Pollen mitosis in the slipper orchid Cypripedium fasciculatum

Pollen mitosis in the slipper orchid Cypripedium fasciculatum was studied using correlated methods of immunofluorescence and transmission electron microscopy. Unlike the more highly evolved orchids, the cypripedioid orchids shed pollen as monosulcate monads. Prior to pollen mitosis, the microspore nucleus migrates to a proximal position opposite the aperture, as is typical of monocotyledons. There is no distinct generative pole microtubule system (GPMS) like that recently reported in development of pollen polarity in the vandoid moth orchid Phalaenopsis. Instead, microtubules in early prophase are concentrated around the nucleus and extend into the cytoplasm toward the future generative pole. Once the nucleus has migrated to the continuous surface opposite the aperture, microtubules surround the nucleus evenly and show no tendency to be more concentrated in the generative domain. The mitotic spindle, which develops from the perinuclear microtubules, is asymmetrically placed in the microspore and is cone-shaped. The generative pole is broad and closely appressed to the continuous spore surface, while the vegetative pole is pointed and located in the interior of the microspore. As the chromosomes move poleward, microtubules proliferate in the interzone and a phragmoplast develops. The phragmoplast expands in a hemispherical path beyond the interzone following an array of microtubules that radiates from the generative nucleus. Data from this study indicate that evolution of pollen in orchids includes a shift in location of the generative cell from proximal to distal and the evolution of a GPMS, in addition in the well-known trend toward increased pollen aggregation and loss of exine.     

Ultrastructural studies on plastids of generative and vegetative cells inLiliaceae 3. Plastid distribution during the pollen development inGasteria verrucosa (Mill.) Duval

Summary This paper describes the development of pollen grains ofGasteria verrucosa from the late microspore to the mature two-cellular pollen grain. Ultrastructural changes and the distribution of plastids as a result of the first pollen mitosis have been investigated using light and electron microscopy. The microspores as well as the generative and the vegetative cell contain mitochondria and other cytoplasmic organelles during all of the observed developmental stages. In contrast, the generative cell and the vegetative cell show a different plastid content. Plastids are randomly distributed within the microspores before pollen mitosis. During the prophase of the first pollen mitosis the plastids become clustered at the proximal pole of the microspore. The dividing nucleus of the microspore is located at the distal pole of the microspore. Therefore, the plastids are not equally distributed into both the generative and the vegetative cell. The possible reasons for the polarization of plastids within the microspore are briefly discussed. The lack of plastids in the generative cell causes a maternal inheritance of plastids inGasteria verrucosa.     

Actin microfilament organization during pollen development ofBrassica napus cv. Topas

Summary The organization of actin microfilaments (MFs) was studied during pollen development ofBrassica napus cv. Topas. Cells were prepared using three techniques and double labelled for fluorescence microscopy with rhodamine-labelled phalloidin for MFs and Hoechst 33258 for DNA. Microfilaments are present at all stages of pollen development with the exception of tricellular pollen just prior to anthesis. Unicellular microspores contain MFs which radiate from the surface of the nuclear envelope into the cytoplasm. During mitosis MFs form a network partially surrounding the mitotic apparatus and extend into the cytoplasm. Both cytoplasmic and phragmoplast-associated MFs are present during cytokinesis. Nuclear associated-, cytoplasmic, and randomly oriented cortical MFs appear in the vegetative cell of the bicellular microspore. Cortical MFs in the vegetative cell organize into parallel MF bundles (MFBs) aligned transverse to the furrows. The MFBs disappear prior to microspore elongation. At anthesis MFs are restricted to the cortical areas subjacent to the furrows of the vegetative cell. The use of cytochalasin D to disrupt MF function resulted in: (1) displacement of the acentric nucleus in the unicellular microspore; (2) displacement of the spindle apparatus in the mitotic cell; (3) symmetrical growth of the bicellular microspore rather than elongation and (4) inhibition of pollen tube germination in the mature pollen grain. This suggests that MFs play an important role in anchoring the nucleus in the unicellular microspore as well as the spindle apparatus during microspore mitosis, in microspore shape determination and in pollen tube germination.Abbreviations MF microfilament - MFB microfilament bundle - rhph rhodamine phalloidin Dedicated to the memory of Professor John G. Torrey     

Pollen development in orchids 4. Cytoskeleton and ultrastructure of the unequal pollen mitosis inPhalaenopsis

Summary The unequal first mitosis in pollen ofPhalaenopsis results in a small generative cell cut off at the distal surface of the microspore and a large vegetative cell. No preprophase band of microtubules is present, but polarization of the microspore prior to this critical division is well marked. A generative pole microtubule system (GPMS) marks the path of nuclear migration to the distal surface, and the organelles become unequally distributed. Mitochondria, plastids and dictyosomes are concentrated around the vegetative pole in the center of the microspore and are almost totally excluded from the generative pole. The prophase spindle is multipolar with a dominant convergence center at the GPMS site. The metaphase spindle is disc-shaped with numerous minipoles terminating in broad polar regions. In anaphase, the spindle becomes cone-shaped as the spindle elongates and the vegetative pole narrows. These changes in spindle architecture are reflected in the initial shaping of the telophase chromosome groups. F-actin is coaligned with microtubules in the spindle and is also seen as a network in the cytoplasm. An outstanding feature of orchid pollen mitosis is the abundance of endoplasmic reticulum (ER) associated with the spindle. ER extends along the kinetochore fibers, and the numerous foci of spindle fibers at the broad poles terminate in a complex of ER.Abbreviations CLSM confocal laser scanning microscope/microscopy - DMSO dimethyl sulfoxide - ER endoplasmic reticulum - FITC fluorescein isothiocyanate - GPMS generative pole microtubule system - MBS m-maleimidobenzoic acidN-hydroxysuccinimide ester - PPB preprophase band of microtubules - RhPh rhodamine palloidin - TEM transmission electron microscope/microscopy     

杜仲花粉不对称分裂的超微结构观察

运用透射电镜对杜仲花粉发育进程进行了观察研究。结果显示,杜仲小孢子的第一次分裂为不等分裂,形成小的生殖细胞和大的营养细胞。分裂开始前小孢子的营养极形成许多小液泡,建立细胞极性;然后随着核膜的解体核周围的细胞器逐渐向纺锤体区靠近,围绕在纺锤体周围。花粉第一次有丝分裂完成后,生殖细胞所获得的细胞器开始分布在细胞的两侧,后来移向生殖细胞的营养极,而紧贴花粉壁的生殖极无细胞器分布。这种生殖细胞早期的细胞极性,可能为进一步分裂形成精细胞奠定基础。     

The mitotic apparatus during unequal microspore division observed by a confocal laser scanning microscope

Summary The structure of the mitotic apparatus during the microspore division ofTradescantia paludosa, which has a distinctively unequal division of large vegetative and small generative cells, was studied using -tubulin immunofluorescence methods and confocal laser scanning microscopy. Mitotic apparatuses began to develop asynchronously during early prophase at the vegetative pole (VP) and during prometaphase at the generative pole (GP). Both, however, reached completion together at the same time during metaphase. At the VP from prophase to prometaphase, microtubules (MTs) did not converge on the pole, and there was a circular area containing only a few MTs. The prophase spindles on the VP side were in the form of domes or cones that lacked the top. In the metaphase, however, the MTs concentrated at the pole to form a representative cone-shaped half-spindle. At the GP from prometaphase to metaphase, the MTs did not concentrate, and a circular area existed that lacked MTs. The half-spindles formed truncated cones. When the phragmoplast developed and curved around the generative nucleus during the telophase. it first grew toward the long axis of the ellipsoidal-shaped microspore; and after it arrived at the inner membrane of the microspore, it again curved past the generative nucleus toward the short axis. In conclusion, it was found that the mitotic apparatus ofT. paludosa microspores with its asynchronous growth and asymmetrical spindle structure and with its three dimensional growth of phragmoplasts had a peculiar developmental manner related to unequal division.     

Male gametophyte development inPlumbago zeylanica: cytoplasm localization and cell determination in the early generative cell

Summary The behavior of the generative cell during male gametophyte development inPlumbago zeylanica was examined by epifluorescence microscopy and electron microscopy with organelle nucleoid as a cytoplasm marker. When the thin sections stained with 4,6-diamidino-2-phenylindoIe (DAPI) were observed under an epifluorescence microscope, two types of fluorescence spots were detected in the cytoplasm of the pollen cells before the second mitosis. The spots emitting stronger fluorescence were confirmed as plastid nucleoids and those emitting dimmer fluorescence were mitochondrial nucleoids. Before the first mitosis, both plastid and mitochondrial nucleoids distributed randomly in the cytoplasm of the microspore. A small lenticular generative cell formed with attachment to the interior of the intine after the mitosis. Small vacuoles were found in the lenticular cell. In the cytoplasm of the lenticular cell, both plastid nucleoids and the small vacuoles were distributed randomly at the very beginning but began to migrate in opposite directions immediately. Plastid nucleoids aggregated to the side of the cell that faces the pollen center and the small vacuoles aggregated to the side of the cell that attaches to the inline. As the result, the lenticular generative cell appeared highly polarized in cytoplasm location soon after the first mitosis. In accordance with the definition of the cytoplasm polarization, the primary wall between the generative and the vegetative cells began to flex and the lenticular generative cell started to protrude towards the pollen center. When the generative cell peeled away from the inline, it was spherical in shape with the pole that aggregated plastids towards the vegetative nucleus. But the cell direction appeared to be transformed immediately. The pole that aggregated small vacuoles turned to the position towards the vegetative nucleus and the pole that aggregated plastid nucleoids turned to the position countering to the vegetative nucleus. A cellular protuberance formed at the edge of the pole that aggregated small vacuoles and elongated into a tapered end that got into contact with the vegetative nucleus. The polarization of the cytoplasm kept constant throughout the second mitosis. The small vacuoles that apportioned to the sperm cell which attached the vegetative nucleus (the leading sperm cell) disappeared during sperm cell maturation. Plastid nucleoids were apportioned to the other sperm cell (the trailing sperm cell) completely. Mitochondrial nucleoids became undetectable after the second mitosis.     

Lithium treatment of Nicotiana tabacum microspores blocks polar nuclear migration,disrupts the partitioning of membrane-associated Ca2+, and induces symmetrical mitosis

We have found that the normal developmental pathway of Nicotiana tabacum microspores is blocked or switched when microspores are exposed to lithium, and these effects are reversible with Ca²⁺ and myo-inositol. Normal development was defined by the following characteristics: changes in microspore shape from spherical to oval and then ellipsoid; two nuclear displacements, first from a central location to the cell periphery, and then from the periphery to the generative pole; a localization of membrane-associated Ca²⁺ at the generative pole preceding nuclear division; and, finally, an asymmetrical mitosis that results in a two-celled pollen grain with well-differentiated generative and vegetative nuclei. Lithium treatment blocked the localization of membrane-associated Ca²⁺ at the generative pole, and instead it was evenly distributed at both poles. Lithium treatment also blocked the asymmetrical positioning of the microspore nucleus at the generative pole and resulted in an approximately four-fold increase in the frequency of symmetrical mitosis. When Ca²⁺ and myo-inositol were added along with lithium, the effects were substantially decreased, and there was only a small increase in the frequency of symmetrical mitosis compared with controls. The timing of treatment was important; microspores isolated before the first nuclear displacement had a low frequency of further development, while microspores isolated immediately preceding the onset of mitosis were much less sensitive to lithium, and the result was only a small increase in the frequency of symmetrical mitosis. In microspores isolated after the first nuclear displacement, a 1-day exposure to lithium was sufficient to switch the developmental pathway from an asymmetrical to a symmetrical mitosis while still allowing limited further development. However, we have not optimized culturing conditions for embryogenesis and the furthest development observed after a 1-week culture was to four- or five-celled proembryo-like structures.     

Nuclear fusion in cultured microspores of barley

Fusion of the generative and vegetative nuclei physically separated by a wall has been observed in cultured microspores of barley. The generative cell appears to play an active role in fusion as it elongates toward the vegetative nucleus, becomes detached from the microspore wall, and finally completely encloses the vegetative nucleus. The generative cell wall disappears before nuclear fusion takes place. Since these events have been known to occur during pollen development in vivo, it is hypothesized that the occurrence of nuclear fusion in cultured microspores is the result of continued expression of the genes for gametophytic development.     

Distinct chromatin environment associated with phosphorylated H3S10 histone during pollen mitosis I in orchids

Pollen developmental pathway in plants involving synchronized transferal of cellular divisions from meiosis (microsporogenesis) to mitosis (pollen mitosis I/II) eventually offers a unique “meiosis-mitosis shift” at pollen mitosis I. Since the cell type (haploid microspore) and fate of pollen mitosis I differ from typical mitosis (in meristem cells), it is immensely important to analyze the chromosomal distribution of phosphorylated H3S10 histone during atypical pollen mitosis I to comprehend the role of histone phosphorylation in pollen development. We investigated the chromosomal phosphorylation of H3S10 histone during pollen mitosis I in orchids using immunostaining technique. The chromosomal distribution of H3S10ph during pollen mitosis I revealed differential pattern than that of typical mitosis in plants, however, eventually following the similar trends of mitosis in animals where H3S10 phosphorylation begins in the pericentromeric regions first, later extending to the whole chromosomes, and finally declining at anaphase/early cytokinesis (differentiation of vegetative and generative cells). The study suggests that the chromosomal distribution of H3S10ph during cell division is not universal and can be altered between different cell types encoded for diverse cellular processes. During pollen development, phosphorylation of histone might play a critical role in chromosome condensation events throughout pollen mitosis I in plants.     

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.     

Derepression of the cell cycle by starvation is involved in the induction of tobacco pollen embryogenesis

Summary Microspectrophotometry following Feulgen staining and autoradiography following (³H)-thymidine labelling were used to study cell-cycle events during pollen development in tobacco (Nicotiana tabacum L.). During normal gametophytic pollen development in the anther and in vitro the generative nucleus passes through the S phase to the G₂ phase soon after microspore mitosis, while the vegetative nucleus remains arrested in G₁ (=G₀). During embryogenie induction by an in vitro starvation treatment of immature pollen ongoing DNA replication in the generative nucleus is completed and followed by DNA replication in the vegetative cell in a large fraction of the pollen grains. Addition of the DNA replication inhibitor hydroxyurea to the starvation medium postpones S phase entry until the pollen is transferred to a rich medium and does not affect embryo formation. These results demonstrate that one of the crucial events of embryogenic induction is the derepression of the G₁ arrest in the cell cycle of the vegetative cell.     

Intracellular motility and the evolution of the actin cytoskeleton during development of the male gametophyte of wheat (Triticum aestivum L.)

The uniaperturate pollen of wheat is dispersed in a partially hydrated condition. Amyloplasts are concentrated in the apertural hemisphere where they surround the two sperms, while vigorously moving polysaccharide-containing wall precursor bodies (P-particles) together with the vegetative nucleus occupy the other. This disposition is the product of a post-meiotic developmental sequence apparently peculiar to the grasses. During vacuolation of the spore after release from the tetrad, the nucleus is displaced to the pole of the cell opposite the site of the germination aperture, already defined in the tetrad. Following pollen mitosis, the vegetative nucleus migrates along the wall of the vegetative cell towards the aperture, leaving the generative cell at the opposite pole isolated by a callose wall. As the vacuole is resorbed, the generative cell rounds up, loses its wall and follows the vegetative nucleus, passing along the wall of the vegetative cell towards the aperture where it eventually divides to produce the two sperms. Throughout this period of nucleus and cell manoeuvrings, minor inclusions of the vegetative cell cytoplasm, including mitochondria, lipid globuli and developing amyloplasts, move randomly. Coordinated vectorial movement begins after the main period of starch accumulation, when the amyloplasts migrate individually into the apertural hemisphere of the grain, a final redistribution betokening the attainment of germinability. In the present paper we correlate aspects of the evolution of the actin cytoskeleton with these events in the developing grain, and relate the observations to published evidence from another monocotyledonous species concerning the timing of the expression of actin genes during male gametophyte development, as revealed in the synthesis of actin mRNA.     

Spatial and temporal expression of actin depolymerizing factors ADF7 and ADF10 during male gametophyte development in Arabidopsis thaliana

The actin cytoskeleton plays a crucial role in many aspects of plant cell development. During male gametophyte development, the actin arrays are conspicuously remodeled both during pollen maturation in the anther and after pollen hydration on the receptive stigma and pollen tube elongation. Remodeling of actin arrays results from the highly orchestrated activities of numerous actin binding proteins (ABPs). A key player in actin remodeling is the actin depolymerizing factor (ADF), which increases actin filament treadmilling rates. We prepared fluorescent protein fusions of two Arabidopsis pollen-specific ADFs, ADF7 and ADF10. We monitored the expression and subcellular localization of these proteins during male gametophyte development, pollen germination and pollen tube growth. ADF7 and ADF10 were differentially expressed with the ADF7 signal appearing in the microspore stage and that of ADF10 only during the polarized microspore stage. ADF7 was associated with the microspore nucleus and the vegetative nucleus of the mature grain during less metabolically active stages, but in germinating pollen grains and elongating pollen tubes, it was associated with the subapical actin fringe. On the other hand, ADF10 was associated with filamentous actin in the developing gametophyte, in particular with the arrays surrounding the apertures of the mature pollen grain. In the shank of elongating pollen tubes, ADF10 was associated with thick actin cables. We propose possible specific functions of these two ADFs based on their differences in expression and localization.     

The distribution of cytoplasmic microtubules throughout the cell cycle of the centric diatom Stephanopyxis turris: their role in nuclear migration and positioning the mitotic spindle during cytokinesis

The cell cycle of the marine centric diatom Stephanopyxis turris consists of a series of spatially and temporally well-ordered events. We have used immunofluorescence microscopy to examine the role of cytoplasmic microtubules in these events. At interphase, microtubules radiate out from the microtubule-organizing center, forming a network around the nucleus and extending much of the length and breadth of the cell. As the cell enters mitosis, this network breaks down and a highly ordered mitotic spindle is formed. Peripheral microtubule bundles radiate out from each spindle pole and swing out and away from the central spindle during anaphase. Treatment of synchronized cells with 2.5 X 10(-8) M Nocodazole reversibly inhibited nuclear migration concurrent with the disappearance of the extensive cytoplasmic microtubule arrays associated with migrating nuclei. Microtubule arrays and mitotic spindles that reformed after the drug was washed out appeared normal. In contrast, cells treated with 5.0 X 10(-8) M Nocodazole were not able to complete nuclear migration after the drug was washed out and the mitotic spindles that formed were multipolar. Normal and multipolar spindles that were displaced toward one end of the cell by the drug treatment had no effect on the plane of division during cytokinesis. The cleavage furrow always bisected the cell regardless of the position of the mitotic spindle, resulting in binucleate/anucleate daughter cells. This suggests that in S. turris, unlike animal cells, the location of the plane of division is cortically determined before mitosis.     

Histone H4 acetylation and DNA methylation dynamics during pollen development

Summary The first pollen mitosis results in generative and vegetative cells which are characterised by a striking difference in their chromatin structure. In this study, histone H4 acetylation and DNA methylation have been analysed during pollen development inLilium longiflorum. Indirect immunofluorescence procedures followed by epifluorescence and laser scanning microscopy enabled a relative quantification of H4 acetylation and DNA methylation in microspores, immature binucleate pollen, mature pollen, and pollen tubes. The results show that histone H4 of the vegetative nucleus, in spite of its decondensed chromatin structure, is strongly hypoacetylated at lysine positions 5 and 8 in comparison with both the original microspore nucleus and the generative-cell nucleus. These H4 terminal lysines in the vegetative nucleus are, however, progressively acetylated during the following pollen tube growth. The DNA methylation analysis inversely correlates with the histone acetylation data. The vegetative nucleus in mature pollen grains is heavily methylated, but a dramatic nonreplicative demethylation occurs during the pollen tube development. Changes neither in H4 acetylation nor in DNA methylation have been found during development of the generative nucleus. The results obtained indicate that the vegetative nucleus enters the quiescent state (accompanied by DNA hypermethylation and H4 underacetylation) during the maturation of pollen grain which enables pollen grains a long-term survival without external source of nutrients until they reach the stigma.     

Unequal cell division and chromatin diffrentiation in pollen grain cells

The dynamics of the microtubule (MT) were studied by α-tubulin immunofluorescence methods during the polleng rain ontogeny inTradescantia paludosa. Before the microspore division, interphase nuclei of themicrospore cells were twice displaced from the center to one side (NM-1) and from the side to the center near the inner wall (NM-2). During NM-1, a few MTs appeared around the nucleus, but the movement was not interrupted by colchicine treatment. In NM-2, however, which was essential to the unequal division of microspores, many MTs and MT bundles became organized and shifted in a manner corresponding to the nuclear movement. This movement was inhibited by the colchicine treatment. It was concluded that NM-2 was dependent on the MT cytoskeleton, but NM-1 was independent. Througthout the microspore division, mitotic spindles were organized asymmetrically. From prophase to prometaphase, the spindle began to construct itself in the vegetative pole preceding the generative pole. The half-spindles were asymmetric at the metaphase and the phragmoplast developed curving toward the generative pole at the telophase. No pre-prophase band of MTs was observed throughout the cell cycle. The relationship between the characteristic MT dynamics and the nuclear movement, or unequal cell division, was revealed and is discussed here.     

Detection and quantification of rRNA by high-resolutionin situ hybridization in pollen grains

We examined changes in the localization of cytoplasmic rRNA during pollen development inNicotiana tabacum SR-1. The rRNA was visualized byin situ hybridization, and the signal intensity of rRNA in microspore, vegetative and generative cell was quantified by microphotometry. The amount of rRNA per microspore or pollen section increased about 5 times from microspore to mature pollen grain and kept increasing even in the late stage of pollen development after PMI. The increase of rRNA occur in both vegetative and generative cells. The results suggest that synthesis of rRNA occur even after PM I in both vegetative and generative cells.     

Differentiation of generative and vegetative cells in angiosperm pollen

 Cellular differentiation of a generative and a vegetative cell is an important event during microspore and pollen development and is requisite for double fertilization in angiosperms. The generative cell produces two sperm cells, or male gametes, whereas the vegetative cell produces an elongated pollen tube, a gametophytic cell, to deliver the male gametes to the embryo sac. For typical differentiation of the gametic and gametophytic cells, cell polarity, including nuclear positioning, must be established prior to microspore mitosis and be maintained during mitosis. Microtubules are closely involved in the process of asymmetric cell division. On the other hand, alteration of the chromatin composition seems to be responsible for the differential gene expression between the generative and vegetative cells. Cytoplasmic regulatory molecules, which affect chromatin configuration, are postulated to be unequally distributed to the two cells at the asymmetric cell division. Thus, typical differentiation of the cells is accomplished by a cellular mechanism and a molecular mechanism, which might be independent of each other. These results are discussed in relation to one model that accounts for the different fates of generative and vegetative cells during sexual plant reproduction. Received: 3 September 1996 / Revision accepted: 23 September 1996     

Characterization and dynamics of cytoplasmic F-actin in higher plant endosperm cells during interphase, mitosis, and cytokinesis

We have identified an F-actin cytoskeletal network that remains throughout interphase, mitosis, and cytokinesis of higher plant endosperm cells. Fluorescent labeling was obtained using actin monoclonal antibodies and/or rhodamine-phalloidin. Video-enhanced microscopy and ultrastructural observations of immunogold-labeled preparations illustrated microfilament-microtubule co-distribution and interactions. Actin was also identified in cell crude extract with Western blotting. During interphase, microfilament and microtubule arrays formed two distinct networks that intermingled. At the onset of mitosis, when microtubules rearranged into the mitotic spindle, microfilaments were redistributed to the cell cortex, while few microfilaments remained in the spindle. During mitosis, the cortical actin network remained as an elastic cage around the mitotic apparatus and was stretched parallel to the spindle axis during poleward movement of chromosomes. This suggested the presence of dynamic cross-links that rearrange when they are submitted to slow and regular mitotic forces. At the poles, the regular network is maintained. After midanaphase, new, short microfilaments invaded the equator when interzonal vesicles were transported along the phragmoplast microtubules. Colchicine did not affect actin distribution, and cytochalasin B or D did not inhibit chromosome transport. Our data on endosperm cells suggested that plant cytoplasmic actin has an important role in the cell cortex integrity and in the structural dynamics of the poorly understood cytoplasm-mitotic spindle interface. F-actin may contribute to the regulatory mechanisms of microtubule-dependent or guided transport of vesicles during mitosis and cytokinesis in higher plant cells.