In vivo identification of Tetrahymena actin probed by DMSO induction of nuclear bundles

We report the first successful identification of actin, an ubiquitous contractile protein, in Tetrahymena pyriformis (strain W). We employed dimethyl sulfoxide (DMSO) as a probe to induce the formation of actin bundles in the cell nucleus [1, 2] through disruption of cytoplasmic microfilament organization [3, 4]. The cells were incubated for 30 min at 22 °C in the inorganic medium of Prescott & James [5] containing 10% DMSO, and observed under a transmission electron microscope (TEM). Microfilarment bundles were formed in interphase macronuclei, and these microfilaments, approx. 6 nm in diameter, could be decorated by rabbit skeletal muscle heavy meromyosin (HMM) in the glycerinated model. In many cases, the bundles formed closely parallel to natively existing bundles of microtubules. Interestingly, these microtubules had prominent striation with 15–16 nm periodicity. SDS-polyacrylamide gel electrophoresis was designed to show the low actin content of Tetrahymena cells in comparison with that of Dictyostelium. Actin was suggested to comprise less than 1.7% of the total protein in Tetrahymena, whereas as much as 6% was actin in Dictyostelium cells. In assessing the physiological significance of the bundle formation, we further performed HMM and myosin subfragment-1 (S1)-binding studies to clarify the organization process and the polarity of the DMSO-induced nuclear actin filaments by using the tannic acid staining technique [6]. Randomly oriented short filaments appeared in the nucleus treated with 10% DMSO for 10 min. These filaments became elongated and associated with each other to form loose bundles in the following 10 min. With 30-min treatment, the filaments were organized and large bundles with single axes developed. With these well-developed bundles, the Student's t-test was performed on 172 pairs of neighboring filaments and the probability (p) of the deviation from random polarity was 0.08, suggesting that the filaments were organized in an anti-parallel manner. The results show that the DMSO induction of nuclear actin is a powerful tool to demonstrate the existence of cellular actin in vivo and to study the mechanism of microfilament organization in relation to cell physiological activities.     

Heavy meromyosin induces sliding movements between antiparallel actin filaments

Suzuki et al. [Biochemistry 28, 6513-6518 (1989)] have shown that, when F-actin is mixed with inert high polymer, a large number of actin filaments closely align in parallel with overlaps to form a long and thick bundle. The bundle may be designated non-polar, as the constituent filaments are random in polarity (Suzuki et al. 1989). I prepared non-polar bundles of F-actin using methylcellulose (MC) as the high polymer, exposed them to heavy meromyosin (HMM) in the presence of ATP under a light microscope, and followed their morphological changes in the continuous presence of MC. It was found that bundles several tens of micrometers long contracted to about one-third the initial length, while becoming thicker, in half a minute after exposure to HMM. Subsequently, each bundle was split longitudinally into several bundles in a stepwise manner, while the newly formed ones remained associated together at one of the two ends. The product, an aster-like assembly of actin bundles, was morphologically quiescent; that is, individual bundles never contracted upon second exposure to HMM and ATP, although they were still longer than the F-actin used. Bundles in this state consisted of filaments with parallel polarity as examined by electron microscopy. This implies that non-polar bundles were transformed into assemblies of polar bundles with ATP hydrolysis by HMM. Importantly, myosin subfragment-1 caused neither contraction nor transformation. These results are interpreted as follows. In the presence of ATP, the two-headed HMM molecule was able to cross-bridge antiparallel actin filaments, as well as parallel ones.(ABSTRACT TRUNCATED AT 250 WORDS)     

Actin-like filaments in bone cells of cultured mouse calvaria as demonstrated by binding to heavy meromyosin

A variety of intracellular filaments (50-70 A in diameter) found in bone cells was shown to bind specifically to HMM. Because of this property, these filaments are probably biochemically similar to muscle actin. in osteoblasts and osteocytes, these reactive filaments were oriented in bundles parallel to the plasma membrane and filling the cell processes. In the osteoclast the filaments along the cell membrane were not so highly organized. In the clear zone, the quiescent part of the cell adjacent to the motile ruffled border, organized filament bundles were oriented perpendicular to the cell membrane and terminated in short processes at the bone surface. These filaments were also reactive with HMM. The possible significance of the filaments with respect to the physiology of bone cells is discussed.     

Microfilament bundles of F-actin inSpirogyra observed by fluorescence microscopy

Microfilament bundles (MFBs) of F-actin were observed by fluorescence microscopy in cells ofSpirogyra treated with rhodamine-phalloidin. Four types of MFBs could be recognized on the basis of locality and appearance: those dispersed in the cytoplasm near the cell surface; those beneath the plasma membrane running parallel to each other; those at the edges of the chloroplast; and those surrounding the nucleus. Each type exhibited a unique behavior during the cell cycle. Microfilament bundles dispersed in the cytoplasm came together at the middle of the cell to form a fibril ring at the mitotic prophase. The fibril ring decreased in diameter, causing the development of a furrow in the protoplast that progressed from the outside to the inside. After the completion of furrowing, the MFBs in the fibril ring dispersed beneath the plasma membrane. Microfilament bundles surrounding the nucleus formed a net-like cage which became invisible at the mitotic anaphase, while MFBs seen at the chloroplast edges persisted there during the cell cycle without changing their position. Parallel MFBs running perpendicular to the long axis of the cell were seen at all stages in the cell cycle.Abbreviations MF microfilament - MFB microfilament bundle - MT microtubule     

Ultrastructure of Acrasis rosea,a Cellular Slime Mold,During Development*

SYNOPSIS. An ultrastructural study of the myxamoebae of Acrasis rosea in the vegetative, aggregative and culminative stages was made. An intracytoplasmic system of microfibrillar bundles develops as the cells enter the aggregative stage and commence the morphogenetic sequence leading to the construction of a fruiting body. The fibrillar bundles disappear in the cells of the mature fruiting body. No relevant ultrastructural differences were observed between spores, stalk cells and microcysts. Each of these cells is surrounded by a single-layered coat of fibrillar material that is oriented parallel to the cell surface. Tubular structures were observed between the plasma membrane and the cell coat. The tubules may be layered along the cell periphery or they may be recessed in pockets formed by the plasma membrane. They resemble lomasomes typical of fungal cells. The myxamoebae of A. rosea clearly differ from the Dictyostelium-type myxamoebae in mitochondrial structure, the presence of lamellate structures in the nucleolus and the absence of prespore vacuoles.     

The Cysts of Blastocrithidia triatomae Cerisola et al., 19711

ABSTRACT. Flagellar cysts of Blastocrithidia triatomae form from active flagellates by diminution in size. The pellicular microtubules disappear. The inner layer of the cell membrane thickens progressively as the organism shrinks. The fully formed cyst has an electrondense layer that corresponds to the outer layer of the unit membrane. An electron-lucent layer is approximately twice the thickness of the middle layer of the unit membrane. Inside that is a 92 nm layer that may represent the cytoplasm. The nuclear content is in the form of whorled bundles of 10–15 nm fibrils. The kinetoplast was not seen in electron micrographs of cysts.     

Myosin‐X facilitates Shigella‐induced membrane protrusions and cell‐to‐cell spread

The intracellular pathogen Shigella flexneri forms membrane protrusions to spread from cell to cell. As protrusions form, myosin‐X (Myo10) localizes to Shigella. Electron micrographs of immunogold‐labelled Shigella‐infected HeLa cells reveal that Myo10 concentrates at the bases and along the sides of bacteria within membrane protrusions. Time‐lapse video microscopy shows that a full‐length Myo10 GFP‐construct cycles along the sides of Shigella within the membrane protrusions as these structures progressively lengthen. RNAi knock‐down of Myo10 is associated with shorter protrusions with thicker stalks, and causes a >80% decrease in confluent cell plaque formation. Myo10 also concentrates in membrane protrusions formed by another intracellular bacteria, Listeria, and knock‐down of Myo10 also impairs Listeria plaque formation. In Cos7 cells (contain low concentrations of Myo10), the expression of full‐length Myo10 nearly doubles Shigella‐induced protrusion length, and lengthening requires the head domain, as well as the tail‐PH domain, but not the FERM domain. The GFP‐Myo10‐HMM domain localizes to the sides of Shigella within membrane protrusions and the GFP‐Myo10‐PH domain localizes to host cell membranes. We conclude thatMyo10 generates the force to enhance bacterial‐induced protrusions by binding its head region to actin filaments and its PH tail domain to the peripheral membrane.     

Cell walls,plasma membranes,and dictyosomes during zygote maturation ofClosterium ehrenbergii

Summary The cell wall formation and its correlation with the plasma membrane and dictyosome were investigated by an electron microscope in the zygote cells ofClosterium ehrenbergii. During zygote maturation, six wall layers were formed outside the plasma membrane. Wall layer III was the thickest layer and consisted of microfibril bundles. Dictyosomes produced flat vesicles during formation of wall layer III. Hexagonal arrays of rosette particles appeared in the plasma membrane in this period, thus confirming the simultaneous occurrence of flat vesicles and hexagonal particle arrays in the formation of microfibril bundles even at different stages of the life cycle. Wall layer VI was second in thickness and consisted of single microfibrils. Neither flat vesicles nor hexagonal particle arrays were observed during formation of this layer.     

Ultrastructural changes during sporangium formation and zoospore differentiation in Blastocladiella Emersonii

Samples from synchronized cultures of Blastocladiella emersonii were examined by electron microscopy from the late log phase to the completion of zoospore differentiation. Log-phase plants contain the usual cytoplasmic organelles but also have an unusual system of large tubules ca. 45 mμ diam that ramify in organized bundles throughout the protoplast. After induction, zoosporangium differentiation requires a 2-hr period in which the nuclei divide, a cross wall forms to separate the basal rhizoid region, and an apical papilla is produced. Nuclear division in B. emersonii is intranuclear with a typical microtubular spindle apparatus and paired, unequal, extranuclear centrioles at each pole. The papilla is formed by a process of localized cell wall breakdown and deposition of the papilla material by secretory granules. Differentiation of zoospores begins when one of the two centrioles associated with each nucleus elongates to form a basal body. The flagella fibers arise from the basal body and elongate into an expanding vesicle formed by the fusion of small secondary vesicles. The cleavage planes are formed by fusion of vesicles similar to those associated with flagellum initiation. When cleavage is complete, each sporangium contains ca. 250–260 uninucleate spore units with their flagella lying in the cleavage planes. Probable fusion of mitochondria to produce the single mitochondrion of the zoospore occurs after cleavage; the mitochondrion does not take its position around the basal body and rootlets until just before zoospore release. The ribosomal nuclear cap is organized and enclosed by a membrane formed through fusion of many small vesicles during a short period near the end of differentiation.     

The cytoskeletal involvement in cellularization of theDrosophila melanogaster embryo

Summary The distribution and arrangement of cytoskeletal components in the early embryo ofDrosophila melanogaster were examined by thin-section electron microscopy to elucidate their involvement in the formation of the cellular blastoderm, a process called cellularization. During the final nuclear division in the cortex of the syncytial blastoderm bundles of astral microtubules were closely associated with the surface plasma membrane along the midline where a new gutter was initiated. Thus the new gutter together with the pre-formed ones compartmentalized the embryo surface to reflect underlying individual daughter nuclei. Subsequently such gutters became deeper by further invagination of the plasma membrane between adjacent nuclei to form so-called cleavage furrows. Nuclei simultaneously elongated in the direction perpendicular to the embryo surface and numerous microtubules from the centrosomes ran longitudinally between the nucleus and the cleavage furrow. Microtubules often appeared to be in close association with the nuclear envelope and the cleavage furrow membrane. The plasma membrane at the advancing tip of the furrow was always undercoated with an electron-dense layer, which could be shown to be mainly composed of 5–6 nm microfilaments. These microfilaments were decorated with H-meromyosin to be identified as actin filaments. As cleavage proceeded, each nucleus with its perikaryon became demarcated by the furrow membrane, which then extended laterally to constrict the cytoplasmic connection between each newly forming cell and the central yolk region. The cytoplasmic strand thus formed possessed a prominent circular bundle of microfilaments which were also decorated with H-meromyosin and bidirectionally arranged, similar in structure to the contractile ring in cytokinesis. These observations strongly suggest that both microtubules and actin filaments play a crucial role in cellularization ofDrosophila embryos.     

Cytoskeletal dynamics ofApedinella radians (Pedinellophyceae) II. Cell division and maintenance of cell polarity and symmetry

Summary The dynamics of the cytoskeletal proteins centrin, actin, and tubulin were followed during cell division in the unicellular phytoflagellateApedinella radians (Pedinellophyceae). Three centrin, or centrin-like, components appear to coordinate independent developmental events during cell division. The first component, basal body centrin, maintains a physical link between basal bodies and the anterior nuclear membrane. Basal body centrin divides in two at metaphase, and each portion segregates with two basal bodies at anaphase. As the positioning of basal bodies defines the anterior region of the cell, basal body centrin appears to play a role in maintaining cell polarity throughout the cell cycle. The second centrin component consists of an array of filamentous bundles arranged as a six-pointed star. During cell division, the star undergoes a conformational change resulting in two distinct centrin triangles, one distributed to each daughter cell, suggesting that centrin filamentous bundles are involved in maintaining cell (radial) symmetry. The third centrin component is transient and associates with the spindle poles, emerging prior to mitosis and remaining until late anaphase/early telophase. Spindle pole centrin establishes temporary horizontal bipolarity, thereby establishing the spindle axis. Unlike centrin filamentous bundles, actin filamentous bundles depolymerize prior to mitosis, indicating they do not influence cell symmetry during cell division. Mitosis is described for the first time in a pedinellid and features a closed spindle, the absence of rhizoplasts and a persistent spindle.     

Actin in Tetrahymena paravorax: Ultrastructural Localization of HMM-Binding Filaments in Glycerinated Cells1,2

Actin has been identified in the ciliated protozoon Tetrahymena paravorax on the basis of the ultrastructural detection of filaments typically decorated with heavy meromyosin (HMM) in glycerinated microstome cells. These filaments are widely distributed in endoplasmic and cortical regions and can form bundles. They are particularly numerous in elongating cells; HMM-binding filaments run approximately parallel to rib microtubules in the ectoplasm of the right wall of the buccal cavity and seem to extend to the cytopharyngeal region, suggesting some role of actin in maintenance of the crest-trough pattern of ribbed wall and/or in formation of food vacuoles. Extensive actin bundles are observed below some membranellar areas and are thought to follow the course of the microtubular “deep fiber bundle.” The “fine filamentous reticulum” underlying the oral ribs and the “apical ring” extending beneath kinetosomes of ciliary couplets display filaments that do not bind HMM and are ? 14 nm in diameter. No evidence for actin in these structures was obtained in the present study. The “specialized cytoplasm” of the cytostome-cytopharyngeal region appears as an undecorated reticulum with 20 nm-spaced nodes. Occasionally HMM-binding filaments were found inside the macronucleus, just beneath its envelope. Actin is suggested to be involved in cell shaping and in control of the transport of food vacuoles.     

The organization of microtubules during generative-cell division inConvallaria majalis

Summary The organization of the microtubule cytoskeleton in the generative cell ofConvallaria majalis has been studied during migration of the cell through the pollen tube and its division into the two sperm cells. Analysis by conventional or confocal laser scanning microscopy after tubulin staining was used to investigate changes of the microtubule cytoskeleton during generative-cell migration and division in the pollen tube. Staining of DNA with 4,6-diamidino-2-phenylindole was used to correlate the rearrangement of microtubules with nuclear division during sperm cell formation. Before pollen germination the generative cell is spindle-shaped, with microtubules organized in bundles and distributed in the cell cortex to form a basketlike structure beneath the generative-cell plasma membrane. During generative-cell migration through the pollen tube, the organization of the microtubule bundles changes following nuclear division. A typical metaphase plate is not usually formed. The generative-cell division is characterized by the extension of microtubules concomitant with a significant cell elongation. After karyokinesis, microtubule bundles reorganize to form a phragmoplast between the two sperm nuclei. The microtubule organization during generative-cell division inConvallaria majalis shows some similarities but also differences to that in other members of the Liliaceae.Abbreviations CLSM confocal laser scanning microscopy - EM electron microscopy - GC generative cell - GN generative nucleus - MT microtubule - SC sperm cell - SN sperm nucleus - VN vegetative nucleus     

Structural organization of ovarian follicle cells in the cotton bug (Dysdercus intermedius) and the honeybee (Apis mellifera)

Summary The somatic epithelia of Dysdercus and Apis follicles were analyzed by electron microscopy, and the patterns of F-actin and microtubules were studied by fluorescence microscopy. The epithelia in both species differ considerably in shape and in the organization of the cytoskeleton. During previtellogenic stages, the epithelium consists of columnar-shaped cells with small (Dysdercus) or no (Apis) lateral intercellular spaces. During vitellogenesis, the follicle cells round up; the intercellular spaces increase in size in Dysdercus follicles, whereas in Apis follicles they remain small. Along the basal surface of the follicle cells, there are conspicuous parallel bundles of microfilaments perpendicular to the anteroposterior axis of the follicles. In the honeybee, these microfilament bundles are present in long filopodia, most of which are embedded in thickenings of the basement membrane and extend over the surfaces of neighbouring cells. In the cotton bug, the basal surface of the follicle cells is thrown into parallel folds. The microfilament bundles are located just underneath the cell membrane where the folds contact the basement membrane. In the polar regions of the Dysdercus follicle, the epithelial cells become flat and adhere to each other without forming intercellular spaces. The basement membrane is particularly thick in the polar areas; this has also been observed in Apis follicles around the intercellular bridge connecting oocyte and nurse cells.     

Ultrastructure of the nephridio-circulatory connections in Tubulanus annulatus (Nemertini,Anopla)

Summary The protonephridial terminal organs in the nemertean Tubulanus annulatus form an integral part of the blood vessel wall. Both endothelial and muscle-cell layers of the vessel's wall are discontinued at the site of each terminal organ. The terminal organs are usually composed of from one to three terminal cells enclosing a central lumen provided with many microvilli and separated from the blood vessel's lumen by a membranous filtration area. The latter is perforated by numerous winding clefts formed by interdigitation of minute cytoplasmic pedicels arising from processes issued by each of the involved terminal cells. Ultrafiltration of blood plasma takes place across a filtration membrane which spans the cleft system and the basal lamina of the terminal cells. Fluid is propelled into the lumen of the terminal organs through the activity of ciliary bundles, one for each terminal cell involved, perhaps supplemented by vascular turgor. All efferent conduits of the protonephridium have profuse infoldings of the luminal cell surfaces and/or numerous pinocytotic pits suggestive of reabsorption of substances from the primary urine.Abbreviations BL basal lamina - C cilium - CP coated pit - CT collecting tubule - CV inzcoated vesicle - D dictyosome - E endothelial cell - F fenestration of endothelial cell - FA filtration area - FM filtration membrane - G glycogen granule - LV lateral vessel - M mitochondrion - MC muscle cell - MV microvillus - N nucleus of terminal cell - NE nucleus of endothelial cell - NP nephridiopore - PC protonephridial capillary cell - PT protonephridial tubule - R rootlet - TC terminal cell     

VASCULAR ORGANIZATION IN SHOOTS OF CACTACEAE. I. DEVELOPMENT AND MORPHOLOGY OF PRIMARY VASCULATURE IN PERESKIOIDEAE AND OPUNTIOIDEAE

Primary shoot vasculature has been studied for 31 species of Pereskioideae and Opuntioideae from serial transections and stained, decorticated shoot tips. The eustele of all species is interpreted as consisting of sympodia, one for each orthostichy. A sympodium is composed of a vertically continuous axial bundle from which arise leaf- and areole-trace bundles and, in many species, accessory bundles and bridges between axial bundles. Provascular strands for leaf traces and axial bundles are initiated acropetally and continuously within the residual meristem, but differentiation of procambium for areole traces and bridges is delayed until primordia form on axillary buds. The differentiation patterns of primary phloem and xylem are those typically found in other dicotyledons. In all species vascular supply for a leaf is principally derived from only one procambial bundle that arises from axial bundles, whereas traces from two axial bundles supply the axillary bud. Two structural patterns of primary vasculature are found in the species examined. In four species of Pereskia that possess the least specialized wood in the stem, primary vascular systems are open, and leaf traces are mostly multipartite, arising from one axial bundle. In other Pereskioideae and Opuntioideae the vascular systems are closed through a bridge at each node that arises near the base of each leaf, and leaf traces are generally bipartite or single. Vascular systems in Pereskiopsis are relatively simple as compared to the complex vasculature of Opuntia, in which a vascular network is formed at each node by fusion of two sympodia and a leaf trace with areole traces and numerous accessory bundles. Variations in nodal structure correlate well with differences in external shoot morphology. Previous reports that cacti have typical 2-trace, unilacunar nodal structure are probably incorrect. Pereskioideae and Opuntioideae have no additional medullary or cortical systems.     

The fine structure of developing bristles in wild type and mutant Drosophila melanogaster

In an attempt to understand the factors involved in morphogenesis of a complex cell like a scale or bristle, the fine structure of the normal development of bristle cells in Drosophila melanogaster (Oregon R) has been studied and compared with that of the mutants sn³ and Sb. In the development of the normal bristle rounded bundles of longitudinally oriented fibrils lie just beneath the cell surface at regularly spaced intervals. Fiber bundles constitute about 20% of the cross sectional area. The cytoplasmic surface between these bundles is active in enveloping the nerve fiber associated with the bristle and in sending out cytoplasmic processes associated with which the longitudinally oriented bristle ridges form. Singed bristles are bent and twisted and the fiber bundles are present as flattened bands constituting only about 5% of the cross-sectional area. In Sb mutants the total cross-sectional area of fiber bundle material is the same as that in Oregon R, but fiber bundles are smaller and more numerous, being distributed over the larger surface of this thicker and shorter bristle. They constitute only 7% of the cross-sectional area of the bristle. In Sn³Sb mutants characteristics of each gene are exaggerated and an extremely short, wide, and irregular bristle is formed.     

Cytochemical demonstration of actin filaments in myoepithelial cells of the human parotid gland

Ultrastructurally, myoepithelial cells were shown to contain numerous fine filaments in their cytoplasm and resembled smooth muscle cells. The myoepithelial cell of the salivary gland has been considered to play an important role in the secretion of saliva. The present study showed that all the thin filaments (actin filaments) in the myoepithelial cell of the human parotid gland bound heavy meromyosin (HMM) and formed characteristic arrowhead structures. These filaments ran in two opposite directions with the poles at different ends. On the other hand, there was no binding of HMM with thicker filaments (10-nm filaments), plasma membrane, nuclear membrane, collagen fibrils, basement membrane or other cytoplasmic organelles. The present results strongly suggest that myoepithelial cells possess a contractile function parallel to the long axis of the cell for supporting the secretion of saliva in the parotid gland.     

Vascular floral anatomy of the east asianHeloniopsis orientalis (Thunb.) C. Tanaka (Liliaceae-Helonieae)

Observations on the vascular floral anatomy, carpel morphology and floral biology ofHeloniopsis orientalis are presented. The lower flowering pedicel has six large bundles which lack an enclosing sclerenchymatous sheath. At mid-pedicel, branch bundles originate via radial divisions from each of these bundles. Subsequently, there is a vascular ring of 12 bundles below the receptacle. The six smaller bundles which are derived from alternate pedicel bundles eventually establish all of the ventral gynoecium supply. The six larger bundles supply the tepals, stamens and dorsal gynoecial vasculature. The simple dorsals do not branch or fuse in their vertical ascent. The ventral and placental supplies are far more complex. Fusion occurs between paired sets of the six smaller pedicel bundles along the septal radii and results in a submarginal laminal ventral network. An independent ventral plexus is formed in each septum and from each plexus two septal axials, of which the innermost has a reversed xylem-phloem disposition, and four placental bundles are derived. Two placental bundles are associated with each septal axial. Basally the septa are fused centrally, but are freed at mid-gymoecial height. The broadly tri-lobed, tri-carpellate gynoecium is depressed terminally where the erect, hollow style with its capitate stigma is attached. Dorsal grooves are present: the fruit is loculicidally dehiscent. There are no septal glands due to complete lateral fusion of the septal wings. Basally each of the six equal tepals has a saccate nectary. The similarity in vascular anatomy and carpel morphology of the AsianHeloniopsis and eastern North American endemic,Helonias bullata, justifies their position in the same tribe. Research and publication supported in part by the M. Graham Netting Research Fund through a grant from the Cordelia Scaife May Charitable Trust, the U. S.—Japan Cooperative Science Program Grant GF-41367, the Japan Society for the Promotion of Science, and Grant-in-Aid No. 934053 from the Ministry of Education, Japan.     

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