THE EFFECT OF METHANOL ON SPORE GERMINATION AND RHIZOID DIFFERENTIATION IN ONOCLEA SENSIBILIS

In germinating spores of Onoclea sensibilis, the nucleus migrates to one end prior to an asymmetric cell division that partitions each spore into two daughter cells of unequal size. The larger cell develops into a protonema, whereas the smaller cell immediately differentiates into a rhizoid. When spores were germinated in the presence of methanol, nuclear migration was inhibited and most nuclei moved only to the raphe on the proximal side of the spores. Subsequent cell division partitioned each spore into daughter cells of equal size of which both developed into a protonema and neither into a rhizoid. Spores became sensitive to methanol at a time just prior to or coincident with nuclear migration and the effects of the alcohol were rapidly reversible as long as the spores were removed from methanol prior to the completion of cell division. Exposure to methanol prior to, but not during, nuclear migration or after mitosis had no effect upon rhizoid differentiation. The alcohol disrupted the formation of crosswalls after mitosis and they were often convoluted and irregularly branched. These results are consistent with the interpretation that methanol may disrupt a membrane site that plays an essential role in nuclear movement and rhizoid differentiation.     

The Effects of Centrifugation on Asymmetric Cell Division and Differentiation of Fern Spores

We have investigated the effects of centrifugation on sporepolarity, asymmetric cell division, and rhizoid differentiationin the sensitive fern Onoclea sensibilis L. Centrifugation at10000 g for 30 min produces a random orientation of spores withstratification of the cell contents. After centrifugation atmost early stages of development, the nucleus retains its normalpattern of migration from the centre of the ellipsoidal sporeto the proximal face and then to an end of the spore, withoutregard to the orientation of stratification. This indicatesthat the polarity of the spore is stable to centrifugation.As long as the nucleus migrates to an end of the spore and asymmetriccell division occurs, the small cell differentiates into a rhizoid.The arrangement of large cytoplasmic organelles appears to haveno influence on nuclear migration, asymmetric cell division,or rhizoid differentiation. The only period during developmentwhen centrifugation blocks asymmetric cell division is immediatelypreceding and during mitosis and cytokinesis. Spores centrifugedat this stage do not complete nuclear migration, and symmetriccell division results, with neither cell differentiating intoa rhizoid. The source of the stable polarity of the spore isdiscussed. cell polarity, rhizoid differentiation, centrifugation, Onoclea sensibilis L., sensitive fern, fern spores     

Effects of caffeine on germination and differentiation in spores of the fern, Onoclea sensibilis

During spore germination in the fern, Onoclea sensibilis L., the nucleus moves from a central position to one end, and an asymmetrical cell division partitions the spore into two cells of greatly unequal size. The smaller cell differentiates directly into a rhizoid, whereas the larger cell and its derivatives give rise to the prothallus. In the presence of 5 mM caffeine, the nuclei of most of the spores undergo mitotic replication, whereas cell wall formation is blocked. Multinucleate single cells are produced, which are capable of growth, but no rhizoid differentiation occurs. In some cases a partial cell wall is produced, but the nucleus moves through the discontinuity back to the center of the spore, and the enucleate, incompletely partitioned small “cell” fails to differentiate into a rhizoid. In less than 1% of the spores a broad protuberance, whose wall is yellow-brown, is formed in a multinucleate single cell. The color, staining reaction to ruthenium red, and ultrastructural appearance of the protuberance resemble that of the rhizoid wall. It appears that infrequently in the caffeine-treated spores, a feature which is characteristic of rhizoids is expressed, in the absence of asymmetric cell division, in a cell which otherwise is unable to produce a rhizoid. The results are interpreted to mean that the spore has a highly localized, persistent differentiated region. For rhizoid differentiation to occur, a nucleus must be confined in that region – a confinement which normally is accomplished by the geometrically asymmetric first cell division of germination.     

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.     

The role of asymmetric cell division in pteridophyte cell differentiation. I. Localized metal accumulation and differentiation inVittaria gemmae andOnoclea prothallia

Summary In gemmae ofVittaria graminifolia and prothallia ofOnoclea sensibilis, cell differentiation is initiated by nuclear migration and geometrically asymmetric cell division. The small daughter cells inVittaria develop into antheridia in the presence of gibberellic acid or into rhizoids or new prothallia in its absence. Antheridial differentiation from asymmetric division is induced inOnoclea byPteridium antheridiogen, whereas rhizoid or vegetative cell formation occurs in its absence. Although asymmetric cytokinesis initiates differentiation, it does not in itself determine the developmental fate of the smaller cell. Several histochemical techniques demonstrate that prior to nuclear migration and cell division, Ca²⁺ accumulates in the cytoplasm and wall of the cell at the site where asymmetric division will occur, regardless of the developmental fate of the small cell. The cytoplasmic localization of Ca²⁺ appears to reflect a mobilization of Ca²⁺ from within the cell that eventually moves into the cell wall. We propose that this internal accumulation of Ca²⁺ leads to a localized decrease in cytosolic [Ca²⁺] which in turn may regulate developmental events such as nuclear migration.Publishing prior to 1984 as Alix R. Bassel.     

GROWTH REGULATION BY ETHYLENE IN FERN GAMETOPHYTES. V. ETHYLENE AND THE EARLY EVENTS OF SPORE GERMINATION

Early events during the germination of spores of the fern Onoclea sensibilis were studied to determine the time during germination when ethylene had its greatest inhibiting effect. Water imbibition by dry spores was rapid and did not appear to be inhibited by ethylene. During normal germination DNA synthesis occurred about four hours before the nucleus moved from a central position to the spore periphery. Following nuclear movement, mitosis and cell division occurred, partitioning the spore into a small rhizoid cell and a large protonemal cell. Cell division was complete approximately six hours after nuclear movement. Ethylene treatment of the spores blocked DNA synthesis, nuclear movement, and cell division. The earliest DNA replication in uninhibited spores was observed after 14 hours of germination, and the maximal rate of spore labeling with ³H-thymidine was between 16 and 20 hours. Spores were most sensitive to ethylene, however, during the stages of germination prior to DNA synthesis, and it was concluded that ethylene did not directly inhibit DNA replication but blocked germination at some earlier fundamental step. The effects of ethylene were reversible. since complete recovery from inhibition of germination was possible if ethylene was released and the spores were kept in light. Recovery was much slower in darkness. It was hypothesized that light acted photosynthetically to overcome the ethylene inhibition of germination. Consistent with this, it was shown that spores exhibit net photosynthesis after only two hours of germination.     

SPORE GERMINATION AND DEVELOPMENT OF THE YOUNG GAMETOPHYTE OF THE OSTRICH FERN (MATTEUCCIA STRUTHIOPTERIS)

Light is required for the germination of spores of Matteuccia struthiopteris. Histochemical studies show that dormant spores contain no starch, but have an abundance of storage protein granules. Starch accumulates in the numerous chloroplasts of the spore on exposure to light and becomes gradually more extensive. Protein granules disappear as germination progresses. Following this, the centrally located nucleus migrates toward the proximal spore face. Concomitant with the nuclear migration, an increase of cytoplasmic RNA surrounding the nucleus occurs. An equal nuclear division and unequal cell division give rise to a 2-celled gametophyte consisting of a large prothallial cell and smaller rhizoidal cell. A new peripheral wall forms around the entire protoplast at the time of nuclear migration, while a transverse wall forms after nuclear division. The rhizoid emerges through the split raphe along the proximal spore face; it is rich in cytoplasmic RNA but contains very few chloroplasts and little starch. Electron microscopy of the 2-celled stage revealed a greater concentration of mitochondria, Golgi bodies, and a more extensive endoplasmic reticulum in the rhizoid than was found in the prothallial cell, which, however, was far richer in chloroplasts and lipid bodies. As the rhizoid elongates and becomes more vacuolated, cytoplasmic RNA decreases as cytoplasmic protein increases. The rhizoid undergoes no cell divisions, while the prothallial cell retains the potential for further cell division. The possible significance of the distribution of storage products, cell organelles, and other cell components were considered in relation to the non-equational cell division and differentiation of the 2 cells.     

Separation of processes associated with differentiation of two-celled Fucus embryos

Various inhibitors were used to separate the overlapping processes of polar axis fixation, intracellular localizations forming a polar cell, and cell division, all of which are essential for cellular differentiation in two-celled embryos of Fucus distichus L. Powell. Cycloheximide and sucrose delayed the appearance of a polar cell (rhizoid formation) without inhibiting the fixation of a polar axis. Cytochalasin B, at 10 μg/ml, reversibly inhibited rhizoid formation without altering cell division. At higher concentrations (50–100 μg/ml) given in short pulses, cytochalasin affected the orientation and delayed the fixation of a light-induced polar axis with no qualitative effect on cell division. Disruption of the mitotic apparatus and prevention of cell division by colchicine had no influence on rhizoid formation or on the photopolarization of the developmental axis.     

ROLE OF ASYMMETRIC CELL DIVISION IN PTERIDOPHYTE DIFFERENTIATION. II. EFFECT OF CA2+ ON ASYMMETRIC CELL DIVISION,RHIZOID ELONGATION,AND ANTHERIDIUM DIFFERENTIATION IN VITTARIA GEMMAE

Gametophytes of Vittaria graminifolia reproduce vegetatively by means of gemmae. Each gemma consists of a linear array of six cells: four body cells and a knob-shaped terminal cell at each end. When gemmae are shed from the gametophyte onto Knop's mineral medium, the two terminal cells do not divide, but elongate to form primary rhizoids. The body cells undergo asymmetric cell division, and the smaller daughter cells differentiate into either secondary rhizoids or prothalli. When gibberellic acid is included in the medium, antheridia are formed as a result of asymmetric cell division instead of vegetative structures. We studied the effect of Ca²⁺ on asymmetric cell division, rhizoid elongation, and antheridium formation in gemmae cultured on Knop's mineral medium and variations of Knop's medium. Ca²⁺ inhibited the onset of cell division and rhizoid elongation, but was required for differentiation of antheridia. Treatments which lowered the Ca²⁺ content of gemmae (EGTA and dilute HCl extraction, culture on verapamil-containing and Ca²⁺-deficient medium) caused an early onset of cell division and rhizoid elongation. The stimulation of growth was most pronounced when gemmae were deprived of Ca²⁺ during the first 24 hr of culture. The proportion of cell divisions which differentiated into antheridia in response to GA was greatly reduced when the Ca²⁺ status of gemmae was lowered with verapamil and Ca²⁺-EGTA buffers.     

Spore Germination and Rhizoid Differentiation in Onoclea sensibilis: A Two-Dimensional Electrophoretic Analysis of the Extant Soluble Proteins

Following a geometrically asymmetrical cell division during germination of spores of the fern Onoclea sensibilis L., the small cell differentiates into a rhizoid and the large cell divides to form the protonema. Using silver-staining of two-dimensional gels, we have examined the soluble proteins of spores during germination and of separated rhizoid protoplasts and protonemal cells. Of over 500 polypeptides followed, nearly 25% increased or decreased in prominence during spore germination and the initial phases of rhizoid elongation. Soluble proteins from purified protoplasts of young rhizoids were quantitatively different from those of protonemal cells and germinated spores. Nine polypeptides which appeared after cell division were substantially more prominent in rhizoid protoplasts than in whole germinated spores and have been putatively designated rhizoid-specific polypeptides. The differences in the soluble protein composition of young rhizoids and protonemal cells probably reflect the differential organelle distribution between the two cells as well as differential net protein synthesis in the cytoplasms of the two cells.     

Light germination ofAnthoceros miyabeanus spores

The effects of light on the spore germination of a hornwort species,Anthoceros miyabeanus Steph., were investigated. Spores of this species were photoblastic, but their sensitivities to light quality were different. Under either continuous white, red or diffused daylight, more than 80% of the spores germinated, but under blue light none or a few of them germinated. Under continuous far-red light or in total darkness, the spores did not germinate at all.Anthoceros spores required red light irradiation for a very long duration, i.e., over 12–24 hr of red light for saturated germination. However, the spore germination showed clear photo-reversibility by repeated irradiation of red and far-red light. The germination pattern clearly varied with the light quality. There were two fundamental patterns; (1) cell mass type in white or blue light: spores divide before germination, and the sporelings divide frequently and form 1–2 rhizoids soon after germination, and (2) germ tube type in red light: spores germinate without cell division, and the single-cell sporelings elongate without cell division and rhizoid formation.     

THE SPORE-GERMINATION PATTERN OF THELYPTEROID FERNS

Cell division patterns in germinating spores of several Thelypteris species were studied using light microscopy of sectioned material and scanning electron microscopy. All species exhibited the same basic germination pattern, characterized by an asymmetric cell division of the spore parallel to the equatorial plane to delimit a proximal rhizoid, followed by a perpendicular division of the basal cell to form the protonemal cell. While spore-germination patterns appear to be a potentially useful taxonomic character in some groups of ferns, the homogeneity in this character exhibited by the thelypteroid group impairs its usefulness in the taxonomy of Thelypteris.     

LIGHT-DEPENDENT INHIBITION OF CELL DIVISION AND RHIZOID ELONGATION IN GEMMAE OF THE FERN,VITTARIA GRAMINIFOLIA

Gametophytes of the shoe-string fern Vittaria graminifolia produce linear, six-celled propagules called gemmae. The terminal cells of each gemma elongate into primary rhizoids in culture, and the inner body cells divide asymmetrically to produce prothallial or rhizoid initials. The initiation of both asymmetric cell division and rhizoid elongation is delayed by light intensities greater than 2 w/m². The maximal rates of cell division and rhizoid elongation are unaltered. A 24-hr pulse of high light intensity delays cell division and rhizoid elongation to the same extent, whenever applied during the first 3 d of culture. The model we propose for cell division hypothesizes the existence of a preparatory phase of finite duration prior to mitosis that is sensitive to light intensity. If a cell is irradiated by light intensities greater than 2 w/m² while in the preparatory phase, its entrance into mitosis is delayed. A similar model is proposed for the initiation of rhizoid elongation. Despite the fact that both cell division and rhizoid elongation are dependent on photosynthesis, direct measurements of CO₂-uptake rates show that the inhibitory effects of high light intensities are not due to an inhibition of photosynthesis.     

A COMPARATIVE STUDY OF CELL DIVISION PATTERNS DURING GERMINATION OF SPORES OF ANEMIA,LYGODIUM AND MOHRIA (SCHIZAEACEAE)

Cell division patterns during germination of spores of Anemia (A. hirsuta, A. munchii, A. phyllitidis), Lygodium (L. circinatum, L. flexuosum, L. japonicum, L. salicifolium) and Mohria caffrorum have been examined by light microscopy of glycol methacrylate embedded materials. Spores of all species in a genus exhibited a constant pattern of division under different conditions of germination. In spores of species of Anemia, following an asymmetrical division, the proximal cell differentiated into the protonemal cell while the distal cell divided to produce the rhizoid. A similar division sequence was found in spores of Mohria caffrorum, but the fate of cells formed was reversed. In Lygodium spores, a proximal cell formed by an initial division of the spore cut off a protonemal cell, a rhizoid and a wedge-shaped cell by walls parallel to the polar axis. Our results contradict earlier observations on cell division sequence during germination of spores of these genera based on whole mount preparations.     

Membrane recycling occurs during asymmetric tip growth and cell plate formation inFucus distichus zygotes

Summary Zygotes of the brown algaFucus distichus undergo a series of intracellular changes resulting in the establishment of a polar growth axis prior to the first embryonic cell division. In order to examine the dynamics of membrane recycling which occur in the zygote during polar growth of the rhizoid, we probed living Fucus zygotes with the vital stain FM4-64, N-(3-triethylammoniumpropyl)-4-(6-(4-(diethylammo)phenyl)hexatrienyl)pyridinium dibromide. In newly fertilized, spherical zygotes, FM4-64 staining is symmetric and predominantly in the perinuclear region which is rich in endoplasmic reticulum, Golgi, and vacuolar membranes. As rhizoid or tip growth is initiated, this population of stained membranes becomes asymmetrically redistributed, concentrating at the rhizoid tip and extending centrally to the perinuclear region. This asymmetric localization is maintained in the zygote throughout polar growth of the rhizoid and during karyokinesis. Subsequently, FM4-64 staining also begins to accumulate in a central location between the daughter nuclei. As cytokinesis proceeds, this region of stain expands laterally from this central location, perpendicular to the plane of polar rhizoid outgrowth. The staining pattern thus delineates the formation of a cell plate, similar spatially to the accumulation of nascent plate membranes of higher plants. Treatment of Fucus zygotes with brefeldin-A inhibits both asymmetric growth of the rhizoid and formation of a new cell plate. These data suggest that inF. distichus FM4-64 is labeling a Golgi-derived membrane fraction that appears to be recycling between the site of tip growth, perinuclear region, and new cell plate.Abbreviations AF after fertilization - ASW artificial seawater - BFA brefeldin A - ER endoplasmic reticulum - FM4-64 N-(3-triethylam-moniumpropyl)-4-(6-(4-(diethylamino)phenyl)hexatrienyl)pyridinium dibromide     

Cytoskeletal aspects of nuclear migration during tip-growth in the fernAdiantum protonemal cell

Summary In the tip-growing protonemal cell, the nucleus migrates with the tip as it grows, keeping a constant distance between them. Cytoskeletal control of this nuclear migration was analyzed inAdiantum capillus-veneris. Using rhodamine-phalloidin (Rh-Phal), tubulin antibodies and confocal laser scanning microscopy, we found the presence of microtubule (MT) and microfilament (MF) strands connecting the cell nucleus to the cortex of the growing apex. The strands come from the apical end of the spindle-shaped nucleus and run through the endoplasm, arriving at the apical cortex, where a circular arrangement of MTs and MFs is present. Strands of MFs and MTs were also found to emanate from the proximal end of the nucleus and extend towards the cortex of the basal part of the cell. Double staining of MTs and MFs revealed a co-localization of these cytoskeletal elements. When MF strands were disrupted by cytochalasin B (CB), tip-growth ceased and nuclear movement stopped. After the application of colchicine, MT structures disappeared, tip-growth was largely inhibited, and the nucleus moved towards the basal part of the cell. When both CB and colchicine were applied to the cell, no basipetal migration of cell nucleus was observed. These results suggest that the MT strands between the apex and the nucleus may have a role in the anchorage of the cell nucleus to the tip during tip-growth, and that the MF strands may be important for basipetal movement of the nucleus. When the nucleus was dislocated basipetally by centrifugation, cytoskeletal strands between the cell apex and the nucleus were still observed, and by acropetal movement the nucleus resumed its previous position. The acropetal movement of the nucleus was inhibited by the application of both CB and colchicine but not by CB alone nor by colchicine alone, indicating that both cytoskeletal elements are involved in the forward movement of cell nucleus.Abbreviations CB cytochalasin B - DAPI4 6-diamino-2-phenylin-dole - DMSO dimethylsulfoxide - PIPES piperazine-N,N-bis(2-ethane-sulfonic acid) - EGTA ethyleneglycol-bis-(-aminoethyl-ether)-N,N,N,N-tetraacetic acid - MBS m-maleimidobenzoic acid N-hydroxysuccinimide ester - MF microfilament - MT microtubule - PMSF phenylmethylsulfonyl fluoride - PSM polyoxyethylene sorbitan monolaurate - Rh-Phal rhodamine-labeled phalloidin     

The relationship between the division plane and spindle geometry in Allium cells treated with CIPC and griseofulvin: an anti-tubulin study

Isopropyl N-(3-chlorophenyl)-carbamate (CIPC), and griseofulvin, were used to perturb mitosis and the subsequent plane of division in meristematic cells of Allium cepa. The effects of these compounds on the microtubule organization throughout the cell cycle were investigated by immunofluorescence techniques. Microtubules were not disassembled by drug treatment, but the spindle organization was disrupted, resulting in tripolar spindles which gave rise to multiple nuclei. Ensuing cell plates, with associated phragmoplast microtubules, were branched. The effects of these drugs with respect to MTOC duplication and function in plant cells are discussed as is the relationship between the pre-prophase band (PPB) and the plane of cell division.     

Microspore-derived embryos in Brassica: the significance of division symmetry in pollen mitosis I to embryogenic development

Summary An attempt has been made to manipulate the cytological processes regulating the switch from gametophytic to sporophytic development induced by culturing the microspores of higher plants. Previous studies have indicated that sporophytic development, which leads to the formation of haploid embryos, normally follows the symmetrical division of the microspore rather than the asymmetric mitosis characteristic of normal development. To determine whether symmetry of division is a key factor in the determination of subsequent development, cells were supplied with the antimicrotubule drug colchicine to disrupt elements of the microtubular cytoskeleton believed to be involved in nuclear positioning. The treatment resulted in a highly significant increase in the numbers of cells turning to sporophytic development; further, timed applications indicated that the cells were sensitive to the drug over a 12-h period immediately prior to pollen mitosis. The results suggest that alteration of division symmetry is sufficient to switch the developmental pathway from gametophytic to sporophytic. These findings are discussed in the perspective of current models proposed for the regulation of development in eukaryotic cells.     

Localization of Actin mRNA during the Establishment of Cell Polarity and Early Cell Divisions in Fucus Embryos

Localization of mRNA is a well-described mechanism to account for the asymmetric distribution of proteins in polarized somatic cells and embryos of animals. In zygotes of the brown alga Fucus, F-actin is localized at the site of polar growth and accumulates at the cell plates of the first two divisions of the embryo. We used a nonradioactive, whole-mount in situ hybridization protocol to show the pattern of actin mRNA localization. Until the first cell division, the pattern of actin mRNA localization is identical to that of total poly(A)+ RNA, that is, a symmetrical distribution in the zygote followed by an actin-dependent accumulation at the thallus pole at the time of polar axis fixation. At the end of the first division, actin mRNA specifically is redistributed from the thallus pole to the cell plates of the first two divisions in the rhizoid. This specific pattern of localization in the zygote and embryo involves the redistribution of previously synthesized actin mRNA. The initial asymmetry of actin mRNA at the thallus pole of the zygote requires polar axis fixation and microfilaments but not microtubules, cell division, or polar growth. However, redistribution of actin mRNA from the thallus pole to the first cell plate is insensitive to cytoskeletal inhibitors but is dependent on cell plate formation. The F-actin that accumulates at the rhizoid tip is not accompanied by the localization of actin mRNA. However, maintenance of an accumulation of actin protein at the cell plates of the rhizoid could be explained, at least partially, by a mechanism involving localization of actin mRNA at these sites. The pattern and requirements for actin mRNA localization in the Fucus embryo may be relevant to polarization of the embryo and asymmetric cell divisions in higher plants as well as in other tip-growing plant cells.     

DNA Synthesis and Cell Division During Spore Germination in Lygodium japonicum

This paper describes the ontogenetic sequence of cell divisionsand associated DNA synthetic patterns observed in sectionedspores of Lygodium japonicum (Thunb.) Sw., collected at differentstages of germination. Following exposure to a saturating doseof red light, the spore undergoes an asymmetric division toform a basal cell, which retains nearly all of the storage inclusions,and an apical cell which expands and protrudes from the rupturedsporoderm. Division of the apical cell results in formationof a protonemal cell and an intermediate cell. Subsequently,the latter cell divides to form the primary rhizoid and a wedgecell adjacent to the protonemal cell. Secondary rhizoids mayarise from later divisions of either the basal cell or the wedgecell. In addition, the wedge cell appears to have the capacityto form a secondary prothal-lial filament. Histochemical localizationof cell constituents indicates an increasing concentration ofcytoplasmic RNA and protein in the presumptive protonemal regionof the spore cell prior to division. Autoradiography of ³H–thymidineincorporation has shown that synthesis of nuclear DNA precedeseach cell division. Although strictly nuclear DNA synthesisoccurs during early stages of germination, extra-nuclear DNAsynthesis increases greatly following division of the sporecell. The results are discussed in relation to earlier studieson cell division patterns seen in whole mount preparations ofgerminating spores of different species of Lygodium. Lygodium japonicum, spore germination, cell division, DNA synthesis