免疫测定光敏核不育水稻中光敏色素I含量

光敏核不育水稻（农垦58S）是中国水稻研究中的一个重要发现,水稻杂交育种上有巨大潜力。研究表明：农垦58S的雄性不育性受光周期调控,光敏色素是育性转变过程中光周期反应的光受体。然而,鉴于高等植物中存在至少两种不同的光敏色素分子,并且它们同时存在水稻中,人们对调节农垦58S雄性不育过程的光敏色素分子种类及作用方式仍然不清楚。本文采用酶联免疫吸附测定法（ELISA）,比较了不同光周期下农垦58S和对照品种农垦58叶片（光周期感受器官）中光敏色素（phyA）的含量。从农垦58S的二次技梗原基分化期开始,进行10天的光周期处理,一组为短日照（SD）,另一组为长日照（LD）。在第10个暗期结束前,于暗绿光下收获每株水稻的最上部两片新展叶,立即保存在液氮中。样品在研钵中磨成液氮粉,然后加入提取液（含50mmol/LTris-HCI和0．2mol／L巯基乙醇,pH8．5）匀浆。粗提液经0．5％聚乙烯亚胺（PEI）沉淀一,上清液供ELISA分析。以燕麦phyA的多克隆隆抗体、单克隆抗体分别作ELISA的一抗和检测抗体。供ELISA分析。以燕麦phyA的多克隆抗体、单克隆抗体分别作ELISA的一抗和检测抗体。采用ELISA可以专一性地检测水稻phyA(Table1)。几次独立的实验说明,光周期处理对phyA含量有较大的影响。要相同的光周期下,农垦58S的phyA在较长时间暗期中的合成速度明显比农垦58快,这证实了前人的推测,即农垦58S甲基化程度较低的phyA基因的表达可能比农垦59更活跃。许多研究指出,pohyA含量的高低必然影响有关的生理过程。两种基因型相同的大麦品种对光周期、远红光（FR）敏感性的不同反应正是phyA含量差异所致。因此,SD下叶片积累较多的phA可能是农垦58S花粉育性恢复所必需的。另外,在农垦58S育性转变敏感期内每天的光周期结束时（EOD）进行短暂（15分钟）的FR照射实验,以推测光敏色素(PhyB)在育性转变中的作用,因为EODFR反应由phyB介导。10次EODFR处理后,农垦58S的抽穗、开花期均比SD对照相应地推迟2天。这与穗、开花（LD效应）,其花粉败育、种了结实率却没有变化（图1）,说明开花与花粉育性的调控机制有所不同。从上述结果我们认为,可能是phyA,而不是pohyB参与光周期诱导的农垦58s花粉育性转变过程,并且phyA可能通过其含量的变化起调节作用;phyB与水稻的抽穗、开花等现象有关。农垦58S可能通过其含量的变化起调节作用;phyB与水稻的抽穗、开花等现象有关。农垦58s控制花粉正常发育的phyA信号传导链可能存在某些缺陷,从而导致对光周期的敏感性增加,SD下积累较多的phyA则可以弥补这些缺陷。     

光敏核不育水稻开花和育性转变不同的光反应

从光敏核不育水稻"农垦585"幼穗分化至二次枝梗期开始,在每天的短日照光期（10h日光）结束、暗期开始时（EOD）进行15d的远红光（FR）照射实验,以比较开花、育性转变过程对短暂的远红光（FR）或红光（R）的反应。EODFR明显抑制水稻植株开花（穗分化）,导致"农垦585"和原种"农垦58"的抽穗期均比短日照下推退7d,表现为长日照效应,而"农垦58S"的结实率与原种相比却无显著变化。这暗示诱导农垦58S开花、育性转变过程的光反应可能有差异,前者不仅与光周期有关,且受EODFR的剧烈影响,而育性主要受光周期（临界暗期）控制,基本上不受EODFR的调控。     

免疫测定光敏核不育水稻中光敏色素Ⅰ含量

光敏核不育水稻（农垦５８Ｓ）是中国水稻研究中的一个重要发现,在水稻杂交育种上有巨大潜力。研究表明：农垦５８Ｓ的雄性不育性受光周期调控,光敏色素是育性转变过程中光周期反应的光受体,然而,鉴于高等植物中存在至少两种不同的光敏色素分子,并且它们同时存在于水稻中,人们对调节农垦５８Ｓ雄性不育过程的光敏色素分子种类及作用方式仍然不清楚。本文采用酶联免疫吸附测定法（ＥＬＩＳＡ）,比较了不同光周期下农垦５８Ｓ和对照品种农垦５８叶片（光周期感受器官）中光敏色素Ｉ（ｐｈｙＡ）的含量。从农垦５８Ｓ的二次枝梗原基分化期开始,进行１０天的光周期处理。一组为短日照（ＳＤ）,另一组为长日照（ＬＤ）。在第１０个暗期结束前,于暗绿光下收获每株水稻的最上部两片新展叶,立即保存在液氮中。样品在研钵中磨成液氮粉,然后加入提取液（含５０ｍｍｏｌ／ＬＴｒｉｓ－ＨＣＩ和０．２ｍｏｌ／Ｌ巯基乙醇,ｐＨ８．５）匀浆。粗提液经０．５％聚乙烯亚胺（ＰＥＩ）沉淀后,上清液供ＥＬＩＳＡ分析。以燕麦ｐｈｙＡ的多克隆抗体、单克隆抗体分别作ＥＬＩＳＡ的一抗和检测抗体。采用ＥＬＩＳＡ可以专一性地检测水稻ｐｈｙＡ（Ｔａｂｌｅ１）。几次独立的实验说明,光周期处理对ｐｈｙＡ含     

光敏核雄性不育水稻叶绿体的光合特性

本文报告了在育性转换敏感期光周期处理对湖北光敏核雄性不育水稻（农垦５８ｓ）最新全展叶叶绿体光合特性的影响。结果表明：与短日照（ＳＤ）相比,长日照（ＬＤ）处理的农垦５８ｓ水稻叶绿体只有较低的ＰＳⅡ光化活性和ＰＳⅡ原初光能转化效率,其ＰＳⅡ和全链的电子传递速率低,叶绿体中叶绿素ｂ的含量较少,叶绿素ａ／ｂ值比短日照处理的高约１０％。长日照处理使农垦５８ｓ叶绿体的光化活性普遍下降,这可能是导致农垦５８ｓ败育的初始原因之一。     

光周期调节光敏感核不育水稻叶片抗环血酸过氧化物酶的活性

从第二次枝梗原基分化期开始用长日照(LD)或短日照(SD)处理光敏感核不育水稻农垦58S 和常规水稻农垦58。与 SD 处理比较,LD 处理明显抑制农垦58S 和农垦58的抗坏血酸过氧化物酶(AsAPOD)的活性,对农垦58S 的 AsA POD 活性的抑制效应较之农垦58的大。随着 AsAPOD 活性下降,抗坏血酸(AsA)和丙二醛(MDA)的含量逐渐增加,AsA POD 活性与 AsA 和MDA 含量之间呈负相关。LD 抑制 ASA POD 活性和抑制幼穗发育的时间有一定的一致性。推测在 LD 处理下 AsA POD 活性下降与幼穗发育受阻有某些内在的联系。     

光敏核雄性不育水稻叶绿体的光合特性

本文报告了在育性转换敏感期光周期处理对湖北光敏核雄性不育水稻最新全展叶叶绿体光合特性的影响。结果表明：与短日照相比,长日照处理的农垦５８ｓ水稻叶绿体只有较低的ＰＳⅡ光化活性和ＰＳⅡ原初光能转化效率,其ＰＳⅡ和全链的电子传递速率低,叶绿体中叶绿素ｂ的含量较少,叶绿素ａ／ｂ值比短日照处理的高化活性普遍下降,这可能是导致农垦５８ｓ败育的初始原因之一。     

光周期调节光敏感不育水稻叶片抗坏血酸过氧化物酶的活性

从第二次枝梗原基分化期开始用长日照(LD)或短日照(SD)处理光敏感核不育水稻农垦58S和常规水稻农垦58。与SD处理比较,LD处理明显抑制农垦58S和农垦58的抗坏血酸过氧化物酶(AsAPOD)的活性,对农垦58S的AsA POD活性的抑制效应较之农垦58的大。随着AsA POD活性下降,抗坏血酸(AsA)和丙二醛(MDA)的含量逐渐增加,AsA POD活性与AsA和MDA含量之间呈负相关。LD抑制ASA POD活性和抑制幼穗发育的时间有一定的一致性。推测在LD处理下AsA POD活性下降与幼穗发育受阻有某些内在的联系。     

核酸代谢抑制剂对水稻光敏核不育性的影响

在稻穗分化的二次枝梗期后,观察比较了叶片喷施核酸代谢抑制剂5-FU对水稻光敏核不育性及幼穗发育的影响,结果表明：长日照下,5-FU在使农垦58S穗长缩短、颖花数减少的同时,却使其抽穗提前,可育性得到一定程度的恢复;5-FU处理还使农垦58的抽穗被完全阻止。在短日照下,5-FU处理则使农垦58S与农垦58在穗长与颖花数减少的同时,其抽穗反被延迟,可育性受到抑制而结实率显著降低,上述效应还可被随后施用的恢复剂乳清酸所弱化。因此可以认为光敏核不育现象与稻穗发育中核酸代谢的改变有关。     

光周期敏感核不育水稻叶绿体的特异性蛋白质

用双向聚丙烯酰胺凝胶电泳技术,将光周期敏感核不育水稻“农垦58S”和其对照品种“农垦58”苗期及育性转换光周期敏感期的叶绿体蛋白质分离为大约90个蛋白质点。“农垦58S”的叶绿体内有一个45kD(pI_(6.7))和一个61kD(pI_(6.0))的特异性蛋白质点,而“农垦58”没有。“农垦58S”的另一个61kD(pI_(6.2))蛋白质点的含量明显高于“农垦58”。不同光周期(长日照和短日照)处理不影响光敏感期的这种叶绿体蛋白质的差异。     

水稻光敏核不育系的选育

湖北光敏感核不育水稻的发现,为两系杂交稻奠定了基础。农垦58S为晚梗型,经济性状不理想,直接利用于生产较困难,必须将光敏核不育特性转育到优良的籼、粳品种中,选育出符合生产要求的光敏核不育系,才有生产利用价值。光周期诱导水稻雄性育性转换特性是由1—2对主效基因控制的,可以通过杂交转育。自八十年代以来,湖北和全国的水稻遗传育种学家开展了水稻光敏核不育系的选育,到1991年止,由农垦58S为源的通过省级以上鉴定的水稻光(温)敏核不育系18个,其中籼稻10个粳稻8个,由光、温敏核不育系配制的两系杂交稻组合开始用于生产。     

Effect of Photoperiod Treatments on Phytochrome a Levels and Its mRNA Abundance in Photoperiod-Sensitive Genic Male-Sterile Rice Mutant and the Wild Type

The effect of photoperiod treatments on phytochrome A (Phy A) level and its mRNA abundance in the leaves of a photoperiod-sensitive genic male-sterile mutant (Nongken 58S) and its wild type ("Nongken 58') of Oryza sativa L. was investigated. The top two leaves of each rice shoot were harvested at the end of the last dark phase of 10 cycles during photoperiod-sensitive stage for fertility alteration of the mutant. Phy A was measured by a sandwich enzyme-linked immunosorbent assay (ELISA) using rabbit polyclonal and mouse monoclonal antibodies. Compared with longday (LD) treatment,short day (SD) resulted in 38.5% increase of relative Phy A content in the mutant, only 18.5% increase in the wild type. In an extended darkness (25 h), the accumulation of Phy A also appeared to be more rapid in the mutant seedlings than in its wild type. RNA dot blot analyses with RPA3 (a cDNA clone of rice Phy A) as a probe showed:the abundances of Phy A mRNA in top leaves of Nongken 58S and "Nongken 58" were obviously higher in SD than those in ID at the end of dark phase of 5 d and 10 d photoperiod treatments. Moreover, under SD Phy A mRNA contents in Nongken 58S were more than those in "Nongken 58" during the whole photoperi- od-sensitive stage for fertility alteration. In addition, after 10 cycles of end-of-day far-red irradiations (EOD FR), the heading and flowering date of the mutant was delayed for 2 d. However, EOD FR had little or no effect on male fertility of the mutant.     

Relationship Between Male Fertility and Endogenous Phytohormones in Photoperiod-Sensitive Genic Male-Sterile Rice

A spontaneous male sterile rice plant (Oryza sativa L. cv. Nongken 58S) "Photoperiod-sensitive Genic Male-sterile Rice has been found to be male sterile under long day cycles (LD) and fertile in short day cycles (SD). The period from secondary rachis-branch and spikelet primodia to pollen mother cell formation in the process of panical development was the photoperiod-sensitive stage for fertility alternation. The phenotype of this mutant was reported to be controlled by two pairs of recessive alleles. The research on relationship between the fertility alternation and phytohormone action in this mutant have been performed by Chinese scientists since 1985. In order to study the mechanism of fertility alternation in Nongken 58S, endogenous IAA, ABA, GA1 and GA4 in apical leaves and reproductive organs in different development stages under LD and SD conditions have been quantiatvely and qualitatively identified by GC-MS-SIM method. It was found that endogenous IAA in apical leaves at the stage of pistil and stamen primodia formation and in panicles at pollen mother cell stage of Nongken 58S with LD condition was deficient comparing with those in SD. Endogenous ABA level in panicles at pollen mother cell stage, in spikelets at uninucleate stage and in anthers at anthesis stage of Nongken 58S-LD were lower than those in SD. ABA levels in corresponding organs and developmental stages of wild type of rice, "Nongken 58" were always higher in LD treatment than those in SD. Endogenous IAA, GA1 and GA4 levels in anthers at anthesis stasge of "Nongken 58"-LD were increased obviously. Thus it appeared that "Nongken 58" possess stronger resistance to LD stress than Nongken 58S. It is concluded that IAA deficiency of reproductive organs at early developmental stage, ABA decrease implying poor resistance to LD stress and reduction of GAs in late developmental stages were the factors causing the anther sterility in Nongken 58S-LD.     

光敏核不育水稻幼穗的乙烯生成与育性转换

研究了在不同光温组合下光敏核不育水稻（ＰＧＭＲ）农垦５８５（ＮＫ５８Ｓ）及普通水稻品种农垦５８（ＮＫ５８Ｂ）的幼穗乙烯生物合成变化及其与育性表达的关系。结果表明ＮＫ５８Ｓ幼穗乙烯生成受光周期和温度的共同调节,而光周期对ＮＫ５８Ｂ幼穗乙烯生成无明显影响。ＮＫ５８Ｓ幼穗乙烯生成的变化与育性转换光温作用模式完全吻合。其幼穗乙烯释放速率（ＥＲＲ）与花粉可育度（ｌｎｙ）呈极显著负相关。用ＡＶＧ抑制乙烯生成可使ＮＫ５８Ｓ（ＬＤ）不育性明显逆转,而用ＡＣＣ促进乙烯生成又可急剧降低ＮＫ５８Ｓ（ＳＤ）的可育水平。表明幼穗乙烯生成与ＰＧＭＲ育性表达密切相关,乙烯参与育性转换的调控并可能起着重要作用。     

Effects of Photoperiod on Supramolecular Architecture of Thylakoid Membranes from a Rice Mutant (Oryza sativa Nongken 58S)

Plants of a rice mutant (Hubei photoperiod-sensitive genic male-sterile rice, Oryza sativa L. Nongken 58S) and its wild type cv. Nongken 58 were cultured in natural summer conditions in Beijing. After induction of proper photoperiods small panicle at the stem tip emerged and developed to the stage of secondary rachis-branch and spikelet primordium formation. Subsequently, part of the rice plants received long day (LD), i.e. 10 h of day-light treatment followed by 5 h of white fluorescent illumination with 1～2 Wm-2) . The others were exposed to daylight for 10 h alternating with a 14 h of dark period as short day (SD) treatment. After 10 days of the photoperiodic treatments, the chloroplast ultrastructure of the first leave below the flag leaf was examined by freeze-fracture rotary and unidirectionally shadowed electron microscopy. At anthesis stage, Nongken 58S plants with LD treatment showed complete pollen sterility, while the same plants with SD treatment exhibited normal fertility. And fertility of Nongken 58 was not affected by photoperiod treatments. The results from electron microscopic observation showed no significant effects of either SD or LD treatment on the freeze-fractured uhrastructure of thylakoid membranes in Nongken 58. No significant difference in particle density and size distribution was found on stacked and unstacked thylakoid membrane regions of the Nongken 58S-SD and those of Nongken 58 rice. However, the particle density of the endoplasmic fracture face in the staked region (EFs) and protoplasmic fracture face in the staked region (PFs) faces detected from the leaf thylakoid membranes of Nongken 58S-SD rice was significantly higher than that of the corresponding faces from Nongken 58S-LD. In some cases much more particles on EFs faces of thylakoid membranes isolated from Nongken 58S-SD rice appeared as paracrystalline particle array, indicating increases in the number of PS Ⅱ reaction centres, LHC I and Cyt b6/f per unit area of thylakoid membrane. The particle density of the endoplasmic fracture face in the unstaked region (EFu) and protoplasmic fracture face in the unstaked region (PFu) faces from unstacked thylakoid membranes of Nongken 58S-LD was less than that of the corresponding faces from Nongken 58S-SD. And the particle density of PFu faces from margin and end of the membranes of the grana thylakoids of LD-treated Nongken 58S leaves was also less than that of unstacked thylakoid membranes from SDtreated rice. In severe cases, most of the particles on endoplasmic fracture face in the unstaked region (EFu) and protoplasmic fracture face in the unstaked region (PFu) faces were even missing, indicating a decrease in the numbers of photosystem Ⅰ , LHCⅠ , Cyt b6/f and ATPase per unit area of' thylakoid membrane. The above results could further provide an augmentation for explaning the photoperiod-sensitive genic male-sterility.     

光敏核不育水稻农垦58S与正常品种“农垦58”在pmsl区段无育性基因分离

光敏核不育水稻农垦58S系由正常品种“农垦58”(Oryza sativa L.ssp.japonica)自然突变产生。为弄清该突变基因在染色体上的位置,曾用覆盖整个水稻基因组的300余个RFLP探针对农垦58S和“农垦58”进行了对比分析,得到了7个具多态性的探针,其中2个探针RG30和RZ626正好落在第7染色体上以前定位的光敏核不育基因pmsl所在的区段。以这两个标记对农垦58S/“农垦58”组合F_2随机群体140单株进行了RFLP分析,按RFLP基因型分组对育性作方差分析,结果表明,这2个标记位点与此群体中引起育性分离的位点无连锁关系。说明由正常“农垦58”变为光敏核不育农垦58S的突变基因不在pmsl区段。     

Pms1 is not the Locus Relevant to Fertility Difference Between the Photoperiod-Sensitive Male Sterile Rice Nongken 58S and Normal Rice

The photoperiod-sensitive male sterile rice, Nongken 58S, was obtained as a spontaneous mutant of the Oryza sativa L. ssp. japonica cultivar "Nongken 58". To determine the chromosomal location of the locus related to the fertility difference between Nongken 58S and its wild-type ancestor, the authors assayed the DNA polymorphisms between these two varieties using a total of over 300 RFLP probes covering the entire molecular marker linkage map. Seven probes detected polymor- phisms between "Nongken 58" and Nongken 58S. Two probes, RG30 and RZ626, both from chromosome 7, happened to be located in the genomic region of pmsl, a locus for photoperiod-sensitive male sterility identified in the authors' previous study. These two probes were used to assay a random sample of 140 individuals from a F2 population of a cross between Nongken 58S and "Nongken 58", in which the fertility segregated in a typical 3: 1 ratio. An analysis of variance of the fertility using the RFLP genotypes as the groups clearly evidenced that these two marker loci are not linked to the locus associated fertility segregation in this population. It is concluded that the locus relevant to fertility difference between Nongken 58S and "Nongken 58" is not in the vicinity of the pmsl region.     

Specific Proteins in Chloroplasts of Photoperiod-Sensitive Genic Male-Sterile Rice

The chloroplast proteins of a male-sterile mutant Nongken 58S, namely “Hubei Photoperiod-sensitive Genic Male-sterile Rice”, which is male sterile under long day (LD) cycles and fertile under short day (SD) cycles, and its original cultivar Nongken 58 (Oryza sativa L. subsp, japonica, Nongken 58) at seedling stage and photoperiod sensitive stage of fertility transition could be resolved into at least 20 major and more than 70 minor protein components on two-dimensional gel electrophoresis, with molecular weights ranging from 10kD to 67kD and isoelc points (pI) from 4.3 to 8.5. The mutant Nongken 58S had twospecific proteins with molecular weight of 45kD(pI6.7) and 61 kD (pI6.0) as compared with Nongken 58. Another 61 kD(pI6.2) protein was more in Nongken 58S than in Nongken 58. The existance of these proteins was not influenced by SD or LD treatment. The results showed difference in patterns of gene expression between Nongken 58S and Nongken 58. A possible function of these proteins in relation to regulation of sterility was discussed.     

Effect of End-of-day far-red light exposures on fertility alteration and flowering in photoperiod-sensitive genic male-sterile rice

The rice photoperiod-sensitive genic male-sterile mutant (PGMR) is sterile under long days, but fertile in short days. Phytochrome is involved in the photoperiod-induced male-sterile process. To investigate the mechanisms, of phytochrome action in PGMR, end-of-day (EOD) experiments were carried out. Flowering in PGMR was delayed considerably by EOD far-red light exposures following a short day of 10 hr, whereas its fertility decreased to the same extent as the original line. This result suggests that photoperiod response mediating fertility alteration in PGMR somewhat differed from that in flowering,i.e., fertility alteration and flowering might be under the separate phytochrome signaling control.