水稻胚胎发生与萌发早期分离胚中内源激素的变化

以酶联免疫吸附检测技术分析了水稻(Oryza sativa ssp. japonica)分离胚不同发育时期及萌发早期的内源激素含量的动态变化.GA1含量是所测激素中含量最高的.GA1的变化趋势基本上与ABA相反.花后4 d的胚中GA1和ABA的含量最高;花后8 d到18 d,GA1的含量下降,而ABA含量增加.在早期萌发过程中,种子吸涨后2 d的胚中GA1含量迅速上升,而ABA下降.GA1/ABA的最高比值也出现在吸涨后2 d的胚中.iPAs和ZRs的最高含量也出现在开花后4 d的胚中,但随后含量均下降到相当低的水平,并几乎没有变化.研究结果进一步证实了GA1在早期胚胎发生和萌发过程中起重要的作用;推测iPAs和ZRs可能仅在胚胎发生的早期起作用;GA1与ABA含量之间的相对平衡控制着胚胎发育的过程.用分离胚作为测试材料可以避免胚乳等其他组织成分的干扰,从而比较准确地反映了胚的内源激素变化.此外,本研究是首次用4 d的水稻幼胚作为激素含量测定的起始材料.     

无花果花芽分化与内源激素含量的关系

在‘布兰瑞克’无花果花芽分化形态学研究的基础上,对花芽分化期无花果新梢第7或第8节位花芽中的玉米素核苷(ZRs)、脱落酸(ABA)、赤霉素(GA1 3)、生长素(IAA)4种内源激素含量的变化进行了探讨。结果表明,在无花果花芽分化阶段,GA1 3和IAA初期含量较高,后快速下降,后期稳定在较低水平;ZRs和ABA在初期含量较低,后大幅提高,后期稳定在较高水平。可见,较高水平的内源ZRs、ABA和较低水平的内源GA1 3、IAA,以及较高的ABA/IAA、ABA/GA1 3、ZRs/GA1 3和ZRs/IAA比值有利于无花果花芽分化。     

梾木种子低温层积过程中内源激素含量的动态变化特征

应用酶联免疫吸附测定法(ELISA)研究了梾木种子低温层积过程中内源激素含量的动态变化,分析了内源激素与种子休眠与发芽的关系。结果表明:(1)梾木种子中IAA含量在层积处理初期剧烈降低,持续一段时间后又显著升高,但后期下降,且IAA/ABA也出现同样的变化;种子中ABA含量在层积处理前期较高,但随着处理时间的延长趋于下降;种子内GA1/3含量以及GA1/3/ABA均随层积处理时间的延长逐渐增大;种子内ZRs和iPAs含量的变化相对较为平稳,尽管有一定的波动,但整体呈渐趋增高趋势。(2)梾木种子发芽率及发芽势在未经层积处理以及处理时间少于90d的条件下均为0,但随着层积处理时间的延长二者明显上升,层积处理的时间长短对梾木种子萌发有显著影响。(3)相关分析表明,梾木种子内GA1/3含量与种子的发芽率、发芽势均呈显著正相关关系,相关系数分别为0.688、0.662;种子内GA1/3/ABA增大有利于种子休眠解除和萌发。     

党参体细胞胚胎发生早期阶段内源脱落酸和细胞分裂素的变化

以党参为实验材料,在附加1mg／L2,4-D3％或7％蔗糖的MS培养基上,成功获得体细胞胚胎发生同步化较高的实验体系。用ELISA方法测定了胚性细胞形成球形胚的过程中,内源ABA和CTK的含量变化。结果表明,在这一过程中内源ABA含量持续增加;内源CTK的组分和含量均发生很大变化,表现在组分iPAs在球形胚形成前急剧增加,球形胚形成期急剧下降,组分ZRs在球形胚形成前上升较缓慢,球形胚形成期急剧上升。     

GA3和变温层积对天女木兰种子萌发及内源激素的影响

用不同质量浓度GA3浸泡天女木兰种子并结合变温层积处理,应用高效液相色谱法对不同时期种子中4种激素GA3、IAA、ABA、ZR含量进行测定,并测量种胚长和萌发率,以探讨天女木兰种胚发育,内源激素含量变化与种子休眠萌发之间的调控关系,为进一步研究种子休眠机理提供理论基础。结果表明:(1)天女木兰成熟种子胚发育不完全,胚乳内高浓度ABA和低浓度GA3是其休眠的主要原因。(2)GA3处理能促使天女木兰种子提前30d完成形态后熟,并以1 500mg·L-1 GA3处理效果最佳。(3)在变温层积过程,天女木兰种胚发育可分三个阶段:阶段Ⅰ(0~70d)完成种胚进一步分化;阶段Ⅱ(70~120d)种胚快速生长时期;阶段Ⅲ(120~150d)休眠完全解除,种子具备发芽能力。种子能否打破休眠主要取决于阶段Ⅰ和Ⅱ的状况。(4)GA3/ABA、IAA/ABA和ZR/ABA在种子后熟期间的变化同胚生长发育存在一致性,认为内源激素的相对水平对种子休眠具有重要的调控作用。     

4PU-30对水稻叶片衰老与内源激素的调控

4PU－30能显著地延缓水稻叶片衰老。根据叶片衰老过程中内源激素含量的变化,可明确减缓水稻叶片衰老期间内源ABA含量的增加和内源ZRs、GAs和IAA含量的减少,使叶片中保持有较低水平的ABA与较高水平的ZRs、GAs和IAA,是4PU－30延缓水稻叶片衰老的主要调控机理。     

水稻细胞质雄性不育系及其保持系幼穗发育过程中内源激素的变化

利用酶联免疫测定技术研究了水稻细胞质雄性不育系珍汕97A及其保持系珍汕97B在幼穗发育过程中叶片、幼穗和花药中内源IAA、GA1＋4、ABA和iPAs含量的动态变化。结果表明,1）从幼穗发育的雌雄蕊形成期到三核花粉期,保持系叶片中IAA水平高于不育系,并在二核花粉期最高;在幼穗和花药中也以保持系为高。2）保持系与不育系叶片中GA1＋4含量变化趋势相似,均为先升后降,但从单核到三核花粉期以保持系为高;在幼穗和花药中也都以保持系为高。3）不育系叶片中ABA水平在幼穗发育早期明显高于保持系,中期与保持系相近,后期又高于保持系;在幼穗和花药中也都以不育系为高。4）保持系叶片、幼穗和花药中iPAs含量始终显著高于不育系。5）保持系叶片中IAA＋GA1＋4＋iPAs与ABA之比值也始终高于不育系。提示不育系叶片、幼穗和花药中IAA、GA1＋4、iPAs和ABA含量出现了异常,且IAA、GA1＋4和iPAs亏缺以及ABA盈积可能与水稻细胞质雄性不育发生有关。     

油菜生长发育期间内源激素含量的变化

初花期至盛花期华双3号、华杂4号、恢5900等3个品种花蕾的iPAs含量呈明显上升趋势,而秦油2号则刚好相反(表2)。对双低品种华双3号功能叶的研究表明：苗期至盛花期IAA含量始终最高,其后依次是GA1 3;、iPAs、ABA。功能叶IAA的含量在越冬期处于整个生育期的最低水平,蕾薹期达到高峰,随后下降：GA1 3和iPAs含量随生育进程逐渐升高,并在初花期达到峰值;ABA在苗期及抽薹后一直处于很低水平,但在越冬期达到最高值(图1、2)。蕾薹期IAA主要分布在幼嫩和正在生长的器官中并起重要作用,而在功能叶中相对要少;幼叶GA1 3和iPAs含量最高,功能叶其次,花蕾最低(表1)。角果皮与籽粒的内源激素含量差异极显著,在开花后第39天,籽粒中IAA、GA1 3;、iPAs的含量大大超过角果皮(表3)。结果 表明iPAs在促进籽粒的充实饱满、物质积累转化方面发挥重要作用。     

桂花花芽分化期内源激素含量的变化

在桂花花芽分化期,采用酶联免疫吸附法(ELISA)测定桂花花芽内4种内源激素吲哚乙酸(IAA)、赤霉素(GA)、玉米素核苷(ZRs)和脱落酸(ABA)含量的动态变化.结果表明:在花芽生理分化期,GA和IAA含量有所增加,但在花芽形态分化开始以后GA的含量呈逐步下降趋势,直至分化结束;ZRs含量在花芽生理分化期呈上升趋势,在形态分化前期含量出现高峰,进入形态分化期后其含量下降;ABA含量在桂花花芽分化初期(苞片分化期)有逐步增加的趋势,在6月22日至7月2日达到最高水平,在花序分化以后至花芽形态分化结束,ABA的含量呈逐步下降趋势,但其变化相对平稳.研究认为桂花花芽分化期需要有高水平的ZRs、低水平的GA和IAA.     

离体玉米茎尖直接形成雌、雄花序过程中的内源激素含量变化

用我们实验室建立的离体玉米茎尖培养体系(李学红和张举仁1999),测定了离体玉米茎尖分生组织直接形成雌、雄花序过程中的内源ZRs、DHZRs、iPAs、IAA、GA1/3、ABA的含量变化。     

A method for profiling classes of plant hormones and their metabolites using liquid chromatography-electrospray ionization tandem mass spectrometry: an analysis of hormone regulation of thermodormancy of lettuce (Lactuca sativa L.) seeds

A highly selective and sensitive method for the simultaneous analysis of several plant hormones and their metabolites is described. The method combines high-performance liquid chromatography (HPLC) with positive and negative electrospray ionization-tandem mass spectrometry (ESI-MS/MS) to quantify a broad range of chemically and structurally diverse compounds. The addition of deuterium-labeled analogs for these compounds prior to sample extraction permits accurate quantification by multiple reaction monitoring (MRM). Endogenous levels of abscisic acid (ABA), abscisic acid glucose ester (ABA-GE), 7'-hydroxy-abscisic acid (7'-OH-ABA), phaseic acid (PA), dihydrophaseic acid (DPA), indole-3-acetic acid (IAA), indole-3-aspartate (IAAsp), zeatin (Z), zeatin riboside (ZR), isopentenyladenine (2iP), isopentenyladenosine (IPA), and gibberellins (GA)1, GA3, GA4, and GA7 were determined simultaneously in a single run. Detection limits ranged from 0.682 fmol for Z to 1.53 pmol for ABA. The method was applied to the analysis of plant hormones and hormonal metabolites associated with seed dormancy and germination in lettuce (Lactuca sativa L. cv. Grand Rapids), using extracts from only 50 to 100 mg DW of seed. Thermodormancy was induced by incubating seeds at 33 degrees C instead of 23 degrees C. Germinating seeds transiently accumulated high levels of ABA-GE. In contrast, thermodormant seeds transiently accumulated high levels of DPA after 7 days at 33 degrees C. GA1 and GA3 were detected during germination, and levels of GA1 increased during early post-germinative growth. After several days of incubation, thermodormant seeds exhibited a striking transient accumulation of IAA, which did not occur in seeds germinating at 23 degrees C. We conclude that hormone metabolism in thermodormant seeds is surprisingly active and is significantly different from that of germinating seeds.     

In Situ Abscisic Acid Synthesis : A Requirement for Induction of Embryo Dormancy in Helianthus annuus

When applied to young nondormant embryos of sunflower (Hellanthus annus) (7-10 day[s] after pollination [DAP]), abscisic acid (ABA) inhibited germination as long as it was present. However, whatever the dose used and the duration of its application, ABA was unable to induce dormancy because after transfer of treated embryos to control (without ABA) medium, germination occurred. Thereafter, exogenous ABA became effective and allowed the dormancy to develop in 13 and 17 DAP embryos, i.e. in embryos which after isolation were still able to germinate in high percentage. After embryo dormancy was well established (21 DAP), application of fluridone allowed the germination to occur very quickly on control medium. Isolated dormant axes were also induced to germinate by an application of fluridone. Radioimmunological analysis showed that 24 hours after these treatments, endogenous ABA levels were drastically reduced in the axes. When these fluridone-treated embryos were cultured on ABA medium, germination was again inhibited as long as exogenous ABA was present but germination occurred as soon as embryos were transferred to control medium. Such behavior suggested that in situ ABA synthesis is necessary to impose and maintain the embryo dormancy.     

Onset of desiccation tolerance during development of the barley embryo

We have investigated events which take place in the developing barley (Hordeum vulgare L.) embryo during its acquisition of desiccation tolerance. Excised embryos are capable of precocious germination as early as 8 d after pollination (DAP). At this age, however, they are not capable of resisting a desiccation treatment which induces a loss of 96–98% of their initial water content. At 16 DAP the embryos germinate despite the drastic drying treatment. The pattern of in-vivo and in-vitro proteins synthesized by the developing embryos from 12 DAP (desiccation-intolerant) and 16 DAP (desiccation-tolerant) were compared. A set of 25–30 proteins was identified which is denovo synthesized or enhanced during the developmental period leading to desiccation tolerance. Abscisic acid (ABA; 100 M) applied in vitro for 5 d to 12-DAP embryos induces desiccation tolerance and represses a subset of polypeptides preferentially associated with 16-DAP embryos. During in vitro culture of barley embryos ABA stimulates the appearance of a set of proteins and prevents the precocious germination allowing embryogenesis to continue in vitro. It also suppresses a set of germination-related proteins which appear 4 h after the incubation of the dissected embryo on a germination medium without ABA. Almost all mRNAs remain functional for translation when isolated embryos are dried at the desiccation-intolerant and tolerant stages of embryo development.Abbreviations ABA abscisic acid - DAP days after pollination - GM germination medium - poly(A)RNA polyadenylated RNA - SDS sodium dodecyl sulfate     

Gibberellins and seed development in maize. II. Gibberellin synthesis inhibition enhances abscisic acid signaling in cultured embryos

Abscisic acid (ABA) is required for seed maturation in maize (Zea mays L.) and other plants. Gibberellins (GAs) are also present in developing maize embryos, and mutual antagonism of GAs and ABA appears to govern the choice between precocious germination or quiescence and maturation. Exogenous ABA can also induce quiescence and maturation in immature maize embryos in culture. To examine the role of GAs versus ABA in regulating maize embryo maturation, the effects of modulating GA levels were compared with those of ABA in embryos cultured at successive stages of development. The effects of GA synthesis inhibition or exogenous GA application differed markedly in embryos at different stages of development, indicating changes in both endogenous GA levels and in the capacity for GA synthesis as embryogenesis and maturation progress. In immature embryos, the inhibition of GA synthesis mimicked the effects of exogenous ABA, as shown by the suppression of germination, the acquisition of anthocyanin pigments, and the accumulation of a variety of maturation-phase mRNAs. We suggest that GA antagonizes ABA signaling in developing maize embryos, and that the changing hormone balance provides temporal control over the maturation phase.     

Seed development and vivipary in Zea mays L.

Seed development was investigated in kernels of developing wild-type and viviparous (vp-1) Zea mays L. Embryos and endosperm of wild-type kernels began to dehydrate at approx. 35 d after pollination (DAP); viviparous embryos did not desiccate but accumulated fresh weight via coleoptile growth in the caryopses. Concentrations of endogenous abscisic acid (ABA) in the embryo were relatively high early in development, being approx. 150 ng·g^-1 fresh weight at 20 DAP. The ABA content declined thereafter, falling to approx. 50 ng·g^-1 at 30 DAP. Endosperm ABA content was always low, being less than 20 ng·g^-1. There were no differences between wild-type and vp-1 tissues. Immature kernels did not germinate when removed from the ear until late in development. The ability to germinate was correlated with decreasing moisture content in the endosperm at the time of removal; premature drying of immature kernels resulted in greatly increased germination following imbibition. Excised embryos germinated precociously when removed from the endosperm as early as 25 DAP. Such germination could be prevented by treatment with 10^-5 M ABA or by lowering the solute potential (_s) of the medium with 0.3 M mannitol. Treatment of excised embryos with ABA led to internal ABA concentrations comparable to those in embryos in which germination was inhibited in situ. Mannitol treatment did not have this effect, although water-deficit stress of excised embryos resulted in substantial ABA production. Germinated vp-1 embryos were less sensitive to growth inhibition by ABA or mannitol than germinating wild-type embryos. The vp-1 seedlings were not wilty and their transpiration rates were reduced in response to ABA or water shortage.Abbreviations and symbols ABA abscisic acid - DAP days after pollination - FW fresh weight - vp-1 viviparous genotype - _s solute potential     

A role for brassinosteroids in germination in Arabidopsis

This paper presents evidence that plant brassinosteroid (BR) hormones play a role in promoting germination. It has long been recognized that seed dormancy and germination are regulated by the plant hormones abscisic acid (ABA) and gibberellin (GA). These two hormones act antagonistically with each other. ABA induces seed dormancy in maturing embryos and inhibits germination of seeds. GA breaks seed dormancy and promotes germination. Severe mutations in GA biosynthetic genes in Arabidopsis, such as ga1-3, result in a requirement for GA application to germinate. Whereas previous work has shown that BRs play a critical role in controlling cell elongation, cell division, and skotomorphogenesis, no germination phenotypes have been reported in BR mutants. We show that BR rescues the germination phenotype of severe GA biosynthetic mutants and of the GA-insensitive mutant sleepy1. This result shows that BR stimulates germination and raises the possibility that BR is needed for normal germination. If true, we would expect to detect a germination phenotype in BR mutants. We found that BR mutants exhibit a germination phenotype in the presence of ABA. Germination of both the BR biosynthetic mutant det2-1 and the BR-insensitive mutant bri1-1 is more strongly inhibited by ABA than is germination of wild type. Thus, the BR signal is needed to overcome inhibition of germination by ABA. Taken together, these results point to a role for BRs in stimulating germination.     

无花果花芽分化过程中内源激素含量的变化

无花果花芽分化过程中的花托和小花形成阶段,新梢第7或第8节位芽中,脱落酸（ABA）和玉米素核苷（ZRs）含量先升高,后保持高水平：生长素（IAA）和赤霉素（GA1＋3）含量先下降,后保持低水平。