Microspore and tapetal development in Echinodorus cordifolìus (Alismaceae)

In the microspore tetrad period the exine begins as rods that originate from the plasma membrane. These rods are exine units that on further development become columellae as well as part of the tectum, foot layer and “transitory endexine”. The primexine matrix is very thin in the future sites of the pores. At these sites the plasma membrane and its surface coating (glycocalyx) are without exine units and adjacent to the callose envelope. The exine around the aperture margin is characterized by units of reduced height. After the exine units and primexine matrix have become ca 0.2 μm in height a fibrillar zone forms under the aperture margin. It is the exine units around the aperture that are templates for exine processes on apertures of mature pollen. Oblique sections of the early exine show that the tectum consists of the distal portions of close-packed exine units. The exine enlarges in the free microspore period but initially its substructure (tectum, columellae, foot layer and transitory endexine) is not homogeneous and unit structures are visible until after the vacuolate microspore period. There are indications of a commissural line/plane (junction plane) which separates the foot layer from the endexine during early development. Our observations of development in Echinodorus pollen extend a growing number of reports of “transitory endexines” in monocot pollen. The exine unit-structures become 0.2 μm or more in diameter and many columellae are composed of only one exine unit. Spinules become exceptionally tall, many protruding ca 0.7 μm above the level of the tectum as units only ca 0.1 μm in diameter. The outer portion of the tectum fills in around spinules and by maturity they are microechinate with their bases spread out to ca 1 μm or more. Unit structures can be seen with SEM in mature pollen following oxidation by plasma ashing and in the tapetum these units are arranged both radially, as in spinules, and parallel with the tapetal surfaces. There are clear indications of such an arrangement of units in untreated fresh pollen. Units comprising the basal part of the exine are not completely fused by sporopollenin accumulated during development. This would seem to be a characteristic feature, based on published work, of the alismacean pollen. Our use of a tracer shows, however, that there is considerable space within or between exine structure of mature Echinodorus pollen. Based upon the ca 0.1 μm size of exine-units formed early in development and exine components seen after oxidative treatment it seems that the early (primary) accumulated sporopollenin has greater resistance to oxidation than sporopollenin added, secondarily, around and between units later in development. Both primarily and secondarily accumulated sporopollenin are resistant to acetolysis but published work indicates that acetolysis alters exine material. At the microspore tetrad time and until the vacuolate stages tapetal cells are arranged as in secretory tapetums. During early microspore stages there are orbicules at the inner surface of tapetal cells. At free microspore period tapetal cells greatly elongate into the loculus and surround the microspores. By the end of the microspore vacuolate period tapetal cells release their cellular contents and microspores are for a time enveloped by tapetal organelles and translocation material.     

DEVELOPMENT OF OMNIAPERTURATE POLLEN IN TRILLIUM KAMTSCHATICUM (LILIACEAE)

Ultrastructural changes during omniaperturate pollen development in Trillium kamtschaticum Pall, was examined using transmission electron microscopy. The pollen mother cells are not enveloped within a thick callosic wall. The microspores resulting from successive meiosis are divided by scanty deposition of callosic wall in the tetrad. A primexine/exine template is not recognizable within the tetrad during formation of exinous components. Preexinous globules, originating from vesicles in the callosic wall, accumulate electron-dense materials and develop into exinous globules. The preexinous globules have ca 10 nm wide contacts with tilted and invaginated plasma membrane of the microspore within the callosic wall. After dissolution of the callosic wall, the microspores separate and mitosis subsequently leads to the formation of a generative cell and vegetative cell encased in a loose aggregation of developing exinous globules. When the generative cell is at the pollen grain surface, the channeled zone is initiated at the opposite side of the microspore on the surface of the vegetative cell. Just before pollen maturity, a new layer develops under the channeled zone. Thus, development of the omniaperturate pollen grains of T. kamtschaticum involves some processes that are distinct from those of Canna and Heliconia and some that are similar.     

THE GLYCOCALYX AND INITIATION OF EXINE SPINULES ON MICROSPORES OF CANNA

Spinules of Carina generalis pollen are initiated within a tridimensional network during the microspore tetrad period. The network is stained selectively with the hydrazide-silver proteinate method of Thiéry following periodate oxidation and by phosphotungstic acid at low pH, demonstrating the presence of polyanions. Protein is indicated as a component of the network by positive staining with PTA in acetone. These results suggest the presence of polysaccharides and proteins, possibly as mucopolysaccharides or glycoproteins. The network may be considered as a part of the glycocalyx because of its composition and association with the plasma membrane. Sporopollenin accumulates on the tridimensional network or in meshes of the net. The beaded fine structure of spinules resists the acetolysis mixture of Erdtman. Our results imply that the plasma membrane and its glycocalyx are part of the system which mediates genetic expression of exine form. The implication is compatible with formation of specific exines on all pollen grains of a plant and on aborted microspores, diminutive spores with depauperate chromosome complements, and enucleate bodies of cytoplasm resulting from meiotic abnormalities.     

大葱小孢子母细胞至二胞早期花粉发育的超微结构观察

用电镜观察了章丘大葱 (AlliumfistulosumL .)从小孢子母细胞至二胞早期花粉发育的超微结构。终变期的花粉母细胞 ,胼胝壁外方的相邻初生壁间及胞间隙内 ,存在胞间物质 ,四分体期 ,此物质尚部分存在。小孢子母细胞减数分裂前 ,细胞质内含有脂滴 ,小孢子有丝分裂以后 ,脂滴增多增大。小孢子分裂后期 ,质体已积累淀粉粒 1至多个。二胞早期花粉之营养细胞质内 ,有些含淀粉质体亦含脂滴。各发育期 ,核糖体及多聚合糖体丰富 ,并有很多的粗面内质网、高尔基体及小泡、线粒体 ,显示蛋白质、糖类及其它物质合成及运输作用的活跃。小孢子缺中央大液泡。有丝分裂后期 ,细胞器集中于未来的营养细胞极。小孢子胞质分裂期 ,有些内质网贴近或与花粉质膜相连 ,它们或有可能互相融合 ,扩大质膜面积而适应花粉的生长。还讨论了不同时期高尔基体小泡的作用。     

含笑花药发育的超微结构研究

对含笑花药发育中的超微结构变化进行观察,结果显示:(1)花粉发育中有三次液泡变化过程——第一次是小孢子母细胞在形成时内部出现了液泡,这可能与胼胝质壁的形成有关;第二次是在小孢子母细胞减数分裂之前,细胞内壁纤维素降解区域形成液泡,它的功能可能是消化原有的纤维素细胞壁;第三次是在小孢子液泡化时期,形成的大液泡将细胞核挤到边缘,产生极性。(2)含笑花粉在小孢子早期形成花粉外壁外层,花粉外壁内层在小孢子晚期形成,而花粉内壁是在二胞花粉早期形成;花粉成熟时,表面上沉积了绒毡层细胞的降解物而形成了花粉覆盖物。研究认为,含笑花粉原外壁的形成可能与母细胞胼胝质壁有关,而由绒毡层细胞提供的孢粉素物质按一定结构建成了花粉覆盖物。     

ULTRASTRUCTURE AND DEVELOPMENT OF THE NEXINE AND INTINE IN THE POLLEN WALL OF SILENE ALBA (CARYOPHYLLACEAE)

Nexine and intine development in Silene alba (Caryophyllaceae) was investigated by electron microscopy and enzyme cytochemistry. Nexine-2 forms by deposition of sporopollenin along unit membrane lamellae closely associated with the microspore plasma membrane in the late tetrad stage. After the callose wall dissolves, electron density increases along the tangentially oriented fibers of the proximal primexine, forming nexine-1. When the exine is essentially complete, the intine begins to develop. In the nearly mature microspore, acid phosphatase activity appears in the peripheral cytoplasm just prior to its extrusion into the intine of the mature pollen grain.     

Reproduction in seagrasses: pollen wall morphogenesis in Amphibolis antarctica and wall structure in filiform grains

The pre–meiotic anther of the marine angiosperm Amphibolis antarctica contains microsporocytes and sterile cells. The microsporocytes divide conventionally to produce tetrads, but the sterile cells degenerate and contribute to the future pe–riplasmodium. Each tetrad of young microspores is contained within a vesicle defined by a membrane. After release from the tetrad, the microspores increase in length and rapidly become filiform. The microspore nucleus soon divides and partitioning of the cytoplasm delimits the generative cell from the vegetative cell of the binucleate pollen grain. The division and the early pollen growth occurs while the grains are segregated within vesicles in the periplasmodium. These compartments, established at microspore release, remain structurally intact throughout the vacuolate period of pollen development, when pollen wall assembly begins. This process is initiated as particles migrate from the inner face of the vesicle membrane into the lumen of the vesicle and microfibrillar elements form between adjacent particles. The particles and microfibrils form a loose, three–dimensional network. The vesicle membrane then disappears and the binuclate grains become immersed in the tapetal residuum. Additional wall components are now deposited upon the primary fibrillar stratum. Short lamellae, resembling fragments of membrane, frequently associated with electron–opaque globuli, are found intermixed with the surface microfibrils. Apparently, granular material originating in the degenerating periplasmodium may be the precursor of the globuli, and contact with the lamellae brings about an alteration in state. At this stage the pollen wall is resolved as two distinct fibrillar strata and the lamellae and globuli are incorporated as inclusions into the superficial zone of the outer stratum. The mature pollen wall exhibits faint stratification and the presence of the subsurface inclusions is readily demonstrated in germinating grains by section staining with phosphotungstic acid. The pollen wall in A. antarctica is compared with that in filiform grains of other seagrasses.     

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.     

RUPTURED POLLEN GRAIN1, a member of the MtN3/saliva gene family, is crucial for exine pattern formation and cell integrity of microspores in Arabidopsis

During microsporogenesis, the microsporocyte (or microspore) plasma membrane plays multiple roles in pollen wall development, including callose secretion, primexine deposition, and exine pattern determination. However, plasma membrane proteins that participate in these processes are still not well known. Here, we report that a new gene, RUPTURED POLLEN GRAIN1 (RPG1), encodes a plasma membrane protein and is required for exine pattern formation of microspores in Arabidopsis (Arabidopsis thaliana). The rpg1 mutant exhibits severely reduced male fertility with an otherwise normal phenotype, which is largely due to the postmeiotic abortion of microspores. Scanning electron microscopy examination showed that exine pattern formation in the mutant is impaired, as sporopollenin is randomly deposited on the pollen surface. Transmission electron microscopy examination further revealed that the primexine formation of mutant microspores is aberrant at the tetrad stage, which leads to defective sporopollenin deposition on microspores and the locule wall. In addition, microspore rupture and cytoplasmic leakage were evident in the rpg1 mutant, which indicates impaired cell integrity of the mutant microspores. RPG1 encodes an MtN3/saliva family protein that is integral to the plasma membrane. In situ hybridization analysis revealed that RPG1 is strongly expressed in microsporocyte (or microspores) and tapetum during male meiosis. The possible role of RPG1 in microsporogenesis is discussed.     

Pollen Wall Development of Xiphidium coeruleum (Haemodoraceae) and its Systematic Implications

The development of the pollen grain wall in Xiphidium coeruleum(Haemodoraceae) was studied using TEM and cytochemical stainingtechniques. Microsporocyte ontogeny initiates with the degradationof the cellulosic cell wall and subsequent deposition of a thickcallosic cell wall. Following callose deposition, successivemeiosis occurs, resulting in a tetragonal tetrad of microspores.during meiosis, the cell walls of the tapetum break down, releasingthe syncytial periplasmodium. Irregular non-sporopollenous globularbodies are deposited in this peripheral periplasmodium, whichis rich in ER, golgi bodies, vesicles, and characteristic starchplastids. Within the microspore cytoplasm, vesicles, golgi bodies,and plastids are plentiful during the early tetrad stage. Atthis time the plasma membrane of the microspore develops characteristicevaginations. An extracellular membrane, the ‘white line’,is secreted outside the microspore plasma membrane, followedby callose wall degradation. Bead-like deposits of exine orprimexine are deposited at points along the ‘white line’simultaneously on inner and outer surfaces and opposite theoriginal plasma membrane evaginations. The bead-like exine depositscontinue to grow during the release of the microspores and developinto laterally appressed, rod-shaped ektexinous elements havinga tangentially oriented commissure, the vestige of the original‘white line’. The mature intine is two-layered,the outer exintine containing radially oriented vesicular structures,which are apparently derived from plasma membrane extensions.Exine development in Xiphidium is similar to ‘nexine 1’development in Lilium and may have evolved from an ancestraltectate-columellate condition by the loss of the sexine. Walldevelopment in members of the Zingiberales is strikingly similarto that reported here for the Haemodoraceae—evidence ofa possible relationship between the two taxa. Xiphidium coeruleum, Haemodoraceae, pollen, tapetum, development, exine     

THE POLLEN WALL OF CANNA AND ITS SIMILARITY TO THE GERMINAL APERTURES OF OTHER POLLEN

The pollen wall of Canna generalis Bailey is exceptionally thick, but only a minor part of it contains detectable amounts of sporopollenin. The sporopollenin is in isolated spinules at the exine surface and in the intine near the plasma membrane. There is no sporopollenin in the > 10 μ thick channeled region between spinules and intine. We suggest that the entire pollen wall of C. generalis is similar to the thick intine and thin exine typical for germinal apertures in many pollen grain types. Considered functionally, the Canna pollen wall may offer an infinite number of sites for pollen tube initiation and would differ significantly from grains that are inaperturate in the sense of an exine lacking definite germinal apertures.     

Pollen development in a submerged plant,Ottelia alismoides (L.) Pers. (Hydrocharitaceae)

Exine structure and its developmental program in a submerged plant,Ottella alismoides (L.) Per. were investigated with scanning and transmission electron microscopies. Verrucate protrusions initiate on microspore plasma membrane at early tetrad stage. The verrucate protrusions develop into spines during free microspore stage. A foot layer is formed by accumulation of lamellated structure. The pollen grains ofOttelia alismoides are inaperturate, not omniaperturate, because of the well-developed foot layer. The inaperturate pollen grains ofOttelia are characterized by the spinous protrusions and the granular foot layer.     

洋葱花药发育中钙离子分布特征

采用焦锑酸钾沉淀钙离子技术,对洋葱（Alliumcepa）花药发育中Ca^2＋分布进行了研究。在小孢子母细胞时期,小孢子母细胞中的钙沉淀颗粒很少,但绒毡层细胞的内切向壁已出现明显的钙沉淀颗粒。在四分体时期,四分体小孢子的胼胝质壁中出现较多的钙沉淀颗粒;绒毡层细胞内切向壁的钙沉淀颗粒消失,而在外切向壁和径向壁部位的钙沉淀颗粒增加。在小孢子早期,小孢子中也出现了钙沉淀颗粒,而绒毡层细胞内切向壁表面出现了很多絮状物,其上附有细小钙沉淀颗粒。到小孢子晚期,小孢子中出现一些小液泡,细胞质中的钙沉淀颗粒有所下降。此时绒毡层细胞已明显退化,但在绒毡层膜上仍有一些乌氏体和钙沉淀颗粒。在二胞花粉早期,营养细胞中的液泡收缩、消失,细胞质中又出现了较多的钙沉淀颗粒,在质体和其内部的淀粉粒表面上附有较多的钙沉淀颗粒。到二胞花粉晚期,花粉中的钙沉淀颗粒已明显下降,仅在花粉外壁中还有一地钙沉淀颗粒．     

华北落叶松花粉发育过程中的钙动态分布

运用焦锑酸钾沉淀法研究了华北落叶松(Larix principis-rupprechtii Mayr)小孢子发育过程中不同阶段Ca2 的分布情况.减数分裂时期,小孢子囊壁表皮和中层细胞的细胞壁及细胞间隙Ca2 分布较多,绒毡层只有外切向面的细胞膜有Ca2 分布,小孢子母细胞的各部位则很少有Ca2 ;四分体时期,包围四分小孢子的胼胝质壁上有大量的Ca2 分布,在四分孢子壁上也有较多沉淀;游离小孢子时期,钙离子在小孢子壁的分布较四分体时期有所减少,而到花粉成熟时又逐渐增多;从四分体到花粉成熟,乌氏体周围的Ca2 有增多的趋势.对四分体外壁Ca2 的大量分布与花粉壁的形成及信号物质在花粉表面贮存的关系,以及小孢子囊的外壁、绒毡层和乌氏体在Ca2 向花粉运输中所起的作用进行了讨论.     

EXINE INITIATION AND SUBSTRUCTURE IN POLLEN OF CAESALPINIA JAPONICA (LEGUMINOSAE: CAESALPINIOIDEAE)

Exine development in pollen of Caesalpinia japonica was studied using high resolution scanning electron microscopy, with attention to the initial developmental process of protectum formation and composition. The protectum is originated on the protuberant sites of the invaginated plasma membrane during the early tetrad stage. The present study shows that the initial protectum is composed of irregularly oriented fibrous threads. The fibrous threads accumulate and form a network on the plasma membrane. Granules 10–20 nm in diameter gradually aggregate within the network of fibrous threads during the tetrad stage. Subsequently the fibrous threads are almost masked by the granules. The developing protectum has a coarse texture within the callosic tetrad envelope. At the free microspore stage the granular protectum becomes homogeneous. The present study suggests that the protectum consists of an association of fibrous threads and granules. The fibrous threads may function as receptors and/or the skeleton of the developing exine.     

蜡梅小孢子发生和花粉形成的研究

通过对蜡梅小孢子发生和花粉形成的研究,结果表明：蜡梅幼小花药中的多列孢原细胞经造孢细胞发良为小孢子母细胞。减数分裂为同时型。四分体呈四面体型排列,同时观察了小孢子在发育过程中液泡的动态变化。成熟花粉为２－细胞型。花药壁的发育为双子叶型。花药壁由５－６层细胞组成,腺质绒毡层。花粉具有异型性现象。     

ONTOGENETIC DEVELOPMENT OF SPINOUS EXINE IN HIBISCUS SYRIACUS (MALVACEAE)

Pollen development in Hibiscus syriacus L. (Malvaceae) was studied with light (LM), scanning (SEM) and transmission (TEM) electron microscopes, with special attention to the formation of extremely long spines of the pollen grains. At the early tetrad stage, probacules are initiated directly on the plasma membrane and grow in coincidence with the height of primexine matrix within a callosic wall. Subsequently, a pretectum appears at the top of the probacules and then a foot layer is formed by accumulation of white line centered lamellations. Before dissolution of the callosic wall, a reticulate patterned pretectum is established around the microspores. There is not, however, any morphological indication on the initiation of the spines during the tetrad period within a callosic wall. It is after dissolution of the callosic wall that the spines of exine begin to form by the apposition of lamellated sheets. The lamellated sheets show a concentric configuration around the developing supratectal spines. The mature pollen grain is spheroidal, polycolporate, 160–170 μm in diameter, with supratectal spines 20–25 μm long. The supratectal spines of Hibiscus pollen are not homologous with the other exinous protrusions which are determined within the callosic wall during tetrad stage.     

华北驼绒藜大小孢子的发生及雌雄配子体发育过程的解剖学研究

运用石蜡切片技术对华北驼绒藜大、小孢子发生及雌、雄配子体的发育进行了研究.结果表明:(1)花药4室,花药壁由表皮、药室内壁、1~2层中层及1层绒毡层组成,药壁发育为基本型,腺质绒毡层,发育后期为二核或三核;(2)四分体胞质分裂为同时型,小孢子四分体多数为四面体型,偶见十字交叉型;(3)成熟花粉2-细胞型,单核小孢子时期存在不同比例的空壳花粉,从0%~80%不等;(4)胚珠倒生,双珠被,厚珠心,大孢子四分体直线型排列,合点端为功能大孢子,蓼型胚囊.     

温敏型大白菜不育系的小孢子败育特性

两系法杂交制种中,温度敏感型雄性不育大白菜的小孢子在不育期的发育各阶段都可能发生畸形、退化,主要有4种类型：第一,花药发育受阻于孢原细胞的分化,属于无花粉型;第二,存在孢原细胞的分裂活动,但形成畸形角隅,孢原细胞退化解体或增大并聚成空洞的薄壁细胞;第三,四分体时期绒毡层和小孢子都退化,只剩空的花粉囊腔和几块残存物;第四,成熟花粉粒时期,小孢子畸形,药室收缩成镰刀形,畸形花粉粒杂乱地挤满药室。     

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.