 . 花生SSR标记与品质性状的相关分析. 分子植物育种, 2017,15:2695-2701.
	Li D Y, Liu K G, Lu J M, Yang X L, Cui S L, Mu G J, Chen H Y, Liu L F . Correlation analysis of SSR markers and quality traits in peanut ( Arachis hypogaea L.). Mol Plant Breed, 2017,15:2695-2701 (in Chinese with English abstract).

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性状 Trait	年份 Year	平均值±标准差 Mean ± SD	最大值 Maximum	最小值 Minimum	变异系数 CV (%)	遗传多样性指数 Shannon-Wiener index
株高PH (cm)	2016	331.97±43.33	459.10	43.33	13.05	1.89
	2017	334.69±51.40	482.90	51.40	15.36	2.10
	2018	384.37±64.21	514.90	64.21	16.71	2.40
分枝高BH (cm)	2016	110.35±72.04	352.00	6.57	65.29	2.32
	2017	106.62±67.36	391.40	4.10	63.17	2.34
	2018	170.23±82.87	427.90	5.33	48.68	2.62
茎粗SD (mm)	2016	18.26±2.42	23.72	2.42	13.27	1.82
	2017	20.44±3.30	28.96	3.30	16.16	2.23
	2018	20.88±3.31	28.37	3.31	15.83	2.17
鲜皮厚FBT (mm)	2016	1.33±0.23	2.00	0.23	17.21	1.95
	2017	1.29±0.25	2.02	0.25	19.24	2.08
	2018	1.17±0.32	2.05	0.32	27.53	2.46
节数NMS (个)	2016	18.82±13.48	50.30	1.00	71.63	2.11
	2017	19.02±14.38	78.70	1.00	75.61	2.23
	2018	26.37±14.76	81.33	1.00	55.96	2.48
分枝数NB (个)	2016	19.15±13.81	55.20	2.10	72.12	2.19
	2017	20.55±17.41	74.00	1.50	84.73	2.38
	2018	18.75±14.39	70.30	2.20	76.78	2.28
单株鲜茎重FSW (g)	2016	682.18±244.1	1462.00	71.75	35.79	2.23
	2017	611.51±206.6	1266.00	64.00	33.79	2.14
	2018	598.62±231.7	1380.00	97.00	38.71	2.23
单株鲜皮重FBW (g)	2016	172.8±66.20	421.00	43.50	38.31	2.34
	2017	131.35±66.09	394.00	7.50	50.31	2.37
	2018	128.71±70.57	330.00	8.00	54.83	2.49
单株干皮重DBW (g)	2016	42.92±14.95	141.00	14.95	34.84	1.52
	2017	39.32±19.02	110.00	4.00	48.38	1.93
	2018	31.00±16.84	104.00	6.00	54.31	1.78

性状 Trait	差异源 Source	自由度 DF	总方差 SS	均方 MS	P值 P-value	广义遗传力 Broad-sense capacity
株高PH	年份Years	2	197,483.34	98,741.67	<0.01	-
株高PH	品种Varieties	310	2,018,314.68	6,510.69	<0.01	0.81
分枝高BH	年份Years	2	533,367.61	266,683.80	<0.01	-
分枝高BH	品种Varieties	310	3,902,352.97	12,588.24	<0.01	0.78
茎粗SD	年份Years	2	461.51	230.76	<0.01	-
茎粗SD	品种Varieties	310	5,529.13	17.84	<0.01	0.71
鲜皮厚FBT	年份Years	2	4.90	2.45	<0.01	-
鲜皮厚FBT	品种Varieties	310	35.52	0.11	<0.01	0.61
节数NMS	年份Years	2	8,788.61	4,394.31	<0.01	-
节数NMS	品种Varieties	310	149,702.87	482.91	<0.01	0.82
分枝数NB	年份Years	2	480.19	240.09	0.019	-
分枝数NB	品种Varieties	310	187,378.60	604.45	<0.01	0.90
单株鲜茎重FSW	年份Years	2	1,291,406.03	645,703.01	<0.01	-
单株鲜茎重FSW	品种Varieties	310	28,003,667.06	90,334.41	<0.01	0.72
单株鲜皮重FBW	年份Years	2	270,421.30	135,210.65	<0.01	-
单株鲜皮重FBW	品种Varieties	310	2,529,200.96	8,158.71	<0.01	0.72
单株干皮重DBW	年份Years	2	10,322.48	5,161.24	<0.01	-
单株干皮重DBW	品种Varieties	310	104,444.51	336.92	<0.01	0.70

年份Year	性状 Trait	2016	2017
2017	株高PH	0.727^**
	分枝高BH	0.835^**
	茎粗SD	0.489^**
	鲜皮厚FBT	0.328^**
	节数NMS	0.774^**
	分枝数NB	0.806^**
	单株鲜茎重FSW	0.458^**
	单株鲜皮重FBW	0.541^**
	单株干皮重DBW	0.307^**
2018	株高PH	0.684^**	0.741^**
	分枝高BH	0.597^**	0.626^**
	茎粗SD	0.344^**	0.474^**
	鲜皮厚FBT	0.177^*	0.381^**
	节数NMS	0.625^**	0.635^**
	分枝数NB	0.725^**	0.771^**
	单株鲜茎重FSW	0.368^**	0.370^**
	单株鲜皮重FBW	0.396^**	0.528^**
	单株干皮重DBW	0.267^**	0.398^**

	年份 Year	株高 PH	分枝高 BH	茎粗 SD	鲜皮厚 FBT	节数 NMS	分枝数 NB	单株鲜茎重 FSW	单株鲜皮重 FBW
分枝高 BH	2016	0.018
	2017	0.302^**
	2018	0.398^**
茎粗 SD	2016	0.537^**	0.102
	2017	0.715^**	0.176^**
	2018	0.542^**	0.215^**
鲜皮厚 FBT	2016	0.370^**	0.063	0.751^**
	2017	0.519^**	0.074	0.728^**
	2018	0.385^**	0.055	0.688^**
节数 NMS	2016	0.098	0.959^**	0.104	0.087
	2017	0.214^**	0.927^**	0.115	0.039
	2018	0.282^**	0.908^**	0.159^**	0.055
分枝数 NB	2016	0.547^**	-0.667^**	0.321^**	0.234^**	-0.706^**
	2017	0.442^**	-0.510^**	0.437^**	0.411^**	-0.553^**
	2018	0.468^**	-0.435^**	0.262^**	0.358^**	-0.508^**
单株鲜茎重 FSW	2016	0.509^**	0.291^**	0.715^**	0.634^**	0.309^**	0.535^**
	2017	0.596^**	0.169^**	0.741^**	0.646^**	0.190^**	0.495^**
	2018	0.709^**	0.054	0.662^**	0.644^**	0.001	0.551^**
单株鲜皮重 FBW	2016	0.607^**	0.027	0.798^**	0.695^**	0.059	0.480^**	0.816^**
	2017	0.730^**	0.202^**	0.783^**	0.700^**	0.158^**	0.424^**	0.717^**
	2018	0.703^**	0.241^**	0.671^**	0.660^**	0.168^**	0.384^**	0.809^**
单株干皮重 DBW	2016	0.522^**	0.020	0.529^**	0.535^**	0.025	0.299^**	0.609^**	0.714^**
	2017	0.797^**	0.195^**	0.730^**	0.615^**	0.140*	0.458^**	0.654^**	0.883^**
	2018	0.666^**	0.382^**	0.422^**	0.355^**	0.399^**	0.302^**	0.702^**	0.740^**

标记 Marker	株高 PH	分枝高 BH	节数 NMS	茎粗 SD	鲜皮厚 FBT	分枝数 NB	单株鲜茎重 FSW	单株鲜皮重 FBW	单株干皮重 DBW
CoSSR068	-0.120^*	-0.090	-0.160	-0.07	-0.04	-0.020	-0.110	-0.110	-0.100
CoSSR119	-0.010	-0.240^**	0.130^**	0.031	0.15^*	0.130^*	0.052	0.020	0.007
CoSSR100	0.051	-0.090	0.280	-0.022	-0.02	0.028	0.028	-0.004	-0.020
CoEMS250	-0.020	-0.020	0.030	-0.021	0.045	0.029	-0.010	-0.012	0.018
CoEMS474	-0.160^**	-0.090	-0.020	-0.045	-0.04	-0.020	-0.010	-0.120^**	-0.130^*
CoSSR099	0.131^*	-0.070	0.130^*	-0.072	-0.04	0.133^*	0.111	0.0370	0.110
CoSSR094	0.147^**	-0.170^**	0.200^**	0.195^**	0.22^**	0.200^**	0.174^**	0.213^**	0.065
CoSSR090	-0.140	-0.150^*	0.023	-0.170^**	-0.11	0.023	-0.090	-0.130^*	-0.104
CcID066	0.127^*	-0.160^**	0.170^*	-0.120^*	-0.04	0.130^*	0.076	-0.023	0.049
CcID167	0.176^**	-0.100	0.180^**	0.190^**	0.30^**	0.180^**	0.168^**	0.294^**	0.230^**
CoSSR133	0.147^*	-0.070	0.140^*	0.099	0.13^*	0.140^*	0.088	0.090	0.014
CoSSR086	0.208^**	-0.120^*	0.210^**	0.255^**	0.33^**	0.210^**	0.226^**	0.324^**	0.190^**
CoSSR164	0.081	0.092	0.095	-0.180^**	-0.10	-0.100	-0.050	-0.012	0.031
CcSSR019	0.215^**	-0.140^*	0.241	0.245^**	0.34^**	0.240^**	0.243^**	0.327^**	0.217^**
CcSSR045	-0.110^*	-0.210^*	0.063	-0.160^**	-0.15^**	-0.060	-0.100	-0.105	-0.080

Correlation between SSR markers and fiber yield related traits in jute (Corchorus spp.)

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