异叶苦竹花粉管生长及双受精过程（英文）

以异叶苦竹为材料,采用扫描电镜、荧光显微镜技术及传统的石蜡制片技术,解剖观察其花粉管生长途径及双受精过程。结果表明:(1)授粉后,花粉在柱头上吸水膨胀,约30min即可萌发。(2)授粉1~2h后花粉管可达到花粉长度的5~10倍,花粉管在柱头分支中进一步伸长,并开始伸入花柱中生长。(3)授粉后5h,大量花粉管沿引导组织进入花柱基部与子房顶部之间的子房壁,有少量花粉管在子房壁与外珠被之间的缝隙中生长。(4)授粉后8h,少量花粉管到达珠孔端。(5)授粉后15~18h,精核与极核融合,形成初生胚乳核;精、卵核融合,形成合子。(6)授粉后20~30h,仍可在花柱中见到大量呈束状的花粉管。(7)授粉后48h,子房内的大部分花粉管出现解体,大多数花粉死亡。研究认为,精细胞到达胚珠的时间为8h。     

水稻双受精过程的细胞形态学及时间进程的观察

应用常规石蜡切片和荧光显微镜观察水稻(Oryz a sativa)受精过程中雌雄性细胞融合时的形态特征及时间进程, 确定合子期, 为花粉管通道转基因技术的实施提供理论依据。结果表明: 授粉后, 花粉随即萌发, 花粉管进入羽毛状柱头分支结构的细胞间隙, 继续生长于花柱至子房顶部的引导组织的细胞间隙中, 而后进入子房, 在子房壁与外珠被之间的缝隙中向珠孔方向生长, 花粉与花粉管均具有明显的绿色荧光。花粉管经珠孔及珠心表皮细胞间隙进入一个助细胞, 释放精子。精子释放前, 两极核移向卵细胞的合点端; 两精子释放于卵细胞与中央细胞的间隙后, 先后脱去细胞质, 然后分别移向卵核和极核, 移向卵核的精核快于移向极核的精核; 精核与两极核在向反足细胞团方向移动的过程中完成雌雄核融合。大量图片显示了雌雄性核融合的详细过程以及多精受精现象。水稻受精过程经历的时间表如下: 授粉后, 花粉在柱头萌发; 花粉萌发至花粉管进入珠孔大约需要0.5小时; 授粉后0.5小时左右, 花粉管进入一个助细胞, 释放精子; 授粉后0.5-2.5小时, 精卵融合形成合子; 授粉后约10.0小时, 合子第1次分裂, 合子期为授粉后2.5-10.0小时; 授粉后1.0-3.0小时, 精核与两极核融合; 授粉后约5.0小时, 初生胚乳核分裂。     

水稻双受精过程的细胞形态学及时间进程的观察

应用常规石蜡切片和荧光显微镜观察水稻（Oryza sativa）受精过程中雌雄性细胞融合时的形态特征及时间进程,确定合子期,为花粉管通道转基因技术的实施提供理论依据。结果表明：授粉后,花粉随即萌发,花粉管进入羽毛状柱头分支结构的细胞间隙,继续生长于花柱至子房顶部的引导组织的细胞间隙中,而后进入子房,在子房壁与外珠被之间的缝隙中向珠孔方向生长,花粉与花粉管均具有明显的绿色荧光。花粉管经珠孔及珠心表皮细胞间隙进入一个助细胞,释放精子。精子释放前,两极核移向卵细胞的合点端：两精子释放于卵细胞与中央细胞的间隙后,先后脱去细胞质,然后分别移向卵核和极核,移向卵核的精核快于移向极核的精核：精核与两极核在向反足细胞团方向移动的过程中完成雌雄核融合。大量图片显示了雌雄性核融合的详细过程以及多精受精现象。水稻受精过程经历的时间表如下：授粉后,花粉在柱头萌发：花粉萌发至花粉管进入珠孔大约需要0．5小时：授粉后0．54,时左右,花粉管进入一个助细胞,释放精子：授粉后0．5—2．5小时,精卵融合形成合子：授粉后约10．0小时,合子第1次分裂,合子期为授粉后2．5-10．04,时：授粉后1．0-3．04,时,精核与两极核融合：授粉后约5．0小时,初生胚乳核分裂。’     

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。     

猕猴桃花粉原位生长过程中Ca2+的超微细胞化学定位

应用扫描电镜和荧光显微镜对软枣猕猴桃同种花粉在柱头上原位萌发及花粉管生长情况进行了观察,并用焦锑酸盐沉淀法对其授粉前后柱头及花柱中Ca2+进行超微细胞化学定位.结果显示:(1)猕猴桃柱头属于干性柱头,具有一道裂沟,乳突呈长圆柱形,授粉前后形态差异不明显.(2)授粉后3 h,花粉管生长穿过柱头表面,授粉后7 h,花粉管生长到达花柱底部;(3)授粉前后,柱头接受面靠近柱头外围细胞的角质层一侧细胞器内含有丰富的钙,而柱头非接受表面钙颗粒分布很少;(4)授粉前和授粉后3 h,花柱顶端钙颗粒较少,基部钙颗粒较多;授粉后7 h,花柱顶端和基部钙分布密度无明显差别;(5)授粉前后花柱顶端钙主要均匀分布在细胞质膜位置;在花柱基部授粉前钙主要分布在引导组织胞间隙中,授粉后3 h主要分布在细胞质内,授粉后7 h主要存在于细胞质、内质网上.研究表明,猕猴桃授粉前后,柱头和花柱组织中均含有钙,授粉前和授粉后3 h花柱中的钙呈现出梯度分布,授粉后7 h钙的梯度分布现象减弱甚至消失.     

枇杷少核株系花粉管生长差异研究

以‘大五星’枇杷退化种子少核株系‘川农1号’(C1)为试材,以‘大五星’枇杷自花授粉为对照,采用荧光显微技术,对枇杷少核株系自花、异花授粉后花粉管生长情况进行观察。结果表明:(1)C1株系异花授粉后花粉能在柱头上萌发,并伸入中央花柱道,在授粉后48h左右到达花柱基部。(2)C1株系自花授粉后,花粉萌发与花粉管的伸长速度相对于异花授粉滞后,自花授粉后36h大多数花粉管到达花柱的中上部并停止生长,且伴随产生花粉管顶端形态异常、荧光异常明亮等现象,最终只有极少数花粉管能到达花柱基部。研究表明,C1株系为配子体自交不亲和,C1株系的自交不亲和性是引起其少核的重要原因之一。     

油橄榄授粉受精和胚胎发育过程观察

该研究以油橄榄“鄂植-8”为材料,应用压片荧光观察花粉在柱头和花柱中的萌发及生长情况,采用石蜡制片法观察油橄榄的胚珠结构特点和授粉受精过程。结果表明：油橄榄为1子房2心室4胚珠,珠心较发达,由多层细胞构成,属于厚珠心椭圆型胚珠,胚珠直生;花开时花粉粒落到柱头上立刻萌发,随后花粉管在花粉通道中生长,再后进入子房经子房内表面,大部分花粉管不能到达胚珠,仅少数沿胎座生长经珠柄进入珠孔,释放2个精子,2个精核分别进入卵细胞和极核,并与卵核及极核相互融合;观察到合子中雌、雄性核仁融合的过程。授粉受精各阶段经历的时间为花粉落到柱头上立刻萌发;授粉后6d左右,花粉管长入胚珠的珠孔,随后释放精子;10 d左右完成授粉受精,30 d左右形成心型胚,40 d左右胚发育几乎成熟。在进行子房石蜡切片中,共观察到612个完整子房切片,发育完整的子房为97.53％,完成授粉受精的胚珠为15.52％。油橄榄在自然授粉下,约85％的胚珠授粉受精过程不能完成,在一定程度上影响其坐果。该研究结果为油橄榄授粉受精、高效生产等提供了理论依据。     

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。     

内蒙古居群抗寒西伯利亚杏繁殖生态学研究

对内蒙古居群抗寒西伯利亚杏的12个种源同一树龄的102株进行雌蕊败育率、花粉量、花粉活力、柱头可授性及自交不亲和性进行研究,以明确西伯利亚杏主产地资源的花期生物学特性和繁殖特性,为杏杂交育种和资源利用提供理论依据。结果表明:(1)有86.27%的西伯利亚杏雌蕊败育率低于90%;73.53%的西伯利亚杏单朵花花粉量在1×104～5×104之间;86.27%的西伯利亚杏花粉活力低于50%,且寿命较短。(2)花苞在将开未开时,柱头已经具备一定的可授性,开花后1～4d内柱头可授性保持较高水平,第5天开始有下降趋势。(3)荧光显微观察结果显示,授粉后16h时,96.08%的杏花花粉管在花柱上部;授粉后24h时,74.51%的杏花花粉管仍在花柱上部;授粉后48h时,35.29%的杏花花粉管到达花柱中部;授粉后80h时,花粉管到达花柱下部的杏花约50%,但受精胚珠数为0。研究认为,西伯利亚杏基本为自交不亲和。     

Structural aspects of in vitro pollen tube growth and micropylar penetration inGasteria verrucosa (Mill.) H. Duval andLilium longiflorum Thunb.

Summary In vitro penetration of the micropyle of freshly isolatedGasteria verrucosa ovules by pollen tube was monitored on agar medium. 40–60% of the micropyles were penetrated, comparable with in vivo penetration percentages. When germinated on agar,Gasteria pollen tube elongation lasts for up to 8 h while plasma streaming continues for about 20–24 h. The generative cell divides between 7 and 20 h after germination, and after 20 h the pollen tube arrives at one of the synergids. The sperm cells arrive after 22 h. The whole process takes more time in vitro than in vivo. In fast growing pollen tubes, a pulsed telescope-like growth pattern of tube elongation is observed. The formation of pollen tube wall material precedes tube elongation and probably prevents regular enlargement of the pollen tube tip-zone. Rapid stretching of the new pollen tube wall material follows, probably due to gradually increased osmotic pressure and the use of lateral wall material below the tip. The stretching ceases when the supplies of plasma membrane and excretable wall material are exhausted. Multiple pollen tube penetration of the micropyle occurs in vitro as it does in vivo. Most pollen tube growth ceases within the micropyle but, if it continues, the pollen tubes curl. Inside the micropyle the pollen tube shows haustorial growth. At the ultrastructural level, the wall thickening of in vitro pollen tubes is quite similar to that in vivo. Before transfer of pollen tube cytoplasm a small tube penetrates one of the synergids. Sperm nuclei with condensed chromatin are observed in the pollen tube and the synergid. In vivo prometaphase nuclei are found in the most chalazal part of a synergid, against the egg cell nucleus and nucleus of the central cell at a later stage. Using media forLilium ovule culture,Gasteria ovules were kept alive for at least 6 weeks. Swelling of the ovule depends on pollen tube penetration. The conditions for fertilization to occur after in vitro ovular pollination seem to be present.     

Semi in vivo pollen tube growth of Aechmea fasciata

With semi in vivo pollen tube growth assays, stigmas are pollinated in vivo and, after a fixed time interval, the styles are isolated from the ovary and placed on culture medium in vitro. Semi in vitro pollination includes isolation of the stigma and style complex, followed by pollination and placing the stylar end on nutrient medium. After semi in vivo pollination more and longer pollen tubes protruded from the cut end of the styles into medium, in comparison to semi in vitro pollination. Medium with 3 g l^–1 agar was better than that with 6 g l^–1 agar for pollen tube growth after the tubes emerged from the cut style. Semi in vitro pollination of the reversed style indicated that pollen tube growth was not influenced by the direction of the style. Fructose and glucose inhibited pollen tube growth compared to sucrose. Swollen tips characterized tube growth inhibition. After semi in vivo pollination all generative nuclei had divided to give two sperm nuclei. The average distance between the last sperm nucleus and the pollen tube tip as well as the distance between the two sperm nuclei diminished in growing pollen tubes between 24 and 48 h after pollination. The arrangements between the vegetative and the generative nuclei did not differ in semi in vivo and in vitro cultured pollen tubes of Aechmea fasciata. This information is important to explain why fertilization rate is low after placental pollination in comparison to placental grafted style pollination of Aechmea fasciata. The data may also contribute to the improvement of in vitro fertilization methods in Bromeliaceae and other higher plants.     

INFLUENCE OF THE PISTIL ON POLLEN TUBE KINETICS IN PEACH (PRUNUS PERSICA)

Pollen tube growth has been studied in peach and has been related to changes in the pistil structures which the pollen tube has to traverse in its way from the stigma down to the ovule. Growth of the pollen tubes along the pistil is not continuous. While pollen tubes reach the base of the style 7 days after pollination, fertilization does not take place until 12 days later. Pollen tubes stop for 5 days at the top of the obturator and they further stop for 3 days before entering the ovule. The pollen tube growth is heterotrophic; starch, present all along the pistilar tract at anthesis, vanishes as the pollen tubes pass by. Discontinuous pollen tube growth appears to be controlled by the pistil. At anthesis the pistil is not fully matured. Maturation of the pistil implies a number of secretory processes that occur in a basipetal way starting from the stigma down to the style and ending in the ovule. Some of these secretions at the stigma and the style are triggered by pollination; others appear to be a maturative stage of the pistil and are produced in a discrete way. The fact that the pollen tube depends on these secretions together with the fact that these secretions are not continuously produced confer upon the pistil a role of controlling pollen tube kinetics and point out that, for a successful fertilization, male gametophyte development and pistil maturation need to by synchronized.     

Postulated interaction between branching pollen tubes and ovules inOenothera hookeri de Vries (onagraceae)

The pollen grain germinationin vitro and progamic phase till fertilization inOenothera hookeri de Vries was observed after open and controlled pollination. The same pattern of pollen grain germination was foundin vitro and on the stigma. The pollen tubes can germinate from 1,2 or 3 poruses of the pollen grain, divide and branch during their growth in the ovary. The branches are of different length and give secondary splits. Special short branches are formed near the micropyle of the ovule. They grow into top part of integments. The pollen tubes start to branch profusely near the placental surface. In that place they are likely to react to the stimulus from mature ovules which seems to be dispersed in the exudate covering placenta.     

茜草科二型花柱植物滇丁香传粉精确性研究

异型花柱是一种受遗传因素控制的花型多态性现象,其适应意义在于提高不同花型间传粉精确性,从而促进异交。为检验二型花柱植物滇丁香（Luculia pinceana）是如何促进异交并确定有效传粉者的类型,实验统计自然种群中长、短柱型的植株数量,测量花部特征,统计自然种群植株柱头上的型间花粉落置的数量和比例,比较型内、型间花粉的萌发率以及花粉管长度,比较不同人工授粉处理结实情况,观察传粉昆虫类型并测量虫体特征。结果表明（1）滇丁香自然居群中长、短柱型植株的数量没有显著性差异。长柱型的筒深、筒直径、开口直径、雄蕊长和柱头长均显著小于短柱型,而长柱型的叶片长和宽、雌蕊长、花药体积、花粉粒体积、柱头厚均显著大于短柱型。（2）自然种群植株柱头上型间花粉所占比例显著低于型内花粉的比例。（3）型间授粉的花粉萌发率以及花粉管长度均大于型内授粉和混合授粉。（4）型间授粉的结实率显著高于型内授粉的结实率,型内授粉具有一定的结实。（5）夜行性长喙条背天蛾（Cechenena lineosa）是滇丁香的有效传粉者,其吻长和滇丁香的花筒深相适应。本研究表明二型花柱植物滇丁香主要是通过与其花部特征相匹配的长喙天蛾实现有效的传粉,通过促进型间花粉的萌发和花粉管的伸长而有利于型间授粉结实,提高传粉精确性。     

Evidence for Stigmatic Self-incompatibility, Pollination Induced Ovule Enlargement and Transmitting Tissue Exudates in the Paleoherb, Saururus cernuus L. (Saururaceae)

Saururus cernuus, a species belonging to the primitive herbaceousangiosperm family Saururaceae, exhibits high rates of self-sterility.We investigated the structural and functional aspects of pollen-carpelinteractions following cross and self pollination to assessthe tissue specific site and timing of self-sterility and factorsimportant for successful cross pollen tube growth. Self-sterilitywas due to inhibition of self pollen germination at a dry stigma.Self pollination was associated with anomalous foot formation,reduced cell wall expansion and secretory activity of stigmaticpapillae, and callose production in stigmatic papillae. Followinggermination, cross compatible pollen tubes entered a solid coreof transmitting tissue and grew to the base of a short style.Entry of cross pollen tubes into the ovary was coincident withovule enlargement which placed the micropyle in the proximityof cross pollen tube tips. Ovule enlargement also occurred followingself pollination. Cross pollen tubes either entered an exudate-filledmicropyle directly from the style, or growth in the ovary waslocalized to the epidermis of the locule and outer integumentprior to entry into the micropyle. Prior to pollination, thetransmitting tract was void of secretions except for exudatein the micropyle. Growth of pollen tubes on the locule and integumentwas associated with exudate apparently arising from transmittingcells adjacent to growing pollen tubes. The present study providesthe first evidence in a primitive herbaceous species of stigmaticself-incompatibility (SI) in association with a dry stigma,pollination-induced signalling events affecting developmentof carpellary tissues, and micropylar exudates. Copyright 1999Annals of Botany Company SI evolution, dry stigma, exudates, pollen-carpel signalling, Saururaceae.