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.     

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     

Compositional changes in germinating spores ofAdiantum capillus-veneris L.

Spores ofAdiantum capillus-veneris L. incubated at 25 C for 3 days in the dark were irradiated with continuous red light to induce spore germination and cell growth during following 7 days. A portion of spores were cultured for 8 days in the dark as non-irradiated control. Rhizoidal and protonemal cells were observed at 3 days after transferring spores to the irradiation conditions. During 10 days of the experimental period, changes in the contents of following cell constituents were investigated: total lipid, total soluble sugar, reducing sugar, insoluble glucan, organic acid, protein, soluble α-amino N, and major free amino acids. A large part of nutrient reserves of spores was found to be lipid, whose content decreased markedly as spores germinated. Soluble and insoluble carbohydrates also provided carbon and energy sources during imbibition and germination. Two main reserve proteins were detected by SDS-polyacrylamide gel electrophoresis. These proteins disappeared mostly during germination. Major free amino acids could be assorted into three groups by their patterns of fluctuation during the germination.     

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.     

GIBBERELLIC ACID-INDUCED GERMINATION OF SPORES OF ANEMIA PHYLLITIDIS: NUCLEIC ACID AND PROTEIN SYNTHESIS DURING GERMINATION

The distribution and synthesis of nucleic acids and proteins during gibberellic acid-induced germination of spores of Anemia phyllitidis were studied in order to relate biochemical activity with morphogenetic aspects of germination. Germination is accompanied by the hydrolysis of storage protein granules and the localized appearance of cytoplasmic RNA, protein, and insoluble carbohydrates in a small area adjoining the spore wall and surrounding the nucleus. The protoplast of the spore enlarges in this region, the spore wall breaks and a protonemal cell is formed which contains many chloroplasts. A second division in the spore at right angles to the first yields a rhizoid cell. Autoradiography of ³H-thymidine incorporation has shown that DNA is synthesized both in the nucleus and in the immediately surrounding cytoplasm of the germinating spore until some time after the first division, although a strictly nuclear DNA synthesis is observed later. Synthesis of RNA and proteins is limited to the presumptive regions of the germinating spore which become the protonema and rhizoid, shifting to specific sites in these cells as germination proceeds. The nucleus of the spore continues to be biosynthetically active long after it ceases to divide.     

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.     

Circular arrangement of cortical microtubules around the subapical part of a tip-growing fern protonema

Summary Cortical microtubule arrays in tip-growing protonemal and rhizoid cells of the fernAdiantum gametophytes were observed by immunofluorescence microscopy. A circular arrangement of cortical microtubules was demonstrated around the subapical part of protonemal cells growing under red light conditions. However, such an arrangement was not found in growing rhizoids either by immunofluorescence microscopy or by electron microscopy. The different patterns of microtubule arrays around the apices of tip-growing protonemal and rhizoid cells suggest the possible existence of different mechanisms in regulating the cell diameter in the two types of cylindrical cell.     

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.     

Staining and osmotic properties of young gametophytes ofPolypodium vulgare L. and their bearing on rhizoid function

Summary The rhizoids of gametophytes ofPolypodium vulgare L. rapidly absorb vital stains whereas the protonemal cells are impermeable to these stains, which can only enter the cells from the rhizoids. The protonemal cells which bear rhizoids were found to have a slightly higher osmotic equivalent than did the rhizoids or the protonemal cells on either side. From the results of several staining procedures it was demonstrated that the rhizoid walls contain free carboxyl groups and thus possess cation exchange properties. Most of the carboxyl groups are probably present in a yellow-brown wall matrix substance, which shows high resistance to acid and alkali extraction. The precise nature of this substance has not been determined but it could be an acid mucopolysaccharide. Carboxyl groups are detectable in the protonemal cell walls only after saponification and are probably esterified in the untreated wall. Several other chemical and physiological differences were found between the rhizoids and the protonemal cells and it was concluded that the specific properties of the rhizoids are related to their function as organs of uptake.     

Synthesis of protein and RNA for initiation and growth of the protonema during germination of bracken fern spore

Cycloheximide inhibited initiation and elongation of the protonemal cell during germination of the spores of bracken fern. Incorporation of ¹⁴C-leucine into protein was also profoundly affected by the drug. Concentration of actinomycin D sufficient to inhibit incorporation of ³Huridine into heavy RNA fractions of spores did not prevent initiation of the protonema, but inhibited its subsequent elongation. Protein synthesis during initiation and growth of protonema was not appreciably sensitive to actinomycin D. As in the case of rhizoid initiation, protein synthesis necessary for initiation of protonema during germination appears to involve preformed messenger RNA.     

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     

Hydrolytic enzyme activities in germinating spores ofAdiantum capillus-veneris L.

Changes in hydrolytic enzyme activities were investigated during spore germination ofAdiantum capillus-veneris L. The spores were incubated for 3 days in the dark at 25 C for imbibition, and then germination of the spores was induced by continuous irradiation with red light. At day 2 after onset of the red light irradiation, rhizoids appeared out of spore coats and protonemal cells became visible on the following day. Lipase occurred in dry spores and its activity decreased during 3 days of dark incubation. The activity started to increase when the spore germination was induced by red light irradiation. On the other hand, amylolytic and aminopeptidase activities which were also detected in dry spores decreased continuously during the dark incubation and following the germination process. RNase activity also decreased during 3 days of dark incubation but the activity was retained thereafter at a constant level with or without red light irradiation. Developmental patterns of these hydrolytic enzymes were classified into two groups: One decreased during imbibition and dark incubation but increased after red light irradiation and the other continuously decreased during dark incubation and germination. These results are discussed in relation to compositional changes of cell constitutions such as lipid, sugars, proteins and amino acids during spore germination.     

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.     

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.     

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.     

Jasmonic acid promotes division of fern protoplasts, elongation of rhizoids and early development of gametophytes

The effects of jasmonic acid (JA) on spore germination, early gametophyte development and sporophytic protoplast culture of the fern Platycerium bifurcalum (Cav.) C. Chr. were investigated. JA and no influence on spore germination and primary rhizoid initiation, but significantly promoted early gametophyte development, which was evident from the longer primary rhizoids as well as the higher number of rhizoids and cells per gametophyte. Jasmonic acid (1 μ M ) also promoted the transition of gametophytes from a filamentous to a planar growth. Optimal primary rhizoid elongation and highest cell division activities in the gametophytes were observed at 0.01–1 μ M JA, while the highest number of rhizoids on gametophytes was obtained at 0.1–1 μ M JA. Jasmonic acid (0.01 μ M ) also stimulated initial protoplast divisions. Except for the experiment in which the effect of JA on germination was tested. JA concentrations exceeding 1 μ M did not promote cell elongation or cell division but were instead inhibitory. On the basis of these findings, we propose that JA may be involved in early stages of P. bifurcatum development.     

Identification of two putative adhesive polypeptides in Caulerpa prolifera rhizoids using an adhesion model system

The rhizoid section of the green alga Caulerpa prolifera (Cp) is active in attaching the developing plant to the substratum. A model system for the study of the adhesion of Cp rhizoids has been developed and identification of two putative adhesive polypeptides of Caulerpa (Vn-Cp) was revealed by immunodetection. A method for fast induction of new rhizoids was established using blade-base cutting followed by a few days of incubation. The new rhizoids were gently enclosed between two cover glasses and incubated until firm attachment developed. While analyzing protein extracts, two ∼60–70 kDa polypeptides (Vn-Cp I and Vn-Cp II) were identified by immunodetection with monoclonal antibodies to human vitronectin (Vn). The relative concentration values of the Vn-Cp proteins increased significantly in the ‘cell-wall’ fraction of the attached rhizoids during the incubation period. However, Vn-Cp proteins were not detected in non-attached rhizoids. Furthermore, the Vn-Cp proteins were also detectable on glass substratum subsequent to attached rhizoid removal. The induction and accumulation of Vn-Cp proteins on the ‘cell-wall’ of Caulerpa rhizoids and the firm attachment of the rhizoids to the glass substratum during the incubation period suggest that Vn-Cp proteins play a significant role in adhesion, which may be similar to the function of vitronectin in other adhesion systems. Furthermore, the high accumulation of Vn-Cp proteins on the glass substratum during attachment of new rhizoids suggests that the Vn-Cp proteins are secreted to the extracellular matrix and directly connect rhizoids to the glass substratum as an intermediate compound. These unique properties of Cp make it an excellent model system for the establishment of high amounts of adhesive material for future research. This revised version was published online in August 2006 with corrections to the Cover Date.     

Gene activity during germination of spores of the fern, Onoclea sensibilis. Cell-free translation analysis of mRNA of spores and the effect of alpha-amanitin on spore germination

Poly(A)-RNA fractions of dormant, dark-imbibed (non-germinating) and photoinduced (germinating) spores of Onoclea sensibilis were poor templates in the rabbit reticulocyte lysate protein synthesizing system, but the translational efficiency of poly(A)+RNA was considerably higher than that of unfractionated RNA. Poly(A)+RNA isolated from photoinduced spores had a consistently higher translational efficiency than poly(A)+RNA from dark-imbibed spores. Analysis of the translation products by one-dimensional polyacrylamide gel electrophoresis showed no qualitative differences in the mRNA populations of dormant, dark-imbibed, and photoinduced spores. However, poly(A)+RNA from dark-imbibed spores appeared to encode in vitro fewer detectable polypeptides at a reduced intensity than photoinduced spores. A DNA clone encoding the large subunit of maize ribulose bisphosphate carboxylase hybridized at strong to moderate intensity to RNA isolated from dark-imbibed spores, indicating the absence of mRNA degradation. Although alpha-amanitin did not inhibit the germination of spores, the drug prevented the elongation of the rhizoid and protonemal initial with a concomitant effect on the synthesis of poly(A)+RNA. These results are consistent with the view that some form of translational control involving stored mRNA operates during dark-imbibition and photoinduced germination of spores.     

Analysis of the Dynamics of a Bacillus subtilis Spore Germination Protein Complex during Spore Germination and Outgrowth

Germination of Bacillus subtilis spores is normally initiated when nutrients from the environment interact with germinant receptors (GRs) in the spores'' inner membrane (IM), in which most of the lipids are immobile. GRs and another germination protein, GerD, colocalize in the IM of dormant spores in a small focus termed the “germinosome,” and this colocalization or focus formation is dependent upon GerD, which is also essential for rapid GR-dependent spore germination. To determine the fate of the germinosome and germination proteins during spore germination and outgrowth, we employed differential interference microscopy and epifluorescence microscopy to track germinating spores with fluorescent fusions to germination proteins and used Western blot analyses to measure germination protein levels. We found that after initiation of spore germination, the germinosome foci ultimately changed into larger disperse patterns, with ≥75% of spore populations displaying this pattern in spores germinated for 1 h, although >80% of spores germinated for 30 min retained the germinosome foci. Western blot analysis revealed that levels of GR proteins and the SpoVA proteins essential for dipicolinic acid release changed minimally during this period, although GerD levels decreased ∼50% within 15 min in germinated spores. Since the dispersion of the germinosome during germination was slower than the decrease in GerD levels, either germinosome stability is not compromised by ∼2-fold decreases in GerD levels or other factors, such as restoration of rapid IM lipid mobility, are also significant in germinosome dispersion as spore germination proceeds.