Irrigation regimes modulate non-structural carbohydrate remobilization and improve grain filling in rice(Oryza sativa L.)by regulating starch metabolism

Recently developed ‘super’ rice cultivars with greater yield potentials often suffer from the problem of poor grain filling, especially in inferior spikelets. Here, we studied the activities of enzymes related to starch metabolism in rice stems and grains, and the microstructures related to carbohydrate accumulation and transportation to investigate the effects of different water regimes on grain filling. Two ‘super’ rice cultivars were grown under two irrigation regimes of well-watered(WW) and alternate wetting and moderate soil drying(AWMD). Compared with the WW treatment,the activities of ADP glucose pyrophosphorylase(AGPase), starch synthase(StSase) and starch branching enzyme(SBE), and the accumulation of non-structural carbohydrates(NSCs) in the stems before heading were significantly improved, and more starch granules were stored in the stems in the AWMD treatment. After heading, the activities of α-amylase, β-amylase, sucrose phosphate synthase(SPS) and sucrose synthase in the synthetic direction(SSs)were increased in the stems to promote the remobilization of NSCs for grain filling under AWMD. During grain filling, the enzymatic activities of sucrose synthase in the cleavage direction(SSc), AGPase, StSase and SBE in the inferior spikelets were increased, which promoted grain filling, especially for the inferior spikelets under AWMD.However, there were no significant differences in vascular microstructures. The grain yield and grain weight could be improved by 13.1 and 7.5%, respectively, by optimizing of the irrigation regime. We concluded that the low activities of key enzymes in carbon metabolism is the key limitation for the poor grain filling, as opposed to the vascular microstructures, and AWMD can increase the amount of NSC accumulation in the stems before heading, improve the utilization rate of NSCs after heading, and increase the grain filling, especially in the inferior spikelets, by altering the activities of key enzymes in carbon metabolism.

The auxin transporter OsAUX1 regulates tillering in rice(Oryza sativa)

Tillering is an important agronomic trait of rice(Oryza sativa)that affects the number of effective panicles,thereby affecting yields.The phytohormone auxin plays a key role in tillering.Here we identified the high tillering and semi-dwarf 1(htsd1)mutant with auxin-deficiency root characteristics,such as shortened lateral roots,reduced lateral root density,and enlarged root angles.htsd1 showed reduced sensitivity to auxin,but the external application of indole-3-acetic acid(IAA)inhibited its tillering.We identified the mutated gene in htsd1 as AUXIN1(OsAUX1,LOC_Os01g63770),which encodes an auxin influx transporter.The promoter sequence of OsAUX1 contains many SQUAMOSA PROMOTER BINDING PROTEIN-LIKE(SPL)binding sites,and we demonstrated that SPL7 binds to the OsAUX1 promoter.TEOSINTE BRANCHED1(OsTB1),a key gene that negatively regulates tillering,was significantly downregulated in htsd1.Tillering was enhanced in the OsTB1 knockout mutant,and the external application of IAA inhibited tiller elongation in this mutant.Overexpressing OsTB1 restored the multi-tiller phenotype of htsd1.These results suggest that SPL7 directly binds to the OsAUX1 promoter and regulates tillering in rice by altering OsTB1 expression to modulate auxin signaling.

DDG1 and G Protein α Subunit RGA1 Interaction Regulates Plant Height and Senescence in Rice(Oryza sativa)

Many studies have already shown that dwarfism and moderate delayed leaf senescence positively impact rice yield,but the underlying molecular mechanism of dwarfism and leaf senescence remains largely unknown.Here,using map-based cloning,we identified an allele of DEP2,DDG1,which controls plant height and leaf senescence in rice.The ddg1 mutant displayed dwarfism,short panicles,and delayed leaf senescence.Compared with the wild-type,ddg1 was insensitive to exogenous gibberellins(GA)and brassinolide(BR).DDG1 is expressed in various organs,especially in stems and panicles.Yeast two-hybrid assay,bimolecular fluorescent complementation and luciferase complementation image assay showed that DDG1 interacts with theα-subunit of the heterotrimeric G protein.Disruption of RGA1 resulted in dwarfism,short panicles,and darker-green leaves.Furthermore,we found that ddg1 and the RGA1 mutant was more sensitive to salt treatment,suggesting that DDG1 and RGA1 are involved in regulating salt stress response in rice.Our results show that DDG1/DEP2 regulates plant height and leaf senescence through interacting with RGA1.

Conventional Breeding and Molecular Markers for Blast Disease Resistance in Rice (Oryza sativa L.)

Monogenic lines,which carried 23 genes for blast resistance were tested and used donors to transfer resistance genes by crossing method.The results under blast nursery revealed that 9 genes from 23 genes were susceptible to highly susceptible under the three locations(Sakha,Gemmeza,and Zarzoura in Egypt);Pia,Pik,Pik-p,Piz-t,Pita,Pi b,Pi,Pi 19 and Pi 20.While,the genes Pii,Pik-s,Pik-h,Pi z,Piz-5,Pi sh,Pi 3,Pi 1,Pi 5,Pi 7,Pi 9,Pi 12,Pikm and Pita-2 were highly resistant at the same locations.Clustering analysis confirmed the results,which divided into two groups;the first one included all the susceptible genes,while the second one included the resistance genes.In the greenhouse test,the reaction pattern of five races produced 100%resistance under artificial inoculation with eight genes showing complete resistance to all isolates.The completely resistant genes:Pii,Pik-s,Piz,Piz-5(=bi2)(t),Pita(=Pi4)(t),Pita,Pi b and Pi1 as well as clustering analysis confirmed the results.In the F1 crosses,the results showed all the 25 crosses were resistant for leaf blast disease under field conditions.While,the results in F2 population showed seven crosses with segregation ratio of 15(R):1(S),two cross gave segregated ratio of 3 R:1 S and one gave 13:3.For the identification of blast resistance genes in the parental lines,the marker K3959,linked to Pik-s gene and the variety IRBLKS-F5 carry this gene,which was from the monogenic line.The results showed that four genotypes;Sakha 105,Sakha 103,Sakha 106 and IRBLKS-F5 were carrying Pik-s gene,while was absent in the Sakha 101,Sakha 104,IRBL5-M,IRBL9-W,IRBLTACP1 and IRBL9-W(R)genotypes.As for Pi 5 gene,the results showed that it was present in Sakha 103 and Sakha 104 varieties and absent in the rest of the genotypes.In addition,Pita-Pita-2 gene was found in the three Egyptian genotypes(Sakha 105,Sakha 101 and Sakha 104)plus IRBLTACP1 monogenetic.In F2 generation,six populations were used to study the inheritance of blast resistance and specific primers to confirm the ratio and identify the resistance genes.However,the ratios in molecular markers were the same of the ratio under field evaluation in the most population studies.These findings would facilitate in breeding programs for gene pyramiding and gene accumulation to produce durable resistance for blast using those genotypes.

A Farmer’s Approach to Detecting Photoperiod Sensitivity in Rice (Oryza sativa ssp. indica) Landraces

Most indigenous rice landraces are sensitive to photoperiod during short day seasons,and this sensitivity is more pronounced in indica than in japonica landraces.Attempts to identify photoperiod sensitive(PPS)cultivars based on the life history stages of the rice plant,and several models and indices based on phenology and day length have not been precise,and in some cases yield counterfactual inferences.Following the empirical method of traditional Asian rice farmers,the author has developed a robust index,based on the sowing and flowering dates of a large number of landraces grown in different seasons from 2020 to 2023,to contradistinguish PPS from photoperiod insensitive cultivars.Unlike other indices and models of photoperiod sensitivity,the index does not require the presumed duration of different life history stages of the rice plant but relies only on the flowering dates and the number of days till flowering of a rice cultivar sown on different dates to consistently identify photoperiod sensitive cultivars.

不同遗传背景及环境中水稻(Oryza sativa L.)穗长的QTLs和上位性分析

以粳稻Azucena为父本与舢稻IR64杂交发展的一双单倍体（DH）群体，与籼稻IR1552杂交发展的一重组自交系（RI）群体为材料，应用分子标记图谱对2个群体在大田和盆栽2个环境下的穗长进行QTLs及上位性效应分析。DH群体中共检测到6个穗长QTLs，位于第1、4条染色体上的3个QTLs，在2个环境中稳定表达，未检测到上位性效应，加性效应为穗长遗传主效应。R1群体中，共检测到3个穗长QTLs及6对互作效应位点，位于策4条染色体上的1个QTL及位于第1、12条染色体上的2个互作位点在2个环境中稳定表达，上位性效应表现为遗传主效应。在2个群体中均检测到的与穗长相关的1个QTL位于第4条染色体RG163～RZ23区间内，遗传正效应等位基因来源于Azucena；位于第1条染色体与RG323连锁的位点在DH群体中表现为1个QTL，但在RI群体中表现为互作位点。

K^+,Ca^(2+)和Mg^(2+)对不同水稻(Oryza sativa L.)基因型苗期耐盐性的影响

【目的】进一步探明盐胁迫条件下营养元素K+、Ca2+和Mg2+对苗期不同水稻基因型耐盐性的影响差异,为明确作物耐盐胁迫的生理机制、提高作物耐盐胁迫能力提供参考。【方法】于2009年1—4月在严格控制水、温、光和营养元素供应的国际水稻研究所人工气候室进行水培试验,比较研究营养液中K+、Ca2+和Mg2+浓度的变化对不同水稻基因型苗期耐盐性的影响。【结果】在盐胁迫条件下(100mmol·L-1NaCl),耐盐基因型(FL478和IR651)与盐敏感基因型(IR29和Azucena)相比,植株体内有较低的Na+含量和Na+/K+、Na+/Ca2+、Na+/Mg2+比,有较高的K+含量,这些都是耐盐基因型耐盐胁迫能力高于盐敏感基因型的内在原因。盐胁迫条件下提高营养液中Ca2+和Mg2+的含量(60mg·L-1),可显著降低植株体Na+含量和Na+/K+、Na+/Ca2+、Na+/Mg2+比,明显减轻盐胁迫的危害,增强水稻耐盐胁迫能力,且Ca2+处理的效果优于Mg2+处理;而提高营养液K+含量对以上指标的影响远远小于Ca2+处理和Mg2+处理,这也是K+处理对水稻耐盐性影响相对不明显的内在原因。【结论】K+、Ca2+和Mg2+在植株体内的含量及其与Na+的比值变化都会影响水稻苗期耐盐性;适当提高水稻生长环境的Ca2+和Mg2+浓度可以明显增强植株耐盐胁迫能力,营养元素Ca2+的效果比Mg2+明显;而K+对水稻耐盐性的影响相对不明显。

低钾胁迫对水稻(Oryza sativa L.)化感潜力变化的影响

研究以国际公认的化感水稻PI312777和非化感水稻Lemont为供体,稗草(Echinochloa crus-galli L.)为受体,采用稻/稗共培体系,研究低钾胁迫对水稻化感潜力变化的影响及其机制。受体稗草的形态指标分析结果表明,低钾胁迫促使化感水稻PI312777对共培稗草的根长、株高和干重的抑制率均升高,增幅远大于非化感水稻Lemont。受体稗草生理生化指标分析结果表明,低钾胁迫下化感与非化感水稻对受体稗草保护酶系(SOD、POD、CAT)及根系活力的抑制作用增强,但化感水稻PI312777比非化感水稻Lemont的抑制程度大,且达极显著差异。实时荧光定量PCR分析结果表明,低钾胁迫下,化感水稻PI312777根部与叶部中酚类代谢的关键酶——苯丙氨酸解氨酶、肉桂酸-4-羟化酶、羟化酶、O-甲基转移酶的基因均上调表达,而非化感水稻根部相应酶均下调表达,叶部除苯丙氨酸解氨酶上调,其余酶也下调表达。而萜类代谢途径关键酶——HMG-CoA还原酶、角鲨烯合酶、单萜烯环化酶、倍半萜烯环化酶、二萜烯环化酶的基因,在两种水稻根部中呈现出相同或相似的表达方式(上调或下调),即HMG-CoA还原酶上调表达,角鲨烯合酶、单萜烯环化酶、倍半萜烯环化酶、二萜烯环化酶下调表达;而在水稻叶部,非化感水稻Lmont相应酶基因表达方式仍然不变,化感水稻PI312777除了角鲨烯合酶下调表达,其余4个酶均上调表达。水稻根系分泌物中酚类物质的HPLC分析结果表明,低钾胁迫下,化感水稻PI312777根系分泌物中,所检出的酚酸类物质总量是正常营养条件下的2.30倍,而非化感水稻Lemont则是正常营养条件下的0.91倍。综合分析认为低钾胁迫下,化感水稻PI312777抑草能力增强主要是由于酚类代谢途径关键酶基因表达上调,导致酚类代谢途径旺盛,分泌出更多的酚类物质,进而破坏受体稗草保护酶系统,抑制了稗草的正常生长。

外源水杨酸对水稻(Oryza sativa L.)幼苗根的NaCl胁迫缓解效应

为研究25 mg/L外源水杨酸对0,50,100 mmol/L NaCl处理下水稻幼苗根的胁迫缓解效应,测定了根组织内脯氨酸含量、可溶性糖含量、氨同化关键酶活性等相关指标.结果表明外源水杨酸可使组织内脯氨酸含量显著降低至与正常对照相当水平,而可溶性糖含量升高,说明外源水杨酸存在时可溶性糖作为主要渗透胁迫调节物并对盐胁迫适当缓解,表现在幼苗根谷氨酰胺合成酶及依赖于NADH的谷氨酸脱氢酶的活性上升20%左右、可溶性蛋白质含量的提高,氮同化加强而对盐胁迫有一定的抗性.对50 mmol/L NaCl胁迫处理的材料缓解效应较显著.

水稻(Oryza sativa L·)捕光叶绿素a/b结合蛋白基因全长cDNA的克隆和特性分析

根据捕光叶绿素a／b结合蛋白基因（cab）家族中的保守序列设计PCR引物，扩增出的约310bpcDNA小片段为分子杂交探针，对构建的水稻cDNA文库进行杂交筛选，并结合PCR分析确定阳性克隆中cDNA片段的大小。通过对插入的cDNA片段最长的阳性克隆进行测序分析验证，克隆了水稻中1个cab基因全长cDNA，命名为cab-n8（GenBank登记号：AY445626）。cab-n8长为1128bp，从第55bp开始至789bp含有1个开放阅读框和1个终止密码子，编码244个氨基酸（GenBank登记号为AAR19267．1）；在3’端含有330bp的非编码区和Poly（A）18；在5’端有45bp的非编码区，在转录起始位点附近有TCA序列。通过序列分析，cab-n8编码的蛋白质在第54—216位包括典型的捕光叶绿素a／b结合蛋白功能域（chlorophll a／b binding domain）；在第141—158位含有无名指结构功能域（ring finger structure domain），该位点可能与捕光叶绿素结合蛋白与叶绿素a／b的结合有关；在第194—231位含有甘油醛-3-磷酸脱氢酶C端功能域（C-terminal domain of glyceraldehyde-3-phosphate dehydrogenase-like）。cab-n8编码的蛋白质预测的等电点和分子量分别为6．52和26955．80 Da。通过比较分析，cab-n8DNA序列（AY445626）和编码的氨基酸序列（AAR19267．1）与cab27DNA序列（AF094775．1）和编码的氨基酸序列（AAC67557．1）相似性最高，均为97％，显示cab家族基因在进化过程中是相当保守的。Northern blot分析表明，该基因在水稻叶和茎中表达没有差异，但光对其表达有明显的诱导促进作用。

6-磷酸山梨醇脱氢酶基因转化水稻(Oryza sativa L.)研究

以水稻品种秀水 1 1的幼胚为外植体 ,对影响愈伤组织诱导及植株再生的因素进行了研究 .结果表明 :MS+2 ,4- D 2 mg/L作培养基 ,愈伤组织诱导率达 1 0 0 % ,愈伤组织在 MS+6- BA2 mg/L+NAA 0 .1 mg/L的培养基上 ,分化频率高达 75.3% ;在此基础上利用基因枪转化技术 ,将外源的 6-磷酸山梨醇脱氢酶基因 (gut D)导入水稻基因组 ,转基因植株表现出对 Na Cl较强的耐性 .

不同化感潜力水稻(Oryza sativa L.)苗期的氮素养分效率及相关基因的表达

为了阐明养分水平引起水稻(Oryza sativaL.)化感抑草潜力变化的生理生态机制,研究了不同N素营养处理下,不同化感潜力水稻苗期对N素营养逆境的响应特性及N素养分效率的差异,并运用实时荧光定量RT-PCR技术(FQ-PCR)检测与N素代谢和次生代谢关键酶的基因表达。结果表明:弱化感水稻品种Lemont对N素营养胁迫较敏感,强化感水稻品种PI312777对资源波动的适应性较强,N素养分效率较高。FQ-PCR分析结果显示,在低N条件下Lemont中的亚硝酸还原酶基因(nir),谷氨酰胺合成酶基因(gs)相对表达量均有不同幅度的下调,PI312777分别下调了1.2倍和1.4倍,而Lemont分别下调了3.0倍和1.8倍,Lemont下调的幅度分别是PI312777的2.5倍和1.3倍,但对于苯丙氨酸解氨酶基因(pal)与3-羟基-3甲基戊二酰辅酶A还原酶基因(hmgr)而言,PI312777叶组织中的pal和hmgr均上调表达,与对照相比上调了6.0倍和1.6倍,而Lemont中对应的基因均下调表达,分别下调了1.3倍和6.8倍,佐证了上述差异的分子生态学特性。

上位性和QTL×环境互作对水稻(Oryza sativa L.)抽穗期的影响(英文)

水稻抽穗期是重要的农艺性状之一,对水稻品种的地理分布和适应性起到关键性作用。适宜的抽穗期是获得高产的前提。因此确定水稻抽穗期的遗传基础在育种计划中具有重要的意义。本研究用一套来源于亲本IR64/Azucena的双单倍体(DH)群体在两个种植季节的试验资料,用基于混合线性模型的复合区间作图方法,对水稻抽穗期QTL的加性、上位性及其与环境互作效应进行了研究。结果表明共有14个QTL影响水稻抽穗期,它们分布在除第5和第9条染色体外的10条染色体上,有8个位点携带单位点效应,5对位点携带双位点互作效应,2个单位点和1对双位点存在与环境的互作,所有效应值介于1.179～2.549天之间,相应的贡献率为1.04%～4.84%。基于所估算的QTL效应值,本研究预测了两个亲本和两个极端型品系的遗传效应值,并讨论了影响遗传效应值与实际观测值偏差的可能原因,以及研究群体所具有的遗传潜力。对水稻抽穗期QTL的定位结果与前人研究基本一致,并进一步证实了上位性和QE互作效应是水稻抽穗期的重要遗传基础。

植酸在水稻(Oryza sativa L.)细胞培养中的促进作用

植酸(C_6H_(18)O_(24)P_6)添加到固体和液体培养基中,能显著降低多酚氧化酶活性,稳定培养基中pH值和mV值,并能促进水稻细胞生长,增强细胞抗褐化和水渍化能力,从而改善细胞状态。在培养基中植酸的最佳添加量为0.1%,配合使用MES可以增强其稳定pH值的效果。

亚热带地区水稻(Oryza sativa L.)气孔臭氧通量和产量的响应关系

基于开放式臭氧浓度升高O_3-FACE(Free-Air Concentration Elevation of O_3)实验平台,利用前期水稻O_3-FACE试验的基础数据,通过建立水稻产量与不同评价指标(累积气孔O_3吸收通量PODY和O_3浓度指标AOTX)的响应关系,比较了水稻产量损失与各评价指标的相关性差异,通过对暴露剂量、吸收通量相关参数取值与产量损失的观察和分析结果的比较,找出更为合理的农作物臭氧风险评估阈值。结果表明:随着通量阈值Y[0~11 nmol O_3·m^(-2)PLA·s^(-1)(PLA:projected leaf area,投影叶面积)]和暴露浓度阈值X(0~50 n L·L^(-1))的增加,回归分析R^2值逐渐增加,当Y为11 nmol O_3m^(-2)PLA·s^(-1)和X为50 n L·L^(-1)时,气孔臭氧吸收通量POD11和累积暴露剂量AOT50与水稻相对产量的相关性最大,当通量阈值Y为8~13 nmol O_3·m^(-2)PLA·s^(-1)和暴露阈值X为46~58 n L·L^(-1)时,可获得较高的R^2值取值范围,分别为0.70~0.75和0.70~0.745。参考文献发现,目前地表臭氧污染可能引起的水稻产量损失范围为5%~8%,对照圈中POD9~10和AOT40~45产量损失的预测值亦在这区间,但前者R^2值(0.73~0.74)明显高于后者R^2值(0.64~0.69),表明基于气孔臭氧通量的评价指标能更好地反映水稻产量的变化。通过进一步分析发现,当通量阈值Y为9 nmol O_3·m^(-2)PLA·s^(-1)时,能更准确地评估水稻产量损失,且其R^2值(0.73)高于通量指标POD6(0.57)。以上研究结果表明,通量指标POD9更适合评估亚热带地区O_3污染对水稻作物的影响。

紫稻(Oryza sativa L.)线粒体ATP合成酶atp6基因转录本RNA编辑

紫稻(Oryza sativa L.)细胞质雄性不育系紫稻A是本实验室构建的新型细胞质雄性不育系。本研究使用PCR、RT-PCR、DNA测序等技术,得到了紫稻细胞质雄性不育水稻不育系(樱香A)及其保持系(樱香B)线粒体atp6基因转录本cDNA序列。通过与基因组序列比对发现:樱香Aatp6cDNA序列中,没有发生RNA编辑;而樱香Batp6 cDNA序列中有16个编辑位点,在樱香B cDNA序列16个编辑位点位于15个密码子中,所编码的氨基酸均发生改变:在1003位点由C替换为T,导致原来编码谷氨酰胺密码子(CAA)成为终止密码子(TAA),保证atp6 mRNA编码一个正常的ATP6多肽;而由于没有发生RNA编辑,樱香A mRNA就不能翻译成正常的多肽。研究表明,RNA编辑在合成正常的ATP6多肽的过程中具有至关重要的作用,同时也说明RNA编辑可能与细胞质雄性不育相关。

水稻(Oryza sativa L.)花粉及花药壁发育的超微结构研究

运用透射电子显微镜技术 ,系统观察了水稻花粉及其花药壁层的发育过程 ,发现了一些新的现象 :(1)小孢子母细胞减数分裂期间 ,伴随核内染色体变化的同时细胞质发生了“改组”现象 ,主要表现为核糖体分布密度的规律性变化 ,这标志着孢子体向配子体的转变。 (2 )小孢子外壁的发育始于四分体晚期 ,最早表现在四分孢子质膜上沉积了少量的壁物质。随后沉积增多 ,至小孢子早期即形成初生外壁。此后外壁发育迅速 ,到小孢子晚期外壁已基本发育完成。 (3)小孢子中期 ,小孢子细胞核的双层核膜局部分开 ,并逐渐扩张成一个“大泡”。核膜扩张在这一时期是一种普遍现象。(4 )在花粉发育过程中 ,绒毡层细胞结构发生明显变化 :小孢子母细胞形成之初 ,绒毡层细胞结构完整 ,内质网极少 ;随着减数分裂的进行 ,绒毡层胞质浓缩 ,细胞内出现“空腔”,内质网丰富 ;到了小孢子中期 ,仍有较多堆叠的内质网 ,此后逐渐消失。表明内质网在绒毡层的发育中起着重要的物质合成及运输作用。 (5 )花粉完全成熟时 ,花药中层细胞的壁以及绒毡层的外切向壁紧贴在一起 ,形成了一叠合的“壁”结构。

水稻(Oryza sativa L.)亚种间杂交穗部性状的双列分析

采用6×6没有反交的完全双列杂交,对亚种间杂交穗部性状的遗传和基因作用以及配合力进行了研究。结果表明,粒长、粒宽、长宽比和粒重为不完全显性,遗传方差中以加性效应为主;穗长、二次支梗数、穗粒数为超显性,显性效应大于加性效应;一次支梗数表现有明显的上位性效应。狭义遗传力的排列顺序为粒宽>长宽比>千粒重>粒长>穗长>穗粒数>二次支梗数。二次支梗数和穗粒数具有相似的遗传基础,其余性状的基因系统具有相对的独立性。8EC1936对所有考察性状皆含有较多显性基因,而02428隐性基因偏多。约有1组显示显性的基因控制籽粒长宽比。穗长、千粒重、一次支梗数、二次支梗数和穗粒数的一般配合力和特殊配合力皆达极显著水平,粒长、粒宽、长宽比仅一般配合力达极显著。Lemont和02428对穗粒数及其相关性状的一般和特殊配合力俱佳;而对增加粒重和获得理想的籽粒形状8EC1936.CA529和矮64、Lemont是可供选择的亲源。

温度对长穗颈温敏核不育水稻(Oryza sativa L.)穗颈伸出长度的影响

以隐性长穗颈温敏核不育水稻(OryzasativaL)长选3S为材料,研究了温度对隐性长穗颈温敏核不育水稻长选3S穗颈伸出长度的影响。结果表明:人工24℃条件下,在始花前第12天至始花前第4天和始花当天至始花后第3天两个时段,穗颈节间伸长速度慢,两者节间日均伸长长度基本一致,但从始花前第4天至始花当天,长选3S穗颈节间伸长速度最快,其节间日均伸长的长度是培矮64S的2.1倍。在敏感期分别进行22、24、26、28℃4种人工温度处理,28℃条件下穗颈节间伸长受阻,出现包颈现象;26～22℃条件下穗颈伸出长度都为正值,不包颈,但穗颈伸出剑叶叶鞘的长度随温度降低而增加。通过对穗颈节间细胞数目和细胞长度的比较分析表明,长选3S穗颈节间的伸长主要是由于细胞分裂和细胞伸长共同作用所致,其中后者作用更显著,且随处理温度的升高,穗颈节间最内和最外层薄壁细胞数目减少,细胞平均长度变短。

稻属种间杂种(Oryza sativa×O.officinalis)回交世代的形态学研究

两个组合（中８６－４４×ＹＤ１７８５、中１５６×３－６６）的种间杂种（Ｏ．ｓａｔｉｖａ×Ｏ．ｏｆｆｉｃｉｎａｌｉｓ）Ｆ１植株，完全不育。以栽培稻为轮回亲本进行回交，结合胚拯救技术，获得两组合回交一代（ＢＣ１Ｆ１）植株。两组合回交一代（ＢＣ１Ｆ１）群体中分别出现６个和７个类型的植株，完全不育。通过继续回交获得的组合中８６－４４×ＹＤ１７８５回交二代（ＢＣ２Ｆ１）植株中，出现了４个类型的植株，株型似栽培稻，大部分植株可育。经自交获得株型好，结实正常，抗性强的中间材料。结果表明：（１）栽野杂种回交世代出现疯狂分离，药用野生稻遗传上存在较大异质性；（２）通过连续两次回交，结合胚拯救技术，可改变杂种野生性状，获得具有药用野生稻优良基因的中间材料，如７５－２、７９－１、７９－１１三个株系；（３）证实胚拯救技术在种间杂交转移药用野生稻有利基因中是一条行之有效的途径。