Physiological and proteomic analysis of rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) in flag leaf during flowering stage and milk stage under drought stress

Hybrid rice has the inferiority of early senescence during reproductive stage. Early senescence of leaves induced by drought causes a constraint on crop productivity. Hence, to better understand traits of drought responsive mechanism in hybrid rice flag leaves during sensitive reproductive stage, we performed physiological measurements and conducted 2-D electrophoresis to investigate proteomic profile of rice flag leaves at flowering and milk stage. 43 proteins showed significant changes in silver stained gels were identified by MS/MS at flowering stage and 54 proteins at milk stage. For flowering stage, inactive CO₂ assimilation and ATP synthesis as well abnormal floral development could be postulated from decreased proteins. Additionally, higher levels of defense-related proteins and antioxidases in drought-stressed leaves suggested active ROS scavenging system. For milk stage, both photosynthesis and CO₂ assimilation were impaired. Disrupted oxidative defense and proteolysis system indicated redox imbalance. Upregulation of NADP-MDH facilitated for CO₂ assimilation and antioxidant system. In conclusion, drought stress during reproductive stage impacted a lot on biological processes in rice leaves at protein level, especially energy metabolism and redox balance.     

生育前期遮光对水稻灌浆期剑叶生理特性及籽粒生长的影响

通过盆栽试验研究了生育前期（插秧至孕穗期）遮光对水稻分蘖、灌浆期剑叶生理特性、籽粒生长、产量及其构成因素的影响.结果表明：前期遮光使水稻分蘖数明显降低（降低26.72%）,齐穗期与成熟期发生延迟;遮光结束后,水稻灌浆期剑叶叶面积、可溶性糖含量分别比对照增加了33.86%和30.23%;每穗实粒数、千粒重、籽粒终极生长量、最大灌浆速率、平均灌浆速率分别比对照降低了8.65%、4.81%、9.74%、20.22%和19.13%;有效穗数与产量分别降低了25.26%和39.56%,差异显著;灌浆速率峰值的出现时间提前了1.66 d,实际灌浆时间延长了6.80 d.与弱耐荫水稻品种相比,耐荫品种灌浆前中期的剑叶叶绿素a、叶绿素b、叶绿素(a+b)含量增加,灌浆期的剑叶叶面积增加幅度大,蛋白氮、可溶性糖含量及叶绿素 a/b升高,籽粒终极生长量及千粒重接近对照,减产幅度相对较低.     

Comparative proteomic study reveals dynamic proteome changes between superhybrid rice LYP9 and its parents at different developmental stages

Heterosis is a common phenomenon in which the hybrids exhibit superior agronomic performance than either inbred parental lines. Although hybrid rice is one of the most successful apotheoses in crops utilizing heterosis, the molecular mechanisms underlying rice heterosis remain elusive. To gain a better understanding of the molecular mechanisms of rice heterosis, comparative leaf proteomic analysis between a superhybrid rice LYP9 and its parental cultivars 9311 and PA64s at tillering, flowering and grain-filling stages were carried out. A total of 384 differentially expressed proteins (DP) were detected and 297 DP were identified, corresponding to 222 unique proteins. As DP were divided into those between the parents (DP_PP) and between the hybrid and its parents (DP_HP), the comparative results demonstrate that proteins in the categories of photosynthesis, glycolysis, and disease/defense were mainly enriched in DP. Moreover, the number of identified DP_HP involved in photosynthesis, glycolysis, and disease/defense increased at flowering and grain-filling stages as compared to that at the tillering stage. Most of the up-regulated DP_HP involved in the three categories showed greater expression in LYP9 at flowering and grain-filling stages than at the tillering stage. In addition, CO₂ assimilation rate and apparent quantum yield of photosynthesis also showed a greater increase in LYP9 at flowering and grain-filling stages than at the tillering stage. These results suggest that the proteins involved in photosynthesis, glycolysis, and disease/defense as well as their dynamic regulation at different developmental stages may be responsible for heterosis in rice.     

Abscisic acid and cytokinins in the root exudates and leaves and their relationship to senescence and remobilization of carbon reserves in rice subjected to water stress during grain filling

The possible regulation of senescence-initiated remobilization of carbon reserves in rice (Oryza sativa L.) by abscisic acid (ABA) and cytokinins was studied using two rice cultivars with high lodging resistance and slow remobilization. The plants were grown in pots and either well-watered (WW, soil water potential = 0 MPa) or water-stressed (WS, soil water potential = -0.05 MPa) from 9 days after anthesis until they reached maturity. Leaf water potentials of both cultivars markedly decreased at midday as a result of water stress but completely recovered by early morning. Chlorophyll (Chl) and photosynthetic rate (Pr) of the flag leaves declined faster in WS plants than in WW plants, indicating that the water deficit enhanced senescence. Water stress accelerated starch remobilization in the stems, promoted the re-allocation of pre-fixed (14)C from the stems to grains, shortened the grain-filling period and increased the grain-filling rate. Sucrose phosphate synthase (SPS, EC 2.4.1.14) activity was enhanced by water stress and positively correlated with sucrose accumulation in both the stem and leaves. Water stress substantially increased ABA but reduced zeatin (Z) + zeatin riboside (ZR) concentrations in the root exudates and leaves. ABA significantly and negatively, while Z+ZR positively, correlated with Pr and Chl of the flag leaves. ABA, not Z+ZR, was positively and significantly correlated with SPS activity and remobilization of pre-stored carbon. Spraying ABA reduced Chl in the flag leaves, and enhanced SPS activity and remobilization of carbon reserves. Spraying kinetin had the opposite effect. The results suggest that both ABA and cytokinins are involved in controlling plant senescence, and an enhanced carbon remobilization is attributed to an elevated ABA level in rice plants subjected to water stress.     

Differences in Sugar Accumulation and Mobilization between Sequential and Non-Sequential Senescence Wheat Cultivars under Natural and Drought Conditions

Wheat leaf non-sequential senescence at the late grain-filling stage involves the early senescence of younger flag leaves compared to that observed in older second leaves. On the other hand, sequential senescence involves leaf senescence that follows an age-related pattern, in which flag leaves are the latest to undergo senescence. The characteristics of sugar metabolism in two sequential senescence cultivars and two non-sequential senescence cultivars under both natural and drought conditions were studied to elucidate the underlying mechanism of drought tolerance in two different senescence modes. The results showed that compared to sequential senescence wheat cultivars, under natural and drought conditions, non-sequential senescence wheat cultivars showed a higher leaf net photosynthetic rate, higher soluble sugar levels in leaves, leaf sheaths, and internodes, higher leaf sucrose synthase (SS) and sucrose phosphate synthase (SPS) activity, and higher grain SS activity, thereby suggesting that non-sequential senescence wheat cultivars had stronger source activity. Spike weight, grain weight per spike, and 100-grain weight of non-sequential senescence cultivars at maturity were significantly higher than those of sequential senescence cultivars under both natural and drought conditions. These findings indicate that the higher rate of accumulation and the higher mobilization of soluble sugar in the leaves, leaf sheaths and internodes of non-sequential senescence cultivars improve grain weight and drought tolerance. At the late grain-filling stage, drought conditions adversely affected leaf chlorophyll content, net photosynthetic rate, soluble sugar and sucrose content, SS and SPS activity, gain SS activity, and weight. This study showed that higher rates of soluble sugar accumulation in the source was one of the reasons of triggering leaf non-sequential senescence, and higher rates of soluble sugar mobilization during leaf non-sequential senescence promoted high and stable wheat yield and drought tolerance.     

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．     

生育前期遮光对水稻后期功能叶生长及稻米品质的影响

以2个不同直链淀粉含量的水稻品种为材料,研究了生育前期(插秧至幼穗分化期)遮光对水稻后期功能叶生长及稻米品质的影响。结果表明,前期遮光处理后,水稻剑叶面积明显增大,功能叶的碳、氮代谢水平提高;2个品种的籽粒直链淀粉积累过程受到的影响不同,而蛋白质积累受到的影响均一致(即百分含量下降幅度增大);糙米率有所降低,但未达到显著水平;精米率和垩白率极显著下降;整精米率和直链淀粉含量显著或极显著升高;粒长、粒宽和蛋白质含量无显著性变化,但蛋白质含量表现为下降趋势;2个品种间存在着差异。     

追施氮肥时期对冬小麦旗叶叶绿素荧光特性的影响

在大田条件下,研究了不同追氮时期对小麦旗叶叶绿素荧光特性、光合速率及籽粒产量的影响.结果表明,拔节期追肥较起身期或挑旗期追肥,改善了小麦旗叶PSⅡ的活性(F_v/F_o)、光化学最大效率(F_v/F_m)、光化学猝灭系数(qP)、实际量子产量(ΦPSⅡ)及光合速率,降低了籽粒灌浆中前期非辐射能量耗散,有利于叶片所吸收的光能较充分地用于光合作用,提高了籽粒灌浆后期非辐射能量的耗散,减缓了叶片光抑制程度和衰老进程.拔节期追肥可显著增加穗粒数和千粒重,提高产量.     

Regulation of leaf senescence, grain-filling and yield of rice by kinetin and abscisic acid

Senescence of rice ( Oryza sativa L. cv. Jaya) leaves was regulated with kinetin and abscisic acid (ABA) sprays at the reproductive stage. The effect of such sprays on grain-filling and yield was analyzed. Spraying 100-day-old plants with kinetin solution (100 μg ml^-1) significantly delayed senescence as indicated by higher total chlorophyll and protein levels in the three uppermost leaves compared with the controls. In contrast, spraying with ABA (15 μg ml^-1) significantly promoted foliar senescence. The number of spikelets per panicle, number of panicles, percentage filled grains, panicle weight and grain yield per plant and the mobilization and harvest indices were significantly increased by kinetin treatment, while ABA decreased most of them. The possibility of increased grain-filling and thus, yield due to delayed foliar senescence by kinetin treatment and decreased grain-filling due to hastening of senescence by ABA is discussed.     

Influence of reproductive organs on plant senescence in rice and wheat

The chlorophyll and protein contents of the flag, second and third leaves gradually decreased during the reproductive development of rice (Oryza sativa L. cv. Rasi) and wheat (Triticum aestivum L. cv. Sonalika) plants, whereas proline accumulation increased up to the grain maturation stage and slightly decreased thereafter. In rice plant, the rate of decrease in chlorophyll and protein and increase in proline level were higher in the flag leaf than in the second leaf. It was opposite in wheat plant. The export of [³²P]-phosphate from leaves to grains gradually increased reaching a maximal stage at the grain development stage, and then declined. The export of this radioisotope was greater in rice than in wheat. Removal of panicle at the anthesis and grainfilling stages delayed leaf senescence of rice plant, while in wheat the ponicle removal at any stage did not have a marked effect on delaying leaf senescence. The contents of chlorophyll and protein of glumes were higher in wheat than in rice. The variation of such source-sink relationship might be one of the possible reasons for the above effect on leaf senescence.     

Photosynthetic characterization at different senescence stages in an early senescence mutant of rice <Emphasis Type="Italic">Oryza sativa</Emphasis> L.

An early senescence (es) mutant of rice Oryza sativa L. with progressing death of most of leaves before heading stage was identified in the field in Hainan province. After tillering stage, the brown striations were found in the base of green leaves randomly, and then expanded to whole leaves. No fungi, bacteria, and viruses were detected in the brown striations suggesting that it was a genetic mutant. The ultrastructure of leaf cells at the site of brown striations showed breakdown of chloroplast thylakoid membrane structures and other organelles, and condensation of the cytoplasm at severe senescence stage. The photosynthetic activity and chlorophyll (Chl) contents decreased irreversibly along with leaf senescence process.     

Mechanism of monocarpic senescence in rice

During grain formation stage (90 to 110 days), the youngest flag leaf of rice (Oryza sativa L. cv. Jaya) remained metabolically most active (as indicated by cellular constituents and enzyme activities) and the third leaf the least active. At the grain development stage (110 to 120 days) the above pattern of age-related senescence of the flag leaf completely changed and it senesced at a faster rate than the second leaf which remained metabolically active even up to grain maturation time (120 to 130 days), when both the flag and the third leaf partially senesced. Removal of any leaf temporarily arrested senescence of the remaining attached leaves, that of flag leaf did not hasten senescence of the second leaf, while that of either the second or the third accelerated senescence of the flag. Removal of the inflorescence after emergence or foliar treatment of intact plant with kinetin equally delayed senescence and produced an age-related, sequential mode of senescence or leaves. Both translocation and retention of ³²P by the flag leaf were maximum at the time of grain formation and that by the second leaf was maintained even up to grain maturation time. The induction of senescence of the flag leaf was preceded by a plentiful transport of ³²P to the grains. Kinetin treatment decreased the transport of ³²P, prolonged its duration, and almost equally involved all of the leaves in this process. The pattern of senescence of isolated leaf tips was similar to that of attached leaves. The level of endogenous abscisic acid-like substance(s) maintained a close linearity with the senescence behavior of the leaves of intact and defruited plants during aging, and the rise in abscisic acid in the flag leaf was also preceded by higher ³²P transport to the grains.