不同粒色小麦籽粒铁锌含量和生物有效性及其对氮磷肥的响应

doi:10.3724/SP.J.1006.2018.01506

Abstract

Abstract:

Six wheat cultivars with different-colored grains (white, red, and black) were used to investigate effects of combined N (N1: 90 kg N ha^-1; N2: 240 kg N ha^-1) and P (P1: 60 kg P₂O₅ ha^-1; P2: 209 kg P₂O₅ ha^-1) fertilization on grain yield, Fe and Zn contents and accumulation in grain, and their bioavailability in a two-year field experiment. Black-grain cultivars had a higher average Fe and Zn bioavailability than the red- and white-grain cultivars. Meanwhile, there were inter-annual differences in Fe and Zn contents and accumulation in grains among different wheat cultivars. Maximum grain yield, Fe and Zn contents and accumulation were observed under N2P1 treatment, while highest Fe and Zn bioavailability were observed under N2P2 or N2P1 treatment. Red-grain cultivars Yangmai 15 and Yangmai 22 got the highest Fe and Zn contents, and accumulation amount under N2P1 treatment. Black-grain cultivars Zhouheimai 1 and Zimai 1 got the highest Fe content and accumulation amount under N2P2 treatment, followed by N2P1. Most cultivars had the highest Fe and Zn bioavailability under N2P1 or N2P2 treatment, which indicated that increasing N application results in a higher grain yield, Fe and Zn contents, and their bioavailability. In this experiment, wheat cultivars would benefit from N2P1 treatment in terms of grain yield, Fe and Zn contents, and their bioavailability.

Key words: wheat, nitrogen and phosphorus combinations, grain yield, iron and zinc contents, bioavailability

Xin HUANG,Yao-Guang LI,Wan SUN,Jun-Feng HOU,Ying MA,Jian ZHANG,Dong-Yun MA,Chen-Yang WANG,Tian-Cai GUO. Variation of Grain Iron and Zinc Contents and Their Bioavailability of Wheat Cultivars with Different-colored Grains under Combined Nitrogen and Phosphorus Fertilization[J].Acta Agronomica Sinica, 2018, 44(10): 1506-1516.

Figures/Tables 9

Supplementary table 1

Supplementary table 2

Table 1

Table 2

Table 3

Table 4

Supplementary table 3

Contents and accumulations of Fe and Zn in wheat grains and their bioavailability under combined nitrogen and phosphorus fertilization"

品种类型 Cultivar type	品种名称 Cultivar name	处理 Treatment	铁含量 Fe content (mg kg^-1)	锌含量 Zn content (mg kg^-1)	铁积累量 Fe accumulation (g hm^-2)	锌积累量 Zn accumulation (g hm^-2)	植酸/铁 PA/Fe	植酸/锌 PA/Zn
2013-2014
白粒	豫麦49-198	N1P1	38.13 b	27.26 d	226.7 b	162.0 c	33.96 a	55.13 a
White-grain	Yumai 49-198	N2P1	57.12 a	40.43 a	463.3 a	327.9 a	28.92 b	47.43 ab
		N1P2	56.15 a	31.29 cd	365.0 a	203.4 bc	26.63 bc	55.47 a
		N2P2	56.31 a	34.58 b	391.0 a	240.1 b	24.02 c	45.40 b
	郑麦366	N1P1	37.68 b	36.49 b	257.5 c	249.3 bc	34.36 a	41.19 c
	Zhengmai 366	N2P1	58.90 a	38.90 a	476.1 a	314.4 a	25.52 bc	44.85 c
		N1P2	52.88 a	27.43 d	354.0 bc	183.6 c	27.22 b	60.92 a
		N2P2	62.42 a	33.03 c	456.0 ab	241.3 bc	23.62 c	51.80 b
红粒	扬麦15	N1P1	49.49 b	31.85 c	342.3 b	220.3 c	29.76 b	53.68 a
Red-grain	Yangmai 15	N2P1	68.24 a	39.03 a	494.7 a	282.9 a	22.66 c	44.95 b
		N1P2	43.45 b	32.49 c	288.5 b	215.7 c	32.70 a	50.76 a
		N2P2	45.47 b	37.41 b	319.5 b	262.9 b	32.07 a	45.24 b
	扬麦22	N1P1	40.94 b	31.32 c	265.0 c	202.7 b	30.24 a	45.90 b
	Yangmai 22	N2P1	60.04 a	36.74 a	475.9 a	288.8 a	20.81 d	39.81 c
		N1P2	58.85 a	27.92 d	415.2 ab	197.0 b	26.80 b	65.58 a
		N2P2	59.19 a	37.94 a	356.8 b	228.7 b	25.39 bc	45.99 b
黑粒	周黑麦1号	N1P1	46.28 c	36.53 b	334.2 c	263.8 a	32.09 a	47.18 a
Black-grain	Zhouheimai 1	N2P1	52.35 b	39.46 a	362.0 b	272.9 a	24.69 b	38.02 b
		N1P2	55.69 b	35.58 bc	374.4 b	239.2 a	22.9 bc	41.60 ab
		N2P2	60.55 a	34.23 c	498.9 a	260.5 a	19.21 c	42.70 ab
	紫麦1号	N1P1	42.27 b	36.76 bc	268.9 c	233.8 ab	32.74 a	43.70 b
	Zimai 1	N2P1	63.66 a	40.39 a	456.2 ab	289.5 a	21.73 b	39.76 bc
		N1P2	71.04 a	29.28 c	434.1 b	178.9 b	18.99 bc	53.49 a
		N2P2	77.98 a	35.84 bc	532.9 a	244.9 ab	16.29 c	41.15 b
品种类型 Cultivar type	品种名称 Cultivar name	处理 Treatment	铁含量 Fe content (mg kg^-1)	锌含量 Zn content (mg kg^-1)	铁积累量 Fe accumulation (g hm^-2)	锌积累量 Zn accumulation (g hm^-2)	植酸/铁 PA/Fe	植酸/锌 PA/Zn
2014-2015
白粒	豫麦49-198	N1P1	35.99 b	31.66 a	215.2 b	189.2 a	34.33 a	45.29 a
White-grain	Yumai 49-198	N2P1	49.79 a	40.68 a	328.6 a	268.5 a	23.69 c	33.65 bc
		N1P2	51.65 a	35.07 a	329.1 a	223.4 a	25.51 bc	43.61 a
		N2P2	57.34 a	38.99 a	381.7 a	259.0 a	17.33 d	29.58 c
	郑麦366	N1P1	40.12 b	29.16 a	231.4 b	168.6 b	32.38 a	51.71 a
	Zhengmai 366	N2P1	54.13 ab	40.04 a	391.3 a	289.3 a	20.94 c	32.86 b
		N1P2	48.11 ab	32.63 a	306.6 ab	208.0 ab	26.14 bc	44.73 ab
		N2P2	55.48 a	38.93 a	415.3 a	291.2 a	20.08 d	33.22 b
红粒	扬麦15	N1P1	41.11 b	30.81 b	272.9 b	204.5 b	31.35 a	48.56 a
Red-grain	Yangmai 15	N2P1	68.88 a	41.33 a	511.3 a	306.8 a	18.10 b	35.03 b
		N1P2	46.92 ab	31.17 b	326.7 b	217.0 b	29.54 ba	51.63 a
		N2P2	35.89 b	37.48 ab	234.5 b	244.9 ab	32.36 a	35.97 b
	扬麦22	N1P1	38.03 b	31.43 b	218.0 c	180.2 b	32.61 a	45.81 a
	Yangmai 22	N2P1	55.16 a	39.37 a	425.6 a	303.7 a	21.28 c	34.62 b
		N1P2	39.06 b	29.19 b	240.2 b	179.5 b	31.88 a	49.53 a
		N2P2	39.94 b	36.81 ab	269.6 b	248.4 ab	26.74 c	33.68 b
黑粒	周黑麦1号	N1P1	40.68 c	36.64 a	197.1 c	177.5 b	32.62 a	42.04 ab
Black-grain	Zhouheimai 1	N2P1	50.24 b	38.53 a	339.7 ab	260.5 a	23.93 c	36.22 b
		N1P2	52.62 b	27.68 b	319.8 b	168.2 b	23.74 b	52.37 a
		N2P2	59.95 a	37.34 a	367.7 a	229.0 ab	18.04 c	33.63 b
	紫麦1号	N1P1	42.01 c	31.75 c	181.5 b	144.0 b	31.89 a	46.65 a
	Zimai 1	N2P1	48.98 b	42.81 b	336.7 a	294.3 a	21.48 c	28.52 b
		N1P2	42.86 bc	26.0 8c	216.2 b	131.5 b	27.57 ab	52.60 a
		N2P2	60.30 a	53.46 a	377.71 a	294.9 a	17.52 c	22.94 b

Supplementary table 3

Table 5

Table 6

References 38

[1]	杨莉琳, 刘小京, 徐进, 毛任钊 . 小麦籽粒微量元素含量的研究进展. 麦类作物学报, 2008,28:1113-1117
	Yang L L, Liu X J, Xu J, Mao R Z . Progress in research of micronutrients content in wheat grain. J Trit Crops, 2008,28:1113-1117 (in Chinese with English abstract)
[2]	Cakmak I . Enrichment of cereal grain with zinc: agronomic or genetic biofortification. Plant Soil, 2008,302:1-17 doi: 10.1007/s11104-007-9466-3
[3]	Cakmak I . Enrichment of fertilizers with zinc: an excellent investment for humanity and crop production in India. J Trace Elem Med Biol, 2009,23:28l-289
[4]	Zhou J R, Erdman J W . Phytic acid in health and disease. Crit Rev Food Sci, 1995,35:495-508 doi: 10.1080/10408399509527712 pmid: 8777015
[5]	Cakmak I, Pfeiffer W H, McClafferty B . Biofortification of durum wheat with zinc and iron. Cereal Chem, 2010,87:10-20 doi: 10.1094/CCHEM-87-1-0010
[6]	Cakmak I, Torun A, Millet E, Feldman M, Fahima T, Korol A, Nevo E, Braun H J, Ozkan H . Triticum dicoccoides: an important genetic resource for increasing zinc and iron concentration in modern cultivated wheat. Soil Sci Plant Nutr, 2004,50:1047-1054
[7]	Salunke R, Neelam K, Rawat N, Tiwari V K, Dhaliwal H S, Roy P . Bioavailability of iron from wheat aegilops derivatives selected for high grain iron and protein contents. J Agric Food Chem, 2011,59:7465-7473 doi: 10.1021/jf2008277
[8]	郝志, 田纪春, 姜小苓 . 小麦主要亲缘种籽粒的Fe、Zn、Cu、Mn含量及其聚类分析. 作物学报, 2007,33:1834-1839 doi: 10.3321/j.issn:0496-3490.2007.11.015
	Hao Z, Tian J C, Jiang X L . Analyses of Fe, Zn, Cu and Mn contents in grains and grouping basesd on contents for main kindred germplasm of common wheat (Triticum aestivum). Acta Agron Sin, 2007,33:1834-1839 (in Chinese with English abstract) doi: 10.3321/j.issn:0496-3490.2007.11.015
[9]	Cakmak I, Kalayci M, Kaya Y, Torun A A, Aydin N, Wan G Y, Arisoy Z, Erdem H, Yazici A, Gokmen O, Ozturk L, Horst W J . Biofortification and localization of zinc in wheat grain. J Agric Food Chem, 2010,58:9092-9102 doi: 10.1021/jf101197h pmid: 23654236
[10]	Kutman U B, Yildiz B, Ozturk L, Cakmak I . Biofortification of durum wheat with zinc through soil and foliar applications of nitrogen. Cereal Chem, 2010,87:1-9 doi: 10.1094/CCHEM-87-1-0001
[11]	曹玉贤, 田霄鸿, 杨习文, 陆欣春, 陈辉林, 南雄雄, 李秀丽 . 土施和喷施锌肥对冬小麦子粒锌含量及生物有效性的影响. 植物营养与肥料学报, 2010,16:1394-1401 doi: 10.11674/zwyf.2010.0614
	Cao Y X, Tian X H, Yang X W, Lu X C, Chen H L, Nan X X, Li X L . Effects of soil and foliar applications of Zn on winter wheat grain Zn concentration and bioavailability. Plant Nutr Fert Sci, 2010,16:1394-1401 (in Chinese with English abstract) doi: 10.11674/zwyf.2010.0614
[12]	左毅, 马冬云, 王晨阳, 朱云集, 刘骏, 郭天财 . 花后叶面喷施氮肥和锌肥对小麦粒重及营养品质的影响. 麦类作物学报, 2013,33:123-128 doi: 10.7606/j.issn.1009-1041.2013.01.021
	Zuo Y, Ma D Y, Wang C Y, Zhu Y J, Liu J, Guo T C . Effects of spraying nitrogen and zinc fertilizers after flowering on grain weight and nutritional quality of winter wheat. J Trit Crops, 2013,33:123-128 (in Chinese with English abstract) doi: 10.7606/j.issn.1009-1041.2013.01.021
[13]	Kutman U B, Yildiz B, Cakmak I . Improved nitrogen status enhances zinc and iron concentrations both in the whole grain and the endosperm fraction of wheat. J Cereal Sci, 2011,53:118-125 doi: 10.1016/j.jcs.2010.10.006
[14]	常旭虹, 赵广才, 王德梅, 杨玉双, 马少康, 李振华, 李辉利, 贾二红, 陈枫 . 生态环境与施氮量协同对小麦籽粒微量元素含量的影响. 植物营养与肥料学报, 2014,20:885-895
	Chang X H, Zhao G C, Wang D M, Yang Y S, Ma S K, Li Z H, Li H L, Jia E H, Chen F . Effects of ecological environment and nitrogen application rate on microelement contents of wheat grain. Plant Nutr Fert Sci, 2014, 20:885-895 (in Chinese with English abstract)
[15]	Webb M J, Loneragan J F . Zinc translocation to wheat roots and its implications for a phosphorus/zinc interaction in wheat plants. Plant Nutr, 1990,13:1499-1512 doi: 10.1080/01904169009364171
[16]	Ryan M H, McLnerney J K, Record I R, Angus J F . Zinc bioavailability in wheat grain in relation to phosphorus fertilizer, crop sequence and mycorrhizal fungi. J Sci Food Agric, 2008,88:1208-1216 doi: 10.1002/(ISSN)1097-0010
[17]	买文选, 田霄鸿, 陆欣春, 杨习文 . 磷锌肥配施对冬小麦籽粒锌生物有效性的影响. 中国生态农业学报, 2011,19:1243-1249
	Mai W X, Tian X H, Lu X C, Yang X W . Effect of Zn and P supply on grain Zn bioavailability in wheat. Chin J Eco-Agric, 2011,19:1243-1249 (in Chinese with English abstract)
[18]	Zhang M W, Ma D Y, Wang CH Y , et al. Responses of amino acid composition to nitrogen application in high- and low-protein wheat cultivars at two planting environments. Crop Sci, 2015,56:1-11
[19]	张德奇, 季书勤, 王汉芳, 李向东, 吕凤荣, 郭瑞 . 弱筋小麦郑麦004的氮、磷肥运筹模式研究. 河南农业科学, 2011,40(2):50-53
	Zhang D Q, Ji S Q, Wang H F, Li X D, Lyu F R, Guo R . Research on N and P fertilizer application mode of weak gluten wheat Zhengmai 004. J Henan Agric Sci, 2011,40(2):50-53 (in Chinese with English abstract)
[20]	朱统泉, 吴大付, 金艳 . 豫中南地区优质强筋小麦产量和品质的适宜氮磷配比研究. 中国土壤与肥料, 2014, ( 4):57-60
	Zhu T Q, Wu D F, Jin Y . Effect of different ratio of nitrogen and phosphorus fertilizer on yield and quality of strong gluten wheat in the south central area of Henan province. J Soil Fert China, 2014, ( 4):57-60 (in Chinese with English abstract)
[21]	Li W D, Beta T, Sun S C, Corke H . Protein characteristics of Chinese black-grained wheat. Food Chem, 2006,98:463-472 doi: 10.1016/j.foodchem.2005.06.020
[22]	Li Y G, Ma D Y, Sun D X, Wang C Y, Zhang J, Xie Y X, Guo T C . Total phenolic, flavonoid content, and antioxidant activity of flour, noodles, and steamed bread made from different colored wheat grains by three milling methods. Crop J, 2015,3:328-334 doi: 10.1016/j.cj.2015.04.004
[23]	Ma D Y, Li Y G, Zhang J, Wang C Y, Qin H X, Ding H N, Xie Y X, Guo T C . Accumulation of phenolic compounds and expression profiles of phenolic acid biosynthesis-related genes in developing grains of white, purple, and red wheat. Front Plant Sci, 2016,7:528
[24]	胡秋辉, 陈历程, 吴莉莉, 曹延松, 程万和 . 黑小麦营养成分分析及其深加工制品前景展望. 食品科学, 2001,22(12):50-52 doi: 10.3321/j.issn:1002-6630.2001.12.013
	Hu Q H, Chen L C, Wu L L, Cao Y S, Cheng W H . Analysis of nutritional components of black wheat and prospect of its deep processed products. Food Sci, 2001,22(12):50-52 (in Chinese with English abstract) doi: 10.3321/j.issn:1002-6630.2001.12.013
[25]	褚西宁, 赵美蓉, 王朝健 . 饲用饼粕中植酸量的快速测定法. 饲料工业, 1997,18(7):42-43
	Zhu X N, Zhao M R, Wang Z J . The rapid determination method of the amount of phytic acid in the meal. J Feed Ind, 1997,18(7):42-43 (in Chinese)
[26]	张勇, 王德森, 张艳, 何中虎 . 北方冬麦区小麦品种籽粒主要矿物质元素含量分别及其相关性分析. 中国农业科学, 2007,40:1871-1876
	Zhang Y, Wang D S, Zhang Y, He Z H . Variation of major mineral elements concentration and their relationships in grain of Chinese wheat. Sci Agric Sin, 2007,40:1871-1876 (in Chinese with English abstract)
[27]	高向阳, 宋莲军, 王振, 张小军 . 微波消解原子吸收法在南阳彩麦矿质元素测定中的营养. 河南农业大学学报, 2005,39:365-368
	Gao X Y, Song L J, Wang Z, Zhang X J . Application of AAS method with microwave digesting sample to the determination of mineral elements in Nanyang color wheat. J Henan Agric Univ, 2005,39:365-368 (in Chinese with English abstract)
[28]	何一哲, 宁军芬 . 高铁锌小麦特异新种质“秦黑1号”的营养成分分析. 西北农林科技大学学报(自然科学版), 2003,31:87-90 doi: 10.3321/j.issn:1671-9387.2003.03.020
	He Y Z, Ning J F . Analysis of nutrition composition in the special purple grain wheat “Qinhei 1” containing rich Fe and Zn. J Northweat Sci-Tech Univ For (Nat Sci Edn), 2003,31:87-90 (in Chinese with English abstract) doi: 10.3321/j.issn:1671-9387.2003.03.020
[29]	郝志, 田纪春, 孙玉, 姜小苓 . 不同粒色小麦籽粒中铁锌铜锰含量及其与种皮色素的相关分析. 中国粮油学报, 2008,23(3):12-17
	Hao Z, Tian J C, Sun Y, Jiang X L . Correlation analysis between contents of Cu, Fe, Zn, Mn and pigmentation of testa in different ccolor wheat. J Chin Cereals Oils Assoc, 2008,23(3):12-17 (in Chinese with English abstract)
[30]	苏东民, 齐兵建, 赵仁勇, 林江涛, 李建钊 . 漯珍1号黑小麦营养成分的初步评价. 粮食与饲料工业, 2000, ( 8):1-2 doi: 10.3969/j.issn.1003-6202.2000.08.001
	Su D M, Qi B J, Zhao R Y, Lin J T, Li J Z . Evaluation nutritional compositions of black wheat “Luozhen 1”. Cereal Feed Ind, 2000, ( 8):1-2 (in Chinese) doi: 10.3969/j.issn.1003-6202.2000.08.001
[31]	李峰, 田霄鸿, 陈玲, 李生秀 . 栽培模式、施氮量和播种密度对小麦子粒中Zn、Fe、Mn、Cu含量和携出量的影响. 土壤肥料, 2006, ( 2):42-46
	Li F, Tian X H, Chen L, Li S X . Effect of planting model, N fertilization and planting density on concentration and uptake of Zn, Fe, Mn and Cu in grains of winter wheat. Soil Fert, 2006, ( 2):42-46 (in Chinese with English abstract)
[32]	刘美佳, 韩证仿, 杨世佳, 杨冰, 张卫建 . 氮肥用量对苏中冬小麦地上部主要矿质元素含量的影响. 麦类作物学报, 2012,32:728-733
	Liu M J, Han Z F, Yang S J, Yang B, Zhang W J . Effects of nitrogen application rates on mineral concentrations in above-ground tissues of winter wheat in center of Jiangsu province. J Trit Crops, 2012,32:728-733 (in Chinese with English abstract)
[33]	Erenoglu E B, Kutman U B, Ceylan Y, Yildiz B, Cakmak I . Improved nitrogen nutrition enhances root uptake, root-to-shoot translocation and remobilization of zinc ( ⁶⁵Zn) in wheat . New Phytologist, 2011,189:438-448 doi: 10.1111/j.1469-8137.2010.03488.x
[34]	Syltie P W, Dabnke W C . Mineral and protein content, test weight, and yield variations of hard red spring wheat grain as influenced by fertilization and cultivar. Plant Foods Human Nutr, 2005,32:37-49
[35]	惠晓丽, 王朝辉, 罗来超, 马清霞, 王森, 戴健, 靳静静 . 长期施用氮磷肥对旱地冬小麦籽粒产量和锌含量的影响. 中国农业科学, 2017,50:3175-3185 doi: 10.3864/j.issn.0578-1752.2017.16.012
	Hui X L, Wang Z H, Luo L C, Ma Q X, Wang S, Dai J, Jin J J . Winter wheat grain yield and Zn concentration affected by long-term N and P application in dryland. Sci Agric Sin, 2017,50:3175-3185 (in Chinese with English abstract) doi: 10.3864/j.issn.0578-1752.2017.16.012
[36]	郭战玲, 寇长林, 杨占平, 马政华, 骆晓声, 沈阿林 . 潮土区小麦高产与环境友好的磷肥施用量研究. 河南农业科学, 2015,44(2):52-55
	Guo Z L, Kou C L, Yang Z P, Ma Z H, Luo X S, Shen A L . Phosphate fertilizer application amount for high yield of wheat and environmental safety in fluvo-aquic soil region. J Henan Agric Sci, 2015,44(2):52-55 (in Chinese with English abstract)
[37]	Zhang Y Q, Shi R L, Rezaul K M, Zhang F S, Zou C Q . Iron and zinc concentrations in grain and flour of winter wheat as affected by foliar application. J Agric Food Chem, 2010,58:12268-12274 doi: 10.1021/jf103039k
[38]	Lu X C, Tian X H, Cui J, Zhao A Q, Yang X W, Mai W X . Effects of combined phosphorus-zinc fertilization on grain zinc nutritional quality of wheat grown on potentially zinc-deficient calcareous soil.Soil Sci, 176:684-689

Related Articles 15

[1]	HU Wen-Jing, LI Dong-Sheng, YI Xin, ZHANG Chun-Mei, ZHANG Yong. Molecular mapping and validation of quantitative trait loci for spike-related traits and plant height in wheat [J]. Acta Agronomica Sinica, 2022, 48(6): 1346-1356.
[2]	YAN Jia-Qian, GU Yi-Biao, XUE Zhang-Yi, ZHOU Tian-Yang, GE Qian-Qian, ZHANG Hao, LIU Li-Jun, WANG Zhi-Qin, GU Jun-Fei, YANG Jian-Chang, ZHOU Zhen-Ling, XU Da-Yong. Different responses of rice cultivars to salt stress and the underlying mechanisms [J]. Acta Agronomica Sinica, 2022, 48(6): 1463-1475.
[3]	GUO Xing-Yu, LIU Peng-Zhao, WANG Rui, WANG Xiao-Li, LI Jun. Response of winter wheat yield, nitrogen use efficiency and soil nitrogen balance to rainfall types and nitrogen application rate in dryland [J]. Acta Agronomica Sinica, 2022, 48(5): 1262-1272.
[4]	LEI Xin-Hui, WAN Chen-Xi, TAO Jin-Cai, LENG Jia-Jun, WU Yi-Xin, WANG Jia-Le, WANG Peng-Ke, YANG Qing-Hua, FENG Bai-Li, GAO Jin-Feng. Effects of soaking seeds with MT and EBR on germination and seedling growth in buckwheat under salt stress [J]. Acta Agronomica Sinica, 2022, 48(5): 1210-1221.
[5]	KE Jian, CHEN Ting-Ting, WU Zhou, ZHU Tie-Zhong, SUN Jie, HE Hai-Bing, YOU Cui-Cui, ZHU De-Quan, WU Li-Quan. Suitable varieties and high-yielding population characteristics of late season rice in the northern margin area of double-cropping rice along the Yangtze River [J]. Acta Agronomica Sinica, 2022, 48(4): 1005-1016.
[6]	FU Mei-Yu, XIONG Hong-Chun, ZHOU Chun-Yun, GUO Hui-Jun, XIE Yong-Dun, ZHAO Lin-Shu, GU Jia-Yu, ZHAO Shi-Rong, DING Yu-Ping, XU Yan-Hao, LIU Lu-Xiang. Genetic analysis of wheat dwarf mutant je0098 and molecular mapping of dwarfing gene [J]. Acta Agronomica Sinica, 2022, 48(3): 580-589.
[7]	FENG Jian-Chao, XU Bei-Ming, JIANG Xue-Li, HU Hai-Zhou, MA Ying, WANG Chen-Yang, WANG Yong-Hua, MA Dong-Yun. Distribution of phenolic compounds and antioxidant activities in layered grinding wheat flour and the regulation effect of nitrogen fertilizer application [J]. Acta Agronomica Sinica, 2022, 48(3): 704-715.
[8]	LIU Yun-Jing, ZHENG Fei-Na, ZHANG Xiu, CHU Jin-Peng, YU Hai-Tao, DAI Xing-Long, HE Ming-Rong. Effects of wide range sowing on grain yield, quality, and nitrogen use of strong gluten wheat [J]. Acta Agronomica Sinica, 2022, 48(3): 716-725.
[9]	YAN Yan, ZHANG Yu-Shi, LIU Chu-Rong, REN Dan-Yang, LIU Hong-Run, LIU Xue-Qing, ZHANG Ming-Cai, LI Zhao-Hu. Variety matching and resource use efficiency of the winter wheat-summer maize “double late” cropping system [J]. Acta Agronomica Sinica, 2022, 48(2): 423-436.
[10]	WANG Yang-Yang, HE Li, REN De-Chao, DUAN Jian-Zhao, HU Xin, LIU Wan-Dai, GU Tian-Cai, WANG Yong-Hua, FENG Wei. Evaluations of winter wheat late frost damage under different water based on principal component-cluster analysis [J]. Acta Agronomica Sinica, 2022, 48(2): 448-462.
[11]	XIE Cheng-Hui, MA Hai-Zhao, XU Hong-Wei, XU Xi-Yang, RUAN Guo-Bing, GUO Zheng-Yan, NING Yong-Pei, FENG Yong-Zhong, YANG Gai-He, REN Guang-Xin. Effects of nitrogen rate on growth, grain yield, and nitrogen utilization of multiple cropping proso millet after spring-wheat in Irrigation Area of Ningxia [J]. Acta Agronomica Sinica, 2022, 48(2): 463-477.
[12]	CHEN Xin-Yi, SONG Yu-Hang, ZHANG Meng-Han, LI Xiao-Yan, LI Hua, WANG Yue-Xia, QI Xue-Li. Effects of water deficit on physiology and biochemistry of seedlings of different wheat varieties and the alleviation effect of exogenous application of 5-aminolevulinic acid [J]. Acta Agronomica Sinica, 2022, 48(2): 478-487.
[13]	XU Long-Long, YIN Wen, HU Fa-Long, FAN Hong, FAN Zhi-Long, ZHAO Cai, YU Ai-Zhong, CHAI Qiang. Effect of water and nitrogen reduction on main photosynthetic physiological parameters of film-mulched maize no-tillage rotation wheat [J]. Acta Agronomica Sinica, 2022, 48(2): 437-447.
[14]	MA Bo-Wen, LI Qing, CAI Jian, ZHOU Qin, HUANG Mei, DAI Ting-Bo, WANG Xiao, JIANG Dong. Physiological mechanisms of pre-anthesis waterlogging priming on waterlogging stress tolerance under post-anthesis in wheat [J]. Acta Agronomica Sinica, 2022, 48(1): 151-164.
[15]	MENG Ying, XING Lei-Lei, CAO Xiao-Hong, GUO Guang-Yan, CHAI Jian-Fang, BEI Cai-Li. Cloning of Ta4CL1 and its function in promoting plant growth and lignin deposition in transgenic Arabidopsis plants [J]. Acta Agronomica Sinica, 2022, 48(1): 63-75.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

品种 Cultivar	播期 Sowing date (month/day)	开花期 Flowering date (month/day)	收获期 Harvest date (month/day)	灌浆期 Grain filling duration (d)
2013-2014
豫麦49-198 Yumai 49-198	10/16	4/21	5/31	40
郑麦366 Zhengmai 366	10/16	4/18	5/29	41
扬麦15 Yangmai 15	10/23	4/18	5/29	41
扬麦22 Yangmai 22	10/23	4/18	5/29	41
周黑麦1号 Zhouheimai 1	10/16	4/21	5/31	40
紫麦1号 Zimai 1	10/16	4/21	5/31	40
2014-2015
豫麦49-198 Yumai 49-198	10/15	4/29	6/3	35
郑麦366 Zhengmai 366	10/15	4/25	5/31	36
扬麦15 Yangmai 15	10/22	4/25	5/31	36
扬麦22 Yangmai 22	10/22	4/25	5/31	36
周黑麦1号 Zhouheimai 1	10/15	4/29	6/3	35
紫麦1号 Zimai 1	10/15	4/29	6/3	35

变异来源 Source	穗数 Spike number	穗粒数 GNS	千粒重 TKW	产量 Yield	铁含量 Fe content	锌含量 Zn content	植酸/铁 PA/Fe	植酸/锌 PA/Zn
年份 Year (Y)	1944.0	350.7^*	476.8^*	7812861.2^*	6070.5^**	108.9^**	0.3	923.4^**
肥料 Fertilization (F)	54607.7^*	246.4^*	41.6^*	6809056.7^*	1519.0^**	430.6^**	61.3^**	1102.7^**
品种 Cultivar (C)	28771.5^*	1119.2^*	202.1^*	1434103.0^*	400.9^*	45.2^**	40.8^**	59.4^**
F×Y	12702.4^*	54.9	28.7^*	612532.7	2017.9^**	263.7^**	16.9	171.7^**
Y×C	13975.0^*	54.2	15.0^*	674687.9^*	337.9^*	26.1	7.6^**	75.6^**
F×C	17702.2	359.3	10.4^*	346523.7	479.7^**	42.9^**	7.6^**	23.6^**
F×Y×C	45591.5^*	314.9	10.0^*	456607.8	266.0^*	64.6^**	6.7	46.9^**

类型 Type	品种 Cultivar	穗数 SN (×10⁴hm^-2)	穗粒数 GNS	千粒重 TKW (g)	产量 Yield (kg hm^-2)
2013-2014
白粒 White-grain	豫麦49-198 Yumai 49-198	585 ab	26 b	50.1 a	6875 a
白粒 White-grain	郑麦366 Zhengmai 366	620 a	36 a	41.9 bc	7229 a
红粒 Red-grain	扬麦15 Yangmai 15	518 ab	36 a	50.3 a	6958 a
红粒 Red-grain	扬麦22 Yangmai 22	481 b	39 a	44.0 b	6854 a
黑粒 Black-grain	周黑麦1号 Zhouheimai 1	503 b	37 a	41.1 c	7118 a
黑粒 Black-grain	紫麦1号 Zimai 1	498 b	37 a	43.9 b	6618 a
2014-2015
白粒 White-grain	豫麦49-198 Yumai 49-198	619 a	33 b	45.9 a	6402 ab
白粒 White-grain	郑麦366 Zhengmai 366	559 bc	40 a	40.6 c	6716 a
红粒 Red-grain	扬麦15 Yangmai 15	510 d	39 a	43.0 b	6889 a
红粒 Red-grain	扬麦22 Yangmai 22	600 ab	41 a	39.0 c	6586 a
黑粒 Black-grain	周黑麦1号 Zhouheimai 1	526 cd	42 a	36.4 d	5954 cb
黑粒 Black-grain	紫麦1号 Zimai 1	510 d	39 a	39.8 c	5679 c
2年平均 Average of two years
白粒 White-grain	豫麦49-198 Yumai 49-198	602 a	30 b	48.0 a	6639 ab
白粒 White-grain	郑麦366 Zhengmai 366	590 a	38 a	41.3 b	6973 a
红粒 Red-grain	扬麦15 Yangmai 15	514 b	38 a	46.7 a	6924 a
红粒 Red-grain	扬麦22 Yangmai 22	541 ab	40 a	41.5 b	6720 ab
黑粒 Black-grain	周黑麦1号 Zhouheimai 1	515 b	40 a	38.8 c	6536 ab
黑粒 Black-grain	紫麦1号 Zimai 1	504 b	38 a	41.9 b	6149 b

年份 Year	处理 Treatment	穗数 SN (×10⁴hm^-2)	穗粒数 GNS	千粒重 TKW (g)	产量 Yield (kg hm^-2)
2013-2014	N1P1	518 bc	37 a	45.0 bc	6625 b
	N2P1	560 ab	38 a	45.3 ab	7565 a
	N1P2	478 c	36 a	46.4 a	6620 b
	N2P2	581 a	36 a	44.2 c	6958 b
2014-2015	N1P1	459 c	39 a	39.0 c	5586 d
	N2P1	645 a	41 a	43.7 a	7100 a
	N1P2	510 b	36 b	41.5 b	6163 c
	N2P2	602 a	40 a	39.0 c	6638 b
2年平均	N1P1	489 b	38 ab	42.0 a	6106 c
Average	N2P1	603 a	40 a	44.5 a	7333 a
of two years	N1P2	494 b	36 b	44.0 a	6392 c
	N2P2	592 a	38 ab	41.6 a	6798 b

类型 Type	品种 Cultivar	铁含量 Fe content (mg kg^-1)	锌含量 Zn content (mg kg^-1)	铁积累量 Fe accumulation (g hm^-2)	锌积累量 Zn accumulation (g hm^-2)
2013-2014
白粒 White-grain	豫麦49-198 Yumai 49-198	51.9 b	33.4 c	361.5 b	233.4 b
白粒 White-grain	郑麦366 Zhengmai 366	53.0 b	34.0 bc	385.9 b	245.5 ab
红粒 Red-grain	扬麦15 Yangmai 15	51.6 b	35.2 ab	361.3 b	247.1 ab
红粒 Red-grain	扬麦22 Yangmai 22	54.8 b	33.5 c	378.2 b	229.5 b
黑粒 Black-grain	周黑麦1号 Zhouheimai 1	55.0 b	36.5 a	391.3 b	259.5 a
黑粒 Black-grain	紫麦1号 Zimai 1	63.7 a	35.6 ab	421.8 a	235.3 b
2014-2015
白粒 White-grain	豫麦49-198 Yumai 49-198	48.7 b	36.6 ab	313.7 abc	234.9 a
白粒 White-grain	郑麦366 Zhengmai 366	49.5 a	35.2 ab	336.2 a	239.5 a
红粒 Red-grain	扬麦15 Yangmai 15	48.2 b	35.0 ab	336.3 ab	242.5 a
红粒 Red-grain	扬麦22 Yangmai 22	43.1 c	33.8 b	288.3 cd	227.9 a
黑粒 Black-grain	周黑麦1号 Zhouheimai 1	50.9 a	35.1 ab	306.9 bcd	213.7 a
黑粒 Black-grain	紫麦1号 Zimai 1	48.5 bc	38.5 a	278.1 d	216.2 a
2年平均 Average of two years
白粒 White-grain	豫麦49-198 Yumai 49-198	50.3 c	35.0 ab	337.6 a	234.2 a
白粒 White-grain	郑麦366 Zhengmai 366	51.3 bc	34.6 ab	361.1 a	242.5 a
红粒 Red-grain	扬麦15 Yangmai 15	49.9 c	35.1 ab	348.8 a	244.8 a
红粒 Red-grain	扬麦22 Yangmai 22	49.0 c	33.7 b	333.3 a	228.7 a
黑粒 Black-grain	周黑麦1号 Zhouheimai 1	53.0 b	35.8 ab	349.1 a	236.6 a
黑粒 Black-grain	紫麦1号 Zimai 1	56.1 a	37.1 a	350.0 a	225.8 a

Variation of Grain Iron and Zinc Contents and Their Bioavailability of Wheat Cultivars with Different-colored Grains under Combined Nitrogen and Phosphorus Fertilization

RichHTML337

PDF