外源油菜素内酯缓解水稻穗分化期高温伤害的机理研究

【目的】明确水稻穗分化期高温下喷施2,4-表油菜素内酯(2,4-epibrassinolide, EBR)对穗生长及颖花形成的影响,并探究其生理机制。【方法】以热敏感型水稻IR36为材料,在幼穗分化期设置40℃高温和32℃适温两个处理,并喷施EBR,研究幼穗碳水化合物供应、蔗糖代谢、细胞分裂素代谢及抗氧化能力的变化。【结果】1)高温和适温喷施EBR,水稻每穗粒数分别比不喷施的对照增加13.7%和45.7%,其中以喷施0.15 mg/L效果最好,缓解了高温对水稻幼穗生长的抑制,增加颖花分化数和降低颖花退化率。2)喷施EBR对叶片净光合速率无显著影响,但促进幼穗中干物质和非结构性碳水化合物积累。EBR喷施增加高温下幼穗中蔗糖转运基因OsSUT1、OsSUT2和OsSUT4的表达,并显著提高蔗糖代谢相关酶活性,EBR对高温下碳水化合物利用的促进作用大于适温处理。3)喷施EBR降低高温下细胞分裂素氧化酶基因OsCKX5和OsCKX9的表达量,同时促进细胞分裂素合成和信号调节相关基因的表达,并在适温下也表现出类似的效应。4)喷施EBR降低高温下超氧阴离子含量,增强了超氧化物歧化酶、过氧化氢酶和过氧化物酶活性。【结论】高温下,喷施适宜浓度的EBR促进碳水化合物向幼穗的转运,抑制细胞分裂素分解,同时降低高温引起的过氧化伤害,进而缓解了高温对颖花形成的伤害。适温条件喷施EBR也对颖花形成具有一定的促进作用。     

外源油菜素内酯缓解水稻穗分化期高温伤害的机理研究

【目的】明确水稻穗分化期高温下喷施2,4-表油菜素内酯(2,4-epibrassinolide, EBR)对穗生长及颖花形成的影响,并探究其生理机制。【方法】以热敏感型水稻IR36为材料,在幼穗分化期设置40℃高温和32℃适温两个处理,并喷施EBR,研究幼穗碳水化合物供应、蔗糖代谢、细胞分裂素代谢及抗氧化能力的变化。【结果】1)高温和适温喷施EBR,水稻每穗粒数分别比不喷施的对照增加13.7%和45.7%,其中以喷施0.15 mg/L效果最好,缓解了高温对水稻幼穗生长的抑制,增加颖花分化数和降低颖花退化率。2)喷施EBR对叶片净光合速率无显著影响,但促进幼穗中干物质和非结构性碳水化合物积累。EBR喷施增加高温下幼穗中蔗糖转运基因OsSUT1、OsSUT2和OsSUT4的表达,并显著提高蔗糖代谢相关酶活性,EBR对高温下碳水化合物利用的促进作用大于适温处理。3)喷施EBR降低高温下细胞分裂素氧化酶基因OsCKX5和OsCKX9的表达量,同时促进细胞分裂素合成和信号调节相关基因的表达,并在适温下也表现出类似的效应。4)喷施EBR降低高温下超氧阴离子含量,增强了超氧化物歧化酶、过氧化氢酶和过氧化物酶活性。【结论】高温下,喷施适宜浓度的EBR促进碳水化合物向幼穗的转运,抑制细胞分裂素分解,同时降低高温引起的过氧化伤害,进而缓解了高温对颖花形成的伤害。适温条件喷施EBR也对颖花形成具有一定的促进作用。     

水稻分蘖期干旱锻炼对幼穗分化期高温下穗发育和产量形成的影响

【目的】明确分蘖期干旱锻炼对幼穗分化期高温下水稻穗发育和产量形成的影响,并探究其生理机理。【方法】以两优培九(热敏感型)和汕优63(耐热型)为材料,在盆栽条件下设置全生育期淹灌和分蘖期干旱锻炼、幼穗分化期适温和高温共四种水分和温度处理组合,研究干旱锻炼对高温胁迫下水稻颖花分化与退化、花粉活力、颖花育性、颖花大小、产量及穗生理特性的影响。【结果】与淹灌相比,在适温下干旱锻炼对两个品种产量无显著影响,但高温下干旱锻炼后两优培九和汕优63的产量分别显著提高了54.0%和20.1%,这主要是因为结实率和千粒重显著提高。与淹灌相比,幼穗分化期高温下,分蘖期干旱锻炼显著增强两优培九颖花过氧化物酶和超氧化物歧化酶活性,降低了丙二醛含量,其花粉活力和颖花育性分别显著提高了26.0%和39.0%。与适温相比,全生育期淹灌下,高温显著降低了两个品种的颖花大小和总颖花分化数。与淹灌相比,分蘖期干旱锻炼显著提高了幼穗分化期高温下两品种穗非结构性碳水化合物含量和颖花细胞分裂素(反式玉米素+反式玉米素核苷)含量,两个品种颖花长、颖花宽和总颖花分化数平均显著增加了3.2%、4.4%和15.0%。【结论】分蘖期干旱锻...     

灌浆期高温下外源喷施2,4-表油菜素内酯对浙禾香2号产量及品质的影响

为明确水稻灌浆期高温下喷施2,4-表油菜素内酯（2,4-epibrassinolide, EBR）对水稻产量构成因素及品质的影响，以优质稻品种浙禾香2号为试验材料，在灌浆期进行15 d高温（HT）和适温（NT）处理，同时喷施浓度为0.15 mg/L的EBR和相同浓度的油菜素内酯合成抑制剂油菜素唑（Brassinozole, BRZ），以喷施相同量的清水为对照。结果表明，灌浆期高温处理显著降低浙禾香2号的结实率，但对粒重的影响较小;高温处理降低稻米的加工品质、外观品质和食味品质;高温下外源喷施EBR能够显著提高浙禾香2号的产量、糙米率和整精米率，显著降低垩白粒率、垩白度和蛋白质含量。试验结果为进一步明确EBR缓解水稻高温热害的效应提供理论基础。     

2,4-表油菜素内酯缓解水稻花期高温胁迫的生理机制

为探究喷施2,4-表油菜素内酯(EBR)在水稻开花期缓解高温胁迫的作用,研究分析了在高温胁迫下喷施EBR对水稻产量构成因素、花粉活力、抗氧化酶活性以及内源激素的影响。结果表明,水稻花期受高温胁迫后,结实率、花药开裂率以及穗子花粉活力明显降低,而喷施EBR后水稻的结实率、花药开裂分别提高24.09%、55.4%,且穗中部和下部花粉活力提高了8.64%和24.2%。在高温胁迫下,SOD、POD、CAT活性显著降低,脯氨酸和可溶性糖含量减少,喷施EBR后SOD酶活性提高51.76%,脯氨酸和可溶性糖含量分别增加8.23%和11.02%,但对POD和CAT酶活性无显著影响。此外,高温胁迫下,内源激素ABA含量上升,GA含量降低,而喷施EBR后ABA含量提高4.78%,GA含量降低18.81%。表明喷施EBR可以通过调节水稻内源激素的变化缓解高温伤害。     

水稻幼穗响应稻曲病菌毒素胁迫早期的转录组分析

【目的】由稻曲病菌引起的稻曲病不仅造成水稻减产,而且还会产生对动物和植物有毒的真菌毒素。探明水稻幼穗对稻曲病菌毒素胁迫响应的分子机制,可为发掘水稻抗稻曲病基因以及抗病分子育种开辟新的思路。【方法】用稻曲病菌毒素处理水稻幼穗,采用转录组测序技术对水稻幼穗进行转录组测序,以水稻9311基因组作为参考基因组进行对比,利用TPM法计算基因表达量,设定参数（差异倍数的绝对值不小于2,且q值不大于0.05）筛选差异表达基因。结合基因差异表达分析、富集功能分析,鉴定水稻响应胁迫的关键基因,并利用实时荧光定量PCR技术对差异表达基因进行验证。【结果】在稻曲病菌毒素胁迫12 h后,水稻幼穗出现2526个差异表达基因（DEG）;通过GO富集、KEGG代谢途经和KOG功能分析,将差异基因划分为GO功能下的64个条目、32个代谢途径和KOG功能下23个类别,包括淀粉和蔗糖代谢、苯丙类生物合成、碳代谢、糖酵解/糖异生、氨基糖和核苷酸糖代谢等生物学过程。DEG中有66个植物转录因子,分属7种植物转录因子家族,包括WRKY和Myb两大转录因子。分析二萜类生物合成与淀粉和蔗糖代谢途径相关基因发现,OsCPS2、OsKSL4和细胞色素P450等基因表达量上调,而淀粉酶、β-呋喃果糖苷酶和UDP-焦磷酸化酶等基因表达量下调,推测这些基因在水稻响应稻曲病菌毒素胁迫时发挥重要的作用。【结论】稻曲病菌毒素作为非生物胁迫因素对水稻幼穗具有毒性;通过干扰淀粉和蔗糖代谢等途径而影响种子营养物质的合成,降低水稻抵抗病原菌侵染水稻的能力。     

水稻器官形态和干物质积累对穗分化不同时期高温的响应

为明确水稻穗分化期高温对生长发育所造成的影响,以耐热籼稻黄华占和热敏感籼稻丰两优6号为材料,利用人工气候箱在穗分化期进行40℃(10:00-15:00)高温处理,以人工气候箱32℃适温处理为参考,室外环境温度为对照(CK),研究枝梗-颖花分化期(Ⅰ期)和花粉母细胞形成-减数分裂期(Ⅱ期)高温胁迫对水稻器官形态及干物质积累的影响。结果表明:1)Ⅰ期高温抑制幼穗分化,使穗分化期延长2.5~8.8 d;Ⅱ期高温阻碍水稻抽穗,导致穗分化期延长6.8~7.1 d,显著缩短上部茎节,降低抽穗度,其中热敏感品种降幅大于耐热品种;2)穗分化期高温处理显著降低每穗颖花数和颖花大小,颖花数下降原因在不同处理时期间存在差异,Ⅰ期高温减少颖花分化数;而Ⅱ期高温显著加速颖花退化,两个品种退化幅度均达50%以上,并显著降低了花药大小和颖花受精率,热敏感品种丰两优6号受高温影响要大于耐热品种;3)高温对叶片生长有促进作用,Ⅱ期高温处理表现尤为明显,两个时期高温处理对上3叶净光合速率和水稻单茎干物质积累没有显著影响。Ⅰ期高温不同部位间干物质积累无显著差异,而Ⅱ期高温显著降低茎鞘和穗部干物质积累,但高温导致高节位分枝发生,积累了一部分干物质,整体上单茎干物质积累量并没有显著下降。     

不同氮利用率粳稻品种的碳氮积累与转运特征及其生理机制

【目的】探明不同氮利用率水稻品种的氮素积累与转运特征及其机制。【方法】2个氮高效品种(武运粳30号和连粳7号)和2个氮低效品种(扬粳4038和宁粳1号)种植于大田,设置2个施氮量：全生育期不施氮(0 N)和全生育期施氮180 kg/hm² (180N),比较分析了不同氮利用率粳稻品种干物质生产、氮素积累与转运差异及其机制。【结果】与氮低效品种相比,氮高效品种具有较高的产量、氮肥利用率、总颖花量和结实率,较高的花前干物质转运量和花后干物质积累量,分蘖至穗分化始期和抽穗至成熟期较高的净同化率和作物生长率,抽穗期较高的糖花比,灌浆期较高的籽粒库活性、籽粒中脱落酸与1-氨基环丙烷-1-羧酸含量的比值和茎鞘中较高的非结构性碳水化合物的转运和蔗糖合成相关酶活性以及蔗糖转运蛋白基因的表达量,抽穗后较高的氮转运、氮素吸收量,灌浆期较高的比叶氮含量、叶片中细胞分裂素含量、氮代谢酶活性以及氮素转运相关基因的表达量。【结论】氮高效品种穗分化前和抽穗后较高的物质生产效率以及灌浆期较高的碳氮转运与积累是产量和氮肥利用率协同提高的重要机制。     

水杨酸减轻高温抑制水稻颖花分化的作用机理研究

水稻颖花原基分化期高温可抑制颖花分化,导致每穗粒数下降,最终会影响水稻产量的形成。以杂交稻甬优12为材料,探讨高温下不同浓度水杨酸(salicylic acid, SA)对水稻颖花分化的影响,并揭示其作用机制。研究表明,常温下适量SA促进水稻颖花分化,但高浓度SA严重降低每穗粒数。然而高温下,10~50000 μmol/L SA处理每穗粒数均高于对照。无论常温或高温,100 μmol/L水杨酸处理效果最好,其每穗粒数及产量均显著高于对照。SA增强水稻耐热性表现在三个方面:1)高温下SA处理的叶片实际荧光量子效率及净光合速率均高于对照;2)高温下SA处理的颖花SOD、POD及CAT活性显著高于对照,而MDA含量则显著低于对照;3)无论高温或常温,SA处理的颖花ZR及IAA含量均高于对照,尤其在高温下,差异达显著水平。     

干湿交替灌溉对抗旱性不同水稻品种产量的影响及其生理原因分析

【目的】旨在阐明全生育期干湿交替灌溉对抗旱性不同水稻品种产量的影响。【方法】以抗旱性差异显著的4个水稻品种(籼稻扬稻6号和两优培九,粳稻旱优8号和镇稻88)为材料,以常规水层灌溉(CI)为对照,在盆栽条件下研究了轻干湿交替灌溉(WMD)和重干湿交替灌溉(WSD)对水稻产量、根系、叶片及籽粒部分生理特性的影响。【结果】与CI相比,WMD处理下抗旱性较强品种扬稻6号和旱优8号产量分别提高6.90%和7.45%,抗旱性较弱品种两优培九和镇稻88产量分别降低7.28%和8.10%。WSD处理下,4个水稻品种的产量均显著下降,抗旱性较弱的品种产量降幅远高于抗旱性较强的水稻品种。WMD处理下,扬稻6号和旱优8号复水后根系氧化力、根系与叶片细胞分裂素(玉米素+玉米素核苷)含量、叶片光合速率和籽粒中蔗糖-淀粉代谢途径关键酶的活性均较CI有不同程度提高,而两优培九和镇稻88上述指标则与CI持平或有不同程度降低。WSD处理下,4个品种上述指标均较CI不同程度降低。【结论】轻干湿交替灌溉条件下,根系活性强、叶片细胞分裂素含量和光合速率高、籽粒中蔗糖-淀粉代谢途径关键酶活性强是抗旱性较强水稻品种的基本生理特征。     

Brassinosteroids Mediate Endogenous Phytohormone Metabolism to Alleviate High Temperature Injury at Panicle Initiation Stage in Rice

High temperatures cause physiological and biochemical changes and significantly affect young panicle development of rice (Oryza sativa L.). Brassinosteroids play important roles in enhancing crop stress resistance. In this study, we subjected rice cultivars Huanghuazhan (heat-resistant) and IR36 (heat-sensitive) to high temperature (HT, 40 ºC) or normal temperature (NT, 33 ºC) for 7 d at the panicle initiation stage, in conjunction with application of 24-epibrassinolide [EBR, a synthetic brassinolide (BR)] or brassinazole (BRZ, a BR biosynthesis inhibitor) at the beginning of the treatments. HT exacerbated spikelet degeneration and inhibited young panicle growth, which were partially prevented by EBR application, while BRZ application aggravated the reduction in spikelet number. HT decreased the contents of BR, active cytokinins (aCTK), active gibberellins (aGA) and indole-3-acetic acid (IAA), but increased the content of abscisic acid (ABA) in young panicles. The activities of key enzymes involved in sucrose hydrolysis, glycolysis and the tricarboxylic acid cycle in young panicles were decreased with the change of endogenous hormone levels under HT. In addition, the contents of H₂O₂ and malondialdehyde (MDA) were increased and the activities of antioxidant enzymes were decreased in young panicles. Exogenous application of EBR induced the expression of phytohormone biosynthesis-related genes and down-regulated the expression of phytohormone catabolism-related genes to increase the contents of endogenous BR, aCTK, aGA and ABA, thus promoting the decomposition and utilization of sucrose in young panicles, enhancing the activities of superoxide dismutase, catalase and peroxidase, and reducing the accumulation of H₂O₂ and MDA in young panicles, whereas application of BRZ had the opposite physiological effects. These results showed that brassinosteroids mediate endogenous phytohormone metabolism to alleviate HT injury at the panicle initiation stage in rice.     

Decrement of Sugar Consumption in Rice Young Panicle Under High Temperature Aggravates Spikelet Number Reduction

Two rice genotypes Huanghuazhan(HHZ, heat-resistant) and IR36(heat-susceptible) were subjected to high-temperature(HT, 40 oC) and normal-temperature(NT, 32 oC) treatments at the spikelet differentiation stage. HT treatment inhibited spikelet differentiation, aggravated spikelet degeneration, reduced spikelet size, and disordered carbohydrate allocation. Meanwhile, HT treatment increased nonstructural carbohydrate content in leaves, but decreased that in stems and young panicles, and the same tendencies of sucrose and starch contents were observed in leaves and stem. However, HT treatment significantly increased the sucrose content and sharply decreased the glucose and fructose contents in young panicles. Lower activity levels of soluble acid invertase(EC3.2.1.26) and sucrose synthase(EC2.4.1.13) were observed under HT treatment. Moreover, HT treatment reduced the activities of key enzymes associated with glycolysis and the tricarboxylic acid cycle, which indicated sucrose consumption was inhibited in young panicles under HT treatment. Exogenous glucose and fructose applied under HT treatment increased the spikelet number more than exogenous sucrose. In conclusion, the results demonstrated that the reduction of spikelet number under high temperature was more affected by the decrease in sugar consumption than the blocking of sucrose transport. The impairment of sucrose hydrolysis was the main reason for the inhibition of sugar utilization.     

Response of Rice Starch Synthesis to Night Temperature Changes

【Objective】To clarify the effect of night temperature changes on rice starch accumulation, and to explore circadian changes of physiological characteristics of rice amylose/amylopectin formation at various night temperatures.【Method】High-quality japonica rice ‘Zhehexiang 2’ was subjected to three night temperature gradients of 31℃/20℃ (LT), 31℃/24℃ (NT), and 31℃/28℃ (HT) at the beginning of grain ripening stage, and the amylose and amylopectin contents, the key enzyme activities involved in amylose and amylopectin formation and the expression of related genes were measured at noon and midnight. 【Result】 The results showed that 1) compared with NT, LT and HT treatments significantly reduced grain weight and starch accumulation, LT and HT both reduced amylopectin content and increased amylose content, meanwhile the effect of HT was greater than LT. LT and HT treatments decreased grain pasting temperature and gel consistency, and had a significant influence on branched chain length. 2) The net photosynthetic rate of leaves under LT and HT presented no significant difference compared to NT, but LT and HT significantly reduced the accumulation of non-structural carbohydrates, meanwhile down-regulated the expression level of sucrose transporter genes OsSUT1, OsSUT2, and OsSUT4 both at noon and midnight. 3) LT and HT treatment reduced sucrose hydrolysis-related enzyme activities, meanwhile promoted starch hydrolase activities, resulting in increased soluble sugar contents, sugar utilization in grain was blocked. 4) Compared with NT, the adenosine diphosphate glucose content showed a downward tendency during the day and a rising trend at night under the treatment of LT and HT, which presented that the accumulation and utilization of adenosine diphosphate glucose were inhibited. And the granules bound starch synthetase activity were significantly reduced under LT and HT compared to NT with the prolongation of the treatment, and the enzyme activity at daytime was significantly influenced by temperature changing at night. 5) Compared with NT, LT and HT reduced the activities of night-time amylopectin synthesis-related enzymes and inhibited the expression of night-time related genes, which retarded formation of amylopectin, but the enzyme activities related to amylopectin synthesis was not significantly influenced by night temperature changing. 【Conclusion】High night temperature had a less effect on starch accumulation than low night temperature. High or low night temperature inhibited sucrose transport and metabolism, resulting in declined starch accumulation. The retarding of amylopectin formation was the main reason for the increase of relative content of amylose at high or low night temperature. Night temperature changes directly affected the metabolic process of starch formation at night, but the daytime activities of amylose-related enzymes were affected by night temperature changes, while the daytime activities of amylopectin-related enzymes were not significantly affected by night temperature changes.     

水稻淀粉合成对夜温变化的响应

目的 探究夜温变化对水稻淀粉形成的影响及其生理机制【方法】以优质软米浙禾香2号为材料,在灌浆初期设置31℃/20℃ (LT)、31℃/24℃ (NT)、31℃/28℃ (HT)3个夜间温度模式,测定其直链淀粉和支链淀粉含量及合成关键酶活性及相关基因的表达。结果 1)与NT相比,LT和HT处理显著降低粒重和淀粉积累,降低糊化温度和胶稠度,并影响支链淀粉链长,降低支链淀粉含量,提高直链淀粉含量,HT的影响要大于LT;2) LT和HT处理对白天叶片净光合速率的影响不显著,但显著降低籽粒中非结构性碳水化合物积累,抑制蔗糖转运基因OsSUT1、OsSUT2和OsSUT4在夜间和白天表达;3) LT 和HT处理降低夜间和白天蔗糖水解相关酶活性,增加淀粉水解酶活性,导致可溶性糖含量升高,籽粒中糖利用受阻;4)与NT相比,LT和HT处理下腺苷二磷酸葡萄糖含量呈现白天降低而夜晚升高的趋势,腺苷二磷酸葡萄糖积累及利用受到抑制,颗粒结合淀粉合酶活性随处理时间延长而显著降低,且白天酶活性也受夜间温度的影响;5)与NT相比,LT和HT处理降低了夜间支链淀粉合成相关酶活性,抑制了夜间相关基因的表达,导致支链淀粉合成受阻,但对白天酶活及相关基因表达的影响不大。结论 夜间高温对淀粉积累的影响要大于夜温降低,夜间高温/低温抑制全天蔗糖转运及代谢,进而抑制淀粉积累;支链淀粉合成受阻是导致直链淀粉相对含量升高的主要原因,直链淀粉合成相关酶活性(白天)受夜温变化影响,而支链淀粉合成相关酶活性(白天)受夜温变化的影响不显著。     

水稻蔗糖转运蛋白OsSUT4参与蔗糖转运的功能研究

目的植物蔗糖的跨膜运输主要借助蔗糖转运蛋白（sucrose transporter,SUT）进行。在已鉴定出的5个水稻SUT编码基因中,OsSUT4的作用尚不清楚。方法采用CRISPR/Cas9基因编辑技术构建ossut4缺失变体,出现株高降低、分蘖数增加及产量下降等表型。结果通过进一步分析,发现ossut4突变体水稻叶片蔗糖、淀粉积累,反馈抑制光合速率;因源端光合同化物装载受阻,导致库端籽粒蔗糖供应不足,灌浆延迟。对OsSUT4进行亚细胞和组织化学定位,发现OsSUT4在细胞质膜上,且在萌发种子的胚、胚芽鞘的维管束、小穗颖壳、花药、颖果的糊粉层中都有表达,该现象表明OsSUT4具备转运蔗糖的特征。结论综上所述,OsSUT4在水稻蔗糖源端装载以及籽粒库端卸载等生理过程发挥重要作用。     

Function Analysis of Sucrose Transporter OsSUT4 in Sucrose Transport in Rice

【Objective】The transmembrane transport of sucrose is mainly mediated by sucrose transporters, among which five SUT coding genes have been identified in rice. However, the role of OsSUT4 in the sucrose transport is unclear. 【Method】CRISPR/Cas9 techniques were used to construct ossut4-deleted mutants. The ossut4 mutant was featured by lower plant height and grain yield as well as higher tiller number as compared with wild type plants.【Result】Sucrose and starch accumulation in the leaf of the ossut4 mutants lead to slower net photosynthetic rate; insufficient sugar supply results in the postpone of grain filling. Base on the subcellular and histochemical localization, OsSUT4 was located on the cytoplasmic membrane. Tissue localization showed that OsSUT4 was expressed in the embryo of germinating seed, vascular bundles of coleoptile, glume shell, anthers at flowering stage and aleurone layer of caryopsis at filling stage. 【Conclusion】OsSUT4 plays an important role in sucrose transport.     

超表达蔗糖转运蛋白基因OsSUT1对水稻形态和生理的影响

目的 磷对植物细胞内蔗糖和淀粉合成有重要影响,它们之间的关系还有许多方面有待阐明。方法 本研究利用转基因技术获得OsSUT1超表达材料,通过水培和盆栽实验研究了超表达该基因对蔗糖、磷含量以及植株形态和生理性状的影响。结果 转录水平上的表达分析显示,缺磷诱导OsSUT1在水稻根系中表达。水培实验显示,与野生型相比,正常供磷条件下OsSUT1超表达导致水稻植株地上部蔗糖含量下降,同时水稻植株内的磷含量升高;而在缺磷条件下植株体内蔗糖及磷含量均无显著变化。盆栽实验显示,超表达OsSUT1提高了水稻的分蘖数、有效分蘖数、磷含量、粒长和粒宽。结论 这些结果说明OsSUT1对水稻的蔗糖和磷含量以及种子的生长发育有重要作用。     

水稻白化转绿和穗顶端退化突变体vpa1的遗传分析和基因定位

目的 通过对水稻转绿和穗顶端退化等突变体的研究,可以鉴定更多与叶绿体发育和穗发育相关的基因。方法 在常规种植条件下比较突变体vpa1（virescent and panicle abortion 1)表型及主要农艺性状差异,利用分离群体分析和图位克隆法进行相关基因定位。结果 突变体vpa1表现苗期白化,并逐渐转绿恢复成正常叶色,抽穗后可明显观查到穗顶端退化表型。vpa1的主要农艺性状除了结实率以外,株高、穗长、每穗实粒数等均较野生型显著下降。遗传分析表明白化转绿和穗顶端退化表型受独立的两个隐性基因控制。控制白化转绿叶性状的Osv16定位于第3染色体RM3441和RM3029之间约125kb物理区间内,区间内未见白化转绿性状相关基因的报道。控制穗顶端退化性状的Ospaa10定位于第1染色体RM11157和RM5972之间,区间内物理距离约190kb,区间内未见穗顶端退化相关基因的报道。结论 Osv16和Ospaa10两个基因的突变导致vpa1的叶色和穗型同时出现变异,为白化转绿基因Osv16和穗顶端退化基因Ospaa10的克隆和功能研究打下了基础。