高温对苹果花粉在花柱内萌发和生长的影响

以‘长富2号’红富士苹果为母本,‘红星’苹果为父本,研究35℃高温对苹果花粉在花柱内萌发和生长的影响。结果表明：温度影响花粉在柱头和花柱内的萌发及生长,与对照相比,高温促进花粉在柱头表面快速萌发,并加速花粉管在花柱内的伸长生长,但是在授粉72hN,高温处理下培养的花粉管形态出现花粉管变粗、弯曲并有瘤状小结的异化现象,同时,花柱发生褐变,并产生胼胝质,最终导致花粉管不能进入胚珠完成受精。     

Ca2+、pH在花粉及萌发花粉管生长中的作用研究进展

花粉正常萌发并生长是精细胞顺利到达胚囊并实现受精作用的前提,因而是高等植物有性生殖的一个关键环节。花粉管生长涉及一系列过程,而花粉(或花粉管)内外的Ca^2 和pH的变化与花粉萌发、花粉管生长有着密切的关系。比较详细地论述了Ca^2 和pH在花粉萌发、花粉管生长过程中的分布特点、生理功能及分子机制。     

细胞松弛素B和鬼笔环肽对梨花粉萌发和花粉管生长的影响

以砂梨(Pyrus pyrifoliaNakai)品种今村秋(Imamuraaki)和丰水(Hosui)为材料,分别用光学显微镜和荧光显微镜观察了离体和半活体条件下微丝骨架解聚剂细胞松弛素B(cytochalasin B,CB)和稳定剂鬼笔环肽(phalloidin)对梨花粉萌发和花粉管生长的影响.结果表明:(1)低浓度(10μg/mL)鬼笔环肽能促进花粉萌发和花粉管生长,但高浓度对花粉萌发和花粉管的生长具有抑制作用;CB抑制花粉萌发和花粉管生长,且抑制效应随其浓度的增加而增强.(2)鬼笔环肽处理柱头后进行自花授粉,可明显促进自花花粉萌发和花粉管的生长,而CB处理柱头后异花授粉则抑制异花花粉萌发及其花粉管生长.可见,微丝骨架参与了梨花粉萌发和花粉管生长过程,并参与了梨自交不亲和反应的调节.     

贯叶连翘的开花动态与繁育系统研究

野外观察贯叶连翘的开花进程和花部形态特征,运用花粉萌发、杂交指数、花粉-胚珠比等方法测定其繁育系统。结果显示:贯叶连翘雌雄异熟,柱头先花药成熟,雌雄蕊无明显异位。单花花期4～5d。仅在开花当日有昆虫传粉,蜜蜂为主要传粉者。花粉在花药开裂1h后活力最大,萌发率达40.10%,花粉在柱头萌发3h后接近子房。根据杂交指数(OCI)推测其繁育系统属于异交,部分自交亲和,有时需要传粉者。花粉-胚珠比(P/O)则表明贯叶连翘的繁育系统为兼性异交。贯叶连翘结实率低,可能与花粉活力,花粉管的生长速度及花粉在柱头的竞争有关。     

芥菜型油菜与白菜正反杂交的胚胎学研究

利用荧光技术对芥菜型油菜(Brassica juncea)与白菜(B. pekinesis)种间正反杂交后花粉萌发和花粉管生长过程进行了观察。结果显示: 芥菜型油菜与白菜正交授粉后, 花粉在柱头上能正常萌发, 多数花粉管沿花柱到达胚珠完成受精, 且受精方式有珠孔受精、合点受精和中部受精, 少量花粉管生长不正常, 出现花粉管顶端膨大扭曲, 花粉管分支等异常现象; 反交授粉后, 花粉在柱头上萌发时柱头乳突细胞产生强烈胼胝质反应, 影响花粉管生长, 只有少量花粉管通过花柱到达胚珠完成受精。用石蜡切片技术观察了正反杂交后杂种的胚胎发育, 正交杂种胚胎发育较早, 胚和胚乳生长较正常, 杂种胚一般均能发育至成熟; 反交杂种胚发育至心型期便不能继续发育, 胚乳也停滞在游离核阶段并最终败育。综合分析 表明, 芥菜型油菜与白菜正反杂交都存在一定程度的受精不亲和性。     

杂交石竹授粉受精及其胚胎发育过程的观察

以‘杂交石竹’为试验材料,利用荧光显微镜观察其授粉后花粉萌发、花粉管生长情况,采用石蜡切片法对其受精及胚胎发育过程进行观察研究。结果表明:(1)授粉后1h母本柱头上少量花粉开始萌发;授粉后4h大量花粉萌发,花粉管生长至柱头中部有胼胝质出现;授粉后6h花粉管生长至子房组织并有少量与胚珠结合;授粉后15h柱头中出现大量胼胝质,花粉管与胚珠结合数增多;授粉后24h胚珠周围出现多条花粉管,其中1条花粉管进入胚珠,部分进入胚囊的花粉管卷曲盘绕生长并产生胼胝质;精细胞与极核的融合主要发生在授粉后17~48h,与卵细胞融合主要于授粉后1~3d。(2)杂交石竹胚发育经过原胚、球形胚、棒状形胚、心形胚、鱼雷形胚和子叶形胚阶段。(3)杂交障碍表现为:只有游离的胚乳核而无胚发育的胚囊、合子未分裂、两极核未融合、球形胚败育。研究表明,杂交石竹存在受精前和受精后障碍,这是导致其结实率低的主要原因。     

小报春与岩生报春种间杂交亲和性研究

以报春花属报春花组的小报春(Primula forbesii)和指叶报春组的岩生报春(Primula saxatilis)为亲本,对种间杂交的结实性及花粉管行为进行了观察。结果表明:小报春与岩生报春种间杂交表现为不亲和,正反交组合正常结实率为0,但正交、反交组合花粉在柱头表面的萌发和花粉管伸长过程有明显差异,小报春花粉授粉4h后可以在岩生报春柱头表面萌发,但花粉管伸长的速度明显比对照组[岩生报春(P)×岩生报春(T)、岩生报春(T)×岩生报春(P)]慢,并且花粉管生长弯曲,授粉192h后花粉管仍未到达子房;岩生报春的花粉可以在小报春柱头上正常萌发,授粉48h后花粉管到达子房;4个对照授粉组合均分别于24h(短花柱为母本)、48h(长花柱为母本)时完成受精过程。研究表明,岩生报春×小报春杂交存在受精前障碍,小报春×岩生报春杂交亲和性较好,并可通过幼胚拯救的方法获得组间杂种后代;花柱长度可能是影响种间杂交结实能力的因素之一。     

花粉萌发和花粉管生长发育的信号转导

显花植物授粉是一个复杂的发育过程。从花粉落在柱头上开始,经过粘附、识别、水合、萌发,花粉管在花柱内生长,直至到达子房发生双受精作用,整个过程发生在雌、雄两性细胞和组织之间,受到严格的遗传控制和细胞控制。一方面雌雄配子的基因型决定两者是否亲和,另一方面雌雄两性细胞间发生复杂的相互作用,细胞外信号分子是这些过程的主要调控因子。当花粉或花粉管细胞感知外部信号后,必然通过信号转导级联反应,达到控制萌发、调整花粉管生长方向等目的。这一系列动力学的细胞事件,关系到受精的成败。因此研究此过程中的信号及其转换机…     

芥菜型油菜与白菜正反杂交的胚胎学研究

利用荧光技术对芥菜型油菜（Brassica juncea）与白菜（B．pekinesis）种间正反杂交后花粉萌发和花粉管生长过程进行了观察。结果显示：芥菜型油菜与白菜正交授粉后,花粉在柱头上能正常萌发,多数花粉管沿花柱到达胚珠完成受精,且受精方式有珠孔受精、合点受精和中部受精,少量花粉管生长不正常,出现花粉管顶端膨大扭曲,花粉管分支等异常现象;反交授粉后,花粉在柱头上萌发时柱头乳突细胞产生强烈胼胝质反应,影响花粉管生长,只有少量花粉管通过花柱到达胚珠完成受精。用石蜡切片技术观察了正反杂交后杂种的胚胎发育,正交杂种胚胎发育较早,胚和胚乳生长较正常,杂种胚一般均能发育至成熟;反交杂种胚发育至心型期便不能继续发育,胚乳也停滞在游离核阶段并最终败育。综合分析表明,芥菜型油菜与白菜正反杂交都存在一定程度的受精不亲和性。     

钙和硼对蓝猪耳花粉萌发及花粉管生长的影响

研究了钙(Ca^2 )和硼(H3BO3)对蓝猪耳花粉萌发和花粉管生长的影响。结果表明：(1)在一定范围内Ca^2 几乎不影响花粉萌发频率,而主要影响花粉萌发速度和花粉管生长速度;低Ca^2 不利于花粉管生长,而高Ca^2 抑制花粉萌发速度和花粉管生长;在稍高于最适Ca^2 浓度的条件下,花粉管生长早期呈现波浪形。(2)硼明显影响花粉萌发频率及花粉管形态;花粉管生长必需硼,但不同浓度的硼对花粉管生长速度影响不明显;在高浓度硼条件下,较长时间内花粉管均呈现出波浪形。(3)Cooled-CCD动态跟踪观察进一步证实Ca^2 影响花粉管生长速度,而硼则不明显。     

Spatial and temporal organization of actin during hydration,activation, and germination of pollen inPyrus communis L.: a population study

Summary Dynamics of F-actin organization during activation and germination ofPyrus communis (pear) pollen was examined using rhodaminephalloidin. Prior to activation, the rhodamine-phalloidin labelling pattern appeared as circular profiles in the peripheral cytoplasm of the vegetative cell and as coarse granules around the vegetative nucleus. In activated pollen, parallel arrays of cortical F-actin were aligned circumferentially, along the polar axis in non-apertural areas of the pollen grain, and at 45° to 90° to the polar axis beneath the apertures. Some pollen also showed fluorescent granules or fusiform bodies dispersed throughout the cytoplasm, but as the number of such pollen diminished with prolonged incubation, these are being considered as intermediate patterns. In later stages, the filaments became organized as interapertural bundles traversing the three apertures. However, prior to emergence of the pollen tube, labelling became confined to a single aperture. In germinated pollen grains, actin microfilaments are aligned more or less axially with respect to the axis of the developing pollen tube.The granular labelling pattern seen around the vegetative nucleus prior to pollen activation also became clearly filamentous with pollen activation; this filamentous pattern persisted until germination when it was replaced by cables that aligned longitudinally with respect to the emerging tube axis.The results demonstrate that the organization of actin undergoes considerable changes in the period preceding pollen germination and that microfilament polarization is achieved before pollen germination.     

山玉兰花粉离体萌发和花粉管生长特性的研究

山玉兰(Magnolia delavayi)是木兰科木兰属的常绿乔木或大型灌木,是重要的园林造景、庭院绿化素材,也是重要的育种资源。山玉兰花粉的研究对其杂交育种的成败具有重要影响,但目前尚未见其花粉活力的相关报道。该研究以新鲜的山玉兰花粉为对象,采用悬滴培养法分析了温度、光照以及培养液的蔗糖和硼酸浓度对山玉兰花粉萌发的影响。结果表明:(1)山玉兰花粉萌发时,最适宜的温度为27℃。(2)光暗条件下,山玉兰花粉以浓度为5%的蔗糖培养效果最佳,其萌发率在16%以上;而硼酸浓度则以0.001%的培养效果最佳。(3)蔗糖与硼酸共同作用可有效促进花粉萌发和花粉管生长。其中,在光照条件下,以5.0%蔗糖+0.001%硼酸为最适宜的培养液,花粉萌发率达41.27%,花粉管长达281.49μm;而在黑暗条件下,则以5.0%蔗糖+0.01%硼酸为最适宜的培养液,花粉萌发率达45.71%,花粉管长达254.00μm。该研究结果为进一步开展人工辅助授粉、发掘山玉兰的种质资源工作奠定了基础。     

Polarity, aperture condition and germination in pollen grains ofEphedra (Gnetales)

Pollen grain polarity, aperture condition and pollen tube formation were examined inEphedra americana, E. foliata, E. rupestris, E. distachya, andE. fragilis using LM, SEM and TEM. In the characteristic oblate pollen, as seen in situ in the tetrad configuration, the polar axis is the minor one and the equatorial plane runs between the two narrow ends of the microspore. The intine is thick in fresh fixed mature pollen but we have seen no indication of regions having an exceptionally thick intine that could be considered associated with an aperture or apertures. About three minutes after transferring fresh pollen to the germinating medium the ridged exine splits and twists away from the intine and its enclosed protoplast. The shed exine spreads out and curls into a scroll-like configuration that is as distinctive as that of the pollen shape had been but now having the ridges and valleys perpendicular to the long axis. The pollen tube develops, in our experience with more than a hundred germinating pollen grains, near one of the narrow tips of the pollen grain's equatorial plane. The location of the pollen tube initiation probably is related to the position of the tube cell nucleus. The pollen tube starts to grow about one hour after the exine was shed. The pollen tube emerges close to the narrow end (equator) of the gametophyte. This end emerged first as the exine is shed and is opposite to the prothallial cells. The stout pollen tube is c. 10µm in diameter grown in vitro on agar. In our germination medium the stout tube continued to elongate for about 24 hours reaching a length of c. 100 µm. With respect to exine morphology the aperture condition could be considered as inaperturate. The pollen tube, however, is formed in a germination area near one end of the exineless gametophyte.     

Fast pollen tube growth in Conospermum species

BACKGROUND AND AIMS: An unusual form of pollen tube growth was observed for several Conospermum species (family Proteaceae). The rate of pollen tube growth, the number of tubes to emerge and the ultrastructure of these tubes are given here. METHODS: Pollen was germinated in vitro in different sucrose concentrations and in the presence of calcium channel blockers, and tube emergence and growth were recorded on a VCR. Measurements were taken of the number of tubes to emerge and rate of tube emergence. Pollen behaviour in vivo was also observed. The ultrastructure of germinated and ungerminated pollen was observed using TEM. RESULTS: After 10 s to 3 min in germination medium, up to three pollen tubes emerged and grew at rates of up to 55 micro m s(-1); the rate then slowed to around 2 micro m s(-1), 30 s after the initial growth spurt. Tubes were observed to grow in pulses, and the pulsed growth continued in the presence of calcium channel blockers. Optimal sugar concentration for pollen germination was 300 g L(-1), in which up to 81 % of pollen grains showed fast germination. Germination and emergence of multiple tubes were observed in sucrose concentrations of 100-800 g L(-1). The vegetative and generative nuclei moved into one of the tubes. Multiple tubes from a single grain were observed on the stigma. Under light microscopy, the cytoplasm in the tube showed a clear region at the tip. The ultrastructure of C. amoenum pollen showed a bilayered exine, with the intine being very thick at the pores, and elsewhere having large intrusions into the plasma membrane. The cytoplasm was dense with vesicles packed with inner tube cell wall material. Golgi apparatus producing secretory vesicles, and mitochondria were found throughout the tube. The tube wall was bilayered; both layers being fibrous and loosely packed. CONCLUSIONS: It is proposed that, for Conospermum, initial pollen tube wall constituents are manufactured and stored prior to pollen germination, and that tube extension occurs as described in the literature for other species, but at an exceptionally fast rate.     

Division of the generative nucleus in cultured pollen tubes of the Bromeliaceae

Pollen germination, division of the generative nucleus and position of the generative nucleus in the pollen tube during in vitro germination were examined for six bromeliad cultivars. The influence of mixed amino acids (casein hydrolysate) and individual amino acids (Arg, Asn, Asp, Glu, Gly, Met, Phe, Orn, Tyr) were tested. Aechmea fasciata and A. chantinii pollen tubes showed more generative nuclear division in cultured pollen tubes than the other four cultivars tested. Casein hydrolysate did not stimulate generative nuclear division. In general arginine (1 mM) improved division of the Aechmea generative nucleus and to a lesser extent this of Vriesea `Christiane', Guzmania lingulata and Tillandsia cyanea. A concentration of 2 mM arginine reduced pollen tube growth of Aechmea. The vegetative nucleus was ahead of the generative nucleus in approximately 50% of the pollen tubes of all cultivars studied. In about 25% of the pollen tubes, the generative nucleus was ahead and in ±25% pollen tubes the vegetative and generative nuclei were joined together. The distance between the two generative nuclei and the distance from the generative nuclei to the pollen tube tip differed significantly for Aechmea fasciata and A. chantinii. The influence of different amino acids for Aechmea fasciata and A. chantinii varied with respect to pollen germination and generative nuclear division. Arg and Met improved nuclear division of both Aechmea cultivars. Pollen germination and sperm cell production were not linked. This information is important to ameliorate in vitro pollination methods used to overcome fertilization barriers in Bromeliaceae and other higher plants.     

龙须草花粉活性及结实率与其无融合生殖的关系

以两种生态型无融合生殖龙须草为材料,经去雄套袋、去掉柱头及相互杂交等处理,比较几种方式下的结实率。结果表明：去雄套袋、截去柱头以破坏授粉和杂交授粉等处理与去雄不套袋作对照之间结实率的差异不显著。两种生态型龙须草的成熟花粉粒都具有活力,在蔗糖溶液中的离体萌发率分别为28％和34％;花粉在柱头上的附着和生长的荧光观察表明：花粉附着率较低,花粉在柱头上可以萌发,但不能进入柱头和花柱。证明龙须草花粉对其结实率没有显著影响;龙须草具有很高的无融合生殖度,是优良的无融合生殖基因供体。     

培养基组分及培养条件对蜡梅花粉萌发及花粉管生长的影响

采用液体培养法研究不同培养基组分和培养条件对蜡梅花粉萌发和花粉管生长的影响。结果表明:(1)PEG-4000是蜡梅花粉离体培养所必需的培养基成分,当培养基中无PEG-4000时,花粉不能正常萌发。(2)培养基内低浓度蔗糖对花粉萌发和花粉管的生长无显著影响,但随着蔗糖浓度的升高,则对花粉萌发和花粉管生长表现出强烈的抑制作用,且浓度越高,抑制效应越强。(3)培养基内其它组分分别在一定浓度范围(0～250g/L PEG-4000、0～50mg/L硼酸、0～30mg/L硝酸钙)内对花粉萌发及花粉管生长有促进作用,但超过上述高限值时则起抑制作用。(4)培养基内镁和钾的浓度对花粉萌发及花粉管生长影响不显著。研究表明,蜡梅最适花粉液体培养基组分为250g/L PEG-4000+50mg/L H3BO3+30mg/L Ca(NO3)2.4H2O,且在pH 5.5、温度15℃和600lx的光照培养条件下蜡梅花粉萌发和花粉管生长最佳。     

丹东蒲公英专性无融合生殖特性

采用田间去雄套袋、花粉活性与花粉管萌发观测等交配系统实验,辅以染色体分析、胚囊发育观察以及流式细胞仪检测,对丹东蒲公英(Taraxacum antungense)生殖特性进行系统研究。结果表明,去雄套袋情况下,结籽率高达96%,由此证明交配系统具有极高的无融合发生率;自花授粉不能萌发,花粉活性仅为20.6%,异花授粉虽可萌发,但生长缓慢,花粉在到达子房前,花粉管已停止生长并消失;二分体时期,合子端大孢子发育为功能性大孢子,珠孔端大孢子退化消失,经蓼型发育,形成7细胞8核,卵细胞继续发育形成原胚,中央细胞形成胚乳,其它细胞退化消失,花未开放前,已形成球形胚。此外,丹东蒲公英为三倍体。流式细胞仪检测结果表明,丹东蒲公英为专性无融合生殖,胚乳自主发育。综合以上研究结果,说明丹东蒲公英具专性无融合生殖特性。