辣椒游离小孢子细胞团培养的胚状体形成

从预培养15天后的花药中机械游离小孢子及其细胞团,经28℃液体悬浮暗培养．30天后,获得了自球形期胚到子叶期胚发育程度不等的各类胚状体。从12个花药中可以形成高达22个胚状体,且子叶期胚的比例约为23％。显微镜检表明,这些胚状体来自游离的小孢子细胞．经核的对称分裂形成多核细胞或者早期形成多细胞团,最后经细胞的分裂分化形成。胚状体体表具毛,活力有差异。在适当培养基上,具活力的鱼雷期及子叶期胚状体均能发育成正常植株。7℃、32℃、35℃8天的胁迫处理均能诱导小孢子胚状体发生。但花药培养中7℃、35℃处理下的出胚率较32℃下高,而游离小孢子细胞团培养中以35℃、32℃下较好。7℃处理下获得的胚状体数很少．对产生这种现象的原因进行了探讨。出胚率在基因型间,不同胁迫处理温度间表现明显差异。而在温度处理的不同天数间差异不明显。流式细胞仪对再生株真叶的DNA含量分析表明．获得的再生株中具有单倍体、双单倍体以及单倍一双倍嵌合体植株。本结果为进一步开展辣椒雄性生殖途径的胚状体发育研究。提高辣椒成熟胚状体的频率提供了实验体系。     

菸草(Nicotiana tabacum)和辣椒(Capsicum annuum)花药离体培养的研究

本文报道关于菸草和辣椒花药离体培养的研究结果。对于菸草花药离体培养曾进行四种培养基的对比试验,结果以 NH 效果最好,Blaydes 次之。10—20%(体积/体积)椰乳能提高花药成胚的百分比,对单倍体幼苗也有促进作用。蔗糖浓度从1—4%都能产生“胚状体”,以3%的蔗糖浓度产生“胚状体”的百分比最高,长出的幼苗也比较健壮。对花粉不同发育时期进行了比较试验,花药中花粉单核靠边时期进行培养的出苗率最高。“胚状体”的形成主要由单核花粉粒均等分裂或由营养核分裂两种方式形成“胚状体”。生殖核只进行几次分裂而最后逐渐退化消失。对菸草花粉植株进行根尖或茎尖制片,观察其染色体数目为24,证明是单倍体。用不同浓度的秋水仙碱对单倍体植株进行染色体加倍,得到许多二倍体后代,其中少数是四倍体。本文对花药离体培养和组织培养中产生“胚状体”问题进行了讨论。辣椒采用花粉单核靠边时期的花药,培养在 NT 及 MS 加有补充物质的培养基上,花药既产生“胚状体”又产生愈伤组织。观察到单核花粉最初分裂发育成多细胞“原胚”到最后形成幼苗的过程。“胚状体”的发育与合子胚的发育过程相似。在花粉发育成幼苗的各个发育时期都可能停止发育,长成幼苗的只是少数。由单核花粉粒所形成的多细胞“原胚”可突出花粉壁外但仍与花粉粒相连,花粉粒内细胞大而染色淡,花粉壁外的多细胞“原胚”的细胞排列紧密,体积小而有分生能力,有的已开始分化。小苗的根尖和愈伤组织细胞,用醋酸洋红压片检查,其染色体数目为12,证明是单倍体。     

芝麻核雄性不育系ms86-1微粉发生的细胞学观察

芝麻(Sesamum indicum)核雄性不育系ms86-1姊妹交后代表现为可育、部分不育(即微粉)及完全不育(简称不育)3种类型。不同育性类型的花药及花粉粒形态差异明显。Alexander染色实验显示微粉植株花粉粒外壁为蓝绿色, 内部为不均一洋红色, 与可育株及不育株花粉粒的染色特征均不相同。为探明芝麻微粉发生机理, 在电子显微镜下比较观察了可育、微粉、不育类型的小孢子发育过程。结果表明, 可育株小孢子母细胞减数分裂时期代谢旺盛, 胞质中出现大量脂质小球; 四分体时期绒毡层细胞开始降解, 单核小孢子时期开始出现乌氏体, 成熟花粉时期花粉囊腔内及花粉粒周围分布着大量乌氏体, 花粉粒外壁有11–13个棱状凸起, 表面存在大量基粒棒, 形成紧密的覆盖层。不育株小孢子发育异常显现于减数分裂时期, 此时胞质中无脂质小球出现, 细胞壁开始积累胼胝质; 四分体时期绒毡层细胞未见降解; 单核小孢子时期无乌氏体出现; 成熟花粉时期花粉囊腔中未发现正常的乌氏体, 存在大量空瘪的败育小孢子, 外壁积累胼胝质, 缺乏基粒棒。微粉株小孢子在减数分裂时期可见胞质内有大量脂质小球, 四分体时期部分绒毡层发生变形, 单核小孢子时期有部分绒毡层开始降解; 绒毡层细胞降解滞后为少量发育进程迟缓的小孢子提供了营养物质, 部分小孢子发育为正常花粉粒; 这些花粉粒比较饱满, 表面有少量颗粒状突起, 但未能形成覆盖层, 花粉囊腔中及小孢子周围存在少量的乌氏体。小孢子形成的育性类型与绒毡层降解是否正常有关。     

黑麦(Secale cereale L.)花药培养及其雄核发育

离体培养黑麦花药,单核花粉可以通过不等分裂和均等分裂由营养性质的核发育成花粉胚状体或愈伤组织,并且最后形成了单倍体植株。接种前对穗子进行适当的低温处理,可以有效地提高胚状体和愈伤组织的生成率。根据多核和多细胞花粉的败育情况,认为新壁的形成和花粉外壁的适时破裂是已经启动分裂的小孢子能否发育成胚状体和愈伤组织的两个关键问题。     

濒危植物瑶山苣苔的大小孢子发生和雌雄配子体发育研究

利用石蜡切片技术对瑶山苣苔大小孢子发生、雌雄配子体发育及胚胎发育进行了细胞学观察,结果表明:瑶山苣苔胚珠倒生,单珠被,薄珠心,具珠被绒毡层。大孢子母细胞减数分裂形成的四分体呈直线排列,合点端的大孢子发育为功能大孢子,其余3个大孢子退化,胚囊为单孢子发生的蓼型胚囊发育方式。花药为四囊形,花药壁由外到内依次为表皮、药室内壁、中层和腺质绒毡层,小孢子形成时胞质分裂为修饰性同时型,小孢子四分体排列方式为四面体形,成熟花粉为2核细胞。胚乳发育为细胞型,在胚的发育过程中被吸收耗尽。瑶山苣苔大小孢子发生和雌雄配子体发育基本正常,不是导致其濒危的原因。但瑶山苣苔果实成熟时,胚仅发育至球形胚时期,需要经过一定时间休眠才能完成形态后熟,表明胚未发育完全可能是该物种天然更新困难的原因之一。     

中国特有属牛筋条属的花粉形态与其系统位置

从发育的角度研究了中国特有单种属DichotomanthesKurz及与其系统学研究有关的外类群Prinsepiautilis的花粉形态 ,扫描电镜观察显示Dichotomanthes花粉粒自脱离四分体胼胝质膜开始至成熟二核花粉粒不同发育时期 ,花粉形态和外壁纹饰未见变化 ,仅花粉体积随成熟度增加而有所增大。而Prinsepiautilis ,其花粉粒刚脱离四分体时形状和成熟花粉明显不同 ,成熟花粉极面观为三裂圆形 ,赤道面观为圆形 ,外壁具清晰的平行条纹 ,但幼嫩花粉粒的形状很特别 ,极面观为深三裂圆形 ,赤道面观亦见花粉在两条沟之间下陷而沟部外突 ,明显为角萌发孔花粉 ,且花粉体积较成熟者小 ,而外壁纹饰同成熟者相比无根本性差异。前述两种植物花粉在不同成熟期体积有明显差异 ,而外壁纹饰在不同成熟期不存在质的变化并相对稳定 ,说明花粉外壁纹饰这一性状在蔷薇科中具有较为重要的分类学意义。DichotomanthesKurz具典型Rosaceae花粉的三孔沟结构 ,外壁具条纹 -穴状纹饰。将其孢粉学特征同Rosaceae 4个亚科有关类群的同类资料相比较 ,并结合其它形态解剖与细胞学等研究结果 ,支持将Dichotoman thes置入Maloideae下而不赞同将其另立亚科或置于Prunoideae之下。此外 ,由于Prinsepiautilis的花粉在其发育初期具角萌发孔花粉 ,与Cunoniacea     

禾本科植物组织培养中的体细胞胚胎发生

在植物组织培养中,形态发生的途径通常有两条:一条是器官发生(Organogensis),另一条是胚胎发生(Embryogenesis)。在胚胎发生途径中形成类似合子胚而被称为胚状体的结构。根据外植体的不同来源,胚状体又可分为两类,即由普通植物体的各种器官、组织等的二倍体细胞产生的体细胞胚(Somatic embryos)和由小孢子或其分裂产物等单倍体细胞产生的花粉胚(Polleuembryos)。本文主要论述体细胞胚胎的发生。     

埃及白睡莲的胚胎学研究

对埃及白睡莲的大、小孢子的发生,雌、雄配子体的发育,以及胚和胚乳的发育进行了观察研究.结果表明埃及白睡莲的花药壁由5层细胞组成,绒毡层细胞具双核,属于分泌型.小孢子母细胞减数分裂时,胞质分裂属于同时型,小孢子四分体呈四面体型.成熟花粉为三细胞类型,花粉粒表面具有环沟.胚珠为倒生型、双珠被、厚珠心,珠孔仅由内珠被形成.大胞子母细胞减数分裂形成三分体,合点端2个细胞退化,珠孔端1个细胞发育为功能性大胞子.成熟雌配子体由4细胞组成,即2助细胞,1卵细胞和1中央细胞.合子的第一次分裂是横向的,形成的基细胞不再分裂,体积增大后成为一个大的胚柄细胞.而顶细胞进行一系列分裂形成胚.在此基础上,还比较了睡莲目不同属的胚胎学特征.     

灯盏花雄性不育种质鉴定与花药发育的细胞学研究

对云南泸西栽培灯盏花群体进行调查,发现了灯盏花雄性不育种质个体,其出现频率约为1.06×10-4.对所发现的灯盏花不育株形态特征及其花药发育过程进行了观察,并对花粉活力进行鉴定.结果显示:(1)灯盏花不育株根、茎、叶形态与正常可育植株基本相似,管状花小,花丝短,花药瘦小,无花粉粒散出或花粉无活力.(2)灯盏花在其花药发育的小孢子母细胞时期、四分体时期、小孢子时期和单核早期,由于绒毡层细胞液泡化、提前解体,不能为小孢子或花粉发育提供所需物质,导致小孢子母细胞和四分体解体,产生无花粉的花药;或小孢子和单核花粉胞内降解,形成不同形状和外壁纹饰的败育花粉.研究认为,灯盏花花药绒毡层异常是其花粉败育的主要原因.     

在三叶橡胶花药培养中体细胞与小孢子的关系

研究了三叶橡胶花药体细胞的愈伤组织化与花粉胚形成的关系。在只能促进花药体细胞增殖的培养基上,小孢子没有进一步发育而空瘪;在抑制体细胞增殖的培养基上,无论是花药体细胞组织或小孢子都未能进一步发育,小孢子逐渐解体,而在能诱导体细胞有一定程度的发育,同时又能诱导小孢子发育的培养基上,约有10—20%的花粉形成多细胞球。它们的发育与体细胞密切有关。还发现,在接种培养基中加入1—2毫克/升a—萘乙酸对体细胞与小孢子发育均有良好效果。对胚状体的细胞学观察表明:这些胚状体是单倍体(2n=18)。此外,花药接种前冷冻预处理(11℃24小时及3—5℃20小时),对小孢子有明显的不利影响。在经冷冻预处理后所得胚状体中,有相当多的二倍性细胞分裂相出现。这些胚状体可能来源于体细胞组织。     

Scanning electron microscopy of microspore embryogenesis inBrassica spp.

Scanning electron microscopy was employed to study and compare microspore embryogenesis in vitro with pollen development in planta inBrassica napus andB. oleracea. An exine with its specific pattern had already been formed, when microspores were released from tetrads. During subsequent pollen development, microspores increased in size and continued to strengthen the exine. Upon in vitro culture, all microspores, i.e., embryogenic and nonembryogenic, initially showed the same morphological features. After 24 h in culture, the microspores had increased in size. Thereafter, embryogenesis was indicated in some microspores by two different morphological changes. One featured an expansion in volume of the cell cluster around the germination aperture (type I), the other showed cell cluster volume expansion over the entire microspore surface (type II). Two-thirds of embryogenic microspores in bothB. napus andB. oleracea demonstrated type I development. When followed by fluorescence microscopy, in vitro culture of microspores revealed cultures with a high embryo frequency were those with a high frequency of symmetrical division.Abbreviations SEM Scanning electron microscopy - TEM Transmission electron microscopy     

白菜核雄性不育花药超微结构的研究

对白菜核雄性不育两用系的可育与不育花药进行了超微结构的比较观察。结果显示不育花药的造孢细胞核仁靠边分布:包裹小孢子母细胞的胼胝质厚薄不均匀,不完整等早期异常现象。减数分裂后,四分体细胞中常有多个细胞核。从四分体释放出的小孢子外壁的孢粉素物质不均匀沉积．呈不连续的单层异常结构。最后小孢子通过细胞质收缩方式败育。在可育花药中,绒毡层细胞在小孢子发育后期已显示出退化迹象,同时在细胞中开始积累脂类物质。但在同时期的不育花药中, 绒毡层细胞没有显示出退化的迹象,也不合成脂类物质。从时间上看,败育花药中小孢子母细胞及小孢子的异常在先,绒毡层细胞的异常在后。本研究揭示了白菜核雄性不育花药的超微结构特征, 对我们以前的光学显微镜观察结果予以补充和修正。     

白菜核雄性不育花药超微结构的研究

对白菜核雄性不育两用系的可育与不育花药进行了超微结构的比较观察。结果显示不育花药的造孢细胞核仁靠边分布;包裹小孢子母细胞的胼胝质厚薄不均匀,不完整等早期异常现象。减数分裂后．四分体细胞中常有多个细胞核。从四分体释放出的小孢子外壁的孢粉素物质不均匀沉积,呈不连续的单层异常结构。最后小孢子通过细胞质收缩方式败育。在可育花药中．绒毡层细胞在小孢子发育后期已显示出退化迹象,同时在细胞中开始积累脂类物质。但在同时期的不育花药中．绒毡层细胞没有显示出退化的迹象,也不合成脂类物质。从时间上看,败育花药中小孢子母细胞及小孢子的异常在先,绒毡层细胞的异常在后。本研究揭示了白菜核雄性不育花药的超微结构特征．对我们以前的光学显微镜观察结果予以补充和修正。     

Ultrastructure of microsporogenesis and microgametogenesis in Campsis radicans (L.) Seem. (Bignoniaceae)

In the present study, microsporogenesis, microgametogenesis and pollen wall ontogeny in Campsis radicans (L.) Seem. were studied from sporogenous cell stage to mature pollen using transmission electron microscopy. To observe the ultrastructural changes that occur in sporogenous cells, microspores and pollen through progressive developmental stages, anthers at different stages of development were fixed and embedded in Araldite. Microspore and pollen development in C. radicans follows the basic scheme in angiosperms. Microsporocytes secrete callose wall before meiotic division. Meiocytes undergo meiosis and simultaneous cytokinesis which result in the formation of tetrads mostly with a tetrahedral arrangement. After the development of free and vacuolated microspores, respectively, first mitotic division occurs and two-celled pollen grain is produced. Pollen grains are shed from the anther at two-celled stage. Pollen wall formation in C. radicans starts at tetrad stage by the formation of exine template called primexine. By the accumulation of electron dense material, produced by microspore, in the special places of the primexine, first of all protectum then columellae of exine elements are formed on the reticulate-patterned plasma membrane. After free microspore stage, exine development is completed by the addition of sporopollenin from tapetum. Formation of intine layer of pollen wall starts at the late vacuolated stage of pollen development and continue through the bicellular pollen stage.     

拟南芥雄性不育突变体ms1142的遗传定位与功能分析

经EMS诱变野生型拟南芥(Arabidopsis thaliana)群体筛选得到一株雄性不育突变体ms1142, 突变体的果荚短小, 不含种子。细胞学观察和扫描电镜结果表明, 突变体花药发育过程中, 花药中小孢子外壁异常、破裂, 最后没有花粉形成。遗传分析表明, 该突变体为隐性单核基因突变所致; 利用图位克隆的方法将MS1142基因定位于第1条染色体的BAC克隆F16P17上44 kb区间内, 目前尚未见该区间内有雄性不育基因的报道。以上结果结合生物信息学分析表明, MS1142是一个新的调控花药发育的关键基因。该工作为花药发育关键基因MS1142的克隆及功能分析奠定了基础。     

拟南芥雄性不育突变体ms1142的遗传定位与功能分析

经EMS诱变野生型拟南芥（Arabidopsis thaliana）群体筛选得到一株雄性不育突变体ms1142,突变体的果荚短小,不含种子。细胞学观察和扫描电镜结果表明,突变体花药发育过程中,花药中小孢子外壁异常、破裂,最后没有花粉形成。遗传分析表明,该突变体为隐性单核基因突变所致;利用图位克隆的方法将MS1142基因定位于第1条染色体的BAC克隆F16P17上44kb区间内,目前尚未见该区间内有雄性不育基因的报道。以上结果结合生物信息学分析表明,MS1142是一个新的调控花药发育的关键基因。该工作为花药发育关键基因MS1142的克隆及功能分析奠定了基础。     

A glycine-rich protein that facilitates exine formation during tomato pollen development

Formation of the unique and highly diverse outer cell wall, or exine, of pollen is essential for normal pollen function and survival. However, little is known about the many contributing proteins and processes involved in the formation of this wall. The tomato gene LeGRP92 encodes for a glycine-rich protein produced specifically in the tapetum. LeGRP92 is found as four major forms that accumulate differentially in protein extracts from stamens at different developmental stages. The three largest molecular weight forms accumulated during early microspore development, while the smallest molecular weight form of LeGRP92 was present in protein extracts from stamens from early microsporogenesis through anther dehiscence, and was the only form present in dehisced pollen. Light microscopy immunolocalization experiments detected LeGRP92 at only two stages, late tetrad and early free microspore. However, we observed accumulation of the LeGRP92 at the early tetrad stage of development by removing the callose wall from tetrads, which allowed LeGRP92 detection. Transmission electron microscopy confirmed the LeGRP92 accumulation from microspore mother cells, tetrads through anther dehiscence. It was observed in the callose surrounding the microspore mother cells and tetrads, the exine of microspores and mature pollen, and orbicules. Plants expressing antisense RNA had reduced levels of LeGRP92 mRNA and protein, which correlated to pollen with altered exine formation and reduced pollen viability and germination. These data suggest that the LeGRP92 has a role in facilitating sporopollenin deposition and uniform exine formation and pollen viability.     

Tapetum and middle layer control male fertility in Actinidia deliciosa

Background and Aims

Dioecism characterizes many crop species of economic value, including kiwifruit (Actinidia deliciosa). Kiwifruit male sterility occurs at the microspore stage. The cell walls of the microspores and the pollen of the male-sterile and male-fertile flowers, respectively, differ in glucose and galactose levels. In numerous plants, pollen formation involves normal functioning and degeneration timing of the tapetum, with calcium and carbohydrates provided by the tapetum essential for male fertility. The aim of this study was to determine whether the anther wall controls male fertility in kiwifruit, providing calcium and carbohydrates to the microspores.

Methods

The events occurring in the anther wall and microspores of male-fertile and male-sterile anthers were investigated by analyses of light microscopy, epifluorescence, terminal deoxynucleotidyl transferase-mediated dUTP nick-end labelling (TUNEL assay) and transmission electron microscopy coupled with electron spectroscopy. The possibility that male sterility was related to anther tissue malfunctioning with regard to calcium/glucose/galactose provision to the microspores was also investigated by in vitro anther culture.

Key Results

Both tapetum and the middle layer showed secretory activity and both degenerated by programmed cell death (PCD), but PCD was later in male-sterile than in male-fertile anthers. Calcium accumulated in cell walls of the middle layer and tapetum and in the exine of microspores and pollen, reaching higher levels in anther wall tissues and dead microspores of male-sterile anthers. A specific supply of glucose and calcium induced normal pollen formation in in vitro-cultured anthers of the male-sterile genotype.

Conclusions

The results show that male sterility in kiwifruit is induced by anther wall tissues through prolonged secretory activity caused by a delay in PCD, in the middle layer in particular. In vitro culture results support the sporophytic control of male fertility in kiwifruit and open the way to applications to overcome dioecism and optimize kiwifruit production.     

莴苣花药发育过程中钙的分布特征

减数分裂前,莴苣花药中的钙颗粒很少。减数分裂后,花药绒毡层细胞中的钙颗粒明显增加。同时在花药药室基质中也出现许多细小的钙颗粒。刚从四分体中释放出的小孢子内钙颗粒很少。伴随着花粉外壁物质在小孢子表面的沉积,钙颗粒开始积累在花粉壁部位。随后。小孢子中开始出现钙颗粒。当小孢子开始形成液泡后,钙颗粒向其中聚集,伴随着小液泡融合成大液泡。体积较大的钙颗粒主要集中在液泡中,而细胞质基质中的钙颗粒很少。随着二胞花粉中的大液泡消失,花粉细胞质中的钙颗粒变得很少。在以后的发育中,只有花粉壁中积累较多的钙颗粒。在莴苣花药发育过程中,钙与绒毡层细胞的退化和小孢子液泡形成以及二胞花粉中大液泡的消失有关。而花粉外壁表面积累丰富的钙与以后花粉的萌发有关。     

Evidence for microspore embryogenesis in wheat anther culture

Summary In wheat, plants may be regenerated from microspores via direct embryogenesis or organogenesis or embryogenesis from callus. Light and scanning electron microscopy were used to carefully study morphogenesis of microspore-derived plants from anther culture on modified 85D12 starch medium and to determine whether the plants were formed via organogenesis or embryogenesis. Our results indicate that plants are formed via embryogenesis from microspores. Evidence for embryogenesis included the formation of the epidermis and a suspensorlike structure (21 days after culture), followed by initiation of an apical meristem, differentiation of the scutellum, and embryo elongation. At 28 days in culture, the embryo possessed a well-developed scutellum and axis with suspensor. Embryogenesis was further confirmed by coleoptile and radicle elongation during germination when the embryos were cultured on medium supplemented with kinetin with or without coconut water. In this system, an average 67 microspores per responsive anther began cell division but only 3.69 embryos were formed per responsive anther after 6 wk. Adventitious embryos could be induced if the embryos, once formed, remained on initiation medium for 10 wk instead of being transferred to regeneration medium. Developmental stages which may be amenable to changes that could enhance plant production were identified. The potential to use this information to enhance plant production is discussed.