夏玉米花丝和穗轴有机营养和矿质养分变化规律的研究
|
摘要
本文以掖单12(穗型短粗)和掖单19(穗型细长)为材料,在花丝生长发育期间对果穗穗轴的上部、中部和下部及对应部位花丝中的有机营养(可溶性糖、淀粉、氨基酸和蛋白质)以及矿质养分(氮、磷、钾、钙、镁、硫、铁、锰、铜、锌元素)进行了测定。其结果如下:
可溶性糖浓度呈现出单峰曲线变化趋势,峰值出现在吐丝后5天。花丝和穗轴中的变化趋势一致,两品种间的差异不明显。不同部位的穗轴和花丝中变化趋势一致。花丝的不同部位可溶性糖浓度也呈现出类似的趋势,但花丝上部浓度最低,中部和基部的浓度较高,这可能与花粉管的延伸有关。
淀粉的浓度也呈现出单峰曲线变化,但花丝和穗轴中峰值出现的时间不一致:花丝中的淀粉浓度出现吐丝后5天,而穗轴在吐丝后3天。两品种间及不同部位的花丝和穗轴中的变化趋势一致。
氨基酸的浓度在花丝和穗轴中的趋势表现不一致:花丝中的氨基酸浓度表现为单峰曲线变化趋势,峰值出现在吐丝后9天;而穗轴中的氨基酸浓度表现为前低后高的变化,吐丝后1天的浓度最低,以后逐渐上升,吐丝5天浓度达到较大值,以后在此范围内波动。两品种间及不同部位花丝和穗轴的不同部位变化趋势一致。
蛋白质的浓度变化在两品种间的变化一致,花丝和穗轴中的浓度均表现为双曲线型变化:吐丝前的浓度较高,随着生长发育,花丝和穗轴中的蛋白质浓度下降,吐丝后1天浓度最低,以后在此范围内波动。不同部位花丝和穗轴的不同部位变化趋势一致。
氮、磷、钾三种元素在花丝生长发育过程中的变化呈现出逐渐下降的趋势。花丝和穗轴中的变化趋势一致;不同部位花丝和穗轴的不同部位,两品种间的浓度也无显著不同。穗轴中的氮、磷、钾元素含量较花丝中的含量高,三种元素与玉米的授粉结实率呈现出显著的相关关系。
总体上钙、镁、硫元素在玉米体内的变化均呈现出前高后低的逐渐下降的趋势,吐丝后的钙、镁浓度变化较硫的变化平稳。穗轴中的钙、镁、硫浓度较花丝中的高,该变化在花丝和穗轴中无明显差异,穗轴的不同部位和对应花丝及两品种间的差异亦不明显。
吐丝后掖单12花丝中的铁元素浓度有所增加,而掖单19中的变化较平稳;穗轴中的铁浓度呈现出逐渐下降的趋势,吐丝后的浓度变化较稳定。各品种穗轴的不同部位及对应花丝中的浓度变化趋势一致。
吐丝前后花丝中的锰元素浓度的变化较平稳,变幅较小,花丝和穗轴中的变化趋势一致,不同部位花丝和穗轴的不同部位变化趋势一致。穗轴中的元素浓度较花丝中的高,掖单12中的浓度低于掖单19。两品种的变化趋势一致。
铜元素浓度在掖单12和掖单19中的花丝中变化一致,表现为逐渐下降的趋势;
吐丝麻 掖单12穗轴中的铜浓度较高,吐丝前1大含量达最低,吐丝后1大有所
上升,但幅度不大,以后在此范围内变化,但吐丝后1天掖单19中的变化幅度较
大,以后又下降。各品种不同部位花丝和穗轴的不同部位变化趋势一致。掖单19
的含量大于掖单门的含量。
花丝和穗轴中的锌元素浓度变化基本一致,为逐渐下降的趋势。吐丝后花丝中
的锌元素浓度变化较穗轴中的变化幅度小。穗轴中的锌浓度较花丝中的高。不同部
位花丝和穗轴的不同部位变化趋势一致,品种间也无明显差异。
各种物质的绝对含量均表现为前期的含量较低,后期花丝中以自然授粉的元素
含量低于套袋的花丝,穗轴中的表现则与之相反。
The research was conducted with two hybrids "yedan 12" (with short-thick ears) and "yedan 19" (with long-thin ears). The dynamic of nutrition (soluble sugar, starch, amnio acid, protein) and mineral element (nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, manganese, copper, zinc) in the different position (top, middle and base) of silk and cob was studied during the growth, development and senescence of silk. The result as follows:
The dynamic of soluble sugar content presents single apex curve, and the apices were in the 5th after silking. The content of soluble sugar in the silk and cob has the same trend. The difference in two hybrids was not evident. The trend in different position of cob was accord with the silk. The soluble sugar concentration in different position of silk shows similar to other position trend, but the concentration in the top of silk is the lowest, the middle and the base of the silk have higher concentration, which possible relate to extend of pollen tube.
Starch in the silk and cob has the single apex, too. But the peak value was showed in different time between cob and silk: silk in the 5th, but the cob in the 3rd after silking. The two hybrids and different position of silk and cob have the same changing.
Amnio acid has different curve in silk and cob. In the silk, the content present single apex curve and the 9* was the time that the peak value show, but the content of amnio acid in cob present low content before silking and higher after silking. The content was low before silking and then ascends gradually, the 5* reach the higher content and then moving hi this range.
Protein in the silk and cob has the similarity trend and show the dynamic of hyperbola: before silking, protein has the higher content, with the processing of cob growth, protein content decline, and the 1st reach lowest after silking and then changing in this rang. The different position of silk and cob have the same trend.
Nitrogen, Phosphorus, Potassium content decline gradually during silk grows, develops and senesces. In the silk and cob, the content has the same changing. There were
not prominent difference in the different position of silk and cob, even in the different hybrids. However, the content of N > P> K in cob was higher than that in the silk. And the three elements show prominent correlatively with the rate of pollination-seed.
As a whole, calcium, magnesium, sulfur declines gradually from high to low. But the changing of Cax Mg was gently than S'. The content of Ca> Mg^ S in the cob was higher than that in the silk, but the difference of trend in the silk and in the cob was not obviously, the different position of silk and cob, even different hybrids have not apparent diversities, either.
In the silk of "yedan 12", iron content increase a little after silking, but the change was gently for the silk of''yedan 19"; in the cob, the content of iron decline gradually, and there was a calm trend after silking. The different position of silk and cob have the same trend.
Manganese content in the silk change gently fore-and-aft silking, and scope was small. The trend in the silk and cob was the same, even in the different position of silk and cob. The content was higher in the cob than in the silk, the content in the yedan 12 is lower than yedan 19.The two hybrids have the same changing trend.
The changing trend of copper content was descendent in the silk of "yedan 12" and "yedan 19". But in the cob of "yedan 12", content was higher before silking, the lowest in the 1st before silking, ascending a little with small scope after silking, and then changing in this rang. But in the "yedan 19", the change scope was wide in the 1 rt after silking, and then decline. The different position of silk and cob have the same trend in the two hybrids. The content of copper in the yedan 19 is higher than that in the yedan 12.
Zinc also present degressive trend, the change in the silk and cob was consistent. Zinc content change was small in the silk than that in the cob. But the cob
可溶性糖浓度呈现出单峰曲线变化趋势,峰值出现在吐丝后5天。花丝和穗轴中的变化趋势一致,两品种间的差异不明显。不同部位的穗轴和花丝中变化趋势一致。花丝的不同部位可溶性糖浓度也呈现出类似的趋势,但花丝上部浓度最低,中部和基部的浓度较高,这可能与花粉管的延伸有关。
淀粉的浓度也呈现出单峰曲线变化,但花丝和穗轴中峰值出现的时间不一致:花丝中的淀粉浓度出现吐丝后5天,而穗轴在吐丝后3天。两品种间及不同部位的花丝和穗轴中的变化趋势一致。
氨基酸的浓度在花丝和穗轴中的趋势表现不一致:花丝中的氨基酸浓度表现为单峰曲线变化趋势,峰值出现在吐丝后9天;而穗轴中的氨基酸浓度表现为前低后高的变化,吐丝后1天的浓度最低,以后逐渐上升,吐丝5天浓度达到较大值,以后在此范围内波动。两品种间及不同部位花丝和穗轴的不同部位变化趋势一致。
蛋白质的浓度变化在两品种间的变化一致,花丝和穗轴中的浓度均表现为双曲线型变化:吐丝前的浓度较高,随着生长发育,花丝和穗轴中的蛋白质浓度下降,吐丝后1天浓度最低,以后在此范围内波动。不同部位花丝和穗轴的不同部位变化趋势一致。
氮、磷、钾三种元素在花丝生长发育过程中的变化呈现出逐渐下降的趋势。花丝和穗轴中的变化趋势一致;不同部位花丝和穗轴的不同部位,两品种间的浓度也无显著不同。穗轴中的氮、磷、钾元素含量较花丝中的含量高,三种元素与玉米的授粉结实率呈现出显著的相关关系。
总体上钙、镁、硫元素在玉米体内的变化均呈现出前高后低的逐渐下降的趋势,吐丝后的钙、镁浓度变化较硫的变化平稳。穗轴中的钙、镁、硫浓度较花丝中的高,该变化在花丝和穗轴中无明显差异,穗轴的不同部位和对应花丝及两品种间的差异亦不明显。
吐丝后掖单12花丝中的铁元素浓度有所增加,而掖单19中的变化较平稳;穗轴中的铁浓度呈现出逐渐下降的趋势,吐丝后的浓度变化较稳定。各品种穗轴的不同部位及对应花丝中的浓度变化趋势一致。
吐丝前后花丝中的锰元素浓度的变化较平稳,变幅较小,花丝和穗轴中的变化趋势一致,不同部位花丝和穗轴的不同部位变化趋势一致。穗轴中的元素浓度较花丝中的高,掖单12中的浓度低于掖单19。两品种的变化趋势一致。
铜元素浓度在掖单12和掖单19中的花丝中变化一致,表现为逐渐下降的趋势;
吐丝麻 掖单12穗轴中的铜浓度较高,吐丝前1大含量达最低,吐丝后1大有所
上升,但幅度不大,以后在此范围内变化,但吐丝后1天掖单19中的变化幅度较
大,以后又下降。各品种不同部位花丝和穗轴的不同部位变化趋势一致。掖单19
的含量大于掖单门的含量。
花丝和穗轴中的锌元素浓度变化基本一致,为逐渐下降的趋势。吐丝后花丝中
的锌元素浓度变化较穗轴中的变化幅度小。穗轴中的锌浓度较花丝中的高。不同部
位花丝和穗轴的不同部位变化趋势一致,品种间也无明显差异。
各种物质的绝对含量均表现为前期的含量较低,后期花丝中以自然授粉的元素
含量低于套袋的花丝,穗轴中的表现则与之相反。
The research was conducted with two hybrids "yedan 12" (with short-thick ears) and "yedan 19" (with long-thin ears). The dynamic of nutrition (soluble sugar, starch, amnio acid, protein) and mineral element (nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, manganese, copper, zinc) in the different position (top, middle and base) of silk and cob was studied during the growth, development and senescence of silk. The result as follows:
The dynamic of soluble sugar content presents single apex curve, and the apices were in the 5th after silking. The content of soluble sugar in the silk and cob has the same trend. The difference in two hybrids was not evident. The trend in different position of cob was accord with the silk. The soluble sugar concentration in different position of silk shows similar to other position trend, but the concentration in the top of silk is the lowest, the middle and the base of the silk have higher concentration, which possible relate to extend of pollen tube.
Starch in the silk and cob has the single apex, too. But the peak value was showed in different time between cob and silk: silk in the 5th, but the cob in the 3rd after silking. The two hybrids and different position of silk and cob have the same changing.
Amnio acid has different curve in silk and cob. In the silk, the content present single apex curve and the 9* was the time that the peak value show, but the content of amnio acid in cob present low content before silking and higher after silking. The content was low before silking and then ascends gradually, the 5* reach the higher content and then moving hi this range.
Protein in the silk and cob has the similarity trend and show the dynamic of hyperbola: before silking, protein has the higher content, with the processing of cob growth, protein content decline, and the 1st reach lowest after silking and then changing in this rang. The different position of silk and cob have the same trend.
Nitrogen, Phosphorus, Potassium content decline gradually during silk grows, develops and senesces. In the silk and cob, the content has the same changing. There were
not prominent difference in the different position of silk and cob, even in the different hybrids. However, the content of N > P> K in cob was higher than that in the silk. And the three elements show prominent correlatively with the rate of pollination-seed.
As a whole, calcium, magnesium, sulfur declines gradually from high to low. But the changing of Cax Mg was gently than S'. The content of Ca> Mg^ S in the cob was higher than that in the silk, but the difference of trend in the silk and in the cob was not obviously, the different position of silk and cob, even different hybrids have not apparent diversities, either.
In the silk of "yedan 12", iron content increase a little after silking, but the change was gently for the silk of''yedan 19"; in the cob, the content of iron decline gradually, and there was a calm trend after silking. The different position of silk and cob have the same trend.
Manganese content in the silk change gently fore-and-aft silking, and scope was small. The trend in the silk and cob was the same, even in the different position of silk and cob. The content was higher in the cob than in the silk, the content in the yedan 12 is lower than yedan 19.The two hybrids have the same changing trend.
The changing trend of copper content was descendent in the silk of "yedan 12" and "yedan 19". But in the cob of "yedan 12", content was higher before silking, the lowest in the 1st before silking, ascending a little with small scope after silking, and then changing in this rang. But in the "yedan 19", the change scope was wide in the 1 rt after silking, and then decline. The different position of silk and cob have the same trend in the two hybrids. The content of copper in the yedan 19 is higher than that in the yedan 12.
Zinc also present degressive trend, the change in the silk and cob was consistent. Zinc content change was small in the silk than that in the cob. But the cob
引文
[1].秦泰辰.玉米开花习性的观察及其花粉柱头生活力的测定[J].江苏农学报,1962,2:75~82.
[2].汪茂华,苏祯禄,陈伟程.玉米花粉柱头生活力及其开花生物学的观察[J].农业学报,1959,3:165~170
[3].李纯,龙正容.合肥地区玉米开花习性研究[J].安徽农业科学,1986,1:24~27.
[4].玉米受精的若干问题[J].科学文摘-植物学,1956,3:165~170.
[5]. Jones M D, Newell L C. Longevity of pollen and stigmas of grasses: buffalograss, buchloe dactyloides (nutt.) engelm, and corn (Zea mays L.)[J]. J Am Soc Agron: The society, 1913-(1948) Mar 1948,40(3): 195~204.
[6].Paole Bassettti.玉米花丝的衰老和受精力[J].国外农学,1997,4:21
[7].王树安.作物栽培学各论[M].北京:中国农业出版社,1995.
[8].山东省农业科学院玉米研究所编著,玉米生理[M].北京:农业出版社,1987
[9].高聚林,刘克礼.春玉米植株中蔗糖含量的变化[J].华北农学报,1993,8(1):29—34
[10].胡昌浩,潘子龙.夏玉米同化产物积累与养分吸收分配规律的研究Ⅰ.干物质积累与可溶糖和氨基酸的变化规律[J].中国农业科学,1982(1):56—64
[11].李扬汉.植物学[M].北京:高等教育出版社,1985.
[12].刘克礼,高聚林.春玉米淀粉含量变化的研究[J].内蒙古农牧学院学报,1992,13(4):80—86
[13].赵可夫编,玉米生理[M].济南:山东科学技术出版社,1982,2
[14]. Reed A J, Singletary G W. Roles of carbohydrate supply and phytohormones in maize kernel abortion [J]. Plant physiol, 1989, 91: 986~992
[15].陈国平 李伯航 主编,紧凑型玉米高产栽培的理论与实践[M].北京:中国农业出版社,1996,4:153~222
[16].胡昌浩,潘子龙.夏玉米同化产物积累与养分吸收分配规律的研究Ⅱ.氮、磷、钾的吸收、分配与转移规律[J].中国农业科学,1982(2):38—48
[17].贺竟赪,侯忠.施肥对不同玉米品种品质的影响[J].陕西农业科学,1988,(1):8—10
[18].山东农业科学院 王忠孝主编,山东玉米[M].北京:中国农业出版社,1999
[19].王忠孝,王庆成,牛玉贞,等.夏玉米高产规律的研究[J].山东农业科学,1989(4):10—14
[20].王庆成,张军,牛玉贞,等.高产夏玉米养分吸收分配规律的研究[J].土壤肥料,1993,(3):23—26
[21].张凤路,王志敏,赵明,等.玉米果穗矿质元素分布与籽粒败育关系研究[J].河北农业大学学报2001,24(4):8~10
[22].王海生,吴晓明.春玉米对氮磷钾养分的吸收与分配[J].浙江农业大学学报,1994,20(5):538—542
[23]. D. L. Karlen, R. L. Flannery, and E. J. sadler. Aerial Accumulation and Partitioning of Nutrients by corn, Agronomy Journal [J]. 1988,vol 82, No. 2, 232~242
[24]. A. Mozafar, Kernel Abortion and Distribution of Mineral Elements Along the Maize Ear, Agronomy Journal [J]. 1990,vol 82,No. 3,511~514
[25].邹春琴,李春俭,张福锁,等.铁和不同形态氮素对玉米植株吸收矿质元素及其在体内分布的影响[J].植物营养与肥料学报,1996,2(1):68—73
[26].崔彦宏,张桂银,郭景伦,等.高产夏玉米钙的吸收与再分配研究[J].河北农业大学学报,1994,17(4):31—35
[27].张桂银,崔彦宏,郭景伦,等.高产夏玉米镁的吸收与再分配研究[J].河北农业大学学报,1994,17(1):18—23
[28].崔彦宏,张桂银,郭景伦,等.高产夏玉米硫的吸收与再分配研究[J].玉米科学,1993,1(1):48—52
[29].王空军,胡昌浩,董树亭.夏玉米硫素吸收与时空分布研究[J].作物学报,2001,26(6):899~904
[30].沈蕴石,刘锡禄,胡昌浩,等.夏玉米微量元素吸收分配规律的研究[J].山东农业大学学报,1993,24(3):333—340
[31].佟屏亚,凌碧莹,高富兰,等.铜肥对玉米生长发育和产量构成影响的研究[J].北京农业科学,1995,36—39
[32].崔文华,郝桂娟,谷淑香,等.不同中微量元素对玉米生理指标和产量的影响[J].黑龙江农业科学,1998,4:12~16
[33].张福锁主编,植物营养-生态生理学和遗传学[M].中国科学技术出版社,1993
[34].吴礼树,硼对棉花花粒及叶柄解剖结构的影响[J].华中农学院学报,1985,4(3):34~37;
[35].曹亨云.硼对叶片解剖结结构的影响,华中农业大学学报,1971,7(3):251~254
[36].郑丕尧.作物生理学导论[M],北京农业大学出版社,1990
[37].王庆成,牛玉贞,张军,等.玉米叶片生长过程中蛋白氮、非蛋白氮和可溶糖含量的变化[J].玉米科学,1993,1(3):59—62
[38].夏培桢,王少仁.氮磷肥对小麦、玉米籽粒氨基酸的影响[J].土壤肥料1995,2:9~13
[39].陈丹,李志洪,孙晓秋,等.缺锌对玉米吸收锌的动力学及氨基酸分泌的影响[J].吉林农业大学学报,1998,20(4):58~60)。
[40].邹德乙,韩晓日.棕壤连续施用钾肥对玉米子粒蛋白质及氨基酸影响的研究[J].土壤通报,1997,28(1):28~30
[41].邹德乙,刘小虎,韩晓日,等.长期定位施肥对作物子实氨基酸含量影响[J].沈阳农业大学学报,1997,28(2):120~124
[42].刘景辉,刘克礼.春玉米需氮规律的研究[J].内蒙古农牧学院学报,1994,15(3):12—18
[43].张宝烈,雷永振,邱卫文,等.玉米营养积累特性及钾肥效果[J].辽宁农业科学,1994(2):3—8
[44].A.Suwansrit, M. Sestapukdee. 玉米发育适期叶喷钾肥的促进作用:一种提高产量和改善品质的新途径[J].国外农学(玉米),1990,(3):43-47.
[45].曹敏建,戴俊英,贾方伟,等.玉米苗期磷锌营养研究[J].土壤通报,1992,23(4):165—167
[46].刘景辉,刘克礼.春玉米需磷规律的研究[J].内蒙古农牧学院学报,1995,16(2):19—25
[47].刘景辉,刘克礼,高聚林,等.春玉米需钾规律的研究[J].内蒙古农牧学院学报,1996,17(2):30—35
[48].邹国元,李晓林,杨志福.不同温度下施用钾肥对玉米生长及磷钾养分吸收的影响[J].华北农学报,1998,13(4):51—55
[49].张智猛,郭景伦,李伯航,等.不同肥料分配方式下高产夏玉米氮、磷、钾吸收、积累与分配的研究[J].玉米科学,1994,2(4):50—55,封底
[50].田士明,王梅芳,张韶华,等.锰锌肥对玉米吸收氮磷钾及干物质积累的影响[J].土壤肥料,1999,(1):44—45
[51].张国印,赵同科,孙祖琰.锰锌的土壤吸附和小麦夏玉米对锰锌的吸收规律研究[J].河北农业科学,1998,2(2):21—25
[52].刘存辉,董树亭,胡昌浩.硫素营养对高产夏玉米施用效应的研究[J].山东农业大学学报(自然科学版),2001,32(1):11~16
[53].宋凤斌,戴俊英,黄国坤.水分胁迫对玉米雌穗的伤害作用[J].吉林农业大学学报,1996,18(4):1—6
[54].张毅,戴俊英,苏正淑,等.孕穗期低温对玉米雌穗的伤害作用[J].作物学报,1995,21(2):235—238
[55].王茅雁,于秀翠,武兰芳,等.低温对玉米幼苗可溶性蛋白质含量与合成的影响[J],内蒙古农牧学院学报,1990,11(2):133~137
[56]. Hanft JM, RJ Jones, Kernel abortion in maize. Ⅱ Distribution of ~(14)C among kernel carbohydrates [J]. Plant Physiol. 1986, 81:511~515;
[57]. Hanft JM, RJ Jones, Kernel abortion in maize. Ⅰ Carbohydrate concentration patterns and acid invertase activity in maize kernels induced to abort in vitro [J]. Plant Physiol 1986, 81:503~510
[58].夏叔芳等,叶片光合产物的输出的抑制与淀粉和蔗糖的积累[J].植物生理学报,1981,7(2):135—141
[59].夏叔芳等,玉米叶片淀粉和蔗糖的昼夜变化与光合产物的输出[J].植物生理学报1982,8(2):141—14
[60]. Kovacevic V, Juric I, Musac I, Zugec I. Skender M. Mineral nutrition in the production of maize seed [J]. Symposium on seed and seed production in maize. 1977, 107~116
[61].孙政才,陈国平.甜玉米与普通玉米子粒发育过程中碳水化合物及氨基酸消长规律的比较研究Ⅱ氨基酸含量的消长变化[J].作物学报,1992,18(4):307~311,
[62].王鹏文,戴俊英,张明.玉米成熟过程中子粒蛋白质、氨基酸含量的研究[J].沈阳农业大学学报,1996,27(2):103~106
[63]. Walker wm: Peck TR. Relationship between corn yield and plant nutrient content[J]. Agronomy Journal, 1974, 66: 253—256
[64].张宪政.作物生理研究法[M].农业出版社,1990
[65].中国土壤学会农业化学专业委员会.土壤农业化学常规分析方法[M].北京:科学出版社,1983.
[66].王艳哲.夏玉米花丝活力及其受精结实能力的研究[D].河北农业大学硕士学位论文,2001.
[67].阙求登.花粉—雌蕊相互作用的控制机理[J].植物生理学通讯,1987,(2):22~26.
[68].张英华、曹宗巽.高等植物受精过程中的花粉—柱头相互识别研究进展[J].植物生理学通讯.1983,(6):3~8.
[69].孙羲.植物营养原理[M].北京:中国农业出版社,1997,5
[70].石小燕.玉米不同时期氮肥分配对产量的影响[J].栽培与耕作.2000,3:24,27
[71].郑丕尧.(北條良夫,星川清亲等著).作物的形态与机能[M].北京:农业出版社.1983.
[72].田惠桥,远彤.钙在被子植物受精过程中的作用[J].植物生理学报,2000,26(5):369~380.
[73].龚明,曹宗巽.钙和钙调素对花粉萌发和花粉管生长的调控[J].植物生理学通讯,2000,36(4):321~328.
[74].陈绍荣,杨弘远.花粉—雌蕊的相互作用机制[J].植物生理学通讯.2000,36(4):356~361.
[75].潘瑞炽,董愚得.植物生理学(第三版)[M].北京:高等教育出版社,1979.
[76].宋秀芬,洪剑明.植物细胞中钙信号的时空多样性与信号转导[J].植物学通报,2001,18(4):436~444
[77].陆时万,徐祥生,沈敏健.植物学(第二版)上册[M].北京:高等教育出版社,1991,1
[78].荆家海.植物生理学[M].西安:陕西科学技术出版社1994
[79].胡适宜.植物的受精作用—第二讲 花粉在柱头上萌发和花粉管进入胚囊的途径[J].植物学通报,1983,1(2):60~64
[80]. Malh R, Read ND, Pais MS, Trewavas AJ (1994). Role of cytosolic free calcium in the reorientation of pollen tube growth [J]. Plant J, 5: 331~341
[81].李金才.夏玉米花丝生长发育动态和解剖结构的研究[D].河北农业大学硕士学位论文,2000.
[82].李伏生.热带作物的镁素营养问题[J].广西热作科技,1994 2:48~83.
[83].杨竹青,陶为民.不同浓度钙、镁营养液对番茄生育的影响及其与元素吸收的关系[J].土壤通报,1994,26(4):190~192
[84].张英聚.植物的硫营养[J].植物生理学通讯,1987,(2):9~15.
[85].宋纯鹏.植物衰老生物学[M].北京:北京大学出版社,1998.
[86].尹光灿,万明春.锰对猪睾丸曲细精管精子密度及琥珀酸脱氢酶活性的研究[J].江西农业学报,1995,7(1):28~31.
[87].吴振球,吴岳轩.铜、锌对水稻幼苗生长及超氧化物歧化酶的影响[J].植物生理学报,1990,16(2):139~146,
[88].徐晓燕,杨肖娥 铜、锌对水稻幼苗生长及超氧化物歧化酶的影响[J].山西农业大学学报,1997,17(2):113~115.
[89].吴振球,欧阳龙.铜、锌对水稻生长及超氧物歧化酶活性的影响[J].湖南农学院学报,1988,14(2):21~29
[90].徐勤松,施国新,杜开和.锌胁迫下水车前叶细胞自由基过氧化损伤与超微结构变化之间关系的研究[J].植物学通报,2001,18(5):597~604
[91].许长成,邹琦.大豆叶片旱促衰老及其与膜脂过氧化作用的关系[J].作物学报,1993,3:360~363.
[92].林植芳,李双顺,张东林,等.采后荔枝果实中氧化和过氧化作用的变化[J].植物学报.1988,30(4):382~387.
[93].宋凤鸣,郑重,葛秀春.活性氧及膜脂过氧化作用在植物—病原体互作中的作用[J].植物生理学通讯,1996,32(5):377~385.
[2].汪茂华,苏祯禄,陈伟程.玉米花粉柱头生活力及其开花生物学的观察[J].农业学报,1959,3:165~170
[3].李纯,龙正容.合肥地区玉米开花习性研究[J].安徽农业科学,1986,1:24~27.
[4].玉米受精的若干问题[J].科学文摘-植物学,1956,3:165~170.
[5]. Jones M D, Newell L C. Longevity of pollen and stigmas of grasses: buffalograss, buchloe dactyloides (nutt.) engelm, and corn (Zea mays L.)[J]. J Am Soc Agron: The society, 1913-(1948) Mar 1948,40(3): 195~204.
[6].Paole Bassettti.玉米花丝的衰老和受精力[J].国外农学,1997,4:21
[7].王树安.作物栽培学各论[M].北京:中国农业出版社,1995.
[8].山东省农业科学院玉米研究所编著,玉米生理[M].北京:农业出版社,1987
[9].高聚林,刘克礼.春玉米植株中蔗糖含量的变化[J].华北农学报,1993,8(1):29—34
[10].胡昌浩,潘子龙.夏玉米同化产物积累与养分吸收分配规律的研究Ⅰ.干物质积累与可溶糖和氨基酸的变化规律[J].中国农业科学,1982(1):56—64
[11].李扬汉.植物学[M].北京:高等教育出版社,1985.
[12].刘克礼,高聚林.春玉米淀粉含量变化的研究[J].内蒙古农牧学院学报,1992,13(4):80—86
[13].赵可夫编,玉米生理[M].济南:山东科学技术出版社,1982,2
[14]. Reed A J, Singletary G W. Roles of carbohydrate supply and phytohormones in maize kernel abortion [J]. Plant physiol, 1989, 91: 986~992
[15].陈国平 李伯航 主编,紧凑型玉米高产栽培的理论与实践[M].北京:中国农业出版社,1996,4:153~222
[16].胡昌浩,潘子龙.夏玉米同化产物积累与养分吸收分配规律的研究Ⅱ.氮、磷、钾的吸收、分配与转移规律[J].中国农业科学,1982(2):38—48
[17].贺竟赪,侯忠.施肥对不同玉米品种品质的影响[J].陕西农业科学,1988,(1):8—10
[18].山东农业科学院 王忠孝主编,山东玉米[M].北京:中国农业出版社,1999
[19].王忠孝,王庆成,牛玉贞,等.夏玉米高产规律的研究[J].山东农业科学,1989(4):10—14
[20].王庆成,张军,牛玉贞,等.高产夏玉米养分吸收分配规律的研究[J].土壤肥料,1993,(3):23—26
[21].张凤路,王志敏,赵明,等.玉米果穗矿质元素分布与籽粒败育关系研究[J].河北农业大学学报2001,24(4):8~10
[22].王海生,吴晓明.春玉米对氮磷钾养分的吸收与分配[J].浙江农业大学学报,1994,20(5):538—542
[23]. D. L. Karlen, R. L. Flannery, and E. J. sadler. Aerial Accumulation and Partitioning of Nutrients by corn, Agronomy Journal [J]. 1988,vol 82, No. 2, 232~242
[24]. A. Mozafar, Kernel Abortion and Distribution of Mineral Elements Along the Maize Ear, Agronomy Journal [J]. 1990,vol 82,No. 3,511~514
[25].邹春琴,李春俭,张福锁,等.铁和不同形态氮素对玉米植株吸收矿质元素及其在体内分布的影响[J].植物营养与肥料学报,1996,2(1):68—73
[26].崔彦宏,张桂银,郭景伦,等.高产夏玉米钙的吸收与再分配研究[J].河北农业大学学报,1994,17(4):31—35
[27].张桂银,崔彦宏,郭景伦,等.高产夏玉米镁的吸收与再分配研究[J].河北农业大学学报,1994,17(1):18—23
[28].崔彦宏,张桂银,郭景伦,等.高产夏玉米硫的吸收与再分配研究[J].玉米科学,1993,1(1):48—52
[29].王空军,胡昌浩,董树亭.夏玉米硫素吸收与时空分布研究[J].作物学报,2001,26(6):899~904
[30].沈蕴石,刘锡禄,胡昌浩,等.夏玉米微量元素吸收分配规律的研究[J].山东农业大学学报,1993,24(3):333—340
[31].佟屏亚,凌碧莹,高富兰,等.铜肥对玉米生长发育和产量构成影响的研究[J].北京农业科学,1995,36—39
[32].崔文华,郝桂娟,谷淑香,等.不同中微量元素对玉米生理指标和产量的影响[J].黑龙江农业科学,1998,4:12~16
[33].张福锁主编,植物营养-生态生理学和遗传学[M].中国科学技术出版社,1993
[34].吴礼树,硼对棉花花粒及叶柄解剖结构的影响[J].华中农学院学报,1985,4(3):34~37;
[35].曹亨云.硼对叶片解剖结结构的影响,华中农业大学学报,1971,7(3):251~254
[36].郑丕尧.作物生理学导论[M],北京农业大学出版社,1990
[37].王庆成,牛玉贞,张军,等.玉米叶片生长过程中蛋白氮、非蛋白氮和可溶糖含量的变化[J].玉米科学,1993,1(3):59—62
[38].夏培桢,王少仁.氮磷肥对小麦、玉米籽粒氨基酸的影响[J].土壤肥料1995,2:9~13
[39].陈丹,李志洪,孙晓秋,等.缺锌对玉米吸收锌的动力学及氨基酸分泌的影响[J].吉林农业大学学报,1998,20(4):58~60)。
[40].邹德乙,韩晓日.棕壤连续施用钾肥对玉米子粒蛋白质及氨基酸影响的研究[J].土壤通报,1997,28(1):28~30
[41].邹德乙,刘小虎,韩晓日,等.长期定位施肥对作物子实氨基酸含量影响[J].沈阳农业大学学报,1997,28(2):120~124
[42].刘景辉,刘克礼.春玉米需氮规律的研究[J].内蒙古农牧学院学报,1994,15(3):12—18
[43].张宝烈,雷永振,邱卫文,等.玉米营养积累特性及钾肥效果[J].辽宁农业科学,1994(2):3—8
[44].A.Suwansrit, M. Sestapukdee. 玉米发育适期叶喷钾肥的促进作用:一种提高产量和改善品质的新途径[J].国外农学(玉米),1990,(3):43-47.
[45].曹敏建,戴俊英,贾方伟,等.玉米苗期磷锌营养研究[J].土壤通报,1992,23(4):165—167
[46].刘景辉,刘克礼.春玉米需磷规律的研究[J].内蒙古农牧学院学报,1995,16(2):19—25
[47].刘景辉,刘克礼,高聚林,等.春玉米需钾规律的研究[J].内蒙古农牧学院学报,1996,17(2):30—35
[48].邹国元,李晓林,杨志福.不同温度下施用钾肥对玉米生长及磷钾养分吸收的影响[J].华北农学报,1998,13(4):51—55
[49].张智猛,郭景伦,李伯航,等.不同肥料分配方式下高产夏玉米氮、磷、钾吸收、积累与分配的研究[J].玉米科学,1994,2(4):50—55,封底
[50].田士明,王梅芳,张韶华,等.锰锌肥对玉米吸收氮磷钾及干物质积累的影响[J].土壤肥料,1999,(1):44—45
[51].张国印,赵同科,孙祖琰.锰锌的土壤吸附和小麦夏玉米对锰锌的吸收规律研究[J].河北农业科学,1998,2(2):21—25
[52].刘存辉,董树亭,胡昌浩.硫素营养对高产夏玉米施用效应的研究[J].山东农业大学学报(自然科学版),2001,32(1):11~16
[53].宋凤斌,戴俊英,黄国坤.水分胁迫对玉米雌穗的伤害作用[J].吉林农业大学学报,1996,18(4):1—6
[54].张毅,戴俊英,苏正淑,等.孕穗期低温对玉米雌穗的伤害作用[J].作物学报,1995,21(2):235—238
[55].王茅雁,于秀翠,武兰芳,等.低温对玉米幼苗可溶性蛋白质含量与合成的影响[J],内蒙古农牧学院学报,1990,11(2):133~137
[56]. Hanft JM, RJ Jones, Kernel abortion in maize. Ⅱ Distribution of ~(14)C among kernel carbohydrates [J]. Plant Physiol. 1986, 81:511~515;
[57]. Hanft JM, RJ Jones, Kernel abortion in maize. Ⅰ Carbohydrate concentration patterns and acid invertase activity in maize kernels induced to abort in vitro [J]. Plant Physiol 1986, 81:503~510
[58].夏叔芳等,叶片光合产物的输出的抑制与淀粉和蔗糖的积累[J].植物生理学报,1981,7(2):135—141
[59].夏叔芳等,玉米叶片淀粉和蔗糖的昼夜变化与光合产物的输出[J].植物生理学报1982,8(2):141—14
[60]. Kovacevic V, Juric I, Musac I, Zugec I. Skender M. Mineral nutrition in the production of maize seed [J]. Symposium on seed and seed production in maize. 1977, 107~116
[61].孙政才,陈国平.甜玉米与普通玉米子粒发育过程中碳水化合物及氨基酸消长规律的比较研究Ⅱ氨基酸含量的消长变化[J].作物学报,1992,18(4):307~311,
[62].王鹏文,戴俊英,张明.玉米成熟过程中子粒蛋白质、氨基酸含量的研究[J].沈阳农业大学学报,1996,27(2):103~106
[63]. Walker wm: Peck TR. Relationship between corn yield and plant nutrient content[J]. Agronomy Journal, 1974, 66: 253—256
[64].张宪政.作物生理研究法[M].农业出版社,1990
[65].中国土壤学会农业化学专业委员会.土壤农业化学常规分析方法[M].北京:科学出版社,1983.
[66].王艳哲.夏玉米花丝活力及其受精结实能力的研究[D].河北农业大学硕士学位论文,2001.
[67].阙求登.花粉—雌蕊相互作用的控制机理[J].植物生理学通讯,1987,(2):22~26.
[68].张英华、曹宗巽.高等植物受精过程中的花粉—柱头相互识别研究进展[J].植物生理学通讯.1983,(6):3~8.
[69].孙羲.植物营养原理[M].北京:中国农业出版社,1997,5
[70].石小燕.玉米不同时期氮肥分配对产量的影响[J].栽培与耕作.2000,3:24,27
[71].郑丕尧.(北條良夫,星川清亲等著).作物的形态与机能[M].北京:农业出版社.1983.
[72].田惠桥,远彤.钙在被子植物受精过程中的作用[J].植物生理学报,2000,26(5):369~380.
[73].龚明,曹宗巽.钙和钙调素对花粉萌发和花粉管生长的调控[J].植物生理学通讯,2000,36(4):321~328.
[74].陈绍荣,杨弘远.花粉—雌蕊的相互作用机制[J].植物生理学通讯.2000,36(4):356~361.
[75].潘瑞炽,董愚得.植物生理学(第三版)[M].北京:高等教育出版社,1979.
[76].宋秀芬,洪剑明.植物细胞中钙信号的时空多样性与信号转导[J].植物学通报,2001,18(4):436~444
[77].陆时万,徐祥生,沈敏健.植物学(第二版)上册[M].北京:高等教育出版社,1991,1
[78].荆家海.植物生理学[M].西安:陕西科学技术出版社1994
[79].胡适宜.植物的受精作用—第二讲 花粉在柱头上萌发和花粉管进入胚囊的途径[J].植物学通报,1983,1(2):60~64
[80]. Malh R, Read ND, Pais MS, Trewavas AJ (1994). Role of cytosolic free calcium in the reorientation of pollen tube growth [J]. Plant J, 5: 331~341
[81].李金才.夏玉米花丝生长发育动态和解剖结构的研究[D].河北农业大学硕士学位论文,2000.
[82].李伏生.热带作物的镁素营养问题[J].广西热作科技,1994 2:48~83.
[83].杨竹青,陶为民.不同浓度钙、镁营养液对番茄生育的影响及其与元素吸收的关系[J].土壤通报,1994,26(4):190~192
[84].张英聚.植物的硫营养[J].植物生理学通讯,1987,(2):9~15.
[85].宋纯鹏.植物衰老生物学[M].北京:北京大学出版社,1998.
[86].尹光灿,万明春.锰对猪睾丸曲细精管精子密度及琥珀酸脱氢酶活性的研究[J].江西农业学报,1995,7(1):28~31.
[87].吴振球,吴岳轩.铜、锌对水稻幼苗生长及超氧化物歧化酶的影响[J].植物生理学报,1990,16(2):139~146,
[88].徐晓燕,杨肖娥 铜、锌对水稻幼苗生长及超氧化物歧化酶的影响[J].山西农业大学学报,1997,17(2):113~115.
[89].吴振球,欧阳龙.铜、锌对水稻生长及超氧物歧化酶活性的影响[J].湖南农学院学报,1988,14(2):21~29
[90].徐勤松,施国新,杜开和.锌胁迫下水车前叶细胞自由基过氧化损伤与超微结构变化之间关系的研究[J].植物学通报,2001,18(5):597~604
[91].许长成,邹琦.大豆叶片旱促衰老及其与膜脂过氧化作用的关系[J].作物学报,1993,3:360~363.
[92].林植芳,李双顺,张东林,等.采后荔枝果实中氧化和过氧化作用的变化[J].植物学报.1988,30(4):382~387.
[93].宋凤鸣,郑重,葛秀春.活性氧及膜脂过氧化作用在植物—病原体互作中的作用[J].植物生理学通讯,1996,32(5):377~385.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |