Association of the Generative Cell and Vegetative Nucleus in Pollen Tubes of Rhododendron

Mixed fluorescence/bright field microscopy of Rhododendron pollentubes in the first 72 h after germination reveals a lens-shapedgenerative cell which divides to give two associated spermswithin the original cell boundary. The generative cell is closelyassociated with the vegetative nucleus which precedes it in92 per cent of pollen tubes. Three-dimensional reconstruction from serial thin sections ofa pollen tube fixed 24 h after germination shows that the associationbetween the generative cell and vegetative nucleus is extremelycomplex. Elongated tails of the generative cell physically enfoldthe vegetative nucleus and penetrate into enclaves within it.The association has been clarified by use of the periodic acid-phosphotungsticacid-chromic acid technique to enhance electron contrast ofthe plasma membranes surrounding the generative cell. In thisbicellular system, the male germ unit association is apparentlyinitiated after pollen maturity but prior to generative celldivision. Pollen tube, generative cell, male germ unit, plasma membrane, vegetative nucleus, Rhododendron, Ericaceae     

The Comportment of the Vegetative Nucleus and Generative Cell in the Pollen and Pollen Tubes of Helleborus foetidus L

It has been reported that in species of Plumbaginaceae, Chenopodiaceae,Cruciferae and Amaryllidaceae a ‘male germ unit’is formed in which the two male gametes remain inter-connected,with one of the pair linked intimately to the vegetative nucleus.In two species the unit has been shown to remain intact in thepollen tube, and some accounts imply that it is polarized inits movement, the vegetative nucleus leading in the tube. Evidence given in this paper indicates that such a unit is unlikelyto be present in Helleborus foetidus L. (Ranunculaceae). Applicationof an optical sectioning technique has shown that at no timeis there a persistent linkage between the generative cell andthe vegetative nucleus in unhydrated, hydrated and germinatingpollen, nor is one present in the early pollen tube. Furthermore,no inter-connections between the two entities were seen in protoplastsfrom living, hydrated and incipiently germinating grains isolatedmechanically in an osmotically balancing medium. Following germination,the vegetative nucleus leaves the grain in advance of the generativecell in most instances, but in the samples examined the generativecell led in about 30 per cent of the tubes. Assembling a polarisedmale germ unit in these circumstances would require (a) theformation of an inter-connection between the vegetative nucleusand the generative cell or one of the gametes derived from itduring passage through the tube, and (b) where the generativecell initially leads in the tube, an exchange in relative positions.It is considered improbable that these conditions could consistentlybe met. Mature, incipiently germinating pollen of H. foetidus releasesa fibrillar component when extruded into suitable media. Websor clusters of fibrils are commonly seen to be associated withboth the vegetative nucleus and the generative cell. The possibilitythat the fibrils are composed of aggregates of microfilamentsis considered. Helleborus foetidus L., pollen germination, generative cell, vegetative nucleus, male germ unit     

Ultrastructural Observation on Microtubules of the Generative Cell in Amaryllis Germinated Pollens and Pollen Tubes

The organization of microtubules (MTs) in the generative cell (GC) of germinated pollen and pollen tube in Amaryllis vittata Ait. has been studied with electron microscopy. At the beginning of pollen germination, the GC is long elliptic in shape, and is surrounded by its own membrane and also by that of the vegetative cell (VC) ,both of which appear undulated. In cross section, the GC appears roundish and has many lobes. The MT system of GC is mainly organized in bundles, but single MTs can also be observed. The MT bundles are generally located in the lobes, directly beneath the plasma membrane of the cell. These MT bundles orientate along the longitudinal axis of the cell. They are formed by aggregation of 5–6 MTs at least,more often about 30 MTs. In the bundles the MTs are often linked to each other by "cross-bridge". The single tubules in the eytopiasm distribute randomly in different orientations. When the GC has migrated into the pollen tube after germination ,it becomes elongated and has cytoplasmic extensions both in the anterior and posterior end of the cell. The organization of MTs of the GC in pollen tube is similar to that in the germinated pollen grain,but the number of MTs in a bundle often increases to 50–60. In the bundle the "cross-bridges" between the MTs which always link 3–5 MTs, are still seen clearly. Positional shift between the GC and Vegetative nucleus (VN) may take place during the growth of pollen tube. The physical association between GC and VN may be demonstrated some ultrastructural figures. It may be seen that irregular cytoplasmic extensions in the anterior end of the GC is always enclosed by the VN and the projections of the cytoplasmic extensions lie within enclaves of the VN. There are many MTs sheets in the lobes or extensions in the cytoplasm of the GC. Thus the present study demonstrates that MTs have an important role in maintaining the peculiar shape of the GC and the close association between GC and VN. However, it seems that the MTs are probably also engaged in the movement of the GC during pollen growth.     

肌动蛋白在丝瓜花粉管顶端生长中的作用

用非固定荧光标记的鬼笔环肽作为肌动蛋白探针观察并证明了丝瓜未萌发的花粉粒和不同生长时期花粉管中肌动蛋白纤丝的分布及其形态变化。又用细胞松弛素B（CB）、氯两嗪（CPZ）及N-乙酰马来酰胺（NEM）证明了丝瓜花粉管伸长与肌动蛋白既有密切的关系,也受Ca2 的调节。     

Pollen Tubes: a Model System for Plant Cell Growth*

Recent observations of pollen tubes show that these tubes may grow in a pulsatory fashion (Pierson et al., 1995; Plyushch et al., 1995; Li et al., 1996; Geitmann et al., 1996a, 1996b), in which phases of fast and slow growth alternate regularly. The occurrence of pulsatory growth has been used by Geitmann and coworkers (1996b) to study factors that might control growth. Their results emphasize the role of the cell wall and secretory events in regulating pollen tube growth. Here we will briefly review recent results related to the role of exocytosis, cytoskeleton, calcium and the cell wall in pollen tube growth.     

萌发百合花粉中一种低分子量鸟苷三磷酸酶的研究

研究表明,鸟苷三磷酸酶（ＧＴＰ酶）超家族是细胞中一类重要的酶类．其功能之一是水解ＧＴＰ或ＡＴＰ,提供细胞生存和运动所需要的能量,如已发现的具ＧＴＰ酶活性的微管相关马达蛋白、动蛋白和力蛋白等,在微管系统相关运动中提供所需的动力,其分子量一般较大,在１０...     

Growing Pollen Tubes Possess a Constitutive Alkaline Band in the Clear Zone and a Growth-dependent Acidic Tip

Using both the proton selective vibrating electrode to probe the extracellular currents and ratiometric wide-field fluorescence microscopy with the indicator 2′,7′-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein (BCECF)-dextran to image the intracellular pH, we have examined the distribution and activity of protons (H⁺) associated with pollen tube growth. The intracellular images reveal that lily pollen tubes possess a constitutive alkaline band at the base of the clear zone and an acidic domain at the extreme apex. The extracellular observations, in close agreement, show a proton influx at the extreme apex of the pollen tube and an efflux in the region that corresponds to the position of the alkaline band. The ability to detect the intracellular pH gradient is strongly dependent on the concentration of exogenous buffers in the cytoplasm. Thus, even the indicator dye, if introduced at levels estimated to be of 1.0 μM or greater, will dissipate the gradient, possibly through shuttle buffering. The apical acidic domain correlates closely with the process of growth, and thus may play a direct role, possibly in facilitating vesicle movement and exocytosis. The alkaline band correlates with the position of the reverse fountain streaming at the base of the clear zone, and may participate in the regulation of actin filament formation through the modulation of pH-sensitive actin binding proteins. These studies not only demonstrate that proton gradients exist, but that they may be intimately associated with polarized pollen tube growth.     

Mitosis and Amitosis of Generative Cell Nuclei in Artificially Germinated Pollen Tubes in Zephyranthes candida(Lindl.)Herb.

This paper deals with the comportmem of the vegetative nucleus and its spatial association with the generative cell and sperm cells in the artificially germinated pollen tubes of Zephyranthes candida (Lindl.) Herb. before and after generative cell mitosis with the use of DNA-specific fluochrome 4′,6-diamidino-2-phenylindole (DAPI). The induction of amitosis and abnormal mitosis of generative cell nuclei by cold-pretreatment of the pollen prior to germination was studied in particular. In normal case, the generative cell, after appressing to the vegetative nucleus for certain time, underwent mitosis to form two sperms, while the vegetative nucleus became markedly elongated, diffused, and exhibited blurring of its fluorescence. After division, a pair of sperms remained shortly in close connexion with the vegetative nucleus. Then the vegetative nucleus returned to its original state. In the pollen tubes germinated from cold-pretreated pollen, amitosis of some generative cell nuclei were frequently observed. Amitosis took place via either equal or unequal division with a mode of constriction. During amitosis, the dynamic change of vegetative nucleus and its intimate association with generative cell afore described did not occur. Sperm nuclei produced from amitosis could farther undergo amitisis resulting in micronnclei. Factors affecting the amitosic rate of generative cells, such as pollen developmental stage, temperature and duration of cold-pretreatment, were studied. Besides amitosis, cold-pretreatment also induced some abnormal mitotic behavior leading to the formation of micronuclei. Based on our observations and previously reported facts in other plant materials, it is inferred that the vegetative nucleus plays an important role in normal mitosis of generative cell and development of sperms.     

Generative Cell Division and Sperm Cell Association in the Pollen Grain of Sambucus nigra

Generative cell division in tricellular pollen grains of Sambucusnigra L. (Caprifoliaceae) has been examined with light and electronmicroscopy. During division the generative cell is located inthe centre of the pollen grain, near to the nucleus of a surroundingvegetative cell. Conventional mitosis of the generative cellis followed by cytokinesis through centrifugal cell plate formation.Two sister sperm cells remain in spatial contact with each otherand are surrounded, as formerly their progenitor cell was, bythe vegetative cell. From the changes of shape of the generativecell during division and of the sperm cells it may be assumedthat the space between these cells and the vegetative one containsa labile, non-rigid, wall material. No plastids have been observedin the generative cell and its mitochondria appear to be unequallydistributed between the two future sperm cells during division. Sambucus nigra L., generative cell division, pollen, sperm cell association     

Cytochemical Analysis of Callose Localization in Lilium longiflorum Pollen Tubes

Callose, a ß, 1–3 glucan as a component of plantcells has received sporadic attention. Here, we report an attemptto determine whether aniline blue and lacmoid are indeed specificfor visualizing callose. We also re-evaluate, based on a checkfor stain specificity, the localization of callose in elongatingLilium longiflorum, cv. ‘Ace’ pollen tubes. Specificityof these stains was checked by chemical and enzymatic extractionprocedures which solubilize proteins and polysaccharides. Resultsherein question the generally accepted validity of the fluorescent-anilineblue method for detecting callose. Lacmoid either possessesan affinity for both callose and protein or for callose as aglycoprotein. As for callose localization, the walls of thenon-growing region of the lily pollen tube contain callose,probably as a glycoprotein. Presence of the callosicglycoproteinin the wall of the growing tube-tip is dependent on tube length.Callose plugs exhibiting an affinity for aniline blue or lacmoidwere never seen. Phase-contrast microscopy revealed non-stainablewall ingrowths in fixed-tubes and free-moving cytoplasmic masseswithin living tubes.     

Organelle Movement in the Germinated Plooen Grains and Pollen Tubes of Oenothera odorata

The movement of organelles in the germinated pollen of Oenothera odorata was studied in detail by video microscopy. The image of the organelle movement was processed by computergation. The pollen grain of Oenothera odorata is large and easy to germinate in vitro and is suitable for the study of organelle movement . The motion of organelles in the germinated pollen grains and pollen tubes is very vigorous. But the movement of organelles in the pollen tubes is more vigorous than that in the germinating pollen grains. Some of their motion is saltatory. A kind of fibrils was observed in the germinated pollen grains. They are supposed to be made up of actin filaments. Some of the fibrils have one end connected to the plasma membrane and others have both ends linked to the plasma membrane , forming a network. Organelles move along the fibrils continuosely and the speed changes constantly . The speed of movement of organelles is not related to their dimensions. Cytochalasin B can inhibit the movement of organelles. Our results suggest that the movement of organelles is independent of the cytoplasmic streaming in the germinated pollen grains and pollen tubes.     

花粉管细胞结构与生长机制研究进展

花粉管的极性顶端生长是一个复杂的动力学过程, 在高等植物有性生殖过程中起着重要的作用。花粉管的生长过程包括许多方面, 其中最为重要的是花粉管细胞骨架动态和胞质运动。本文较全面地综述了花粉管的结构、细胞骨架、胞质运动、囊泡转运及循环、线粒体运动以及内质网和高尔基体之间囊泡运动等。     

花粉管细胞结构与生长机制研究进展

花粉管的极性顶端生长是一个复杂的动力学过程,在高等植物有性生殖过程中起着重要的作用。花粉管的生长过程包括许多方面,其中最为重要的是花粉管细胞骨架动态和胞质运动。本文较全面地综述了花粉管的结构、细胞骨架、胞质运动、囊泡转运及循环、线粒体运动以及内质网和高尔基体之间囊泡运动等。     

Subcellular Localization of the S Locus F-box Protein AhSLF-S2 in Pollen and Pollen Tubes of Self-Incompatible Antirrhinum

The distribution of the S locus F-box (SLF) protein was examined by immunocytochemistry and Western blot techniques using an antibody against the C-terminal part of AhSLF-S2 in self-incompatible lines of Antirrhinum. Abundant gold particles were found where pollen tubes emerge in vitro. With the elongation of pollen tubes, binding sites for the antibody were found in the cytoplasm of the pollen tubes,including the peripheral part of the endoplasmic reticulum. After germination in vitro for 16 h, the product of AhSLF-S2 and possibly its allelic products could still be detectable, implying that the SLF protein has a role in the elongating process of pollen tubes. The present study provides evidence at the protein level that the SLF protein is present in pollen cytoplasm during pollen tube growth. These findings are discussed, as is their potential role in the self-incompatible response in Antirrhinum.     

Subcellular Localization of the S Locus F-box Protein AhSLF-S2 in Pollen and Pollen Tubes of Self-Incompatible Antirrhinum

The distribution of the S locus F-box (SLF) protein was examined by immunocytochemistry and Western blot techniques using an antibody against the C-terminal part of AhSLF-S2 in self-incompatible Iines of Antirrhinum. Abundant gold particles were found where pollen tubes emerge in vitro. With the elongation of pollen tubes, binding sites for the antibody were found in the cytoplasm of the pollen tubes,including the peripheral part of the endoplasmic reticulum. After germination in vitro for 16 h, the product of AhSLF-S2 and possibly its allelic products could still be detectable, implying that the SLF protein has a role in the elongating process of pollen tubes. The present study provides evidence at the protein level that the SLF protein is present in pollen cytoplasm during pollen tube growth. These findings are discussed, as is their potential role in the self-incompatible response in Antirrhinum.     

Development of the Generative Cell Wall in Monotropa uniflora L. Pollen

During an ultrastructural survey of an achlorophyllus dicotyledonous plant, Monotropa uniflora L., a stage of pollen development was encountered which suggests a relationship between the activity of the rough endoplasmic reticulum and the development of the generative cell wall.     

花粉管细胞壁结构及胞质运动

花粉管的极性顶端生长是将雄配子体运输到子房的过程,在高等植物有性生殖过程中起着重要的作用。花粉管的生长过程包括许多方面,其中最为重要的是花粉管细胞壁的合成和胞质运动。本文就细胞壁的结构及组成,生殖细胞和营养核的移位,细胞器以及分泌小泡的运动等方面作了较全面论述。     

Exocytosis Precedes and Predicts the Increase in Growth in Oscillating Pollen Tubes

We examined exocytosis during oscillatory growth in lily (Lilium formosanum and Lilium longiflorum) and tobacco (Nicotiana tabacum) pollen tubes using three markers: (1) changes in cell wall thickness by Nomarski differential interference contrast (DIC), (2) changes in apical cell wall fluorescence in cells stained with propidium iodide (PI), and (3) changes in apical wall fluorescence in cells expressing tobacco pectin methyl esterase fused to green fluorescent protein (PME-GFP). Using PI fluorescence, we quantified oscillatory changes in the amount of wall material from both lily and tobacco pollen tubes. Measurement of wall thickness by DIC was only possible with lily due to limitations of microscope resolution. PME-GFP, a direct marker for exocytosis, only provides information in tobacco because its expression in lily causes growth inhibition and cell death. We show that exocytosis in pollen tubes oscillates and leads the increase in growth rate; the mean phase difference between exocytosis and growth is –98° ± 3° in lily and –124° ± 4° in tobacco. Statistical analyses reveal that the anticipatory increase in wall material predicts, to a high degree, the rate and extent of the subsequent growth surge. Exocytosis emerges as a prime candidate for the initiation and regulation of oscillatory pollen tube growth.