Disruption of cellulose synthesis by isoxaben causes tip swelling and disorganizes cortical microtubules in elongating conifer pollen tubes

Summary.  In elongating pollen tubes of the conifer Picea abies (Norway spruce), microtubules form a radial array beneath the plasma membrane only at the elongating tip and an array parallel with elongation throughout the tube. Tips specifically swell following microtubule disruption. Here we test whether these radial microtubules coordinate cell wall deposition and maintain tip integrity as tubes elongate. Control pollen tubes contain cellulose throughout the walls, including the tip. Pollen tubes grown in the presence of isoxaben, which disrupts cellulose synthesis, are significantly shorter with a decrease in cellulose throughout the walls. Isoxaben also significantly increases the frequency of tip swelling, with no effect on tube width outside of the swollen tip. The decrease in cellulose is more pronounced in pollen tubes with swollen tips. The effects of isoxaben are reversible. Following isoxaben treatment, the radial array of microtubules persists beneath the plasma membrane of nonswollen tips, while this array is specifically disrupted in swollen tips. Microtubules instead form a random network throughout the tip. Growth in these pollen tubes is turgor driven, but the morphological changes due to isoxaben are not just the result of weakened cell walls since pollen tubes grown in hypoosmotic media are not significantly shorter but do have swollen tips and tubes are wider along their entire length. We conclude that the radial microtubules in the tip do maintain tip integrity and that the specific inhibition of cellulose microfibril deposition leads to the disorganization of these microtubules. This supports the emerging model that there is bidirectional communication across the plasma membrane between cortical microtubules and cellulose microfibrils. Received January 15, 2002; accepted August 3, 2002; published online March 11, 2003     

The actin microfilament network within elongating pollen tubes of the gymnospermPicea abies (Norway spruce)

Summary Actin microfilaments form a dense network within pollen tubes of the gymnosperm Norway spruce (Picea abies). Microfilaments emanate from within the pollen grain and form long, branching arrays passing through the aperture and down the length of the pollen tube to the tip. Pollen tubes are densely packed with large amyloplasts, which are surrounded by branching microfilament bundles. The vegetative nucleus is suspended within the elongating pollen tube within a complex array of microfilaments oriented both parallel to and perpendicular with the growing axis. Microfilament bundles branch out along the nuclear surface, and some filaments terminate on or emanate from the surface. Microfilaments in the pollen tube tip form a 6 m thick, dense, uniform layer beneath the plasma membrane. This layer ensheathes an actin depleted core which contains cytoplasm and organelles, including small amyloplasts, and extends back 36 m from the tip. Behind the core region, the distinct actin layer is absent as microfilaments are present throughout the pollen tube. Organelle zonation is not always maintained in these conifer pollen tubes. Large amyloplasts will fill the pollen tube up to the growing tip, while the distinct layer of microfilaments and cytoplasm beneath the plasma membrane is maintained. The distinctive microfilament arrangement in the pollen tube tips of this conifer is similar to that seen in tip growth in fungi, ferns and mosses, but has not been reported previously in seed plants.     

Microtubules and microfilaments are both responsible for pollen tube elongation in the coniferPicea abies (Norway spruce)

Summary InPicea abies (Norway spruce), microtubules and actin microfllaments both form a dense matrix throughout the tube mainly parallel to the direction of elongation. In these conifer pollen tubes the organization of this matrix is different from that in angiosperms. This study tests our hypothesis that differences in cytoskeletal organization are responsible for differences in tube growth and physiology. Pollen grains were germinated in media containing cytoskeletal disrupters and analyzed for germination, tube length, tube branching, and tip swelling. Disruption of microtubules significantly inhibits tube elongation and induces tube branching and tip swelling. Tip swelling is probably caused by disruption of the microtubules in the tip that are perpendicular to the direction of elongation. Confocal microscopy indicates that colchicine and propyzamide cause fragmentation of microtubules throughout the tube. Oryzalin and amiprophosmethyl cause a complete loss of microtubules from the tip back toward the tube midpoint but leave microtubules intact from the midpoint back to the grain. Disruption of microfilaments by cytochalasins B and D and inhibition of myosin by N-ethylmaleimide or 2,3-butanedione monoxime stops tube growth and inhibits germination. Microfilament disruption induces short branches in tubes, probably originating from defective microfilament organization behind the tip. In addition, confocal microscopy coupled with microinjection of fluorescein-labeled phalloidin into actively growing pollen tubes indicates that microfllament bundles extend into the plastid-free zone at the tip but are specifically excluded from the growing tip. We conclude that microtubules and microfilaments coordinate to drive tip extension in conifer pollen tubes in a model that differs from angiosperms.     

川百合精细胞的超微结构(英文)

川百合与朱顶红花粉管中的生殖细胞分裂行为非常不同。诸如：染色体行为、微管的组织形式和分布、包括着丝点、微管形成的时间,纺锤体的形状及间期周质微管网络在生殖细胞分裂过程中消失与否等。但这两种细胞具有某些共性,包括在有丝分裂前期缺乏早前期带微管（ＰＰＢ）,末期形成细胞板等。这两种植物精细胞的结构应有较大差异。我们曾报道了朱顶红精细胞的超微结构,本文详细从超微结构方面描述了川百合精细胞的特征。川百合花粉管的萌发采用半离体活体培养方式。１１～１８小时后,ＤＮＡ荧光染料Ｈｏｅｃｈｓｔ３３２５８和醋酸地衣红染色检查花粉管中生殖细胞和精细胞发育时期。切取含有分裂的生殖细胞和精细胞的花柱部分,按曾报道的方法固定、包埋、切片、染色及观察。在所有检查的花粉管中,两精子均前后排列（Ｆｉｇ．１～３）,营养核前导并靠近花粉管顶端（Ｆｉｇ．２,３）。Ｈ３３２５８染色可见两精核间以ＤＮＡ联系（Ｆｉｇ．３）。两个新形成的精核彼此分离（Ｆｉｇ．１）,后来又相互靠近,并维持一定距离（Ｆｉｇ．３）。偶尔一对精子与营养核靠近（Ｆｉｇ．２）。两精细胞被一共同的细胞壁连接,他们不仅被自己的质膜也被营养细胞的质膜包围构成周质。周质平坦光滑。共同壁横向     

The initiation and organization of microtubules in germinating pear (Pyrus communis L.) pollen

To study microtubule organization in germinating pear (Pyrus communis L., cv., Bartlett) pollen, we removed the pollen wall by freeze-fracturing before treating the resultant pollen protoplasts by conventional immunofluorescence procedures. Results reveal that axial bundles of microtubules are present in the generative cell of both inactivated and activated pollen grains. Microtubules are not present in the vegetative cells of inactivated pollen, but they are present in the vegetative cells of activated pollen grains. Microtubule nucleation occurs in the vegetative cell cortex. Subsequently, the microtubules grow as branching arrays through most of the vegetative cell cortex except at the apertures where they form localized converging or criss-cross patterns. Eventually, in a germinated pollen grain, the microtubules form network-like arrays through most of the pollen grain and a collar of short arrays at the base of the pollen tube. It is suggested that the role of vegetative cell microtubules in pollen germination is indirect through their mediation of the conformational changes in actin organization that are essential for pollen germination.     

The spermatogenous body cell of the coniferPicea abies (Norway spruce) contains actin microfilaments

Summary In conifer pollen, the generative cell divides into a sterile stalk cell and a body cell, which subsequently divides to produce two sperm. InPicea abies (Norway spruce, Pinaceae) this spermatogenous body cell contains actin microfilaments. Microfilament bundles follow the spherical contour of the body cell within the cell cortex, and also traverse the cytoplasm and enmesh amyloplasts and other organelles. In addition, microfilaments are associated with the surface of the body cell nucleus. The sterile stalk cell also contains microfilament bundles in the cytoplasm, around organelles, and along the nuclear surface. Within the pollen grain, microfilament bundles traverse the vegetative-cell cytoplasm and are enriched in a webbed cage which surrounds the body cell. Microfilaments were identified with rhodamine-phalloidin and with indirect immunofluo-rescence using a monoclonal antibody to actin. The majority of evidence in literature suggests that the spermatogenous generative cell in angiosperms does not contain actin microfilaments, so the presence of microfilaments within the spermatogenous body cell inP. abies appears to be a fundamental difference in sexual reproduction between conifers and angiosperms.     

Sites of Origin of the Peripheral Microtubule System of the Vegetative Cell of the Angiosperm Pollen Tube

From earlier published work it is known that microtubules inthe vegetative cell of angiosperm pollen tubes mainly occurin the form of longitudinally disposed strands closely associatedwith the plasmalemma. This peripheral cytoskeleton is extendedapically at a speed matching the growth rate of the tube. Immunofluorescencelocalization shows that in the actively elongating tube it originatesin the sub-apical zone in bands or ribbons up to 2 µmwide, interpreted here as comprising aggregates of apposed,axially oriented microtubules. These appear first in the corticalcytoplasm in close association with the wall in the part ofthe tube where the callose inner lining can first be detected.The bands do not extend apically into the region of the pecticsheath of the extreme tip. In the course of normal growth, theperipheral microtubule investment remains in the older partsof the tube from which the bulk of the cytoplasm has been withdrawn,indicating that tubulin is probably not recycled. If the growth of the tube is retarded, the inner callosic layerextends apically. The acropetal movement of callose is accompaniedby a migration of the limit of detectable tubulin towards theextreme tip, and the axially oriented bands are replaced bya confused mass of granules and short spicules. It is suggested that the bands represent nucleation zones associatedwith the stabilizing plasmalemma in the sub-apical stretch ofthe tube where the insertion of wall-precursor material is diminishing,and that it is from these zones that the microtubule cytoskeletonof the pollen tube originates. Since during growth the nucleationzones progress rapidly forward into association with new membrane,it is considered unlikely that their sites are determined bylocal differentiations of the plasmalemma. An alternative possibilityis that the distribution of the zones is related to the calciumion gradient known to be present in the apical stretch of theextending pollen tube. Microtubules, pollen tube growth, Lilium auratum     

Organization of the cytoskeleton in pollen tubes ofPyrus communis: a study employing conventional and freeze-substitution electron microscopy,immunofluorescence, and rhodamine-phalloidin

Summary The structure and organization of the cytoskeleton in the vegetative cell of germinated pollen grains and pollen tubes ofPyrus communis was examined at the ultrastructural level via chemical fixation and freeze substitution, and at the light microscopic level with the aid of immunofluorescence of tubulin and rhodamine-phalloidin.Results indicate that cortical microtubules and microfilaments, together with the plasma membrane, form a structurally integrated cytoskeletal complex. Axially aligned microtubules are present in cortical and cytoplasmic regions of the pollen grain portion of the cell and the distal region of the pollen tube portion. Cytoplasmic bundles of microfilaments are found in association with elements of endoplasmic reticulum and vacuoles. Axially aligned microfilaments are also found in this region, associated with and independent of the microtubules. Microtubules are lacking in the subapical region where short, axially aligned microfilaments are found in the cell cortex. In the apical region, which also lacks microtubules, a 3-dimensional network of short microfilaments occurs. Microfilaments, but not microtubules, appear to be associated with the vegetative nucleus.     

Polarized cell growth, organelle motility, and cytoskeletal organization in conifer pollen tube tips are regulated by KCBP, the calmodulin-binding kinesin

Kinesin-like calmodulin-binding protein (KCBP), a member of the Kinesin 14 family, is a minus end directed C-terminal motor unique to plants and green algae. Its motor activity is negatively regulated by calcium/calmodulin binding, and its tail region contains a secondary microtubule-binding site. It has been identified but not functionally characterized in the conifer Picea abies. Conifer pollen tubes exhibit polarized growth as organelles move into the tip in an unusual fountain pattern directed by microfilaments but uniquely organized by microtubules. We demonstrate here that PaKCBP and calmodulin regulate elongation and motility. PaKCBP is a 140 kDa protein immunolocalized to the elongating tip, coincident with microtubules. This localization is lost when microtubules are disrupted with oryzalin, which also reorganizes microfilaments into bundles. Colocalization of PaKCBP along microtubules is enhanced when microfilaments are disrupted with latrunculin B, which also disrupts the fine network of microtubules throughout the tip while preserving thicker microtubule bundles. Calmodulin inhibition by W-12 perfusion reversibly slows pollen tube elongation, alters organelle motility, promotes microfilament bundling, and microtubule bundling coincident with increased PaKCBP localization. The constitutive activation of PaKCBP by microinjection of an antibody that displaces calcium/calmodulin and activates microtubule bundling repositions vacuoles in the tip before rapidly stopping organelle streaming and pollen tube elongation. We propose that PaKCBP is one of the target proteins in conifer pollen modulated by calmodulin inhibition leading to microtubule bundling, which alters microtubule and microfilament organization, repositions vacuoles and slows organelle motility and pollen tube elongation.     

Microtubules and microfilaments coordinate to direct a fountain streaming pattern in elongating conifer pollen tube tips

This study investigates how microtubules and microfilaments control organelle motility within the tips of conifer pollen tubes. Organelles in the 30-m-long clear zone at the tip of Picea abies (L.) Karst. (Pinaceae) pollen tubes move in a fountain pattern. Within the center of the tube, organelles move into the tip along clearly defined paths, move randomly at the apex, and then move away from the tip beneath the plasma membrane. This pattern coincides with microtubule and microfilament organization and is the opposite of the reverse fountain seen in angiosperm pollen tubes. Application of latrunculin B, which disrupts microfilaments, completely stops growth and reduces organelle motility to Brownian motion. The clear zone at the tip remains intact but fills with thin tubules of endoplasmic reticulum. Applications of amiprophosmethyl, propyzamide or oryzalin, which all disrupt microtubules, stop growth, alter organelle motility within the tip, and alter the organization of actin microfilaments. Amiprophosmethyl inhibits organelle streaming and collapses the clear zone of vesicles at the extreme tip together with the disruption of microfilaments leading into the tip, leaving the plasma membrane intact. Propyzamide and oryzalin cause the accumulation of membrane tubules or vacuoles in the tip that reverse direction and stream in a reverse fountain. The microtubule disruption caused by propyzamide and oryzalin also reorganizes microfilaments from a fibrillar network into pronounced bundles in the tip cytoplasm. We conclude that microtubules control the positioning of organelles into and within the tip and influence the direction of streaming by mediating microfilament organization.Electronic Supplementary Material Supplementary material is available in the online version of this article at Abbreviations APM Amiprophosmethyl - FITC Fluorescein isothiocyanate - LATB Latrunculin B     

Dynein-related polypeptides in pollen and pollen tubes

 Microtubules in pollen tubes are evident within the vegetative and generative cell cytoplasm. This observation led to the formulation of several hypotheses regarding the role of microtubules in cytoplasmic movement and the migration of the vegetative nucleus/generative cell along the pollen tube. The study of microtubular motor proteins in pollen tubes followed the discovery and characterization of an immunoreactive homolog of mammalian kinesin in tobacco pollen tubes. Recent identification of dynein-related polypeptides in pollen tubes of Nicotiana tabacum and pollen of Ginkgo biloba is a significant step in the definition of the role of microtubule function within pollen and pollen tubes. Received: 31 May 1996 / Revision accepted: 26 July 1996     

The cytoskeleton and polarization during pollen development in Carex blanda (Cyperaceae)

Patterns of cytoskeletal organization during distinct polarizations that characterize pollen development in the sedge Carex blanda (Cyperaceae) were studied by correlated methods of immunohistochemistry and confocal and transmission electron microscopy. As is typical of the family Cyperaceae, Carex produces a unique pollen type known as a pseudomonad in which all four microspores of the tetrad are enclosed within the wall of a single pollen grain. Only one member of the tetrad is functional and the other three abort. The pseudomonads are precisely oriented in the locule with the functional microspore in the wide abaxial portion of the wedge-shaped cytoplasm adjacent to the tapetum, and the degenerative microspores are packed tightly in the pointed adaxial portion. A unique sequence of post-meiotic developmental events reflects both intracellular and intercellular polarity. Development includes: (1) random placement of tetrad nuclei in the coenocytic sporocyte after meiosis, (2) interrupted cytokinesis resulting in a tetrad of nuclei that migrates as a unit into the narrow adaxial tip, (3) completion of unequal cytokinesis and centering of the functional nucleus in the wide abaxial portion of the microsporocyte via a radial array of microtubules and microfilaments, (4) unequal mitosis resulting in a small generative cell at the proximal surface of the functional microspore (adjacent to the abortive microspores), and (5) recentering of the vegetative nucleus in the abaxial cytoplasm via a radial cytoskeletal array.     

The anti-microtubule drug carbetamide stopsNicotiana sylvestris pollen tube growth in the style

Summary Recently, we found that the anti-microtubule drugs colchicine and propham caused the absence of microtubules and thus loss of cytoplasmic zonation in in vitro growing pollen tubes ofNicotiana sylvestris, but did not seriously affect growth. In the present study we used the herbicide carbetamide as an anti-microtubule drug. It had the same effect as colchicine and propham: the cytoplasm, including the generative cell, was no longer concentrated in the tip but was distributed randomly. In addition, ultrastructural investigations have shown that even the vesicle zone, usually found at the very tip of pollen tubes, had disappeared in some tubes. Nonetheless, in vitro growth was not inhibited by more than 20% over a period of 22 h.In contrast, tube growth in plants ceased 1 cm down in the style when carbetamide was applied to the stigma before pollination. At the lowest concentration causing this effect, microtubules of the vegetative cell had disappeared and the cytoplasm was distributed randomly, as it was for in vitro grown tubes. It can be concluded that microtubules of the vegetative cell are essential for pollen tube growth in the style.Abbreviations DAPI 4,6-diamidmo-2-phenylindole - EGTA ethyleneglycerol-bis-(aminoethyl ether) tetraacetic acid - DIC differential interference contrast - GC generative cell - IC₅₀ inhibition concentration 50% - MF microfilament - MT microtubule - PEM-buffer 50 mM PIPES 1 mM EGTA, 2 mM MgSO₄, pH 6.9 - PBS phosphate buffered saline - PIPES piperazine-bis-ethanesulphonic acid - PTG-Test pollen tube growth test - SAM substrate adhesion molecule - VC vegetative cell     

PROTONEMAL ORGANIZATION AND GROWTH IN THE MOSS DAWSONIA SUPERBA: ULTRASTRUCTURAL CHARACTERISTICS

The elongating, tip cell of the protonema of Dawsonia superba is characterized by a variety of organelles distributed uniformly over the length of the cell. Chloroplasts, vacuoles, mitochondria and dictyosomes are present in the terminal portion of the cell. Dictyosomes are abundant throughout the cell and their production of vesicles is pronounced. Stratification of the cytoplasm and exclusion of organelles from the tip are not observed. The orientation of microtubules and microfibrils follows the pattern observed in filamentous fern prothallia. Microtubules are not observed at the tip of the protonema, but microfibrils are abundant and randomly oriented. While microtubules and microfibrils in lower regions of the apical dome are arranged randomly, more basally they assume an axial arrangement.     

Microgametogenesis in Plumbago zeylanica (Plumbaginaceae). 1. Descriptive cytology and three-dimensional organization

The generative cell is initiated as a small, lenticular, unpolarized cell with a cell wall traceable to two origins: the external segment originates as intine, while an inner callose positive cell wall forms de novo. As the lenticular generative cell begins its migration into the pollen cytoplasm, the generative cell becomes polarized both externally and internally, displaying a characteristic shape and patterns of organelle distribution oriented with respect to the vegetative nucleus and independent of pollen aperture location. Separation of the generative cell from the pollen wall begins at the end opposite the vegetative nucleus and results in an elongating protuberance at the opposite end of the generative cell; this becomes associated with a preformed groove located on the surface of the vegetative nucleus. The generative cell subsequently separates from the intine near the vegetative nucleus and moves progressively toward the opposite end of the cell; during this separation, the edge of the wall facing the intine becomes callose-positive and remains so until separating from the intine. The generative cell becomes a free cell within the pollen, which is in physical association with the vegetative nucleus. Generative cell organization and organelle content become increasingly polarized during maturation, with microtubules evident both in the elongating protuberance of the generative cell and in association with organelles. The generative nucleus migrates away from the vegetative nucleus and toward the plastid-rich end of the generative cell, whereas mitochondria are more generally distributed within the cell. Generative cell polarization is made permanent during mitotic division and cytokinesis, i.e., two sperm cells differing in morphology are formed: the larger cell associated with the vegetative nucleus (S_vn) contains a majority of the mitochondria, and the smaller, unassociated sperm cell (S_ua) receives the plastids.     

Actin-Based Domains of the "Cell Periphery Complex" and their Associations with Polarized "Cell Bodies" in Higher Plants

Abstract: Nascent cellulosic cell wall microfibrils and transverse (with respect of cell growth axis) arrays of cortical microtubules (MTs) beneath the plasma membrane (PM) are two well established features of the periphery of higher plant cells. Together with transmembrane synthase complexes, they represent the most characteristic form of a “cell periphery complex” of higher plant cells which determines the orientation of the diffuse (intercalary) type of their cell growth. However, there are some plant cell types having distinct cell cortex domains which are depleted of cortical MTs. These particular cell cortex domains are, instead, typically enriched with components of the actin‐based cytoskeleton. In higher plants, this feature is prominent at extending apices of two cell types displaying tip growth ‐ pollen tubes and root hairs. In the latter cell type, highly dynamic F‐actin meshworks accumulate at extending tips, and they appear to be critical for the apparently motile character of these subcellular domains. Importantly, tip growth of both root hairs and pollen tubes is immediately stopped when the most dynamic F‐actin population is depolymerized with low levels of anti‐F‐actin drugs. Intriguingly, MTs of tip‐growing plant cells are organized in the form of longitudinal arrays, throughout the cytoplasm, which interconnect the extending tips with the subapical nuclei. This suggests that actin‐rich cell cortex domains polarize plant “cell bodies” represented by nucleus‐MTs complexes. A similar polarization of “cell bodies” is typical of mitotic and cytokinetic plant cells. A further type of MT‐depleted and actomyosin‐enriched plant cell cortex domain comprises the plasmodesmata. Primary plasmodesmata are formed during cytokinesis as part of the myosin VIII‐enriched callosic cell plates, representing “juvenile” forms of the plant “cell periphery complex”. In phylogenetic terms the association between F‐actin and the PM may be considered for a more “primitive” form of cellular organization than does the association of cortical MTs with the PM. We hypothesize that the actin cytoskeleton is a natural partner of the PM in all eukaryotic cells. In most plant cells, however, it was replaced by a tubulin‐based “cell periphery apparatus” which regulates, via still unknown mechanisms, the spatial deposition of nascent cellulosic microfibrils synthesized by PM‐associated synthase complexes.     

Distribution of F-actin and Microtubules in Pollen and Pollen Tube of Lilium davidii

F-actin and microtubules are important components of pollen tube, which have very important function in cytoplasm streaming of pollen tube. The authors observed the distribution of Factin and microtubules in the pollen tube of Lilium davidii Duch. by immunofluorescence technique and confocol laser scanning microscopy, through which some new results were obtained. 1. Chemical fixation could preserve F-actin well in pollen tube, so the relation between F-actin and microtubules could be studied by the methods of chemical fixation and fluorescence labelling in pollen tube. 2. F-actin bundles were absent near the pollen tube tip, while microtubules were abundant and web formed in the pollen tube tip. The authors found that the terminal of microtubules was closely associated with the plasma membrane in the pollen tube tip. 3. Only a few F-actin bundles co-exist with the microtubules in the pollen tube of Lilium davidii. The results provided new evidence for the fimction and relationship between F-actin and microtubules in the pollen tube.     

Spatial and temporal organization of actin during hydration,activation, and germination of pollen inPyrus communis L.: a population study

Summary Dynamics of F-actin organization during activation and germination ofPyrus communis (pear) pollen was examined using rhodaminephalloidin. Prior to activation, the rhodamine-phalloidin labelling pattern appeared as circular profiles in the peripheral cytoplasm of the vegetative cell and as coarse granules around the vegetative nucleus. In activated pollen, parallel arrays of cortical F-actin were aligned circumferentially, along the polar axis in non-apertural areas of the pollen grain, and at 45° to 90° to the polar axis beneath the apertures. Some pollen also showed fluorescent granules or fusiform bodies dispersed throughout the cytoplasm, but as the number of such pollen diminished with prolonged incubation, these are being considered as intermediate patterns. In later stages, the filaments became organized as interapertural bundles traversing the three apertures. However, prior to emergence of the pollen tube, labelling became confined to a single aperture. In germinated pollen grains, actin microfilaments are aligned more or less axially with respect to the axis of the developing pollen tube.The granular labelling pattern seen around the vegetative nucleus prior to pollen activation also became clearly filamentous with pollen activation; this filamentous pattern persisted until germination when it was replaced by cables that aligned longitudinally with respect to the emerging tube axis.The results demonstrate that the organization of actin undergoes considerable changes in the period preceding pollen germination and that microfilament polarization is achieved before pollen germination.     

朱顶红花粉萌发过程中营养细胞质的超微结构变化

本文应用透射电镜对朱顶红成熟花粉水合、活化和萌发的动态过程中营养细胞质的结构和组成变化进行了观察。成熟花粉具质体、线粒体、内质网、高尔基体。微丝束以聚集体的形式存在。花粉活化后,细胞器的数目和结构发生显著变化：质体和线粒体的片层明显增加,内质网片层狭窄,高尔基体活跃产生小泡,脂体降解及微丝聚集体散开。花粉萌发后,细胞质中出现周质微管和被刺小泡,此期细胞器的变化不明显。微丝以纤丝状遍布整个花粉管中。     

百合花粉及花粉管内微丝和微管的分布

利用免疫荧光定位及荧光定位方法,结合共焦激光扫描显微镜,对百合（ＬｉｌｉｕｍｄａｖｉｄｉＤｕｃｈ．）花粉及花粉管内微丝及微管的分布进行了观察,得出了一些新的结果：１化学固定方法可以较好地保存花粉和花粉管内的微丝,从而可以在此条件下较好地进行微管和微丝的双标记,并进行两者相互关系的研究;２在距花粉管顶端１０～２０μｍ的范围内,用化学固定及ＴＲＩＴＣ鬼笔碱标记显示微丝的存在是很微弱的,基本上无法看到明显的微丝束,而同时用免疫荧光法标记却发现此部位微管很丰富,在花粉管顶端微管形成浓密的网状,而且其末端与花粉管顶端质膜相连;３在花粉管中,只有少数微丝与微管相互平行排列,而其中大多数微丝骨架与微管骨架并不存在共分布现象。为了解花粉管内微管和微丝的功能及相互关系提供了新的证据。