杂交水稻开花结实期间叶片衰老

在杂交水秀开花期间,通过剪却穗部部分枝梗和叶片等处理,形成不同的库源比,叶片衰老的生理生化指标变化和结实率的测定表明,杂交水稻组合的库源矛盾大,叶片衰老快;但谷粒数与旗叶面积比不一定高,降低库源比,能明显减缓杂交水稻叶片中蛋白质,叶绿素含量及倒３,４,５片叶叶绿素含量的平均值和旗叶叶绿素含量的比率的下降和丙二醛含量的升高。     

杂交稻及其三系叶片衰老过程中SOD、CAT活性和MDA含量的变化

对杂交水稻及其三系主茎第11叶叶片自然衰老过程中超氧物歧化酶(SOD)、过氧化氢酶(CAT)和丙二醛(MDA)含量的变化进行了研究,结果表明:叶片衰老过程中,SOD和CAT活性下降,MDA的含量增加,可作为衰老特征的叶绿素和可溶性蛋白质含量明显下降;SOD的活性和MDA的含量变化相对应;CAT活性大幅度下降与SOD之间的不平衡,致使O_2~-代谢中间产物累积而引起膜的损伤。不育系的衰老进程比杂交水稻、恢复系和保持系慢,其SOD和CAT活性明显高于其它三者,可能是不育系不易早衰的原因之一。     

应用灰色关联度分析影响两系杂交稻结实率的生理因素

采用灰色关联度分析法分析了在两系杂交水稻抽穗期喷施植物生长调节物质ALA对旗叶6个生理因素的综合影响,并对各生理因素与结实率间的灰色关联度进行了分析,所得结果如下:10-70 mg/L ALA处理的旗叶生理指标值与其最优值的关联度均比对照高,其中以30 mg/LALA处理与最优值的关联度最大．在灌浆前期,影响水稻结实率的主要生理因素是可溶性蛋白质含量和叶绿素含量,在灌浆中期、灌浆后期,影响水稻结实率的主要生理因素分别是叶绿素含量和鞘糖含量、叶面积和叶绿素含量．上述结果表明,在水稻抽穗期喷施10-70 mg/L ALA,能提高旗叶的生理活性．在水稻的整个灌浆期,叶绿素含量对水稻结实率作用最强烈,是水稻籽粒灌浆动态生理因素．     

三种栽培模式下不同基因型冬小麦旗叶衰老代谢比较

为了探索冬小麦在不同栽培模式下功能叶片衰老代谢的生理机制,以cp02(213)、cp99(1)和陕农512为材料,比较研究了常规栽培、覆草栽培、地膜覆盖3种栽培模式下小麦旗叶衰老代谢特性.结果表明,覆草栽培叶面积、旗叶功能期、叶绿素含量、叶片保护酶活性(SOD、POD、CAT)显著高于常规栽培,膜脂过氧化程度较低,叶片衰老速度缓慢,代谢强度旺盛,有利于籽粒灌浆和光合产物的积累.灌浆前期,地膜覆盖叶面积、旗叶功能期、叶绿素含量、叶片保护性酶活性(SOD、POD、CAT)显著高于常规栽培,膜脂过氧化程度低于常规栽培;灌浆后期,叶绿素含量急剧下降,叶片衰老速度加快,膜脂过氧化程度加剧.参试品种(系)中陕农512叶片衰老速度缓慢,保绿性好.     

施氮量和栽培模式对旱地冬小麦旗叶衰老及其活性氧代谢的影响

以冬小麦小偃22为试验材料,研究3种栽培模式(常规栽培、覆草栽培、地膜覆盖)和3种施氮水平(施纯氮0、120和240 kg/hm2)下旗叶衰老与活性氧代谢特性.结果表明,与常规栽培(CK)相比较,覆草栽培条件下叶绿素含量始终较高(P<0.05),叶片衰老速度缓慢,代谢强度旺盛,有利于籽粒灌浆和光合产物的积累,产量显著增加(P<0.05).在灌浆前期,地膜覆盖条件下叶片叶绿素含量增加(P<0.05),叶片保护性酶活性(POD、CAT)提高,膜脂过氧化程度低;但在灌浆后期,叶绿素含量急剧下降,叶片衰老速度加快,膜脂过氧化程度加剧,产量仍显著增加(P<0.05).施用氮肥在一定范围内可提高旗叶叶绿素含量和保护性酶活性(POD、CAT),降低膜脂过氧化程度;施氮量为120 kg/hm2时,冬小麦旗叶叶绿素含量最高,叶片衰老迟缓,代谢强度降低缓慢,膜脂过氧化程度低,有利于小麦后期生长和籽粒灌浆,在3种栽培模式下产量均最高.     

黑暗诱导衰老对不同年代冬小麦品种旗叶光系统Ⅱ功能的影响

小麦品种的更新换代是小麦产量不断提高的重要因素,阐明小麦品种演替过程中不同生理特性的变化对新品种选育具有重要参考价值.旗叶衰老速率快慢是影响小麦产量水平的关键因素,目前对于不同小麦品种衰老过程中旗叶光系统Ⅱ功能的变化规律尚不清楚.本试验选用1941-2014年间河南地区不同时期种植的31个品种,通过黑暗诱导离体叶片衰老,测定旗叶叶绿素荧光诱导动力学参数、叶绿素相对含量的变化,分析了光系统Ⅱ功能的变化规律.结果表明:品种演替过程中旗叶的叶绿素含量逐渐提高,衰老过程中近代品种叶绿素的降解速率低于较早年代品种;旗叶衰老过程中,近代品种荧光诱导动力学曲线的J点上升幅度小于I点;品种更替过程中光系统Ⅱ最大光化学效率和单位面积有活性反应中心数目逐渐增加,但是近代品种降低速率低于较早年代品种.叶绿素含量的变化与未衰老叶片中F_v/F_m没有显著相关性,但是随着衰老程度增加,相关性逐渐增大,且趋势线斜率逐渐提高;光系统Ⅱ单位面积有活性反应中心数目与品种育成时间呈显著正相关,且随着衰老程度增加,相关程度和趋势线斜率均显著提高.综上,小麦品种演替过程中,旗叶叶绿素含量逐渐升高,降解速率逐渐减缓,光合电子传递过程中Q_A到Q_B电子传递的抗衰老能力得到改善,从而减缓了衰老过程中光系统Ⅱ最大光化学效率和有活性反应中心的衰减速率,同时,叶绿素含量的提高和旗叶光系统Ⅱ抗衰老能力的增强也是品种更替过程中产量逐渐提高的重要因素.     

控制水稻叶片叶绿素含量及其离体叶片叶绿素降解速度相关的QTL定位(简报)

许多研究认为,在一定范围内,叶绿素含量与光合速率成正相关关系、叶绿素含量高的水稻叶片能延缓衰老。理论上推算,水稻叶片如果推迟1天衰老,可使水稻增产2％左右,而实际实验结果表明可增产1％左右。叶片早衰往往也是造成有些水稻品种结实率偏低、空秕率较高及产量降低的主要原因。叶片衰老是水稻发育过程中的生命现象,它是水稻在长期进化过程中形成的适应性。叶片衰老的显著特征之一是叶绿素含量下降,叶色褪绿变黄。[第一段]     

晚播小麦叶片衰老代谢和粒重变化的比较研究

对７个小麦品种在晚播条件下的叶片衰老生理特性和粒重变化进行了比较研究。根据小麦叶片的衰老特征相差差异,将７个小麦品种区分为３个类型;后健型、早衰型和中间型。在小麦旗叶的衰老过程中,后健型小麦品种旗叶叶绿素和类胡萝卜素含量显著高于早衰型,脂质过氧化产物ＭＤＡ含量显著低于早衰型,小麦粒重降幅依次为早衰型〉中间型〉后健型,并讨论了活性氧代谢在小麦叶片衰老过程中可能作用。     

水稻叶片衰老过程中氨肽酶活性的变化

水稻叶片中存在着氨肽酶,其最适反应pH和最适反应温度分别为8.2℃和40℃,酶促反应的产物量在最初30min内与时间呈直线相关。 水稻叶片衰老过程中叶绿素和蛋白质含量下降,而氨肽酶比活上升;用植物激素延缓或促进叶片衰老蛋白质降解的同时也抑制或促进了氨肽酶比活的上升,说明氨肽酶在水稻叶片衰老蛋白质降解过程中起一定的作用。根据水稻叶片衰老过程中大分子化合物和叶片外部形态的变化,可将叶片衰老过程划分为缓衰期、急衰期和竭衰期。     

水稻幼苗不同叶位的叶片叶绿素荧光和类胡萝卜素的生物合成对高光胁迫的响应

研究了水稻 (OryzasativaL .)幼苗叶片生长过程中叶绿素荧光和类胡萝卜素各组分含量的变化以及它们对高光胁迫的响应。结果表明 :随着叶片的衰老 ,光合速率、类胡萝卜素不同组分及总的类胡萝卜素含量和叶黄素循环库下降 ;不同叶龄的叶片经高光胁迫后 ,第 5叶 (成熟叶 )qN增加的幅度比第 6叶 (幼嫩叶 )和老叶 (第 3和 4叶 )大 ;与高光胁迫前相比 ,第 3、4、5和 6叶光系统Ⅱ激发压 (1-qP)分别增加了 4 4 %、5 7%、19%和 4 5 % ;第 5叶具有高胡萝卜素含量和高紫黄质到玉米黄质的转化 ,这与其呈现较强的抗高光胁迫相一致。水稻叶片抵御光抑制的能力与类胡萝卜素水平和类胡萝卜素的生物合成能力以及叶片所处的生长时期相关。     

Regulation by kinetin and abcisic acid of correlative senescence in relation to grain maturation,source-sink relationship and yield of rice (Oryza sativa L.)

When kinetin was applied to the source organ (flag leaf) of rice (Oryza sativa L. cv. Ratna), foliar senescence was delayed and grain yield per plant (as evidenced by grain weight, grain/straw weight ratio and 1,000 grain growth) was increased through the increase of sink activity (increase in dry weight of the grains/plant), duration of sink capacity as well as photosynthetic ability of the glumes (as determined by the chlorophyll content of the glumes of the developing grains). However, application of kinetin to the sink organs (fruits), promoted senescence of the source but increased the yield by increasing the sink capacity and 1,000 grain growth mostly at the earlier stage of reproductive development. Lower sterility percentage was associated with higher grain yield of the plant by kinetin treatments. ABA applied either to the source or the sink promoted leaf senescence and reduced the grain yield by reducing the sink activity, harvest index, sink capacity duration and increasing the sterility percentage. Thousand grain dry weight at harvest did not vary significantly amongst the treatments. It was concluded that nutrient drainage was associated with the correlative influence of fruit on the monocarpic senescence of rice plant and that a competetion for differential allocation of cytokinin and ABA in the source and sink organs initiates this senescence syndrome.     

丝氨酸内肽酶在黄瓜叶片衰老中的作用

采用丝氨酸内肽酶抑制剂和植物生长调节剂处理离体黄瓜叶片,研究了黄瓜叶片暗诱导衰老过程中丝氨酸内肽酶的作用。结果表明,6-BA50μmol／L与丝氨酸内肽酶抑制剂AEBSF能抑制叶片内肽酶活性的升高,延缓蛋白质降解,而ABA50μmol/L则促进了内肽酶活性的升高：其作用效果与AEBSF相反。活性电泳结果显示,黄瓜叶片中检测到6条内肽酶同工酶,其中4条（CEP2、3、4、6）为丝氨酸类型内肽酶,而ABA使丝氨酸内肽酶CEP2、3、4、6的活性明显增强,提示了丝氨酸类型内肽酶在黄瓜叶片衰老过程中具有重要作用。     

转ipt和反义ACO基因番茄的叶片衰老相关特性

以ipt和反义ACO转化的两类转基因番茄纯系为材料,研究在植株不同生长发育阶段,不同叶位中,与叶片衰老相关的生理生化指标.结果表明:两类基因导入番茄后,均可增强内源iPA和IAA表达水平,增加或保持番茄叶片的叶绿素含量、提高光合效率,进而明显地延缓植株的叶片衰老,提高单株果实产量.但它们调控叶片衰老的途径不同,ipt主要通过提高CTK的水平延缓叶片衰老,而反义ACO则主要是通过抑制乙烯生成,间接提高IAA的水平来实现.     

Regulation of leaf photosynthetic rate correlating with leaf carbohydrate status and activation state of Rubisco under a variety of photosynthetic source/sink balances

There is evidence suggesting that in plants changes in the photosynthetic source/sink balance are an important factor that regulates leaf photosynthetic rate through affects on the leaf carbohydrate status. However, to resolve the regulatory mechanism of leaf photosynthetic rate associated with photosynthetic source/sink balance, information, particularly on mutual relationships of experimental data that are linked with a variety of photosynthetic source/sink balances, seems to be still limited. Thus, a variety of manipulations altering the plant source/sink ratio were carried out with soybean plants, and the mutual relationships of various characteristics such as leaf photosynthetic rate, carbohydrate content and the source/sink ratio were analyzed in manipulated and non-manipulated control plants. The manipulations were removal of one-half or all pods, removal of one-third or two-third leaves, and shading of one-third or one-half leaves with soybean plants grown for 8 weeks under 10 h light (24 degrees C) and 14 h darkness (17 degrees C). It was shown that there were significant negative correlations between source/sink ratio (dry weight ratio of attached leaves to other all organs) and leaf photosynthetic rate; source/sink ratio and activation ratio (percentage of initial activity to total activity) of Rubisco in leaf extract; leaf carbohydrate (sucrose or starch) content and photosynthetic rate; carbohydrate (sucrose or starch) content and activation ratio of Rubisco; amount of protein-bound ribulose-1,5-bisphosphate (RuBP) in leaf extract and leaf photosynthetic rate; and the amount of protein-bound RuBP and activation ratio of Rubisco. In addition, there were significant positive correlations between source/sink ratio and leaf carbohydrate (sucrose or starch) content; source/sink ratio and the amount of protein-bound RuBP; carbohydrate (sucrose or starch) content and amount of protein-bound RuBP and the activation ratio of Rubisco and leaf photosynthetic rate. The plant water content, leaf chlorophyll and Rubisco contents were not affected significantly by the manipulations. There is a previous report in Arabidopsis thaliana that the amount of protein-bound RuBP in leaf extract correlates negatively with the activation ratio of Rubisco in the leaf extract. Therefore, the results obtained from the manipulation experiments indicate that there is a regulatory mechanism for the leaf photosynthetic rate that correlates negatively with leaf carbohydrate (sucrose and starch) status and positively with the activation state of Rubisco under a variety of photosynthetic source/sink balances.     

光照条件下低温对水稻籼粳亚种幼苗抗氧化物质含量的影响

与对低温不敏感的粳稻台北309和武育粳相比,对低温敏感的籼稻IR64、CA212和Pusa经光照条件下8℃处理后最大光合速率(Pmax)和原初光化学效率(Fv/Fm)下降较多,出现了O2-·、过氧化氢、氧化型谷胱甘肽(GSSG)和氧化型抗坏血酸(DHA)的大量累积,其GSSG和DHA的含量分别与叶绿素含量的下降呈极显著负相关,表明光照条件下低温胁迫下,还原态的谷胱甘肽(GSH)和抗坏血酸的再生受阻,不能有效地清除活性氧,导致其叶绿素含量降低和光合能力受抑,而汕优63的变化位于上述两种类型之间。其中AsA/DHA和GSH/GSSG的变化与叶绿素含量的变化呈极显著正相关。     

Rice tillering dwarf mutant dwarf3 has increased leaf longevity during darkness-induced senescence or hydrogen peroxide-induced cell death

Senescence or cell death in plant leaves is known to be inducible by darkness or H(2)O(2). When the Arabidopsis gene MAX2/ORE9 is disrupted, leaf senescence or cell death in response to the above stimuli is delayed. Because the rice (Oryza sativa L.) gene DWARF3 (D3) is orthologous to MAX2/ORE9, we wished to know whether disruption of D3 also results in increased longevity in leaves. We found that darkness-induced senescence or H(2)O(2)-induced cell death in the third leaf [as measured by chlorophyll degradation, membrane ion leakage and expression of senescence-associated genes (SAGs)] in a d3 rice mutant was delayed by 1-3 d compared to that in its reference line Shiokari. Moreover, the mRNA levels of D3, HTD1 and D10, which are orthologs of Arabidopsis MAX2/ORE9, MAX3 and MAX4, respectively, increased during cell death. These results suggest that D3 protein in rice, like MAX2/ORE9 in Arabidopsis, is involved in leaf senescence or cell death.     

水稻叶片生育过程中RubisCO活性与光合、光呼吸的关系

水稻生育过程中,ＲｕＢＰ羧化酶活性与光合速率、ＲｕＢＰ加氧酶活性与光呼吸速率、ＲｕＢＰ羧化酶活性与加氢酶活性以及光合速率与光呼吸速率之间是相关的。籼型品种与粳型品种间酶活性的高低及光合、光呼吸速率的高低基本一致,籼型三系杂交稻（Ｆ１）无明显的光合优势。酶的羧化活性的高低只在一定范围内与光合速率的高低平行。在正常生育条件下,酶蛋白的数量不是水稻光合速率的限制因子。     

Genotypic variation in source and sink traits affects the response of photosynthesis and growth to elevated atmospheric CO2

This study aimed to understand the response of photosynthesis and growth to e-CO₂ conditions (800 vs. 400 μmol mol⁻¹) of rice genotypes differing in source–sink relationships. A proxy trait called local C source–sink ratio was defined as the ratio of flag leaf area to the number of spikelets on the corresponding panicle, and five genotypes differing in this ratio were grown in a controlled greenhouse. Differential CO₂ resources were applied either during the 2 weeks following heading (EXP1) or during the whole growth cycle (EXP2). Under e-CO₂, low source–sink ratio cultivars (LSS) had greater gains in photosynthesis, and they accumulated less nonstructural carbohydrate in the flag leaf than high source–sink ratio cultivars (HSS). In EXP2, grain yield and biomass gain was also greater in LSS probably caused by their strong sink. Photosynthetic capacity response to e-CO₂ was negatively correlated across genotypes with local C source–sink ratio, a trait highly conserved across environments. HSS were sink-limited under e-CO₂, probably associated with low triose phosphate utilization (TPU) capacity. We suggest that the local C source–sink ratio is a potential target for selecting more CO₂-responsive cultivars, pending validation for a broader genotypic spectrum and for field conditions.     

两个大豆类受体蛋白激酶基因的克隆及其结构和功能的初步分析

利用高等植物类受体蛋白激酶基因的保守域设计简并引物的通过RT-PCR方法,从大豆叶片中克隆到两个新的,可能的类受体蛋白激酶基因的部分cDNA片段。对其基因结构的分析表明：在RLPK2的激酶保守域Vib与Ⅸ之间有一个407bp长的内含子。利用RT-PCR方法对它们的表达特性进行初步研究。发现这两个基因可能参与了对大豆叶片衰老和/或细胞分裂素延缓衰老过程的调节机制。     

Mobilization of metabolites from leaves to grains as the cause of monocarpic senescence in rice

The pattern of senescence was studied by following the changes in chlorophyll and protein in the leaves and by measuring ³²P retention and export from source to sink during development of the rice plant (Oryza sativa L. cv. Jaya) subjected to different manipulative treatments. With the advance of reproductive development, the chronological sequence of leaf senescence was changed, so that the flag and the third leaf senesced earlier than did the second leaf. In presence of the daughter shoot of defruited plants, senescence was delayed in all three leaves of the mother plant, as compared to the same leaves of intact plants. Senescence of all three leaves was further delayed when both panicle and daughter shoots were removed from the plant. The above manipulative treatments caused the initial sequential pattern of senescence of leaves to persist. Removal of both panicle and daughter shoots caused little export of ³²P between leaves. In the presence of daughter shoots of defruited plants, export of ³²P was maximum from leaves of the mother plant to the nearest daughter shoots. This led to earlier senescence of such mother plant leaves than that of plants from which both panicle and daughter shoots were removed. The pattern of senescence and export of ³²P in the flag and the second leaf of the daughter shoot was essentially the same as that of the intact plant. Based on these findings, it was concluded that mobilization of metabolites from source to sink is the primary cause of monocarpic senescence in rice.