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1.
氮磷养分胁迫下小麦幼苗期生物学响应研究   总被引:1,自引:0,他引:1       下载免费PDF全文
为了阐明小麦苗期耐低氮、低磷胁迫的生物学响应特征,以矮抗58品种为试验材料,采用水培试验法研究了小麦在不同营养环境中(全营养、低氮胁迫、低磷胁迫)的地上部生物学特性(地上部干重、株高、叶面积)、根系形态学特性(最大根长、总根数、根系总长度、根系干重和根冠比)和根系生理特性(根系活力、根系吸收面积),以及小麦苗期氮、磷素吸收与根系形态之间的关系。结果表明,在低氮和低磷胁迫下,小麦的株高、叶面积、茎叶干重、含氮量、根系干重、总根长、总根数及根冠比均明显降低,其中低磷胁迫下根系干重、总根长及根冠比的下降幅度大于低氮胁迫,低氮下最大根长的增加幅度较低磷增加7.3%;在低磷条件下小麦的含氮量下降了57.7%。低氮、低磷胁迫下小麦根系的总吸收面积、活性吸收面积及根系活力均明显降低;正常条件下的小麦氮、磷素吸收量与根系形态指标之间相关性较差,在低氮和低磷条件下小麦的氮、磷吸收量与根系干重、总根长、总吸收面积、活性吸收面积及根系活力呈极显著正相关。总之,该小麦品种根系对低磷环境反应较为敏感,而对低氮胁迫具有较好的适应性,小麦通过改变根系形态增加对低氮、磷胁迫的适应。  相似文献   

2.
玉米苗期根系对氮胁迫反应的配合力分析   总被引:2,自引:2,他引:2  
研究利用7个玉米自交系,采用NC-Ⅱ设计,分析了玉米苗期根系性状对氮胁迫反应的配合力及遗传参数变化。结果表明,在2个氮水平下,玉米苗期根系性状的一般配合力、特殊配合力都存在显著的基因型差异,而且不同的基因型在氮胁迫下的反应也不尽相同。高氮下,根系性状除轴根长以外均以非加性遗传为主;氮胁迫下,除轴根数以外的根系性状以加性遗传为主。2个氮水平下,根干重、总根长和侧根长的广义遗传力均较高;与高氮处理相比,在低氮胁迫下,根系性状的广义遗传力表现为下降趋势,根干重、总根长和侧根长的狭义遗传力有上升的趋势。  相似文献   

3.
不同春小麦品种耐低磷性评价及种质筛选   总被引:2,自引:0,他引:2  
筛选磷高效作物是充分利用土壤磷素和减少磷肥施用量的重要手段。本研究以162份春小麦种质资源为材料,对其苗期的株高、总根长、根表面积等8个指标的耐低磷系数进行分析,采用隶属函数法综合评价春小麦苗期的耐低磷特性,初步筛选耐低磷材料,并进一步进行成株期的耐低磷特性鉴定,筛选出耐低磷材料和磷敏感材料,分析其在低磷下酸性磷酸酶的活性变化。结果表明,低磷胁迫下春小麦材料苗期和成株期的各性状均受到不同程度的影响,并随着胁迫程度的增加,小麦生长受抑制程度增强。通过主成分分析将苗期8个指标转化成4个综合指标(累计贡献率为82.60%),将成株期的10个指标转化为3个综合指标(累计贡献率为83.23%);采用隶属函数法计算耐低磷综合评价值(D)值,对D值进行聚类分析,将苗期的162份春小麦种质资源划分为耐低磷型(10份)、较耐低磷型(26份)、低磷较敏感型(91份)、低磷敏感型(35份)4类。选取耐低磷型材料(5份)和低磷敏感型材料(4份),进一步进行成株期鉴定,最终筛选1份耐低磷材料wp-35和1份磷敏感材料wp-119。通过分析其酸性磷酸酶活性,发现在低磷胁迫下春小麦根系和叶片中的酸性磷酸酶活性均升高,且耐低磷材料的酸性磷酸酶活性高于磷敏感材料。本研究结果可为解析春小麦耐低磷特性、培育耐低磷品种提供种质资源和理论依据。  相似文献   

4.
为探究不同根型水稻对缺磷和干旱的响应情况,本研究筛选了不同根型的10个典型水稻品种作为试验对象,在水培条件下对其进行低磷和渗透胁迫处理1个月,研究水稻根系的可塑性。结果表明,不同根型水稻对低磷胁迫的响应差异显著,低磷胁迫会特异性地促进深根品种根系的伸长,平均比浅根品种伸长48.78%,同时显著抑制浅根品种根数目的增加,平均比深根品种根数减少24.90%。渗透胁迫对地上部分的抑制作用大于对地下部分的作用,分别减少地上干重和地下干重37.51%和5.73%。水稻对低磷和渗透2种非生物胁迫的响应方式不同,两者交互作用会加剧抑制植株生长。与2种处理叠加相比,低磷胁迫分别增加地上干重、地下干重和最大根长53.31%、54.05%和36.36%,减少根数9.05%;渗透胁迫分别增加地上干重、地下干重、最大根长和根数136.33%、49.19%、5.37%和32.91%。与对照相比,经3种处理的根冠比均显著上升,分别增加57.30%、142.70%、141.01%,但不同根型品种受相同程度胁迫后均倾向于保持近似的根冠比。本研究首次发现深根型水稻品种在低磷环境下特异性伸长根系这一特性,为水稻的营养高效和节水抗旱的研究和育种提供了理论依据。  相似文献   

5.
水稻根系生长对不同氮形态响应的动态变化   总被引:3,自引:2,他引:3  
赵学强  施卫明 《土壤》2007,39(5):766-771
土壤养分供应变异很大,植物根系生长对这种养分变异的响应非常敏感.为了探索水稻根系生长对N素供应响应的动态变化规律以及这种适应性变化与水稻N效率之间的关系,采用水培方法,以两个苗期不同N效率水稻品种桂单4号和南光为研究材料,比较了不同铵硝比、不同浓度NH4、不同浓度NO3-和不同浓度NH4NO3对水稻根系构型参数的影响.结果表明:NH4 和NH4NO3供应显著降低了总根长、总根表面积和总根体积,且有增加平均根直径的趋势;而NO3-供应在0~1 mmol/L浓度范围内,增加了总根长、总根表面积和总根体积,降低了平均根直径,但当NO3-供应超过1 mmo1/L后,NO3-却有降低总根长、总根表面积和总根体积的趋势,对平均根直径没有明显影响.苗期N高效基因型桂单4号总根长和总根表面积在各种N素营养条件下均显著高于N低效基因型南光.上述结果表明,NH4 和NH4NO3都抑制了水稻根系生长,而NO3-为低浓度诱导、高浓度抑制根系生长,根长和根表面积,对提高水稻N效率贡献较大.  相似文献   

6.
不同糜子品种对低氮胁迫的生物学响应   总被引:10,自引:2,他引:8  
采用溶液培养的方法,研究了低氮胁迫下不同糜子品种苗期生物学性状、 氮素吸收利用效率差异及与根系形态生理指标之间的相关关系。 结果表明, 低氮胁迫下,糜子地上部生长受抑程度大于根部,植株氮累积量降低但氮利用效率明显提高。晋黍7号株高、 叶面积、 茎叶干重、 根干重、 总根数、 总吸收面积和活性吸收面积下降幅度在所测试品种中均最小, 其总氮累积量分别是晋黍1号、 晋黍5号、 晋黍8号的1.35、 1.50、 1.39倍,根系氮累积量/总氮量的百分率增加的幅度和地上部氮累积量/总氮量的百分率下降的幅度均最低,分别为9.75% 和 3.47%; 植株氮利用效率比晋黍1号、 晋黍5号、 晋黍8号分别高20.92%、 12.44%、 14.83%。晋黍7号较其他品种更耐低氮胁迫。低氮胁迫下,糜子根系干重、 总根长、 总吸收面积与总氮累积量呈显著线性相关,表明低氮胁迫下,根系形态生理指标对氮素吸收效率起重要作用。  相似文献   

7.
为评价马铃薯耐盐性,筛选耐盐种质资源,本研究以164份二倍体马铃薯杂种后代及其亲本为试验材料,进行NaCl胁迫处理,测量盐胁迫和对照条件下杂交后代和亲本的芽长、芽鲜重、芽干重、根长、根鲜重和根干重6个形态指标,然后运用隶属函数分析和聚类分析方法进行综合评价及分类。结果表明,以亲本为对照,比较综合评价D值,筛选出26个耐盐无性系和10个盐敏感无性系;利用6个形态指标和D值分别聚类分析,166个无性系均被分为4个耐盐性不同的类群,表明可以分别利用6个形态指标和D值进行聚类,筛选出在同一类群中共同包含的无性系,提高耐盐评价的精确性;后代无性系根长相对值平均值较高(62.5),且聚类分析后,第一类群和第二类群的根长相对值的差异较小,说明根长不是理想的形态筛选指标,可以考虑用主根数替代根长,作为耐盐筛选的形态指标之一。本研究结果为快速评价大量马铃薯种质资源的耐盐性和马铃薯耐盐育种提供了理论依据和材料基础。  相似文献   

8.
  【目的】  石灰性土壤高pH和高重碳酸盐含量严重影响土壤中有效铁含量,导致作物缺铁黄化、减产,铁高效玉米品种的推广应用是实现石灰性土壤玉米高产稳产的重要途径。 本研究探讨不同铁效率玉米品种适应低铁胁迫的根系特征与铁积累差异,旨在为铁高效玉米品种的推广应用提供科学依据。  【方法】  试验以铁高效玉米品种正红2号 (ZH2)、正大619 (ZD619) 和铁低效玉米品种川单418 (CD418)、先玉508 (XY508) 为材料,设置极低铁处理 (Fe0,Fe浓度为0 μmol/L)、低铁处理 (Fe10,Fe浓度为10 μmol/L) 和正常供铁 (Fe100,Fe浓度为100 μmol/L) 3个处理,通过砂培试验,研究不同铁效率玉米品种适应低铁胁迫的根系形态特征、干物质重、铁积累及铁吸收利用差异。  【结果】  低铁胁迫下,玉米幼苗的根干重、单株干重、铁积累量、根系相对铁吸收效率均显著降低,而根冠比与铁素生理效率均显著升高,且随胁迫程度的增加变幅加大;总根长、根表面积、根体积和根直径则表现出明显的品种差异,与正常铁处理 (Fe100)相比,低铁处理下铁低效品种的总根长、根表面积和根体积显著降低,根直径显著增加,而铁高效品种的总根长和根表面积差异不显著,根体积显著增加,根直径在极低铁处理(Fe0)下显著降低,低铁处理 (Fe10)下差异不显著;铁高效品种总根长、根表面积、根体积、根干重、单株干物重、铁积累量和根系铁吸收效率的降幅及根冠比的增幅均明显低于铁低效品种,而铁生理效率的增幅高于铁低效品种。相关性分析结果表明,玉米幼苗铁积累量与总根长、根表面积、根体积和根干重均呈显著正相关,而与根冠比呈负相关,其中与总根长 (R2 = 0.8546) 和根表面积 (R2 = 0.8983) 相关性最强。  【结论】  与铁低效玉米品种相比,铁高效玉米品种低铁胁迫下具有较优的总根长、根表面积及较高的根系铁吸收效率与铁生理效率,促进了其对铁的高效吸收与利用,提高了其对低铁环境的适应能力。  相似文献   

9.
马蔺苗期耐镉性分析及鉴定指标筛选   总被引:2,自引:0,他引:2  
为探讨马蔺苗期耐镉特性,筛选耐镉性快速鉴定指标并建立耐镉性数学评价模型,本研究通过盆栽砂培试验,以16份马蔺种质材料为试验材料,设置5个镉(Cd)浓度处理(0、50、100、200、300mg·kg-1),胁迫40d后测定马蔺种质材料的8项形态和生理指标,即株高(PH)、叶绿素(Chl)含量、地上干重(DWS)、根系干重(DWR)、叶片超氧化物歧化酶(SOD)活性、过氧化物酶(POD)活性、丙二醛(MDA)含量及可溶性蛋白(SP)含量,以各单项指标的耐性指数作为衡量耐镉性的依据,运用主成分分析、隶属函数法分析和逐步回归分析等方法进行综合评价及分类。结果表明,主成分分析将镉胁迫处理下马蔺苗期的8项形态和生理指标转换成3个彼此独立的综合指标;利用隶属函数法对3个综合指标分析,得到不同种质苗期耐镉性综合评价值(D值);通过对D值聚类分析,将16份马蔺种质材料分为3个耐镉群体,其中强耐镉材料6份,中等耐镉材料7份,弱耐镉材料3份;进一步运用逐步回归法建立耐镉性预测回归模型:D=-1.414+1.076DWS+0.744SP+0.266SOD,筛选出显著影响马蔺苗期耐镉能力的3个单项指标(DWS、SOD、SP);ML018、ML019等6份强耐镉材料具有较强的吸收、忍耐和转运能力,可作为Cd污染土壤修复的备选植物。本研究为马蔺种质资源评价及新品种选育奠定了基础。  相似文献   

10.
水分胁迫下氮素增加对玉米生长的抑制作用   总被引:1,自引:0,他引:1  
水分和氮素是影响玉米生长发育的重要因子。在干旱和土壤贫瘠条件下,作物的生长和生理过程受到水分和氮素的交互作用。因此,研究水分胁迫下不同施氮水平对玉米叶片光合生理及根系形态的影响可以为玉米栽培中水氮的高效管理提供科学理论依据。利用温室盆栽试验,在中度水分胁迫(W1,40%~50%田间持水量)、轻度水分胁迫(W2,60%~70%田间持水量)和充足供水(W3,75%~90%田间持水量)三个水分处理下设置低氮(N1,1.0g·盆~(-1))、中氮(N2.5,2.5g·盆~(-1))和高氮(N5,5.0g·盆~(-1))三个施氮水平,研究玉米的生长状况、叶片气体交换参数、光和二氧化碳响应曲线和根系形态等。结果表明:在不同水分条件下玉米对氮素的生理响应过程不同。水分胁迫下根长和根系比表面积较充足供水处理显著增加,增幅分别为106.39%~208.82%和45.81%~105.85%,根干重在中度水分胁迫下降低23.94%~36.61%;此时增加施氮量尤其是高氮处理,玉米的根长和根系比表面积比水分胁迫下低氮处理显著降低41.85%~54.10%和18.68%,根干重比中度水分胁迫下低氮处理显著降低33.75%。因此,水分胁迫下施氮加剧了根际的水分胁迫,造成根水势下降,进而影响地上部分叶片的气孔导度(G_s)及二氧化碳和光的利用效率。水分胁迫和施氮处理均影响玉米叶片的光和CO_2响应曲线,水分处理的影响更显著。相同施氮水平下,随着水分胁迫程度的加剧,光响应曲线参数暗呼吸速率(R_d)、最大净光合速率(A_(max))和饱和光强(Q_(sat))以及CO_2响应曲线参数初始羧化效率(a)、光呼吸速率(R_p)、光合能力(A_(max))和高氮条件下的饱和胞间CO_2浓度(C_(isat))均呈下降趋势,前者参数变化显著,而且中度水分胁迫下,增加施氮量进一步降低了这些参数,即水分胁迫下氮素进一步抑制了植株的光合性能;同时,中度水分胁迫下叶片G_s和光合速率(A_n)分别显著降低32.37%~51.97%和41.85%~56.14%,而中度水分胁迫下增加施氮量尤其是高氮处理可以使G_s和A_n较低氮处理分别降低35.81%和30.71%。水分胁迫促进根长和根系比表面积增加,而水分胁迫下,增施氮肥不仅未缓解水分胁迫,反而抑制根长和根系比表面积的增加,加剧了根系的水分胁迫,造成根水势降低,进而影响了地上部分叶片的G_s,并削弱了叶片的光合性能即降低了对CO_2和光能的利用能力,这些气孔和非气孔因素最终抑制了光合作用,导致光合碳同化能力降低,影响了根系生物量的积累。  相似文献   

11.
酸性磷酸酶活性与大豆耐低磷能力的相关研究   总被引:39,自引:1,他引:39  
在水培条件下研究了11个南方春大豆地方品种和育成品种对低磷胁迫反应的差异及其与酸性磷酸酶活性(APA)的相关关系。结果表明,不同大豆品种的地上部干重、根干重、植株全磷和全氮积累量差异极显著(P<0.01),表现出品种间耐低磷的差异性。大豆品种地上部干重、根干重、植株全磷和全氮量与APA的相关性均达到显著或极显著水平。APA是大豆品种磷效率的一种机制,它可作为耐低磷品种筛选的一个生化指标。  相似文献   

12.
低氮胁迫对谷子苗期性状的影响和耐低氮品种的筛选   总被引:2,自引:1,他引:1  
筛选和培育耐低氮能力强的作物品种,是提高作物氮素利用效率,减少氮肥施用量,降低环境污染的有效措施。本研究以45份谷子品种为试材,采用水培的方法,在低氮(0.1mmol·L~(-1))和正常氮(5mmol·L~(-1))条件下,测定苗高、根长和根数等22个氮效率相关指标,采用综合耐低氮系数法以及基于主成分分析的隶属函数法评价参试谷子品种的耐低氮性。结果表明,与正常氮条件相比,低氮胁迫下,谷子苗期根长、根冠比、地上部氮素生理效率、地下部氮素生理效率、单株氮素生理效率有不同程度提高,其余17个指标都有不同程度降低。两种评价方法均根据45个谷子品种的耐低氮能力将其划分为强耐低氮型、耐低氮型、中间型、较敏感型和敏感型5类。筛选出耐低氮性较强的品种5份,编号分别为11、14、17、35和39。利用GGE双标图对品种-耐低氮相关指标的分析表明,编号39和14的耐低氮品种主要耐低氮性状为地下部干重、地下部鲜重、根长;编号为11、35和17的耐低氮品种主要耐低氮性状为地上部鲜重、叶片数、叶宽、叶长、单株氮累积量、地上部氮累积量、单株干质量、地上部干重、地下部氮累积量、根数、苗高和SPAD。可见不同谷子品种的耐低氮机制存在一定差异,研究结果可为谷子耐低氮品种的选育提供材料基础。  相似文献   

13.
为充分利用盐碱地资源,明确野生大豆耐盐碱生理机制,本研究对采集于冀东地区的349份野生大豆种质资源进行耐盐碱性鉴定,测定了高耐材料2010-12和敏感材料2012-34、2012-49在0、100和200 mmol·L-1盐碱胁迫下的丙二醛、脯氨酸和可溶性糖含量、电解质外渗率以及脯氨酸代谢关键酶吡咯琳-5-羧酸合成酶(GmP5CS)、吡咯琳-5-羧酸还原酶(GmP5CR)、脯氨酸脱氢酶(GmPDH)及谷胱甘肽S-转移酶19(GsGST19)相关基因的表达量。结果表明,表现耐性等级1级的高耐材料有2份(Yong 2和2010-12),表现耐性等级2级的耐性材料有22份,表现耐性等级3、4、5级的材料各有80、77和161份。与CK相比,高耐野生大豆材料2010-12在盐碱胁迫下脯氨酸及可溶性糖含量显著升高,丙二醛含量及电解质外渗率无显著差异。在高耐盐碱野生大豆材料中,GmP5CSGmP5CRGsGST19基因表达量上调,GmPDH基因表达量下调。以上结果表明高耐野生大豆材料在盐碱胁迫下脯氨酸合成通路激活,脯氨酸含量升高,说明脯氨酸在野生大豆对抗盐碱胁迫中发挥重要作用。本研究筛选的高耐盐碱野生大豆材料可为培育耐盐碱栽培大豆提供优异种质。  相似文献   

14.
The aim of this study was to investigate the effect of silicon (Si) on soybean seedlings under (combined) drought and ultraviolet-B (UV-B) radiation stresses. Specifically, we determined dry matter accumulation and partitioning of the mineral elements in different organs of soybean seedlings using the inductively coupled plasma mass spectrometry (ICP-MS). The amount of dry matter accumulated in root, stem, and leaf of seedlings treated with (combined) drought and UV-B radiation stresses were lower than that of the control. Also, the content of macroelements in seedlings under the combined stress was lower than in those under control conditions. Changes in the contents of microelements varied according to the intensity of drought, UV-B radiation, and the organs of soybean. The relationship between the contents of mineral elements and the accumulation of dry matter also varied similarly. These results demonstrated that drought and UV-B radiation induced an alteration in the distribution of mineral elements in root, stem and leaf, leading to decreases in dry matter accumulation and inhibition of soybean growth.  相似文献   

15.
Relay strip intercropping of soybean has been widely developed in the southwest of China to secure China's soybean production. However, due to the shading from maize, soybean plants are thin and have a poor root system. Uniconazole is a plant-growth retardant that could enhance root vigor; increase root length, root volume, and root dry weight; and affect nitrogen (N) metabolism. To understand the effects of uniconazole on the root growth and N-transfer metabolism of soybean seedlings under relay strip intercropping, the changes in some morphological characteristics of root, dry-matter weight, root vigor, nitrate (NO3 ?)-N, ammonium (NH4 +)-N, and amino acid of xylem sap after seed treatment with uniconazole powder (0, 2, 4, and 8 mg kg?1 seed) were investigated. Main root length, total lateral root lengths, first lateral root numbers, root nodule numbers, root vigor together with bleeding sap, bleeding sap–top ratio, root dry weight, and root/shoot ratio were increased, indicating uniconazole improved soybean root system in relay strip intercropping. Uniconazole powder treatment could increase NO3 ?-N, NH4 +-N, and total amino acid of xylem sap, to increase the potential of leaf and root N reduction and assimilation, and increase of leaf and root N contents. Thus, results suggested that uniconazole treatment can improve root growth and N transfer mechanism of soybean to support its further growth.  相似文献   

16.
In this study, ten‐day‐old seedlings of barley {Hordeum vulgare L. cultivar Anadolu [boron (B)‐tolerant] and Hamidiye (B‐sensitive)} were used. Boron‐treated plants were grown on H3BO3 solution (final concentration of 10 mM) for five days. Control plants received no B treatment during this period. Total protein patterns were obtained by analysis of total protein extract from root and leaf tissues of control and B‐treated plants using two‐dimensional gel electrophoresis followed by silver staining. The protein profile of B‐treated seedlings of each cultivar was compared to the profile of control (no stress treatment) plants of the same cultivar. Silver‐stained gels showed that B stress caused increases or decreases in a number of proteins in root and leaf tissues. Moreover, as a result of B treatment, one newly synthesized protein with relative molecular weight (Mr) of 35.0 kDa was detected in root profile of the tolerant cultivar. This protein failed to show up in root profile of the B‐treated sensitive cultivar. Three proteins were quantitatively increased in B‐treated root profile of both cultivars. Following B treatment, three proteins were increased in root profile of the tolerant cultivar, but were not changed in the sensitive one. In leaf tissues, however, there were remarkable changes in total protein profiles after B treatment, relative to the control. Following B treatment, in leaf tissues, at least seven proteins were increased in amount in tolerant cultivar but were unchanged in the susceptible one. In tolerant and sensitive cultivars, amounts of two proteins were increased in B‐treated plants, relative to control seedlings. In addition, four proteins (Mr:29, 58, 58, and 22 kDa) were unchanged in control and B‐treated seedlings of the tolerant cultivar. In the susceptible cultivar however, among these four proteins, the first one (Mr:29) was very much reduced and the others (Mr: 58, 58, and 22 kDa) were completely lost in B‐treated seedlings. Moreover, following B treatment, a set of high‐molecular‐weight proteins was quantitatively decreased in the susceptible cultivar but was unchanged in the tolerant cultivar. These results indicate that in barley, certain proteins may be involved in tolerance to B toxicity. In this study, changes in polypeptide composition as a result of B toxic concentration in leaf tissues were more abundant than in roots. Therefore, it is suggested that these changes, especially at shoot level may form the basis of the tolerance mechanism to B toxicity.  相似文献   

17.
Siratro (Macroptilium atropurpureum), desmodium (Desmodium intortum), and soybean (Glycine max) were grown in pots with or without irrigation for 20 d at the vegetative growth stage in order to examine the effects of water stress on the leaf water potential, stomatal conductance, biomass production, biological nitrogen fixation, and nitrogen accumulation. Whole plant weight decreased under water stress conditions and the decrease was less pronounced in siratro than in desmodium and soybean. Decrease in total leaf area was the largest and dry matter partition to stem and petioles was the highest in siratro. Decrease in leaf water potential was lower in desmodium and soybean than in siratro. Although water stress decreased biological nitrogen fixation in all the species, the decrease was relatively less pronounced in siratro than in desmodium and soybean. Whole plant nitrogen concentration was higher in siratro than in soybean and desmodium. The results indicated that siratro is more tolerant to water stress than soybean and desmodium. This could be partially attributed to the maintenance of a higher water potential and higher biological nitrogen fixation by siratro under water stress conditions.  相似文献   

18.
Solanum scabrum Mill. (huckleberry) is widespread in West, East and Central Africa, where it constitutes one of the most important leafy vegetables. However, the salinity tolerance of this crop has not yet been assessed. The objective of this study was to assess the response of huckleberry to salinity stress in comparison with eggplant (S. melongena L.). Four-week-old seedlings of both species were subjected to two levels of salinity stress, 50 mM and 150 mM sodium chloride (NaCl), for 14 d. Leaf water potential of both species decreased with increasing salinity stress. This decrease was lower in huckleberry than in eggplant. Total dry weight and total leaf area were also decreased by salinity, and the reductions of total dry weight and total leaf area under the 50 mM treatment compared with the control were 25 and 18% in huckleberry, while they were 47 and 55% in eggplant, respectively. The increases in leaf sodium (Na) accumulation in the 50 and 150 mM treatments compared with the control were 65 and 66% for eggplant and 18 and 36% for huckleberry, respectively. Na accumulation in stem and root in huckleberry was higher than that of leaf, whereas it was the reverse in eggplant under both salinity treatments. Huckleberry accumulated less Na in the leaves than eggplant, suggesting that huckleberry might reduce the transport of Na to its leaves more effectively than eggplant. The decrease of potassium (K) accumulation and the increase of Na in leaves by salinity resulted in a higher Na/K ratio in leaves, but this trend was greater in eggplant than in huckleberry. The calcium (Ca) concentration in leaves of huckleberry was also increased by salinity, whereas that of eggplant was decreased. These results indicate that huckleberry is more tolerant to salinity than eggplant, and less decrease in leaf area associated with lower leaf Na and increased Ca concentrations may be important in enhancing quality and sustaining productivity of the crop under this stress.  相似文献   

19.
将从培养瓶中移出的冬季(12-1月)或春季(3-4月)的香蕉组培苗置于大棚内,并在4种蔗荫水平下进行假植炼苗,相以强分别为100%(S100),33%(S33),10%(S10),3(S3)的光照条件。结果表明,不同光照强度下,单株香蕉苗的鲜茎重、鲜叶重、鲜根重、总鲜重、干茎重、干叶重、干根重和总干重都存在显著差异,但不同的生物量性状对光照强度的反应程度不同,冬季或春季遮荫均不利于单株香蕉苗的物质生产,且随遮荫程度的加重,影响愈大,同时荫还改变物质运输分配到各器官的比例。此外,春季与冬季相比,春季地上部各器官物质积累大于冬季,而冬季地下部根系的物质积累又要大于春季地下部的物质积累。  相似文献   

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