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.     

Effects of microtubule-inhibitors on nuclear migration and rhizoid differentiation in germinating fern spores (Onoclea sensibilis)

Summary Germinating spores of the sensitive fern,Onoclea sensibilis L., undergo premitotic nuclear migration before a highly asymmetric cell division partitions each spore into a large protonemal cell and a small rhizoid initial. Nuclear movement and subsequent rhizoid formation were inhibited by the microtubule (MT) inhibitors, colchicine, isopropyl-N-3-chlorophenyl carbamate (CIPC) and griseofulvin. Colchicine prevented polar nuclear movement and cell division so that spores developed into enlarged, uninucleate single cells. CIPC and griseofulvin prevented nuclear migration, but not cell division, so that spores divided into daughter cells of approximately equal size. In colchicine-treated spores, MT were not observed at any time during germination. CIPC prevented MT formation at a time coincident with nuclear movement in the control and caused a disorientation of the spindle MT. Both colchicine and CIPC appeared to act at a time prior to the onset of normal nuclear movement. The effects of colchicine were reversible but those of CIPC were not. Cytochalasin b had no effect upon nuclear movement or rhizoid differentiation. These results suggests that MT mediate nuclear movement and that a highly asymmetric cell division is essential for rhizoid differentiation.     

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.     

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 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.     

NUCLEAR MIGRATION IN GERMINATING SPORES OF ONOCLEA SENSIBILIS: THE PATH AND KINETICS OF MOVEMENT

Nuclear migration was observed in individual germinating spores of Onoclea sensibilis from the onset of movement to the completion of mitosis. About 16 hr after the initiation of germination, the nucleus migrated from its initial position in the center of the spore to the proximal side. It then appeared to migrate along the raphe to one end of the spore where an asymmetric division occurred. The average velocity of migration was measured at 0.256 ± 0.065 μm/min. During migration the nucleus underwent changes in shape. No migrations or movement other than that by the nucleus were observed.     

DETERMINATION OF RHIZOID ORIENTATION BY LIGHT AND DARKNESS IN GERMINATING SPORES OF ONOCLEA SENSIBILIS

When spores of the fern, Onoclea sensibilis L., are allowed to germinate in darkness, the rhizoid and the protonema are positioned at close to a right angle. If the spores are exposed initially to light and allowed to germinate, the rhizoid and protonema are positioned nearly axially, at opposite ends of the spore. The greater the duration and intensity of the initial illumination, the greater the tendency towards axial arrangement. All colors of light are active to some degree, and the effects are intensity-dependent. The response occurs in a uniform light field and is not dependent on a directional stimulus; the phenomenon reflects the relative arrangement of one part of the gametophyte to another part but not the orientation of growth with respect to an external stimulus. Direct tests show that neither the relative rhizoid orientation nor initial polarity of germination are affected by unilateral white light or polarized red light; the subsequent growth of the protonema, however, is oriented perpendicular to the plane of light polarization. The effects of light in determining the positional relationship between rhizoid and protonema are interpreted in terms of a hypothesis proposing light-induced changes in the structure and mechanical properties of the spore wall.     

Metal-binding sites in germinating fern spores (Onoclea sensibilis)

Summary During germination of the spore of the sensitive fernOnoclea sensibilis L. the nucleus migrates from a central position to the proximal face and then to one end of the ellipsoidal spore. An asymmetric cell division follows giving rise to a small cell which differentiates immediately into a rhizoid, and a large cell which divides further to give rise to the prothallus. The proximal face of the spore coat is differentiated from the remainder of the spore by its ability to bind nickel ions under certain conditions and by its staining with a sulfide-silver procedure which localizes heavy metals. The inner portion of the exine at the proximal face is differentiated from the outer part by its ability to stain with sulfide-silver at specific periods during germination. The exine at the proximal face also contains pore-like structures 50 nm in diameter which extend from the inner layer of the exine to the outer surface. Sulfide-silver staining material appears to be extruded through the pores at specific periods during germination. The percentage of spores showing nickel-binding and sulfide-silver stainability increases sharply during the first two to four hours of imbibition, then decreases sharply during the following two hours. This is followed by a second rise in staining at 8 to 12 hours of imbibition.The role of the ion-binding sites in the exine is discussed in relation to the stable polarity of the spore.Publishing prior to 1984 asAlix R. Bassel     

Chloroplast activities of dark-imbibed and photoinduced spores of the fernOnoclea sensibilis

Summary Chloroplast activities of dark-imbibed (non-germinating) and photoinduced (germinating) spores of the sensitive fern,Onoclea sensibilis were compared to gain insight into the germination process. There were no changes in the number of chloroplasts or in the chlorophyll contents of the spore during dark-imbibition and during the early phase of germination. Levels of increase in the Chloroplast DNA content of dark-imbibed and photoinduced spores were nearly the same and were associated with autoradiographic incorporation of [³H]thymidine into the cytoplasm. However, incorporation of the label into the nucleus occurred only during photoinduction of spores. Analysis of Chloroplast and nuclear DNA contents by dot-blot hybridization with labeled gene-specific probes has confirmed that chloroplast DNA content of the spore increases during dark-imbibition and photoinduction, while increase in nuclear DNA occurs only in photoinduced spores. Chloroplasts isolated from dark-imbibed and photoinduced spores incorporated [³H]TTP into an acid-insoluble fraction identified as DNA. The results show that physiological activities of chloroplasts of dark-imbibed and photoinduced spores ofO. sensibilis are similar and support an exclusive role for nuclear DNA synthesis in spore germination.     

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.     

The Spontaneous Formation of Antheridia in Onoclea is not Blocked by Light

Onoclea sensibilis gametophytes were grown from spores on ashedsoil and agar to determine if the spontaneous formation of antheridiacan be blocked by light. Under most conditions, dark-grown gametophytesformed antheridia later than or at the same time as gametophytesgrown in the light. Under no circumstances was there a rapidonset of maleness in the dark. These results contradict thehypothesis that, in Onoclea, antheridiogen is required to inducemaleness because light inhibits the formation of antheridia.In the light, antheridia formed on heart-shaped thalli. In darkness,antheridia formed on filamentous gametophytes. The timing ofonset of maleness was affected by temperature and the presenceof sucrose. The effect of sucrose on the comparison betweenlight and dark treatments depended on both substrate and temperature Onoclea sensibilis, L., sensitive fern, fern gametophytes, sexuality, light-induced block     

Gene Activity during Germination of Spores of the Fern, Onoclea sensibilis: RNA and Protein Synthesis and the Role of Stored mRNA

Pattern of ³H-uridine incorporation into RNA of spores of Onocleasensibilis imbibed in complete darkness (non-germinating conditions)and induced to germinate in red light was followed by oligo-dTcellulose chromatography, gel electrophoresis coupled with fluorographyand autoradiography. In dark-imbibed spores, RNA synthesis wasinitiated about 24 h after sowing, with most of the label accumulatingin the high mol. wt. poly(A)^–RNA fraction. There was noincorporation of the label into poly(A) ⁺ RNA until 48 h aftersowing. In contrast, photo-induced spores began to synthesizeall fractions of RNA within 12 h after sowing and by 24 h, incorporationof ³H-uridine into RNA of irradiated spores was nearly 70-foldhigher than that into dark-imbibed spores. Protein synthesis,as monitored by ³H-arginine incorporation into the acid-insolublefraction and by autoradiography, was initiated in spores within1–2 h after sowing under both conditions. Autoradiographicexperiments also showed that the onset of protein synthesisin the cytoplasm of the germinating spore is independent ofthe transport of newly synthesized nuclear RNA. One-dimensionalsodium dodecyl sulphate-polyacrylamide gel electrophoresis of³⁵S-methionine-labelled proteins revealed a good correspondencebetween proteins synthesized in a cell-free translation systemdirected by poly(A) ⁺RNA of dormant spores and those synthesizedin vivo by dark-imbibed and photo-induced spores. These resultsindicate that stored mRNAs of O. sensibilis spores are functionallycompetent and provide templates for the synthesis of proteinsduring dark-imbibition and germination. Key words: Onoclea sensibilis, fern spore germination, gene expression, protein synthesis, sensitive fern, stored mRNA     

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.     

Effects of Population Density on Sex Expression in Onoclea sensibilis L. on Agar and Ashed Soil

Population density affected the sex expression of agar-growngametophytes of Onoclea sensibilis L. The time of onset of sexualitywas advanced, the proportion of females was increased, and thegrowth rate of individuals was greater at lower densities. Populationdensity had no effect on the sex expression of Onoclea grownon ashed soil, and there was no difference in growth rate ofindividuals grown on ashed soil at different densities. Covariateanalysis, using thallus width as a measure of growth rate, indicatedthat the effect of density on sex expression was mostly associatedwith growth rate. The differing effects of population densityon agar and ashed soil demonstrate that substrate influencessex expression in Onoclea. This influence is most dramatic insingle-gametophyte cultures, where agar cultures produced 97per cent females and ashed soil cultures 100 per cent males. Onoclea sensibilis L., sensitive fern, fern gametophytes, sexuality, population density     

Promotion of fern rhizoid elongation by metal ions and the function of the spore coat as an ion reservoir

The perine, or outer coat, of spores of the fern Onoclea sensibilis L. may be chemically removed by a brief treatment with dilute NaClO. Treated spores germinate normally on glass-redistilled H₂O, but elongation of the rhizoid which is differentiated during germination is severely limited. Rhizoid elongation in perine-free spores, however, is normal when the spores are germinated on Knop's mineral medium or on single-salt solutions of Ca²⁺, Mn²⁺, or Mg²⁺. In intact spores which retain their perine, rhizoid elongation is normal on distilled H₂O, and the perine serves as a source of ions which are available to the spores and can sustain rhizoid elongation, even when the external medium is deficient. Electron micrographs show that there are structural differences in the rhizoid wall between perine-free spores germinated on distilled H₂O or on nutrient solutions, and also a difference in the number of vesicles in the apical cytoplasm. Localization of Mg²⁺ and Ca²⁺ in the elongating rhizoid can be visualized with chlorotetracycline fluorescence. No concentration of these ions can be detected by this technique in the small rhizoid initial cell before cell elongation begins.     

蕨类植物孢子与种子植物花粉萌发的比较

蕨类植物孢子与种子植物花粉在有性生殖过程中都具有重要的作用。花粉作为种子植物的雄配子体,通过萌发后极性生长的花粉管将精细胞送到胚囊完成受精作用。蕨类植物孢子作为配子体的原始细胞,通过不对称的有丝分裂产生一大一小两个细胞,小细胞萌发出极性生长的假根,大细胞继续分裂发育为原叶体（配子体）。成熟的花粉和蕨类植物孢子都是代谢高度静止的细胞,两者的萌发过程不仅都受到各种不同环境因子的影响,而且在信号转导、极性建立和能量代谢等方面可能有着相似的调控机制。本文综述了蕨类植物孢子和种子植物花粉萌发过程的差异和保守性特征。     

蕨类植物孢子与种子植物花粉萌发的比较

蕨类植物孢子与种子植物花粉在有性生殖过程中都具有重要的作用。花粉作为种子植物的雄配子体, 通过萌发后极性生长的花粉管将精细胞送到胚囊完成受精作用。蕨类植物孢子作为配子体的原始细胞, 通过不对称的有丝分裂产生一大一小两个细胞, 小细胞萌发出极性生长的假根, 大细胞继续分裂发育为原叶体(配子体)。成熟的花粉和蕨类植物孢子都是代谢高度静止的细胞, 两者的萌发过程不仅都受到各种不同环境因子的影响, 而且在信号转导、极性建立和能量代谢等方面可能有着相似的调控机制。本文综述了蕨类植物孢子和种子植物花粉萌发过程的差异和保守性特征。     

Spore Germination Patterns in the Ferns, Cyathea and Dicksonia

Cell division patterns during germination of spores of Cyatheaaustralis, C. cooperi and Dicksonia antarctica were examinedby light microscopy of sectioned materials and by the scanningelectron microscope. In C. australis and C. cooperi the rhizoidwas traced to a small cell formed by an asymmetric divisionof the spore by a wall parallel to its equatorial plane. Incontrast, the rhizoid was formed by a division of the sporeparallel to its polar axis in D. antarctica. In spores of bothgenera, a second division wall oriented in a plane perpendicularto the first gave rise to the protonemal cell. Certain aspectsof germination described here in spores of Cyathea and Dicksoniaare in conflict with the published accounts of spore germinationin these genera. Cyathea, Dicksonia, spore germination, cell division pattern     

INHIBITION OF FERN SPORE GERMINATION BY LIPOPHILIC SOLVENTS

Several alcohols and other solvents inhibit germination of spores of the fern, Onoclea sensibilis L. The inhibition is reversible when spores are transferred to solvent-free media. The effectiveness of different solvents, measured by the concentration needed to inhibit germination by 50%, increases with their lipid solubility. The activity of straight-chain alcohols from methanol through n-heptanol is highly correlated with lipid solubility, whereas the correlation is weaker for several other solvents. The results indicate that some lipophilic site in the spore is important in germination.     

Control of heat-shock response of young gametophytes of the sensitive fern is at the translational level

Young gametophytes of the sensitive fern, Onoclea sensibilis,respond to heat-shock by synthesizing in excess certain proteinsthat are made at normal growth temperature. Enhanced proteinsynthesis occurred during a 2 h heat-shock at a range of temperaturesbetween 38 °C and 50 °C. Although a temperature of 50°C proved lethal, a 5 min pulse at 50 °C resulted inenhanced synthesis of heat-shock proteins which continued forseveral hours at 25 °C. After heat-shock at 50 °C for10 or 15 min, the gametophytes temporarily lost their capacityfor protein synthesis but normal protein synthesis was resumedwithin 24 h of heat-shock. A heat-shock at 38 °C precedingone at 50 °C did not have any protecting effect on the gametophytes.In vitro translation of poly(A)+ RNA isolated from heat-shockedgametophytes yielded several proteins including heat-shock proteins.The results suggest that, rather than activating genes encodingnew messages for the synthesis of stress proteins, heat-shockof gametophytes of O. sensibilis triggers a controlling systemwhich enhances the translation of certain messages that aresynthesized at normal growth temperature. Key words: Onoclea sensibilis, heat-shock response, protein synthesis, sensitive fern, in vitro translation