低温敏核不育水稻go543S育性对温、光的反应

以新型光温敏核不育（PTGMS,Photo-thermo sensitive genic male sterile)水稻go543S为材料,通过自然生态条件下和人工温、光处理条件下的育性观察,对其育性转换与温度和光周期的关系进行了研究。结果表明：go543S育性主要受温度控制,表现为低温条件下不育,高温条件下可育,育性转换的不育临界温度值为29．5℃,对温度传感的部位是幼穗,敏感时期为花粉母细胞形成致减数分裂,对应的剑叶叶枕距变化范围为－12．2－＋0．7cm;育性敏感期在人工恒温28．0℃条件下,无论长日（14－16h）或短日（10－12h）处理均表现不育,其不育性不受光周期影响,在人工恒温31.5℃条件下,无论长日还是短日处理均表现可育,但短日可明显提高其可育性。     

PGMS水稻育性转换中的多胺含量变化

在光敏核不育水稻农垦５８ｓ幼穗的花粉母细胞形成期间,短日可育株的多胺含量高于长日不育株。多胺合成的前体Ａｒｇ在短日可育株中比幼穗中多胺早一个时期在叶片中达到高峰,而在长日不育株中大量积累。用甲基乙二醛－双处理的短日可育株中Ｓｐｄ和Ｓｐｍ水平、花粉可育度和自交结实度都下降,用Ｓｐｄ补充长日不育株中多胺含量,其花粉可育度有提高。     

PGMS水稻育性转换中的多胺含量变化(简报)

在光敏核不育水稻农垦58s幼穗的花粉母细胞形成期间,短日可育株的多胺含量高于长日不育株。多胺合成的前体Arg在短日可育株中比幼穗中多胺早一个时期在叶片中达到高峰,而在长日不育株中大量积累。用甲基已二醛-双（脒腙）（MGBG）处理的短日可育株中Spd和Spm水平、花粉可育度和自交结实率都下降。用Spd补充长日不育林中多胺含量,其花粉可育度有提高。     

光敏核不育水稻的育性与^45Ca的关系（简报）

光敏核不育水稻农垦58s育性转换始期,以涂叶法和灌根法对长日、短日处理植株饲喂的45Ca可自叶片或根部转入功能器官（叶、幼穗）,转入量随标记强度的增加而增加;植株吸收的45Ca可明显提高长日照下稻株的花粉可育率和自交结实率,而短日照下稻株的效应则相反。     

ADH在光敏感核不育水稻中反应特征的研究

乙醇脱氢酶(ADH)活性在湖北光敏感核不育水稻(HPGMR)幼穗发育的育性诱导阶段对光周期反应非常敏感。此时,在短日照或远红光处理的条件下,乙醇脱氢酶同工酶AdhII活性高,湖北光敏感核不育水稻原始不育株农垦58雄性可育;在长日照或红光间断长暗期的条件下,AdhII活性陡降,表现雄性不育。因此认为AdhII与湖北光敏感核不育水稻育性转换有关,可能是它参予了育性基因表达的调控作用。     

水稻光温敏不育基因研究概况

光温敏雄性核不育水稻的花粉育性受日照长度或温度的调控,在长日、高温条件下表现不育,短日、低温条件下表现可育.水稻这一特性的发现使得人们可以利用其进行‘两系法'杂交稻育种来补充传统的‘三系法'杂交育种体系.水稻光温敏核不育基因的研究对于'两系法'杂交稻育种的利用研究至关重要.主要对光温敏核不育基因的遗传规律分析、基因的定位研究进展以及DAN分子标记在基因定位中的应用等方面进行了综述.     

新型光温敏小麦不育系337S的组织结构研究

普通小麦(Triticum aestivum)不育系337S是一种对短日低温、长日高温均敏感不育的新型光温敏雄性不育系。对经过短日低温、长日高温处理的不育系花药及其小孢子的形态和发育过程进行了观察,观察结果表明,不育系337S的花药异常短小,开花后花丝短,花药难外露。花药发育过程中中层组织发育紊乱,绒毡层提前解体,影响了花粉母细胞发育所需的营养供应,导致短日低温处理下的花粉母细胞减数分裂中期Ⅰ和长日高温处理下的花粉母细胞发育时期花粉母细胞发育异常,形成异常小孢子,造成败育。     

籼型光敏核不育水稻育性可转换性的基因定位和基因互作研究

本研究以来源于农垦58S的灿型光敏核不育系培矮64S（短日条件下育性难转换）和8902S（短日条件下育性蝗转换）及其F1,F2群体为材料,通过短日不同光温和不同生态条件4种处理,利用RFLP分子标记研究了影响光敏偿育水稻在短日条件下的育性可转换性的遗传,基因定位和基因互作,主要结果表明：影响光敏不育水稻的育性可转换性表现为微效基因的作用,定位了7个控制光敏核不育水稻的育性可转换性QTL,即S2,S3a,S3b,S5,S8和S10,揭示了基因互作真实存在于光敏核不育水稻中,基因互作形式和互作类型对光敏核不育水稻的育性可转换性的影响表现多种多样,不同类型的基因互作所解释的遗传变异处于2．15％－10．07％之间。     

短光低温不育水稻不育性的遗传观察

用若干常规品种与短光低温不育水稻宜ＤＩＳ配组,考察双亲及Ｆ１在自然低温影响前后的花粉育性,并于不育系稳定不育期间调查Ｆ２及Ｆ３的育性分离。结果表明：（１）低温是影响双亲及Ｆ１育性稳定性的重要生态因子;（２）Ｆ１的育性稳定性除与父本的育性稳定性有关外,可能尚与其他因素有关,这种育性稳定性表现是由可遗传因子决定的;（３）短光低温不育特性基本上符合２对独立主基因控制的遗传模式,但可能尚受到众多微效基因的     

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。     

Fertility response to photoperiod and temperature in indica photoperiod-sensitive male sterile rice

The aim of this work was to develop a photoperiod-sensitive male sterile rice with stable sterility. We developed Changguang S, an indica rice strain, by using a short critical day length. Differences in the fertility responses of Changguang S strain pollen to temperature and photoperiod under natural and controlled conditions were studied. The results showed that Changguang S strain exhibited stable sterility under long-day and low-temperature conditions (22°C, 15 days). The stability of sterility was significantly higher than that of other such rice strains, Nongken 58S and 7001S. The critical photoperiod for inducing male sterility in Changguang S was 13 h or shorter, and its duration was significantly shorter than that required for rice strains Nongken 58S and 7001S. It is suggested that Changguang S is a typical photoperiod-sensitive male sterile rice strain with a shorter critical day length and a lower critical temperature. It is promising to apply this strain to two-line hybrid rice production.     

Characterization of fertility alteration and marker validation for male sterility genes in novel PTGMS lines hybrid rice

Photoperiod and thermosensitive genetic male sterile (PTGMS) lines have become one of the main sources of global rice production increasing. This study was conducted to evaluate the fertility alteration and validate the male sterility genes using validation markers in novel Egyptian Indica and Japonica PTGMS lines under natural conditions. The study revealed that the new genetic male sterile lines belong to the type of photo–thermosensitive genetic male sterility (PTGMS). The fertility alteration of these lines has influenced by photoperiod and temperature interaction. The new PTGMS lines have three sensitive periods of fertility alteration; transformation, sterility, and fertility period. Furthermore, the sensitive stage of fertility transformation might be from secondary branch primordial to pollen mother cells (PMC) meiosis. Under the natural Sakha condition, the new PTGMS lines were stable sterile under the condition of day length upper 13,75 h and temperature over 25 °C, while its convert to fertile under day length under 13 h, and temperature lower than 24 °C. The co-dominant markers identified the pms3 and tms5 genes in the new PTGMS lines, indicated that the fertility alteration in these lines controlled by photoperiod and thermosensitive stages.     

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.     

Abnormality in Male Organ Development and Fertility of Photoperiod sensitive Genic Male Sterile Rice Plants Under Short Day Condition

Ten photoperiod-sensitive genic male sterile rice (PGMSR) lines were studied to observe the development of male organs of their short day (SD) plants. The results were shown as follows: 1 ) The self seed-setting rate and the percentage of fertile pollen of these PGMSR lines were much lower than those of the controls. 2) All the male sterile line plants had variant barriers in anther dehiscing and pollen scattering. In addition, some of their stigmas were devoid of pollen, and some self pollen grains on their stignas germinated weakly. 3) Female fertility of those plants was believed to be normal through observation in their embryo sac development and cross seed-setting rate. The authors deduced that the male sterile gene expression becomes the major factor for low rate of self seed-setting of PGMSR plants under SD condition.     

光周期对光敏核不育水稻光敏色素A含量及其mRNA丰度的影响

光敏核不育水稻(农垦58S)是我国特有的水稻(Oryza sativa L.)种质材料,光敏色素是光周期诱导其育性转变的受体。报道了育性转换敏感期间的光周期处理对农垦58S及对照“农垦58”叶片中光敏色素A(Phy A)含量及其mRNA丰度的影响。在10个光周期处理的最后一个暗期结束前,收获每株水稻的上部两片叶,用酶联免疫吸附测定法测定Phy A。和长日照(LD)相比,短日照(SD)处理导致农垦58SPhy A相对含量增加38.5％;而“农垦58”只增加18.5％。显然,在较长的暗期中,农垦58S中Phy A的积累比对照快。在水稻幼苗中也得出相似的结果。以光敏色素A基因(phy A)的特异性片段RPA3作探针,用RNA斑点杂交的方法对叶片中Phy A mRNA丰度进行分析的结果表明,光周期处理5d和10d时,两品种水稻的Phy A mRNA丰度都是SD处理的比LD的高,而且SD下农垦58S Phy A mRNA的丰度均比“农垦58”的高。这些结果表明,甲基化水平较低的农垦58S phy A可能比“农垦58”的phy A更活跃地表达。另外,在育性转换敏感期每日主光期结束时(EOD)进行10次短暂的远红光(FR)照射。结果表明,农垦58S植株抽穗和开花期比SD处理推迟2d,而花粉败育率、种子结实率却无变化。暗示农垦58S开花和育性转变过程的光周期反应可能不同。     

水稻不育系安农S-1育性转换及相关基因的表达分析

通过在自然环境和高温温室内对安农S-1的不同部位进行高温、低温诱导处理,对水稻温敏核不育系安农S-1的温度敏感时期和诱导部位进行了研究。总共进行了8种处理,结果表明：安农S-1的育性转换时期是从花粉母细胞形成到减数分裂的四分体时期之前。在育性转换时期,处于高温的条件下,根部低温处理不能诱导安农S-1可育,穗部低温处理可以使安农S-1保持可育,可见安农S-1的温度敏感部位在幼穗。aprz基因和育性相关,用RT-PCR方法研究了aprt基因在安农S-1不同部位和不同温度环境的表达变化,结果显示,在幼穗中aprt基因的表达在高温环境中被大幅度下调,而在叶中和根中的变化比较小,这说明幼穗对温度最敏感,从侧面验证了引起安农S-1育性转换的温度敏感部位是在幼穗。     

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.     

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.     

Aanlysis of short photo-periodic sensitive genic male sterility and molecular mapping of rpms3(t) gene in rice (Oryza sativa L.) using SSR markers

A research was conducted on the pollen fertility of rice sterile lines D52S and D38S responsive to photoperiod during the sensitive stage under natural and controlled conditions. Bulk segregant analysis (BSA) and recessive class approach were applied to identify DNA markers that co-segregate with gene conferring male-sterility in D52S mutant rice. The results showed that in day-light higher or equal to 14.00 h, D52S and D38S rice pollen were fertile; however, they were sterile when day-length was less than 14.00 h. They were therefore considered to be short photo-periodic sensitive genic male sterile lines(Short PGMS lines). Under short day-light conditions, the pollen fertility segregation of F₂ populations from crosses between D52S/Shuhui527 and D52S/Gui99showed 3:1 ratio of fertile to sterile plants suggestingthat male sterility in D52S was controlled by one recessive gene. Two markers RM244 and RM216 located on chromosome number 10 co-segregated completely with the rpms locus. The locus was mapped to the interval between SSR markers RM2571 (6.6 cM) and RM244 (4.6 cM).