Physiological Basis of Irrigation Scheduling for Seed Production in Egyptian Clover Syn. Berseem (Trifolium alexandrinum L.) Crop

A field experiment was conducted to find out the critical physiological stages of irrigation schedules inducing better growth, physiological efficiency and seed yield potential of berseem ( Trifolium alexandrinum L., Var. S-99-1). For this purpose eight irrigation treatments were made comprised of four treatments of three irrigation (W₁, W₂, W₃ and W₄), three treatments of four irrigation (W₅, W₇ and W₈) and one treatment of five irrigation (W₆) at various physiological stages i. e. regeneration, flower initiation, full bloom, seed initiation and advance seed development stage.
Thus based on the experimental results the physiological role of watering in berseem seed production could be discussed as:
With-holding of irrigation either at regeneration or at full bloom stage developed potential water stress in plants as indicated by high proline content of irrigation treatments — W₄, W₁ and W₇; and further brought out disturbance on the formation of carotene, synthesis of water soluble sugar and translocation of sugar towards reproductive organs during grain development stage. These stresses adversely affected the plant growth and flowering behaviour. The irrigation at seed initiation stage increased the seed yield. Continuous irrigation did not appear to be useful. Thus it can be concluded that irrigation at three critical physiological stages i. e. regeneration, full bloom and seed initiation was found to be essential for obtaining potential seed yield of berseem.     

铅胁迫对金丝草生长及生理生化的影响

采用土培方法,探究不同梯度铅胁迫(0、1000、2000和3000 mg·kg^-1)对金丝草生长形态、体内抗氧化系统和渗透调节物质的影响。结果表明:低浓度(1000 mg·kg^-1)处理会诱导金丝草叶片过氧化物酶(POD)活性、可溶性蛋白(SP)含量和根系抗超氧阴离子自由基活力(ASAFR)、可溶性糖(SS)及脯氨酸(Pro)含量增加,使得金丝草植株总抗氧化能力(T-AOC)处于较高水平,促进了金丝草株高、叶长和生物量的增加。随胁迫浓度增加,高浓度(2000~3000 mg·kg^-1)处理下,金丝草叶片和根系丙二醛(MDA)含量迅速增加,株高、叶长、叶面积和生物量下降,生长受到抑制。但金丝草通过增强叶片和根系POD、过氧化氢酶(CAT)活性来抵御过氧化作用,提高可溶性蛋白和可溶性糖含量维持细胞正常运作,增加根系生物量占比来加强根系发育,一定程度适应了高浓度铅胁迫。综上表明,金丝草主要通过叶片和根系不同抗氧化酶差异化响应、提高渗透调节物质含量,提升金丝草植株总抗氧化能力等途径来提高Pb耐性,对Pb污染矿区植物修复有较大潜力。     

紫花苜蓿形态和生理指标响应干旱胁迫的品种特异性

为研究紫花苜蓿在叶片和根系水平上响应干旱胁迫的形态和生理的品种特异性规律,在温室内分析了干旱胁迫下WL363HQ和巨能7紫花苜蓿株高、分枝数、生物量及叶片和根系中丙二醛(MDA)、脯氨酸、抗氧化酶类物质、C、N含量、C/N、稳定性C同位素(δ13C)和稳定性N同位素(δ15N).结果表明:干旱胁迫显著降低了供试品种地上...     

NaCl水分复合胁迫下宁夏十种主栽苜蓿品种幼苗体内脯氨酸含量变化

二次通用旋转组合设计盆栽试验,分析比较宁夏10种主栽苜蓿品种苗期在NaCl、水分复合胁迫下体内脯氨酸含量的变化,并对其抗盐、抗旱性进行初步评价。结果表明:NaCl胁迫对各品种体内脯氨酸含量的主效应除陇东和阿尔冈金苜蓿表现为负效应外,其它苜蓿品种均表现为正效应;水分胁迫对各品种的脯氨酸含量均表现为负效应;其单因素效应为:随NaCl胁迫的增加,各品种体内脯氨酸均有先减小,后增大的趋势;随水分胁迫的增加,各品种体内脯氨酸均有增加趋势;其交互效应表现为:NaCl、水分两因素对阿尔冈金、新疆大叶、宁苜1号、内蒙苜蓿和金皇后五个品种体内脯氨酸含量(Y)影响的交互效应不显著;其余五个品种CW301、三得利、陇东苜蓿、朝阳苜蓿和CW200交互作用显著,且均为负交互,交互作用的大小排序为:YCW301=Y陇东苜蓿>YCW200=Y三得利>Y朝阳苜蓿;以脯氨酸含量为主要指标对10个苜蓿品种抗盐、抗旱性初步排序:CW301>CW200>朝阳苜蓿>金皇后>宁苜1号>阿尔冈金>内蒙苜蓿>陇东苜蓿>三得利>新疆大叶。     

不同旱稻品种灌浆期抗旱生理适应性的研究

选择抗旱性不同的4个旱稻品种,对其灌浆期旗叶抗旱性生理指标进行测定。结果表明:超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)活性及游离脯氨酸含量均为抗旱性较强品种(旱稻15号,旱稻2号)极显著地高于抗旱性较弱品种(旱稻1号,旱稻3号);丙二醛(MDA)含量和细胞膜相对透性大小表现为抗旱性较强品种(旱稻15号,旱稻2号)极显著地低于抗旱性较弱品种(旱稻1号,旱稻3号)。SOD、POD、CAT活性和丙二醛含量、游离脯氨酸含量、细胞膜相对透性可用来说明旱稻品种之间的抗旱生理适应性的差异。     

PEG处理葡萄试管苗生理反应及叶片组织形态研究

应用不同浓度的聚乙二醇(PEG10000)处理红地球葡萄生根试管苗,在造成一定程度水分亏缺的情况下,观察葡萄试管苗的生理反应和植株生长、叶片形态解剖结构的变化。结果表明:在PEG处理下,葡萄生长发育迟滞,植株节间变短,株高变矮,但发根数量增加,根变长;新生叶片与对照比,叶片小而皱缩,气孔指数降低,上皮细胞排列更紧凑;同时葡萄试管苗脯氨酸的积累和内源ABA迅速增加。说明在一定强度的水分胁迫下,葡萄试管苗叶片的发育向增强其耐旱能力的方向进行,其渗透调节物质的积累是葡萄试管苗对长期水分胁迫的生理反应。     

不同灌水处理小麦品种抗旱性鉴定指标遗传规律研究

依据Griffing方法配制种植不同类型的复合双列杂交组合,分别设水、旱二种水分条件。在不同生育时期测定株高、株穗数、株粒重、穗粒数、黄叶片数、SOD、POD、MDA等农艺、生理生化性状,研究不同组合类型对杂交后代的遗传力影响及其与抗旱性的关系及遗传规律。结果表明,可采用抗旱指数(DRI)作为评价小麦品种抗旱性强弱的指标。旱地株粒重、旱地穗下节长、旱地黄叶片、籽粒饱满度、落黄、旱地成穗数、旱地株高等7个质量性状和数量性状与抗旱性关系密切且遗传力较强,可作为高产种质杂种后代的早期抗旱性鉴定指标。SOD活性和MDA含量由于广义遗传力和狭义遗传力均较高,可以在杂种后代早期世代进行选择,OA能力和POD活性广义遗传力较高但狭义遗传力低,适宜在杂种后代的晚期世代进行选择。     

超重力处理对大白菜生理生化特性影响的研究

以新丰抗90白菜种子为试验材料,在1 000×g、2 000×g、4 000×g 3种不同超重力的条件下分别处理20、40、60 min后,幼苗期采取叶片测定其游离脯氨酸含量、过氧化物酶活性、超氧化物歧化酶活性。结果显示,2 000×g,40 min处理游离普氨酸含量最低;4 000×g,60 min处理游离脯氨酸含量最高,与对照相比,所有处理均抑制游离普氨酸的形成。1 000×g,20 min处理后的POD活性最高;2 000×g,60 min处理后的POD活性最低,但高于对照,超重力处理能显著提高POD活性。1 000×g,40 min处理SOD活性最高,4 000×g,60 min处理SOD活性最低,适宜的超重力处理有利于提高SOD活性。     

Application of biochar in mitigation of negative effects of salinity stress in wheat (Triticum aestivum L.)

Salinity is a major abiotic stress that affects crop production throughout the world. Biochar is an activated carbon soil conditioner that can alleviate the negative impacts of salinity. The research was conducted to evaluate the ameliorative effect of 1% and 2% of biochar application on wheat seed germination and growth attributes under salinity. Both levels of biochar improved the germination and growth conditions under salinity; however, 2% biochar level was more effective compared to 1% level. Root and shoot length increased up to 23% and11% with 2% biochar, respectively. The maximum increase of 16% and 10% in leaf water potential and osmotic potential was noted with 2% biochar at 150 mM salt. The decrease in proline content and soluble sugar at 2% biochar was 51% and 27%, respectively. Decrease in superoxide dismutase activity was 15.3% at 2% level of biochar under stress biochar mitigates the negative effects of salinity and improved wheat productivity.