深水稻节间伸长生长的机制

淹水可促进深水稻节间快速伸长生长,其主要受内源赤霉素、乙烯、脱落酸等激素信号分子的调控。淹水能促进深水稻植物株体内乙烯、赤霉素的生物合成、抑制脱落酸的生物合成,外源乙烯、赤霉素会加速深水稻节间伸长,而外源脱落酸抑制淹水节间的伸长,其中赤霉素是直接作用因子,乙烯能降低内源脱落酸水平、增加节地赤霉素的敏感性;还与渗透调节、细胞壁组份如膨胀素等有关,淹水及赤霉素都大大增加了膨胀素基因的表达。并就深水稻的     

甘蔗节间伸长过程赤霉素生物合成关键基因的表达及相关植物激素动态变化

以甘蔗(Saccharum officinarum)优良品种桂糖42号(GT42)为研究材料, 分别于未伸长期(9-10叶龄以前) (Ls1)、伸长初期(12-13叶龄) (Ls2)和伸长盛期(15-16叶龄) (Ls3)取甘蔗第2片真叶(自顶部起)对应的节间组织, 测定其赤霉素(GA)、生长素(IAA)、油菜素甾醇(BR)、细胞分裂素(CTK)、乙烯(ETH)和脱落酸(ABA)的含量, 并通过实时荧光定量PCR (qRT-PCR)分析赤霉素合成途径关键基因GA₂₀氧化酶基因(GA20-Oxidase1)、赤霉素受体基因(GID1)和DELLA蛋白编码基因(GAI)的差异表达。结果表明, 在甘蔗伸长期间, GA和IAA含量呈现上升趋势, CTK和ABA含量呈下降趋势, ETH含量先上升后下降, BR含量则变化不明显; GA20-Oxidase1和GID1的表达呈上升趋势, 而GAI的表达则呈下降趋势, 这与相关植物激素的变化基本一致。综上, 甘蔗节间伸长过程主要与GA和IAA相关, 其次为CTK和ABA, 而ETH受到IAA的调控影响节间伸长; 植物激素间通过相互作用调控GA20-Oxidase1、GID1和GAI的表达, 影响GA含量和GA的信号转导过程, 进而影响甘蔗节间的伸长。该研究揭示了甘蔗节间伸长过程中赤霉素生物合成途径和信号转导关键基因的差异表达及植物激素含量的动态变化规律。     

甘蔗节间伸长过程赤霉素生物合成关键基因的表达及相关植物激素动态变化

以甘蔗(Saccharum officinarum)优良品种桂糖42号(GT42)为研究材料, 分别于未伸长期(9-10叶龄以前) (Ls1)、伸长初期(12-13叶龄) (Ls2)和伸长盛期(15-16叶龄) (Ls3)取甘蔗第2片真叶(自顶部起)对应的节间组织, 测定其赤霉素(GA)、生长素(IAA)、油菜素甾醇(BR)、细胞分裂素(CTK)、乙烯(ETH)和脱落酸(ABA)的含量, 并通过实时荧光定量PCR (qRT-PCR)分析赤霉素合成途径关键基因GA₂₀氧化酶基因(GA20-Oxidase1)、赤霉素受体基因(GID1)和DELLA蛋白编码基因(GAI)的差异表达。结果表明, 在甘蔗伸长期间, GA和IAA含量呈现上升趋势, CTK和ABA含量呈下降趋势, ETH含量先上升后下降, BR含量则变化不明显; GA20-Oxidase1和GID1的表达呈上升趋势, 而GAI的表达则呈下降趋势, 这与相关植物激素的变化基本一致。综上, 甘蔗节间伸长过程主要与GA和IAA相关, 其次为CTK和ABA, 而ETH受到IAA的调控影响节间伸长; 植物激素间通过相互作用调控GA20-Oxidase1、GID1和GAI的表达, 影响GA含量和GA的信号转导过程, 进而影响甘蔗节间的伸长。该研究揭示了甘蔗节间伸长过程中赤霉素生物合成途径和信号转导关键基因的差异表达及植物激素含量的动态变化规律。     

微管骨架在轮藻节间细胞伸长生长中的作用

利用免疫荧光定位及激光共聚焦扫描显微镜,结合细胞生长曲线的定量测定,对不同生长阶段的轮藻节间细胞微管骨架进行了观察研究,结果如下：轮藻顶端生长活跃的新生细胞中,与细胞长轴垂直的周质微管(cortical microtubules)占绝对优势,随着生长速率的减慢,周质微管由垂直于细胞长轴逐渐转为平行排列;基部生长基本停止的节间细胞中,胞内微管则以平行细胞长轴为主;不同生长阶段节间细胞的微管骨架,对微管特异解聚剂黄草消(oryzalin)处理的敏感性表现不相同。顶端生长活跃的节间细胞经oryzalin处理40min后,绝大多数周质微管发生解聚;而基部生长基本停止的老细胞中,即使延长处理时间,仍残留一些尚未完全解聚的微管片段;10μmol／L微管解聚剂oryzalin处理轮藻顶端新生细胞,在高精度的细胞伸长生长测定装置监测下,发现oryzalin对细胞的伸长生长速率有明显的抑制作用,去掉药剂后,伸长生长又有一定的恢复。并且发现,经oryzalin处理后,微管的解聚(40min左右)与顶端节间细胞伸长生长的停止(100min左右)两者间存在着时间上的差异,即微管解聚在先,细胞伸长停止在后。以上结果均说明微管骨架在轮藻节间细胞生长中具有重要作用。     

麻竹节间伸长过程的初步研究

竹子秆茎的快速生长是禾本科生物学的一个未解之谜,而秆茎的生长又是以节间为单位进行的。本研究以第8节为标准节,利用统计学及石蜡切片的方法,获得了麻竹的节间伸长曲线以及节间组织发育的形态解剖信息。麻竹节间的伸长呈现“慢-快”的生长趋势,早期节间以细胞分裂为主,然后节间由上到下逐渐进入细胞伸长阶段,最后节间停止伸长进入成熟生长阶段。本研究为大型丛生竹节间发育的研究提供了基础数据,有助于推动对竹子笋株快速生长机制的研究。     

微管骨架在轮藻节间细胞伸长生长中的作用

利用免疫荧光定位及激光共聚焦扫描显微镜,结合细胞生长曲线的定量测定,对不同生长阶段的轮藻节间细胞微管骨架进行了观察研究,结果如下:轮藻顶端生长活跃的新生细胞中,与细胞长轴垂直的周质微管(cortical microtubules)占绝对优势,随着生长速率的减慢,周质微管由垂直于细胞长轴逐渐转为平行排列;基部生长基本停止的节间细胞中,胞内微管则以平行细胞长轴为主;不同生长阶段节间细胞的微管骨架,对微管特异解聚剂黄草消(oryzalin)处理的敏感性表现不相同。顶端生长活跃的节间细胞经oryzalin处理40min后,绝大多数周质微管发生解聚;而基部生长基本停止的老细胞中,即使延长处理时间,仍残留一些尚未完全解聚的微管片段;10μmol/L微管解聚剂oryzalin处理轮藻顶端新生细胞,在高精度的细胞伸长生长测定装置监测下,发现oryzalin对细胞的伸长生长速率有明显的抑制作用,去掉药剂后,伸长生长又有一定的恢复。并且发现,经o-ryzalin处理后,微管的解聚(40min左右)与顶端节间细胞伸长生长的停止(100min左右)两者间存在着时间上的差异,即微管解聚在先,细胞伸长停止在后。以上结果均说明微管骨架在轮藻节间细胞生长中具有重要作用。     

赤霉素和脱落酸对黑稻黄化幼苗中胚轴伸长生长的作用研究

研究了不同浓度的GA和ABA对三种黑稻黄化幼苗中胚轴伸长生长的影响。结果表明 :1.2 5 μmol/L的GA和ABA对三种黑稻黄化幼苗中胚轴的伸长生长有显著的促进作用 ,GA效应高于ABA ;三个供试稻种中 ,黑帅对GA和ABA的反应最为显著 ,且GA和ABA对其有叠加效应     

表油菜素内酯促进小麦胚芽鞘伸长的作用

BR促进小麦胚芽鞘伸长的生理活性大于IAA,但高浓度的促进现象不如IAA明显。BR刺激乙烯生成与浓度相关。BR和IAA混合处理,对芽鞘切段的伸长、乙烯释放和H~+分泌都表现了加成作用。这二种激素在作用时间上有明显的差别,BR作用的滞后期更为清楚。BR有拮抗ABA对小麦胚芽鞘切段伸长的抑制作用。     

春小麦胚芽伸长过程中渗透调节与能量代谢

本文用PEG模拟水分亏缺对春小麦红芒麦和绵阳11号胚芽伸长过程中生长、膨压、渗透势、水势和渗透调节能力与ATP含量、能荷变化及能量代谢间的关系进行了研究。结果表明,通过降低能荷,改变分解代谢与合成代谢的比率,使渗透调节物质积累,增加了幼苗的吸水能力,从而使其在一定的ATP能量水平上维持缓慢生长;抗旱品种红芒麦在水分亏缺下成苗速率较快,能保持一定的ATP能量水平和能荷值,渗透调节和吸水能力都比较强。     

赤霉素诱导甘蔗节间伸长的cDNA-AFLP差异显示

以‘新台糖22号’甘蔗为材料,在其伸长初期以200mg/L的赤霉素进行叶面喷施处理,对照喷清水,分别提取对照和处理(0、6、12、24h)的总RNA进行等量混合,获得2种不同处理的样品池,采用cDNA-AFLP技术对赤霉素诱导下甘蔗节间伸长的差异表达进行分析。结果显示:(1)通过169对引物组合的选择性扩增,共得到了约11 000条大小在50～700bp的cDNA片段,获得186条差异条带。(2)经反向Northern杂交,于结果显示阳性的TDFs中选取56个片段进行克隆和序列分析,获得56条大小在80～500bp的差异条带。(3)经BLAST分析,按功能可将获得的56条TDFs分为7类,分别为能量与代谢相关基因、未知功能蛋白、未知基因、植物抗性相关基因、细胞壁生物合成与修饰相关基因、信号传导相关基因和转录因子相关基因。该研究获得了一些与甘蔗节间伸长相关的差异基因片段,为进一步研究甘蔗节间伸长的分子机理奠定了基础。     

Expansins and Internodal Growth of Deepwater Rice

The distribution and activity of the cell wall-loosening protein expansin is correlated with internodal growth in deepwater rice (Oryza sativa L.). Acid-induced extension of native cell walls and reconstituted extension of boiled cell walls were confined to the growing region of the internode, i.e. to the intercalary meristem (IM) and the elongation zone. Immunolocalization by tissue printing and immunoblot analysis, using antibody against cucumber expansin 29 as a probe, confirmed that rice expansin occurred primarily in the IM and elongation zone. Rice expansin was localized mainly around the vascular bundles at the base of the IM and along the inner epidermal cell layer surrounding the internodal cavity. Submergence greatly promoted the growth of rice internodes, and cell walls of submerged internodes extended much more in response to acidification than did the cell walls of air-grown internodes. Susceptibility of cell walls to added expansin was also increased in submerged internodes, and analysis by immunoblotting showed that cell walls of submerged internodes contained more expansin than did cell walls of air-grown internodes. Based on these data, we propose that expansin is involved in mediating rapid internodal elongation in submerged deepwater rice internodes.     

Influence of Humidity on Ethylene-Induced Internodal Elongation in Floating Rice

When sections of floating rice stems were treated with 1-aminocyclopropane-l-carboxylicacid (ACC) at 60% relative humidity, their ethylene contentincreased but internodes hardly elongated. The internodal elongationinduced by ethylene was promoted in sections incubated at 100%relative humidity but not at 20%. Thus, ethylene-induced internodalelongation in floating rice requires moist surroundings. (Received April 25, 1990; Accepted December 22, 1990)     

Ethylene and Gibberellin: Regulation of Internodal Elongation and Nodal Root Development in Floating Rice

Ethylene and GA₃ stimulated internodal elongation in the excisedstem sections of floating rice. The combined application ofethylene and GA₃ exerted a cooperative effect on internodalelongation, although the effect was variety dependent. Stimulativeeffect of ethylene on internodal growth in intact floating riceplants was virtually absent when the plants were pre-treatedwith Ancymidol, -cyclopropyl--(4-methoxyphenyl)-5-pyrimidinemethanol, an inhibitor of gibberellin biosynthesis. Submergenceof intact plants, which also induced internodal elongation,had no stimulative effect when the plants were pre-treated withAncymidol. Submergence of intact plants increased the endogenousgibberellin level. The internode of young, intact 9 day oldseedlings responded neither to submergence nor ethylene, butwhen seedlings were pre-treated with GA₃ they responded to eitherone. Nodal root development was also enhanced by either ethyleneor GA₃. Combined application of ethylene and GA₃ exerted a co-operativeeffect on nodal root development. Ancymidol-treated plants didnot produce nodal roots even though they were subjected to submergence,whereas nontreated control plants produced nodal roots normally. (Received September 12, 1984; Accepted February 15, 1985)     

水稻茎伸长生长与植物激素

赤霉素（GA）,生长素（IAA）,脱落酸（ABA）和乙烯影响水稻茎（或节间）的伸长,其中赤霉素与水稻茎伸长生长的关系最密切。GA1是植物体内刺激茎伸长的至关重要的赤霉素,GA3已作为最常用的外源激素诱导水稻的节间伸长。水稻茎秆的伸受激素浓度和敏感性的双重控制,激素浓度或敏感性任一方的改变都有可能导致株高的变异。赤霉素如此显著地促进茎的伸长可能与增加细胞分裂和促使细胞壁松弛有关。而生长素主要促进细胞伸长。植物激素促进水稻茎长的分子机理的研究已有较大的进展,预期这方面的研究和应用在未来几年内将有新的突破。     

水稻茎伸长生长与植物激素

赤霉素（GA）、生长素（IAA）、脱落酸（ABA）和乙烯影响水稻茎（或节间）的伸长,其中赤霉素与水稻茎伸长生长的关系最密切。GA1是植物体内刺激茎伸长的至关重要的赤霉素, GA3已作为最常用的外源激素诱导水稻的节间伸长。水稻茎秆的伸长受激素浓度和敏感性的双重控制,激素浓度或敏感性任一方的改变都有可能导致株高的变异。赤霉素如此显著地促进茎的伸长可能与增加细胞分裂和促使细胞壁松弛有关。而生长素主要促进细胞伸长。植物激素促进水稻茎伸长的分子机理的研究已有较大的进展,预期这方面的研究和应用在未来几年内将有新的突破。     

Polyamines and Anaerobic Elongation of Rice Coleoptile

The role of polyamines in the anaerobic elongation of rice (Oryzasativa L.) coleoptiles was studied. The reduced growth of ricecoleoptiles under anoxic conditions was accompanied by a massiveaccumulation of free putrescine. Putrescine was synthesizedfrom arginine in a reaction catalyzed by arginine decarboxylase(ADC). The anoxic titer of putrescine was closely correlatedwith elongation of coleoptiles. In experiments in which putrescineand inhibitors [-difluoromethylarginine (DFMA) and -difluoromethylornithine(DFMO)] of the synthesis of polyamines were exogenously supplied,we demonstrated an absolute requirement for putrescine, synthesizedby ADC, for anaerobic elongation of coleoptiles. The presenceof exogenous putrescine (alone or in combination with DFMA)increased the rate of anaerobic elongation of coleoptile by30–40%. (Received December 1, 1988; Accepted June 19, 1989)     

The Molecular Mechanism of Eukaryotic Elongation Factor 2 Kinase Activation

Calmodulin (CaM)-dependent eukaryotic elongation factor 2 kinase (eEF-2K) impedes protein synthesis through phosphorylation of eukaryotic elongation factor 2 (eEF-2). It is subject to complex regulation by multiple upstream signaling pathways, through poorly described mechanisms. Precise integration of these signals is critical for eEF-2K to appropriately regulate protein translation rates. Here, an allosteric mechanism comprising two sequential conformations is described for eEF-2K activation. First, Ca²⁺/CaM binds eEF-2K with high affinity (K_d(CaM)^app = 24 ± 5 nm) to enhance its ability to autophosphorylate Thr-348 in the regulatory loop (R-loop) by > 10⁴-fold (k_auto = 2.6 ± 0.3 s⁻¹). Subsequent binding of phospho-Thr-348 to a conserved basic pocket in the kinase domain potentially drives a conformational transition of the R-loop, which is essential for efficient substrate phosphorylation. Ca²⁺/CaM binding activates autophosphorylated eEF-2K by allosterically enhancing k_cat^app for peptide substrate phosphorylation by 10³-fold. Thr-348 autophosphorylation results in a 25-fold increase in the specificity constant (k_cat^app/K_m(Pep-S)^app), with equal contributions from k_cat^app and K_m(Pep-S)^app, suggesting that peptide substrate binding is partly impeded in the unphosphorylated enzyme. In cells, Thr-348 autophosphorylation appears to control the catalytic output of active eEF-2K, contributing more than 5-fold to its ability to promote eEF-2 phosphorylation. Fundamentally, eEF-2K activation appears to be analogous to an amplifier, where output volume may be controlled by either toggling the power switch (switching on the kinase) or altering the volume control (modulating stability of the active R-loop conformation). Because upstream signaling events have the potential to modulate either allosteric step, this mechanism allows for exquisite control of eEF-2K output.     

Light-Dependent Short-Term Modulations of Elongation in Rice Plants

The elongation of rice shoots (Oryza saliva L.) exposed to variouslight conditions was measured using angular movement transducers.Plants growing in continuous light responded to a sudden increasein light fluence rate with a pronounced decrease in the rateof elongation. The growth rate returned to the initial steadystate within 15-60 min, depending on the difference in fluencerate between the continuous and the supplemental light. Whenthe fluence rate was reduced to its original level, the elongationrate rose transiently before returning to the initial value.The inhibition of elongation was fluence dependent, and blueand red light were more effective in reducing the elongationrate than was green or infrared irradiation. Irradiation ofa single tiller affected also other tillers of the same plantwhich were shielded from the light. Measurements of transpirationand water uptake by whole plants and of leaf temperatures indicatedthat the transient changes in growth rates were caused by perturbationsin the water balance of the plant. (Received December 5, 1988; Accepted February 7, 1989)