甜椒花药绒毡层的二型性及其组织化学研究

在甜椒（Capsicum annuum L.)中,靠近花粉中部的绒毡层自药隔产生,由较大的细胞组成,而花药外部区域的其余的绒毡层细胞较小,来自于初生壁层,前者的细胞具有大液泡和较大的细胞核,甲基绿－派罗宁和汞－溴酚蓝染色反应较后者弱,在造孢组织时期,二者液泡内都含有较大的球形的酸性磷酸酶颗粒,在以后的发育中,这种颗粒消失,在减数分裂时期,两种绒毡层的DNA,RNA和蛋白质合成活动增强,来自药隔的绒毡层积累了更多的DNA,绒毡层在解体时酸性磷本酶活性很高,两种不同的绒毡层退化过程相似,在全部发育过程中绒毡层内无淀粉粒。     

枸杞花药发育过程中脂滴和淀粉粒的分布特征

宁夏枸杞(Lycium barbarurn L．)花药发育过程中,淀粉粒和脂滴两种营养物质的积累和分布具有一定的特点：在造孢细胞时期,药隔薄壁细胞,表皮和药室内壁细胞中开始积累淀粉粒,而造孢细胞、绒毡层细胞和中层细胞中则没有淀粉粒。在四分体时期,绒毡层细胞开始积累脂滴并且数量逐渐增加。到小孢子晚期,绒毡层细胞降解,内含脂滴流入药室中。在小孢子发育过程中既没有淀粉粒也没有脂滴积累,直到二胞花粉的大液泡消失后花粉粒中才开始积累脂滴,然后又开始出现淀粉粒。枸杞成熟花粉中的营养储存物是脂滴和淀粉粒。     

胡萝卜花药发育的组织化学研究

胡萝卜四分体时期的花药在药室内壁和绒毡层细胞中积累淀粉粒,随着花药的发育,花粉先出现大液泡,同时药室内壁和绒毡层细胞中淀粉粒消失;以后花粉中的大液泡消失,在花粉细胞质中出现淀粉粒。伴随着花粉的发育,绒毡层细胞退化,在细胞中积累较多的脂类物质,同时花粉中脂类物质含量也明显增加。胡萝卜成熟花粉粒的储存物主要为脂滴,也有少部分淀粉颗粒。胡萝卜花药在特定时间和特定部位积累营养储存物的过程也是其发育的一个特征。     

宁夏枸杞异型绒毡层发育的超微结构特点

采用半薄和超薄切片技术对宁夏枸杞(Lycium barbarum L.)异型绒毡层的来源、结构及发育特点进行了研究,结果表明:(1)枸杞异型绒毡层由药隔绒毡层和药壁绒毡层组成,两种绒毡层除了来源、形态及分布位置不同外,其分化、成熟和降解时间,以及细胞质组成、分泌物成分等均有差异.(2)小孢子母细胞期间,药隔绒毡层细胞电子密度大,具有很强的脂质性质,光滑内质网和脂质小泡很丰富;而药壁绒毡层细胞中的核糖体和粗糙内质网较多.四分体后期,两种绒毡层细胞均含有很丰富的核糖体、粗糙内质网和分泌团.减数分裂前,两种绒毡层的细胞壁出现松散并呈絮状.之后,由于不同发育时期绒毡层细胞的不同分泌物在絮状细胞壁中的分布,致使二者的细胞壁都出现了一系列变化.(3)从小孢子早期开始,两种绒毡层细胞的质膜都发生了局部解体.分析推测,在母细胞期间药隔绒毡层具有较高的糖和脂类合成率,药壁绒毡层具有较高的蛋白质类合成率;在四分体后期,药隔绒毡层具有加强胼胝质酶合成和分泌的功能;而两种绒毡层絮状松散的细胞壁和局部解体的质膜有利于绒毡层的较大颗粒分泌物大量、顺利地分泌出绒毡层细胞.     

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。     

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波泡的消失有关。而花粉外壁表面积累丰富的钙与以后花粉的萌发有关。     

辣椒细胞质雄性不育花药败育及淀粉粒分布的细胞学观察

用PAS反应对辣椒细胞质雄性不育系8214A和保持系8214B花药中的淀粉粒分布进行研究.在减数分裂前,保持系花药与不育系花药的结构和淀粉粒分布相似.保持系花药减数分裂后,药壁绒毡层细胞开始液泡化并体积增大,在药隔薄壁细胞中积累了许多较小的淀粉粒;在小孢子晚期,绒毡层细胞退化,在药隔薄壁细胞中淀粉粒体积增大;在二胞花粉时期,随着花粉大液泡的消失花粉中出现淀粉粒;花粉成熟时,其细胞质中积累了丰富的淀粉粒.不育系花药减数分裂后,由于药室腔的空间不能扩大,四分体被挤压在一起,最终四分体小孢子败育.不育花药的维管组织发育正常,但较多的淀粉粒积累在药隔薄壁细胞中.该种辣椒雄性不育系中.花粉的败育发生在四分体时期.绒毡层细胞结构异常可能影响糖类物质向药室的正常转运.该种辣椒雄性不育系的绒毡层异常与花粉败育有关.     

枸杞花药发育过程中钙的分布

在枸杞花药发育过程中,用焦锑酸钾沉淀的钙颗粒显示出了一个与花药发育事件有关的分布特征：在孢原细胞时期的花药中钙颗粒很少。在造孢细胞到小孢子母细胞时期,花药中钙颗粒增加。当花粉母细胞进行减数分裂时,花药中的钙颗粒进一步增加,尤其是在小孢子母细胞的胼胝质壁中。在小孢子发育早期,花药药隔部位的绒毡层细胞质中钙颗粒也明显增加并特异性地分布在其内切向壁上。当小孢子被释放出后,钙颗粒开始特异性积累在正在形成的花粉外壁中,尤其在萌发孔的部位聚集了大量的钙颗粒。当小孢子形成大液泡时,其细胞质中的钙颗粒明显减少。在小孢子分裂形成二胞花粉后,在二胞花粉的大液泡中又特异性地出现许多细小钙颗粒。随着二胞花粉的大液泡完全消失,其细胞质中又出现了许多钙颗粒。接近开花时的成熟花粉粒细胞质中,细小的钙颗粒主要分布在营养细胞和生殖细胞中。枸杞花药发育过程中钙的分布特征反映了其参与调控花粉发育过程。     

白菜细胞核雄性不育花药的细胞化学观察

对一种由一对隐性基因控制的白菜细胞核雄性不育和可育株的花药进行了细胞学和组织化学研究。种子播种后,有1/4植株为不育株,其余的为可育株。通过对不育株和可育株花药发育的细胞学观察,确认不育花粉的败育发生在小孢子发育时期。用组织化学的方法研究了可育株和不育株花药发育过程中的多糖和脂类的分布动态,发现在减数分裂前,可育花药和不育花药的药隔细胞中都储藏了大量的淀粉粒。二者的差异仅是不育花药的绒毡层细胞液泡化明显。在减数分裂后的小孢子发育时期,可育花药的绒毡层细胞具有将药隔细胞中的淀粉粒多糖吸收并转化成脂类的功能,小孢子及以后的二胞花粉中也积累了大量的脂类储藏物质在不育花药中,虽然减数分裂后药隔细胞中的淀粉粒也都消失,但绒毡层细胞中的脂类物质相比很少,同时绒毡层细胞显示了明显的多糖反应,表明不育花药的绒毡层细胞将糖类转化为脂类的功能受阻。在小孢子的表面有些脂类物质,但在细胞质中却没有脂类积累。这一结果暗示在该种白菜细胞核雄性不育株中,由于花药绒毡层细胞转换多糖为脂类的功能失常,导致了小孢子的败育。     

白菜细胞核雄性不育花药的细胞化学观察

对一种由一对隐性基因控制的白菜细胞核雄性不育和可育株的花药进行了细胞学和组织化学研究。种子播种后,有1／4植株为不育株,其余的为可育株。通过对不育株和可育株花药发育的细胞学观察,确认不育花粉的败育发生在小孢子发育时期。用组织化学的方法研究了可育株和不育株花药发育过程中的多糖和脂类的分布动态,发现在减数分裂前,可育花药和不育花药的药隔细胞中都储藏了大量的淀粉粒。二者的差异仅是不育花药的绒毡层细胞液泡化明显。在减数分裂后的小孢子发育时期,可育花药的绒毡层细胞具有将药隔细胞中的淀粉粒多糖吸收并转化成脂类的功能,小孢子及以后的二胞花粉中也积累了大量的脂类储藏物质。在不育花药中,虽然减数分裂后药隔细胞中的淀粉粒也都消失,但绒毡层细胞中的脂类物质相比很少,同时绒毡层细胞显示了明显的多糖反应,表明不育花药的绒毡层细胞将糖类转化为脂类的功能受阻。在小孢子的表面有些脂类物质,但在细胞质中却没有脂类积累。这一结果暗示在该种白菜细胞核雄性不育株中,由于花药绒毡层细胞转换多糖为脂类的功能失常,导致了小孢子的败育。     

Tapetum Dimorphism and Its Histochemical Study in Sweet Pepper (Capsicum annuum L. Var. grossum)

In sweet pepper, the portion of tapetum toward the interior of the anther comprising large cells is derived from cells of connective of anther whereas the remaining tapetum on the outside of the anther comprising comparatively small cells is derived from the parietal layer. Those ceils of the former prosessing large vacuoles and large nuclei are stained weaker than the cells of the latter by methyl green-pyronin and mercuric-bromophenol blue staining. Large spherical grains which contain acid phosphatase appear in the vacuoles in both kinds of tapetum at sporogenesis stage. During meiosis of pollen mother cells, DNA, RNA and protein sysntheses increase in tapetum. The tapetum derived from connective accumulates more DNA than that derived from parietal layer. The activity of acid phosphatase becomes higher in tapetum when it degenerates. The degeneration of two kinds of tapetum is similar. There are no starch grains in tapetum through its whole course of development.     

单叶蔓荆小孢子发生和雄配子体的发育

利用常规石蜡制片法对单叶蔓荆小孢子发生和雄配子体发育进行了详细观察。主要结果如下：（1）花药壁由四层细胞构成,由外到内分别为表皮、药室内壁、中层和绒毡层,花药壁发育方式为双子叶型。（2）花药壁表皮细胞具多细胞腺体。（3）药室内壁和部分药隔细胞具纤维性加厚。（4）绒毡层细胞有两种来源,外周部分来源于初生壁细胞,近药隔部分来源于药隔细胞。绒毡层为分泌型,细胞具双核。（5）小孢子母细胞减数分裂过程中胞质分裂为同时型,形成的四分体主要为四面体型排列,偶有左右对称型。（6）成熟花粉粒为2细胞型,花粉具3孔沟。     

Anther ontogeny in Campsis radicans (L.) Seem. (Bignoniaceae)

In this study anther ontogeny of Campsis radicans (L.) Seem. was investigated by transmission electron microscopy and light microscopy with special reference to the development of the anther wall. The anther wall formation follows the dicotyledonous type. The differentiation in anther starts with the appearance of archesporial cells which undergo periclinal divisions to give primary parietal layer to the epidermal site and the primary sporogenous cells to the inside. The primary parietal layer also divides to form two secondary parietal layers. Later, the outer secondary parietal layer (spl1) forms the endothecium and the middle layer by periclinal division whereas the inner one (spl2) directly develops into the outer tapetum forming the inner most layer of the anther wall. The sporogenous tissue is generally organized in two rows of cells with a horseshoe-shaped outline. The remainder of the tapetum lining the sporogenous mass is derived from the connective tissue. The tapetum thus has dual origin and dimorphic. Anthers are tetrasporangiate. The wall of the anther consists of an epidermis, endothecium, middle layer, and the secretory type tapetum. Tapetal cells are usually binucleated. Epidermis and Endothecium layers of anther wall remain intact until the end of anther and pollen development; however, middle layer and tapetum disappear during development.     

STUDIES IN THE BIGNONIACEAE. II. ONTOGENY OF DIMORPHIC ANTHER TAPETUM IN TECOMA

A developmental study of anther tapetum in Tecoma stans has shown that the hypodermal archesporial layer differentiates in each microsporangium by cutting off a primary parietal layer to the outside (epidermal) and a primary sporogenous layer to the inside (connective). The primary parietal layer divides periclinally, producing the outer secondary parietal layer, which by further divisions, forms the future endothecium and the middle layer. On epidermal side, the inner secondary parietal layer gives rise to tapetum. The remainder of the tapetum on the inside (connective) is contributed by the parenchymatous connective cells lying just outside the sporogenous cells. The tapetum thus follows the dicotyledonous type of ontogeny. It also shows a distinct dual origin and is structurally dimorphic.     

雄性不育与可育楸树花发育的细胞学比较研究

楸树（Catalpa bungei C.A.Meyer.）属紫葳科(Bignoniaceae)梓树属(Catalpa),落叶乔木,是我国特有的珍贵优质用材树种。本文用石蜡切片法对可育株和雄性不育株楸树的大、小孢子发生及雌、雄配子体发育过程进行了详细地比较观察。结果表明：可育株和不育株楸树雌蕊的发育基本相同,胚珠倒生,薄珠心,单珠被,胚囊发育为蓼型。可育株雄蕊花药四室,药隔薄壁组织发达;异型绒粘层,由药壁绒粘层和药隔绒粘层组成;花药壁表皮细胞在小孢子母细胞减数分裂前后开始径向伸长加厚,直到花药开裂并不降解,这可能与花药开裂有关;成熟花粉为四合花粉。雄性不育株花药的早期发育到次生造胞细胞时期与可育雄蕊的相同,小孢子母细胞减数分裂前绒毡层发育不充分;四分体时期,绒毡层细胞高度液泡化,细胞质稀薄,已提前降解,小孢子四分体因绒毡层结构和功能异常而不能正常发育,因此楸树雄性不育为结构型雄性不育。     

Differential distribution of ascorbic acid and RNA in the developing anthers ofDatura stramonium L.

The histochemical localization of ascorbic acid and RNA was studied during developmental stages ofDatura anthers. The concentration of ascorbic acid and RNA was high in primary parietal and primary sporogenous layers, sporogenous cells and pollen grains. The connective of young anther showed remarkably high concentration of ascorbic acid. The high peaks of ascorbic acid and RNA concentration correlated with the growth phases of anther. The connective and anther wall layers act as reservoirs of energy needed for developing sporogenous cells.     

Anther ontogeny in <Emphasis Type="Italic">Brachypodium distachyon</Emphasis>

Brachypodium distachyon has emerged as a model plant for the improvement of grain crops such as wheat, barley and oats and for understanding basic biological processes to facilitate the development of grasses as superior energy crops. Brachypodium is also the first species of the grass subfamily Pooideae with a sequenced genome. For obtaining a better understanding of the mechanisms controlling male gametophyte development in B. distachyon, here we report the cellular changes during the stages of anther development, with special reference to the development of the anther wall. Brachypodium anthers are tetrasporangiate and follow the typical monocotyledonous-type anther wall formation pattern. Anther differentiation starts with the appearance of archesporial cells, which divide to generate primary parietal and primary sporogenous cells. The primary parietal cells form two secondary parietal layers. Later, the outer secondary parietal layer directly develops into the endothecium and the inner secondary parietal layer forms an outer middle layer and inner tapetum by periclinal division. The anther wall comprises an epidermis, endothecium, middle layer and the secretory-type tapetum. Major documented events of anther development include the degradation of a secretory-type tapetum and middle layer during the course of development and the rapid formation of U-shaped endothecial thickenings in the mature pollen grain stage. The tapetum undergoes degeneration at the tetrad stage and disintegrates completely at the bicellular stage of pollen development. The distribution of insoluble polysaccharides in the anther layers and connective tissue through progressive developmental stages suggests their role in the development of male gametophytes. Until sporogenous cell stage, the amount of insoluble polysaccharides in the anther wall was negligible. However, abundant levels of insoluble polysaccharides were observed during microspore mother cell and tetrad stages and gradually declined during the free microspore and vacuolated microspore stages to undetectable level at the mature stage. Thus, the cellular features in the development of anthers in B. distachyon share similarities with anther and pollen development of other members of Poaceae.     

峨眉双蝴蝶的胚胎学研究

首次报道了峨眉双蝴蝶Ｔｒｉｐｔｅｒｏｓｐｅｒｍｕｍ ｃｏｒｄａｔｕｍ（Ｍａｒｑ．）Ｈ．Ｓｍｉｔｈ的胚胎学特征,研究结果用以讨论双蝴蝶属的系统演化关系。主要研究结果如下：花药四室;药壁发育为双子叶型;绒毡层属单型起源,细胞具单核,属腺质型绒毡层,药隔处的绒毡层细胞形成类胎座,其余部位的绒毡层细胞仍为一层细胞;在花药成熟时,花药的药室内壁纤维状如厚且柱状伸长,表皮细胞减缩退化,纤维状加厚不明显。成熟花     

粉背薯蓣雄花的形态发生

通过田间观察与石蜡切片法,对粉背薯蓣雄花的发生发育进行了形态与解剖学观察。结果表明:粉背薯蓣雄花为功能上的单性花,花芽分化时雄蕊原基正常启动,随后,3枚雄蕊正常发育,3枚雄蕊退化。成熟雄蕊药隔分叉、变宽呈加厚短叉状,退化雄蕊呈花丝状,顶端分叉或膨大成瘤状。初步分析了花部构件的演变与功能的关系。对粉背薯蓣小孢子发生及雄配子体发育过程的观察表明,花药具4个花粉囊,花药壁发育为单子叶型,由表皮、药室内壁、中层1层和绒毡层组成,绒毡层为腺质型。小孢子母细胞减数分裂后胞质分裂为同时型,四分体为四面体型排列,偶有左右对称型排列,成熟的花粉粒为二细胞型。     

Comparative microsporogenesis and anther development of selected species from Magnoliaceae

Stamen development and microsporogenesis of four species from Magnoliaceae was investigated in order to provide additional data from this family. Stamen bases were found to be wide and short, without morphological differentiation in Magnolia moto, M. paenetalauma and Woonyoungia septentrionalis. In contrast, stamens are distinctly differentiated into anther and filament regions in Michelia crassipes. The orientation of dehiscence is introrse, introrse‐latrorse and latrorse in M. moto, M. paenetalauma and M. crassipes, respectively. The vascular bundles range from three to five (M. moto, M. paenetalauma) to one (M. crassipes). The amount of the connective tissue has been reduced from three to two times of the sporogenous tissue in M. moto and M. paenetalauma. The two parts are nearly equal in M. crassipess. In W. septentrionalis, the orientation of dehiscence, the vascular bundles and the size of the connective tissue vary in different parts of the floral receptacle. The endothecium and endothecial‐like cells form a ring that encloses the entire anther. The middle layer cells originate from both the outer and inner secondary parietal layers, and start to degenerate gradually at the microspore interphase stage or meiosis stage. The tapetum is of the secretory type, derived from the inner secondary parietal cells. The mature anther wall is composed of one epidermal, one endothecial, three to four middle layer(s) and one glandular tapetum. Only one epidermis, one endothecium, and the remnants of the middle layer and tapetum are left before anther dehiscence. Microspore tetrads appear as isobilateral, tetrahedral, decussate and T‐shaped, produced by a modified simultaneous microsporogenesis, which have evolved from the common ancestor of all Magnoliaceae. Our results support an ancestral state with stamens with non‐marginal sporangia and the amount of sterile tissue exceeding the amount of sporogenous tissue, and evolutionary trends toward equalization of the amount of fertile and sterile tissue on the stamen.