水分条件对豌豆保护酶活性及膜脂过氧化的影响

为探讨不同水分条件对豌豆保护酶系统和膜脂过氧化的影响,采用盆栽人工控水试验方法,模拟干旱胁迫及复水条件,研究了不同水分处理对花荚期豌豆叶片超氧化物歧化酶(SOD)、过氧化氢酶(CAT)、过氧化物酶(POD)活性以及过氧化产物丙二醛(MDA)含量和脂膜相对透性(RC)的影响,并对花荚期豌豆抗氧化能力进行了综合评价.结果表明:不同程度干旱胁迫历时5 d时并未影响豌豆叶片SOD、CAT活性,但有明显的滞后效应.重度干旱胁迫历时10 d可显著降低豌豆叶片SOD、CAT活性,显著提高MDA含量.不同程度的干旱胁迫均导致豌豆叶片POD活性提高,膜脂相对透性加大.复水可对干旱胁迫所造成的CAT、POD活性变化产生显著补偿作用,对SOD活性变化产生超补偿作用.同时,可显著降低MDA含量和脂膜相对透性;干旱胁迫历时10 d内和复水历时10 d内,豌豆有较强的抗氧化能力,仅在重度胁迫10 d后复水历时达到10 d时抗氧化能力趋弱.     

镉胁迫对耐性不同的水稻幼苗膜脂过氧化和保护酶活性的影响

自20世纪60年代日本“痛痛病”被确认是通过食物链传递而对人体健康造成威胁以来,人们对土壤-植物系统的重金属污染问题十分关注,并进行了大量的研究,其中植物对重金属的耐受性及其机制成为研究的热点之一。一些研究者从不同侧面探讨了植物耐受重金属胁迫的机理,如植物对重金属     

酸铝胁迫对栝楼根系生长及铝积累的影响

针对南方酸性红壤对作物的生长造成的不利影响,采用水培方式,研究酸铝环境0、100、300、500、1000μmol·L-1Al3＋pH4.5,处理7d对长兴栝楼根系生长及铝积累的影响。测定指标包括根系活力、质膜透性、抗氧化酶类活性（过氧化物酶POD、过氧化氢酶CAT、抗坏血酸过氧化物酶APX、愈创木酚过氧化物酶GPX、超氧化物歧化酶SOD）及其同工酶、过氧化氢（H2O2）含量、根尖铝含量的影响。结果表明：随着铝处理浓度升高,根系活力增大,根系质膜透性无显著变化;POD、CAT、APX酶活升高,GPX和SOD活性降低,多种抗氧化酶都有多条同工酶谱带出现;根尖相对铝含量升高,桑色素染色情况显示,荧光梯度与铝含量测定结果一致,并观察到根尖以上根毛处细胞凸起较之平整排列的根细胞更容易积累铝。栝楼对南方酸性红壤具有较强的适应能力,其体内抗氧化酶系统及根尖吸收、积累铝的机制对缓解铝毒害起着重要作用。     

分层减量施肥对花生根系生长的影响

在田间试验条件下,以‘青花7号’花生品种为材料,系统研究了分层减量施肥对花生根系生长的影响。结果表明,分层施肥和分层减量施肥均可增加根系总长度、根系表面积、根平均直径和根体积,促进根系干物质积累,对20～40 cm土层根系生长的促进效果明显优于0～20 cm土层,根系生长最大值时(8月1日)0～20和20～40 cm土层根系总长度、根系表面积和根体积较CK分别增加10.9%～16.6%、9.3%～13.5%、5.4%～15.1%和12.3%～19.6%、17.9%～30.1%、3.7%～20.0%,20～40 cm土层增幅较0～20 cm土层平均分别提高2.5、11.8和2.5个百分点;施肥量相同时,对20～40 cm土层根系生长的促进效果明显优于0～20 cm土层,且三层施肥效果优于二层施肥;施肥层次相同,随施肥量的减少根系各指标下降不明显。研究认为,分二层或三层施肥并减少化肥用量10%～20%可作为减肥增效、壮根健株的有效措施。     

NaCl胁迫对嫁接番茄根系质膜和液泡膜ATP酶活性的影响

在NaCl胁迫下,对番茄嫁接苗和自根苗的根系活力、根系质膜H+-ATPase、液泡膜H+-ATPase和H+-PPase、质膜和液泡膜Ca2+-ATPase、质膜氧化还原系统活性进行了比较。结果表明,胁迫条件下,嫁接苗根系活力显著高于自根苗。胁迫前期,嫁接苗根系质膜H+-ATPase活性、液泡膜H+-ATPase和H+-PPase活性、质膜和液泡膜Ca2+-ATPase活性、质膜NADH氧化速率和Fe (CN)63- 还原速率被显著诱导;自根苗根系液泡膜H+-ATPase、H+-PPase和Ca2+-ATPase活性、质膜NADH氧化速率和Fe (CN)63- 还原速率被显著诱导。胁迫后期,嫁接苗和自根苗根系各项指标均被显著抑制,但嫁接苗各指标受抑制时间较自根苗晚,且数值上均显著高于自根苗。表明嫁接苗比自根苗具有较强的耐盐性。     

干旱胁迫对花生生育中后期根系生长特征的影响

花生是较耐旱的经济和油料作物, 长期少雨或季节性干旱是限制花生产量提高的重要环境因子, 也是花生收获前黄曲霉素感染的重要因素。根系是植物吸水的主要器官, 不同土壤水分状况下植物的根系构型可能会表现出显著差异, 进而影响植物根系吸收养分和水分的能力。研究不同土壤水分状况下花生根系形态的发育特征与抗旱性的关系对进一步理解花生的水分吸收、运输、利用和散失机制以及培育抗旱性花生具有非常重要的作用。为明确不同抗旱性花生品种的根系形态发育特征, 探讨其根系形态发育特征对不同土壤水分状况的响应机制, 在防雨棚旱池内进行土柱栽培试验, 研究抗旱型花生品种"花育22号"和干旱敏感型花生品种"花育23号"生育中后期根系生长特征及其对干旱胁迫的响应。设置正常供水和中度干旱胁迫(分别控制土壤含水量为田间持水量的80%~85%和45%~50%)2个水分处理, 分别在花针期、结荚期和饱果期进行取样,根长、根表面积和体积扫描后通过WinRhizo Pro Vision 5.0a程序进行分析; 收获时测定产量和抗旱系数(干旱胁迫处理与正常供水处理下产量之比)。结果表明, "花育22号"具有较高的产量和抗旱系数, "花育23号"对干旱胁迫的适应性小于"花育22号"。抗旱型品种"花育22号"具有较大的根系生物量、总根长和根系表面积, 且深层土壤内根系表面积和体积大于"花育23号"。与正常供水处理相比, 干旱胁迫显著降低2个品种花针期的根系总根长、根系总表面积和总体积, 对结荚期和饱果期根系性状无显著影响; 干旱胁迫增加2个品种生育中后期40 cm以下土层内的根长密度分布比例、根系表面积和体积, 但"花育23号"各根系性状增加幅度小于"花育22号"。干旱胁迫处理下20~40 cm和40 cm以下土层内根系表面积和体积分别与总根长、总表面积和总体积呈显著或极显著正相关, 而正常供水处理下0~20 cm土层内根系表面积和体积与整体根系性状表现极显著正相关。总体而言, 具有较大根系和深层土壤内较多的根系分布是抗旱型花生的主要根系分布特征; 土壤水分亏缺条件下, 花生主要通过增加深层土壤内根长、根系表面积和体积等形态特性调节植株对水分的利用。     

铝对荞麦和金荞麦根系分泌物的影响

以荞麦和金荞麦为实验材料，用砂培方法研究Al胁迫下荞麦和金荞麦根系分泌电解质、糖和氨基酸的变化。结果表明，Al胁迫条件下，电解质外渗率、糖类随Al^3 浓度升高而增加；在低浓度Al^3 作用下，随处理浓度的升高，氨基酸分泌量增加，当处理浓度高于相应浓度时，氨基酸分泌量随浓度升高而减少。Al胁迫使荞麦和金荞麦根系分泌物的种类和浓度发生改变，与其缓解Al毒害相关。     

酸化土壤铝和镉对水稻幼苗根系生长的复合影响

酸雨和大量施用化肥致使我国土壤酸化日益加重。酸性土壤中,铝（Al）毒被认为是限制作物生长与产量的主要因素。镉（Cd）因被广泛应用于电镀、冶金、染料和电池等领域而大量进入土壤,已成为严重影响农业生产的重金属元素之一。在中国多数农业区,土壤酸化、Al和Cd污染重叠发生。目前,国内外关于单一土壤酸化、Al、Cd胁迫或两两复合胁迫对作物毒害效应及其机理研究,已有报道。然而有关酸化土壤Al和Cd复合胁迫对作物影响研究甚少。水稻是重要粮食作物,全球约13％水稻生长于酸化土壤。     

铝胁迫下大豆根系分泌物对根际土壤微生态的影响

通过对19个不同基因型大豆品种的耐铝性筛选实验,选择耐铝型的浙春2号和敏感型的浙春3号作为实验材料;设置5个铝处理浓度(0,0.2,0.4,0.6,0.8 g kg-1,即土壤总Al3+浓度分别为0.293,0.493,0.693,0.893,1.093 g kg-1)土壤,大棚种植大豆30d后,取大豆根际、非根际土壤和外源根系分泌物作用下的土壤样品,对各类微生物生理群进行分析,同时测定土壤呼吸速率、纤维分解作用、氨化作用、硝化作用,以及酸性磷酸酶、过氧化氢酶和蔗糖酶等土壤重要酶类的活性。结果显示,土壤铝含量较低条件下(0.2,0.4g kg-1),大豆根系分泌物的应激分泌促使土壤微生物数量增多、微生物物质转化能力增强和土壤酶活性增大;土壤铝含量较高(0.8 g kg-1)时,根系分泌物的分泌相对受抑制,土壤微生物活性和土壤酶活性相应地受到抑制。实验结果还表明,外源根系分泌物也能影响土壤微生态,引起土壤微生物数量和土壤酶活性的变化,以及各种土壤生化作用(如硝化作用等)的改变,显示出一定的缓解铝毒能力,从而减少铝毒对植物的伤害。     

铝对小麦根尖细胞壁过氧化物酶活性和过氧化氢含量的影响

以2个小麦基因型鉴-864(耐性)和扬麦5号(敏感)为材料,采用溶液培养方法研究了铝胁迫下小麦根系伸长、根尖铝含量、根尖细胞壁过氧化物酶活性和H2O2含量的变化。结果表明,随着铝浓度的提高,小麦根系伸长受铝抑制程度加剧,根尖铝含量也明显升高;但敏感基因型根尖铝含量较高,根系伸长受抑程度更为明显。在铝胁迫下,2个小麦基因型根尖可溶态愈创木酚过氧化物酶(GPX)和松柏醇过氧化物酶(CAPX)活性没有显著变化,细胞壁离子键结合态GPX和CAPX的活性则随着铝浓度的提高而显著升高,H2O2含量也呈现类似的趋势;而敏感基因型过氧化物酶活性升高和H2O2积累更为明显。因此,铝胁迫下,小麦敏感基因型根尖细胞壁离子键结合态GPX和CAPX活性升高而引起H2O2积累,促进根系木质化和细胞壁氧化交联,导致根细胞壁刚性提高而伸展能力降低,是其根系伸长受到严重抑制的原因。     

Effect of aluminum on callose synthesis in root tips of tea (Camellia sinensis L.) plants

Aluminum (Al) toxicity is a major factor limiting yield production on acid soils (Foy 1983). The initial symptom of Al toxicity in many plants is manifested by the inhibition of root elongation (Ownby and Popham 1990; Llugany et al. 1994; Sasaki et al. 1994; Horst et al. 1997), which occurs during a very short period of time after exposure to Al (Llugany et al. 1994; Staß and Horst 1995). In a large number of recent reports, it was shown that the root apex plays a major role in the Al-sensitivity and response mechanisms (Zhang et al. 1994; Sasaki et al. 1997; Sivaguru and Horst 1998). However, it is interesting to note that stimulatory effects of Al on the growth of plants have also been reported in some studies (Chenery 1955; Konishi et al. 1985; Huang and Bachelard 1993; Osaki et al. 1997). In tea plant (Camellia sinensis L.) a stimulatory effect of Al on the growth was also demonstrated in some experiments, using intact plant (Chenery 1955; Konishi et al. 1985), cultured roots (Tsuji et al. 1994), and pollen tubes (Yokota et al. 1997). The growth of tea roots was typically more stimulated than that of shoots by Al (Konishi et al. 1985). It was assumed that Al effects might be due to the amelioration of phosphorus absorption (Konishi et al. 1985), secretion of malic acid from roots to dissolve aluminum phosphate in the rhizosphere (Jayman and Sivasubramaniam 1975), stimulation of growth of microorganisms on the root surface (Konishi 1990) or replacement of some functions of boron (Konishi 1992; Yokota et al. 1997). However, the stimulatory effects of Al on tea plant growth have not yet been el ucidated.

The formation of callose (1,3-β-glucan) has been reported as a common plant response to a variety of stresses, as well as mechanical, biophysical, chemical, and biological injury (Jaffe and Leopold 1984; Zhang et al. 1994). Increased synthesis of callose has been observed upon exposure to excess amounts of some elements, such as boron (McNairn and Currier 1965), cobalt, nickel, zinc (Peterson and Rauser 1979), and manganese (Wissemeier and Horst} 1987, 1992). Callose synthesis was also induced by Al in the roots of Triticum aestivum (Zhang et al. 1994) and Zea mays (Horst et al. 1997; Sivaguru and Horst 1998), suspension-cultured cells of Glycine max (Staß and Horst 1995), and protoplasts of Avena sativa (Schaeffer and Walton 1990) and Zea mays (Wagatsuma et al. 1995). Induction of callose synthesis in roots seems to be a very rapid physiological indicator of Al-induced injury or genotypical differences in Al sensitivity (Wissemeier and Horst 1992; Zhang et al. 1994; Horst et al. 1997). Nevertheless, Al-induced callose synthesis in tea plant, whose growth is stimulated by suitable Al concentrations, has not been described yet. Therefore, to elucidate the physiological basic effects of Al on tea plant, callose synthesis affected by Al in the root tips of intact plants was analyzed in the present study.     

Assessment of aluminum sensitivity of maize cultivars using roots of intact plants and excised root tips

Maize cultivars (Zea mays L.) were evaluated for their aluminum (Al) sensitivity using intact plants and excised root tips exposed to 25 μM Al in nutrient solution of low ionic strength and pH 4.3. Aluminum supply increased callose formation and Al concentrations in root tips of intact plants as well as in excised root tips. Using intact plants, differences in Al sensitivity among cultivars could be characterized by Al‐induced callose formation, Al‐induced inhibition of root elongation, as well as Al contents in root tips as parameters. Significant correlations between Al‐induced callose formation and Al contents in root tips (r² = 0.64**) and inhibition of root elongation (r² = 0.80***) were found. Excised root tips did not show a significant Al‐induced inhibition of root elongation. While average Al‐induced callose formation was similar for root tips of intact plants and excised root tips, mean Al contents in excised root tips were up to 1.5‐fold higher than in root tips of intact plants after 24 h of Al treatment. Aluminum‐induced callose formation as found in excised root tips did neither correspond to Al‐induced callose formation nor to inhibition of root elongation of intact plants. The addition of 10 mM glucose to the incubation medium led to a significant increase in the elongation of excised root tips and a 2‐3‐fold increase in Al‐induced callose formation. Staining with triphenyl‐tetrazolium‐chloride (TTC) revealed increased viability of these root segments. However, these effects of glucose supply did not improve the characterization of the cultivars for Al resistance. The results presented suggest that Al exclusion mechanisms expressed in root tips of intact plants might be non‐operational in excised root tips. Therefore, the characterization of maize germplasm for Al resistance using excised root tips appears not to be reliable.     

花生根、茎中白藜芦醇含量影响因素

为了获得含白藜芦醇较多的花生根、茎作为提取白藜芦醇的原料。该文考察了华东不同地区、不同品种、不同采收时间以及采后存放、提取环境对花生根、茎中的白藜芦醇含量的影响。结果表明:白藜芦醇富集在花生根表皮,木质部含量较少;不同生长环境、不同品种对花生中白藜芦醇的含量影响较大;同一品种,采收时间越晚,白藜芦醇含量越高。采收后的花生根霉变会提高其中的白藜芦醇含量;花生中白藜芦醇在酸性条件下较为稳定,而碱性条件下易变性。采用合适品种的晚收花生根在酸性条件下提取可得到白藜芦醇含量较高的原料。     

土壤水分对花生根际分泌物中低分子量有机酸的释放及根质外体中铁的积累的影响

A three-compartments rhizobox was designed and used to study the low-molecular-weight organic acids in root exudates and the root apoplastic iron of “lime-induced chlorosis“ peanut grown on a clacareous soil in realtion to different soil moistrue conditions.Results showed that chlorosis of peanuts developed under condition of high soil mositure level(250 g kg^-1),while peanuts grew well and chlorosis did not develop when soil moisture was managed to a normal level(150 g kg^-1).The malic acid maleic acid and succinic acid contents of chlorotic peanut increased by 108.723,0.029,and 22.446ug cm^-1 ,respectively,compared with healthy peanuts.The content of citric acid and fumaric acid also increased in root exudates of chlorotic peanuts.On Days 28 and 42 of peanut growth,the accumulation of root apoplastic iron in chlorotic peanuts was higher than that of healthy peanuts.From Day 28 to Day 42,the mobilization percentages of chlorotic peanuts and healthy peanuts to root apoplastic iron were almost the smae,being 52.4% and 52.8%,respectively,indicating that the chlorosis might be caused by the inactivation of iron within peanut plant grown on a calcareous soil under soil moisture conditions.     

热处理对轻度加工葡萄膜脂过氧化作用的影响

为探索热处理对轻度加工葡萄衰老软化及贮藏保鲜效果的影响，以红地球葡萄为试验材料,研究了50℃ 10 min、50℃ 15 min、 55℃ 5 min、55℃ 10 min热空气处理对其衰老过程中膜脂过氧化作用及贮藏效果的影响。结果表明，55℃ 5 min和10 min处理与对照相比，能抑制过氧化物酶(POD)、过氧化氢酶(CAT)和超氧化物歧化酶(SOD)活性的下降，降低丙二醛(MDA)含量的积累和果肉组织的相对电导率，从而抑制轻度加工葡萄的衰老软化。而50℃ 10 min和15 min热处理对延缓轻度加工葡萄衰老软化无明显作用。     

低磷胁迫对番茄叶片膜脂过氧化及保护酶活性的影响

许多土壤全磷量很高,但植物可吸收的有效磷却很低,因此作物表现缺磷.番茄是对缺磷敏感的作物,缺磷时,植株矮小,产量品质下降.目前,植物在逆境条件下的膜脂过氧化反应和保护酶系统超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)活性的变化己广泛用于植物对逆境机理的研究[1].     

波尔多液营养保护剂对花生黄化症的矫治及生长效应的影响

选用山东省花生主产区的代表性石灰性土壤,通过土培试验的方法,研究了3种不同形态铁的波尔多液营养保护剂BNPP-NFe、BNPP-EFe、BNPP-RFe和美国铜基杀菌剂Kocide 4种可湿性粉剂矫治花生缺铁黄化症,以及对花生生长效应的影响。结果表明,与CK(喷清水)相比,喷施BNPP-NFe后,花生叶绿素、活性铁、全铁含量都有显著提高,并且BNPP-NFe、BNPP-EFe和BNPP-RFe处理的产量比CK分别提高92％～115％、67％～98％以及90％～94％。BNPP-NFe处理与Kocide处理相比,花生叶片活性铁和全铁含量差异显著,分别提高77.12％～139%以及29.01％～120%,产量提高27.5％～37.6％。3种不同的波尔多液营养保护剂以BNPP-NFe效果最好,且优于美国Kocide产品。     

Silicon effect on growth,nutrient uptake,and yield of peanut (Arachis hypogaea L.) under aluminum stress

Abstract

The objective of this study was to investigate the effect of silicon (Si) on growth, nutrient uptake, and yield of peanut under aluminum (Al) stress. Peanut (Arachis hypogaea L. cv. Zhonghua 4) raised with or without Si (1.5?mM) in the growth chamber under 0 and toxic Al (0.3?mM) levels. Aluminum stress significantly decreased the biomass and root dry weight by 12.9% and 10.7%, and the pod yield, number of mature pod per plant and seed number of per pod by 16.7%, 10.7%, and 13.9%. The content of nitrogen (N), phosphorus (P), potassium (K), calcium (Ca), and magnesium (Mg) was significantly decreased, but that of Al increased markedly in shoots and roots of peanut after Al exposure at seedling, flower-needle and pod-setting stage. Under Al stress condition, Si application protected peanut by improving nutrient uptake at different growth stages and favoring the partitioning of dry mass to pod and the allocation of tissue N, P, K, Ca, and Mg to shoots and pod and decreasing Al uptake and accumulation.