茉莉酸调控花药开裂的研究进展

茉莉酸(JA)是广泛存在于植物中的生长调节物质,JA及其衍生物茉莉酸甲酯(Me JA)在植物生命活动中起着重要作用。JA参与调控雄蕊发育,影响花药开裂,从而影响植物育性。就JA的生物合成及相关基因的表达调控、JA在植物花药发育尤其是后期花药开裂过程中相关基因以及信号转导的分子机制研究进行回顾总结,并对JA调控花药开裂的分子机理研究提出展望。     

植物MYB转录因子在花药发育中的调控作用

MYB转录因子作为最大的转录因子家族之一,参与植物的生长发育、胁迫反应、产物代谢等过程,在植物花的发育特别是花药发育过程中发挥着重要的调控作用。花药的发育在植物繁殖后代中起关键作用,文中就MYB转录因子在花药绒毡层发育、花药开裂、花粉发育、糖类物质和激素途径等方面对花药发育过程中的调控作用进行总结,以期为植物花药发育调控机制及调控网络的深入研究提供可行的参考。     

生态因子对滇重楼花药开裂的影响

滇重楼为延龄草科重楼属植物,具有极高的药用价值,由于重楼传统药用部位生长缓慢、繁殖力低下,以及人们对野生重楼资源的过度采挖使其资源日趋枯竭。滇重楼的花药在整个花期中存在开裂－关闭的现象,花药的有效闭合应是保护花粉、延长花粉寿命、增强雄性适合度的一种适应机制。该研究以滇重楼为对象,通过设计正交实验和对比实验,观测其花药开裂过程中的光照强度、温度、湿度的变化,探究光照强度、温度、湿度等生态因子对滇重楼花药开裂的影响以及滇重楼花药开裂与生态因子变化的关系。结果表明：(1)在滇重楼花药开裂的过程中,光照强度增强、温度升高、相对湿度下降;(2)温度是影响滇重楼花药开裂时间的主导因子,升温促进花药开裂,降温促进花药关闭;(3)高湿度及黑暗推迟花药开裂,但并不能阻止花药开裂;(4)低温可使滇重楼花药持续关闭,而光照强度越高,花药持续关闭所需的温度越低。该研究有利于解释滇重楼花药白天开裂夜晚关闭的现象与环境因子的关系,对滇重楼的栽培育种提供理论指导。     

京白梨花药开裂异常的解剖学研究

比较研究了京白梨(Pyrus ussuriensis Maxim.)、鸭梨、雪花梨花药开裂特性、环境条件对花药开裂的影响以及花药开裂异常的解剖学结构,结果表明:(1)京白梨花药开裂率明显低于鸭梨和雪花梨,使其产生花粉的量较少,从而导致传粉能力较弱.(2)京白梨、鸭梨、雪花梨在环境温度为25℃,相对湿度在 60%～80%时最适宜花药开裂,但京白梨花药开裂率始终低于鸭梨和雪花梨.(3)在京白梨花药发育后期不能形成开裂腔是引起花药不开裂的主要原因,而导致开裂腔不能形成的原因可能与单核期的绒毡层细胞不退化和药室内壁细胞不进行'U'字型加厚有关.     

扁桃花药开裂前后壁层细胞形态变化及分析

为探明扁桃花药开裂前后壁层细胞形态变化,以鹰咀扁桃鳞片开裂期、小蕾期、大蕾期和盛花期的花蕾为研究材料,运用石蜡切片法结合铁苏木精染色法、考马斯亮蓝染色法、PAS染色法对花药壁层细胞进行染色;同时用Nikon SMZ-250体视显微镜拍摄花药开裂过程,观测花粉粒长、短轴长度。结果表明:(1)从鳞片开裂期到小蕾期,花粉粒的长、短轴长度都增大,多糖颗粒数量增多,绒毡层细胞完全消失,中层细胞和药隔处细胞逐渐溶解;药室内壁细胞切向长度增加幅度大于径向长度,内、外壁长度都增大,螺旋状纤维进一步形成;表皮细胞切向长度增加幅度大于径向长度。(2)从小蕾期到大蕾期花粉粒长、短轴长度明显增大,多糖颗粒持续增多;中层细胞和药隔处细胞大部分溶解;药室内壁细胞径向、切向长度持续增大,内壁长度增大、外壁长度趋于稳定,多糖颗粒数量减少,螺旋状纤维基本形成;表皮细胞切向减小幅度大于径向。(3)从大蕾期到花药半开裂,花粉粒长、短轴长度稍微增大;中层细胞和药隔处细胞完全溶解;药室内壁细胞切向长度持续增大,径向长度趋于稳定,内壁长度持续增大,外壁长度逐渐减小,多糖颗粒数量较少;表皮细胞切向、径向长度持续减小。(4)花药半开裂后,花粉粒长、短轴长度都减小;药室内壁细胞和表皮细胞切向、径向长度都减小;药室内壁细胞内、外壁长度减小并趋于接近,内壁长度减小趋势出现晚于外壁。研究认为,扁桃花药壁层细胞形态变化是花药开裂的基础,并与花药开裂密切相关。     

毛钩藤的小孢子发生和雄配子体发育

在光学显微镜和透射电镜下观察了毛钩藤(Uncaria hirsuta Havil.)的小孢子发生和雄配子体发育过程.结果表明,毛钩藤花两性,具5枚雄蕊,花药4室,花药壁由表皮、药室内壁、中层和绒毡层组成,花药开裂时,药室内壁高度纤维化带状加厚.花药壁的发育方式属于双子叶型,小孢子母细胞减数分裂的胞质分裂为同时型.小孢子在四分体时期开始沉积花粉外壁,小孢子大液泡化时期开始沉积花粉内壁.成熟花粉为2-细胞型.毛钩藤的花粉发育特征和茜草科植物基本一致.毛钩藤绒毡层属于分泌型,双重起源,分别起源于次生周缘层和药隔细胞.小孢子发育早期绒毡层开始降解并分泌形成大量乌氏体,花药开裂时绒毡层完全消失,剩下少量乌氏体.小孢子早期内壁加厚突出形成,小孢子细胞核分裂以后内壁加厚开始脱落,花药开裂时,只剩下少量的内壁加厚突出.初步推测,内壁加厚突出与乌氏体共同作用为雄配子体的发育提供营养物质.     

MYB类转录因子对花药和花粉发育的调控途径

花药发育和花粉形成的各个步骤由众多基因控制,一些转录因子通过调控花药发育相关基因的表达,是功能性花粉形成的关键因子。MYB类转录因子作为植物中最大的转录因子家族,是其中非常重要的一类转录因子。该文结合近年来国内外有关被子植物花粉发育相关MYB转录因子在花药发育和花粉形成的调控途径,包括绒毡层发育、胼胝质的沉积和降解、光合产物的运输、花药的开裂以及雄配子体形成过程中所起的重要作用等方面的研究进展,重点对MYB类转录因子通过形成对绒毡层发育、同化物分配、苯丙烷物质代谢等相关靶位基因的控制网络,转录调控植物花粉发育和花药开裂过程等研究进行综述讨论。     

文冠果可孕花与不孕花发育过程的比较研究

利用半薄切片和透射电镜技术对文冠果可孕花和不孕花的发育过程进行观察和比较。结果显示:(1)小孢子发育初期,两种类型花花药形态无明显差别;小孢子发育双核期,可孕花花药内壁纤维层细胞壁带状加厚,无唇细胞形成。而不孕花花药同侧两个花粉囊之间唇细胞正在分化;小孢子发育成熟期,不孕花花药唇细胞完全形成;散粉期,不孕花花药开裂呈双心形,而可孕花花药则不能开裂散粉。(2)可孕花雌蕊子房内有两室,柱头细胞排列紧密,柱头逐渐发育成圆球形,周围密布乳突细胞,具中空花柱道;不孕花雌蕊柱头停止发育,无中空花柱道,子房室变小,胚囊发育退化。(3)不孕花花药绒毡层中含大量蛋白体,小泡以及乌氏体等细胞器,发育后期绒毡层解体。而可孕花花药绒毡层中细胞器和营养物质积累均较少,发育后期绒毡层解体不完全。(4)可孕花花药内花粉粒细胞壁连续无萌发孔,细胞内含物较少。不孕花花药内花粉出现3个向内凹陷的萌发孔,且花粉内含有大量造粉质体和脂类物质。     

文冠果可孕花与不孕花发育过程的比较研究简

利用半薄切片和透射电镜技术对文冠果可孕花和不孕花的发育过程进行观察和比较。结果显示：(1)小孢子发育初期,两种类型花花药形态无明显差别;小孢子发育双核期,可孕花花药内壁纤维层细胞壁带状加厚,无唇细胞形成。而不孕花花药同侧两个花粉囊之间唇细胞正在分化;小孢子发育成熟期,不孕花花药唇细胞完全形成;散粉期,不孕花花药开裂呈双心形,而可孕花花药则不能开裂散粉。(2)可孕花雌蕊子房内有两室,柱头细胞排列紧密,柱头逐渐发育成圆球形,周围密布乳突细胞,具中空花柱道;不孕花雌蕊柱头停止发育,无中空花柱道,子房室变小,胚囊发育退化。(3)不孕花花药绒毡层中含大量蛋白体,小泡以及乌氏体等细胞器,发育后期绒毡层解体。而可孕花花药绒毡层中细胞器和营养物质积累均较少,发育后期绒毡层解体不完全。(4)可孕花花药内花粉粒细胞壁连续无萌发孔,细胞内含物较少。不孕花花药内花粉出现3个向内凹陷的萌发孔,且花粉内含有大量造粉质体和脂类物质。     

倒地铃花的形态分化与花药结构研究

利用体视显微镜、半薄切片和超薄切片法对倒地铃(Cardiospermum halicacabum Linn.)雄花和假两性花开花过程及花药发育过程进行了观察和比较研究。结果显示:(1)花蕾发育早期,倒地铃雄花和假两性花的花蕾形态没有区别;花蕾发育后期,雄花雌蕊退化,假两性花雌蕊继续发育,花蕾外部形态出现差异;开花时雄花花药开裂,假两性花花药不开裂。(2)倒地铃雄花和假两性花均具四室花药,呈蝶形;花药壁细胞从外到内依次是表皮、药室内壁、中层(2层)和绒毡层;花药壁发育为基本型,绒毡层为单核分泌型,四分体为四面体型,花粉粒两核;开花时雄花和假两性花中层都有残留;小孢子液泡化时,绒毡层开始降解,两核花粉粒时,假两性花绒毡层降解较快。(3)雄花药室内壁次生加厚完全,裂口区发育,连接同侧花粉囊的连接组织降解,花药开裂;假两性花药室内壁次生加厚不完全,具唇形细胞,药隔细胞壁未降解,同侧花粉囊未连通,花药四室,不开裂;假两性花成熟花粉粒细胞质稀少,内壁不完整。本研究结果表明,倒地铃的雄花是由两性花在发育早期雌蕊停止发育形成的,假两性花则由两性花在发育晚期雄蕊功能退化造成的。     

外源茉莉酸甲酯通过调节相关基因表达诱导光温敏雄性不育小麦BS366离体花药开裂

植物育性与花药开裂性状相关. 茉莉酮酸甲酯(methyl jasmonic acid, MeJA)是一种植物激素,广泛参与植物的胁迫应答和生长发育过程. 植物体内存在6类基因所编码的酶共同维持茉莉酮酸(JA)代谢途径的畅通,并与植物花药开裂有关. 本研究以小麦光温敏不育系BS366为材料,于抽穗期—开花期进行穗部离体48 h的 MeJA外源处理. 分别于0、1、3、6、12、24和48 h时间点收集花药并进行RNA提取. 通过半定量RT-PCR分析发现,在内参基因甘油醛-3-磷酸脱氢酶(glyceraldehyde-3- phosphate dehydrogenase, GAPDH)表达基本一致的情况下,BS366的JA代谢途径中参与调控的6种基因均存在不同程度的诱导表达. 经MeJA 的48 h处理后的离体花药开裂程度明显增大. 本研究获得了BS366离体环境下JA代谢途径基因经MeJA诱导后表达水平的概况,并为诱导BS366花药开裂及人工调控育性,达到高效制种及繁种的目的提供了初步的理论依据.     

The final split: the regulation of anther dehiscence

Controlling male fertility is an important goal for plant reproduction and selective breeding. Hybrid vigour results in superior growth rates and increased yields of hybrids compared with inbred lines; however, hybrid generation is costly and time consuming. A better understanding of anther development and pollen release will provide effective mechanisms for the control of male fertility and for hybrid generation. Male sterility is associated not only with the lack of viable pollen, but also with the failure of pollen release. In such instances a failure of anther dehiscence has the advantage that viable pollen is produced, which can be used for subsequent rescue of fertility. Anther dehiscence is a multistage process involving localized cellular differentiation and degeneration, combined with changes to the structure and water status of the anther to facilitate complete opening and pollen release. After microspore release the anther endothecium undergoes expansion and deposition of ligno-cellulosic secondary thickening. The septum separating the two locules is then enzymatically lysed and undergoes a programmed cell death-like breakdown. The stomium subsequently splits as a consequence of the stresses associated with pollen swelling and anther dehydration. The physical constraints imposed by the thickening in the endothecium limit expansion, placing additional stress on the anther, so as it dehydrates it opens and the pollen is released. Jasmonic acid has been shown to be a critical signal for dehiscence, although other hormones, particularly auxin, are also involved. The key regulators and physical constraints of anther dehiscence are discussed.     

The arabidopsis DELAYED DEHISCENCE1 gene encodes an enzyme in the jasmonic acid synthesis pathway

delayed dehiscence1 is an Arabidopsis T-DNA mutant in which anthers release pollen grains too late for pollination to occur. The delayed dehiscence1 defect is caused by a delay in the stomium degeneration program. The gene disrupted in delayed dehiscence1 encodes 12-oxophytodienoate reductase, an enzyme in the jasmonic acid biosynthesis pathway. We rescued the mutant phenotype by exogenous application of jasmonic acid and obtained seed set from previously male-sterile plants. In situ hybridization studies showed that during the early stages of floral development, DELAYED DEHISCENCE1 mRNA accumulated within all floral organs. Later, DELAYED DEHISCENCE1 mRNA accumulated specifically within the pistil, petals, and stamen filaments. DELAYED DEHISCENCE1 mRNA was not detected in the stomium and septum cells of the anther that are involved in pollen release. The T-DNA insertion in delayed dehiscence1 eliminated both DELAYED DEHISCENCE1 mRNA accumulation and 12-oxophytodienoate reductase activity. These experiments suggest that jasmonic acid signaling plays a role in controlling the time of anther dehiscence within the flower.     

Epidermal jasmonate perception is sufficient for all aspects of jasmonate‐mediated male fertility in Arabidopsis

Jasmonate (JA) signaling is essential for several environmental responses and reproductive development in many plant species. In Arabidopsis thaliana, the most obvious phenotype of JA biosynthetic and perception mutants is profound sporophytic male sterility characterized by failure of stamen filament elongation, severe delay of anther dehiscence and pollen inviability. The site of action of JA in the context of reproductive development has been discussed, but the ideas have not been tested experimentally. To this end we used targeted expression of a COI1‐YFP transgene in the coi1‐1 mutant background. As COI1 is an essential component of the JA co‐receptor complex, the null coi1‐1 mutant is male sterile due to lack of JA perception. We show that expression of COI1‐YFP in the epidermis of the stamen filament and anther in coi1 mutant plants is sufficient to rescue filament elongation, anther dehiscence and pollen viability. In contrast, filament expression alone or expression in the tapetum do not restore dehiscence and pollen viability. These results demonstrate that epidermal JA perception is sufficient for anther function and pollen viability, and suggest the presence of a JA‐dependent non‐autonomous signal produced in the anther epidermis to synchronize both anther dehiscence and pollen maturation.     

Expression of rolB in tobacco flowers affects the coordinated processes of anther dehiscence and style elongation

The effect of auxin on stamen and pistil development in tobacco flowers was investigated by means of the localized expression of rolB (root loci B), an Agrobacterium oncogene that increases auxin sensitivity in a cell-autonomous fashion. When rolB is driven by the promoter of the meiosis-specific Arabidopsis gene DMC1 (disrupted meiotic cDNA 1), expression occurs earlier in male than in female developing organs, resulting in a delay in anther dehiscence with respect to normal timing of pistil development. As a consequence of this developmental uncoupling, self-pollination is prevented in pDMC1:rolB plants. Histological analysis of pDMC1:GFP plants indicates that in tobacco, this promoter is active not only in meiocytes but also in somatic tissues of the anther. In contrast, simultaneous expression of rolB in anther and pistil somatic tissues, achieved by expressing a construct containing rolB under the control of the promoter of the petunia gene FBP7 (floral binding protein 7), results in a concomitant delay of both anther dehiscence and pistil development without affecting self-pollination of the plants. Analysis of plants harboring the pFBP7:GUS construct shows that in tobacco, this promoter is active not only in the ovules, as described for petunia, but also in pistil and anther somatic tissues involved in the dehiscence program. The delay in anther dehiscence and pistil development could be phenocopied by exogenous application of auxin. Jasmonic acid (JA) could not rescue the delay in anther dehiscence. These results suggest that auxin plays a key role in the timing of anther dehiscence, the dehiscence program is controlled by the somatic tissues of the anther, and auxin also regulates pistil development.     

高等植物叶绿素生物合成的联乙烯还原酶及编码基因研究进展

联乙烯还原酶(DVR)将各种叶绿素中间物质的8-乙烯基转化为乙基,是叶绿素生物合成必不可少的一个关键酶。迄今已在高等植物中检测到5种DVR活性。水稻和玉米的重组DVR蛋白能将联乙烯叶绿素a、叶绿素酸酯a、原叶绿素酸酯a、镁原卟啉Ⅸ单甲酯和镁原卟啉Ⅸ分别转化为相应的单乙烯物质,从而证实了这5种DVR活性。在高等植物中各种DVR活性是由一个基因编码的具有广谱底物专化性的DVR蛋白所催化,但来源于不同物种的DVR蛋白的催化活性可能具有极显著的差异,并且即使是同一个DVR蛋白,对不同的联乙烯底物也可能具有显著不同的催化活性。在此基础上,提出了"源于一个联乙烯还原酶的叶绿素生物合成多分支路径"假说。该文对近年来国内外有关高等植物叶绿素生物合成途径中联乙烯中间物质与联乙烯还原酶活性、联乙烯还原酶基因的克隆及重组酶活性检测、联乙烯还原酶的数目与叶绿素生物合成的多分支路径等方面的研究进展进行综述,并讨论了有待进一步探讨的若干问题。