Activity of Antheridiogen from the Fern Anemia phyllitidis in Three Flowering Plant Bioassays

Pure samples of the antheridiogen of Anemia phyllitidis (A_An) were tested for their ability to affect the growth of dwarf corn (d₅) and lettuce seedlings, and to influence α-amylase production by barley half-seeds. Stimulation of dwarf corn growth and barley amylase production was, on a molar basis, from 1/2 to 1/250 that given by GA_3. In lettuce, A_An had a synergistic effect with low levels of GA₃; alone, A_An was inhibitory or ineffective. Therefore, in addition to having a close chemical resemblance to gibberellin, A_An induces similar, but not identical physiological responses in flowering plants as well as ferns.     

Identification of Antheridic Acid as an Antheridiogen in Anemia rotundifolia and Anemia flexuosa

Antheridic acid was identified by retention time and full massspectra from GCMS analysis as an antheridiogen in Anemia rotundifoliaand A. flexuosa. In the dark spore germination assay, antheridicacid was active down to 10^–10 and 5 ? 10^–12g.ml^–1in A. rotundifolia and A.flexuosa, respectively. In the antheridiumformation assay, antheridic acid was active down to 10^–10g.ml^–1 in both A. rotundifolia and A.flexuosa (Received April 14, 1987; Accepted July 8, 1987)     

On Dark-Germination and Antheridium Formation in Anemia phyllitidis

Schraudolf's finding is confirmed that gibberellic acid induces antheridia in Anemia phyllitidis and Lygodium japonicum. The activity spectra of gibberellic acid and the native antheridiogen of Anemia phyllitidis are similar: Both induce antheridia in the tested species of the family Schizaeaceae but are inactive towards the tested representatives of other fern families. However, the native antheridiogens of two schizaeaceous species are more species-specific in their action than is gibberellic acid. Anemia medium cancels the light requirement for spore germination as is the case with gibberellic acid. Chromatographic studies indicate that the dark-germination-inducing factor is identical with, or very similar to, the earlier demonstrated antheridiogen. The specificities of the active factors towards dark-germination in A. phyllitidis and L. japonicum are similar to those encountered with antheridium formation. Anemia medium induces dark-germination and induces antheridia on the dark-grown protonemata to a concentration ca. 30 times lower than it induces antheridia on light-grown prothalli. The studies indicate that this differential activity results from a differential competence of the prothalli to react to the active substance in light and darkness.     

The polyadenylic sequences in the ribonucleic acid of the fern Anemia phyllitidis

The vegetative prothalli (1–3 weeks old) of Anemia were incubated for 24 h in [¹⁴C]adenine. The RNA was phenol extracted from whole cells and the poly (A) sequences were isolated by nuclease digestion followed by poly (U)-sepharose chromatography. About 2–3% of the total radioactivity was retained on the column. The base composition of the nuclease resistant RNA was: C, 1.4; G, 3.6; A, 93.3; and U, 1.7. It is concluded that Anemia RNA contains poly adenylate sequences.Part of a post-doctoral work. Fellowship awarded by Alexander von Humboldt-Stiftung, Federal Republic of Germany     

Calmodulin-like protein from the fern Anemia phyllitidis L. Sw.

Spores and prothallia of the fern Anemia phyllitidis L. Sw. contain a protein which in its physicochemical properties corresponds largely to calmodulin. It shows immunoreactivity with a calmodulin antiserum and activates bovine brain phosphodiesterase. Its content increases during the early processes of light-induced spore germination, indicating that the Ca²⁺-dependence of these processes may be mediated by this protein.Abbreviations EGTA ethylene, glycol-bis(-aminoethyl ether)-N,N,N,N-tetraacetic acid - RIA radioimmunoassay     

Factors Influencing Spore Germination and Early Gametophyte Development in Anemia mexicana and Anemia phyllitidis

Spores of Anemia mexicana Klotzsch and Anemia phyllitidis (L.) Swartz were tested comparatively to investigate the effects of various treatments on spore germination and early gametophyte development in light and darkness. The optimum pH for induction of spore germination is approximately 6. Both species have a minimum 8 hour light insensitive preinduction phase for spore germination. An additional 8 to 12 hours of light are needed to induce 50% germination in A. phyllitidis while at least 24 hours of light are needed for A. mexicana spores. A. phyllitidis has greater sensitivity to the four gibberellic acids tested (GA₃, GA₄, GA₇, and GA₁₃) than A. mexicana for induction of spore germination in darkness. In both species the greatest response was observed with GA₄ and GA₇. GA₁₃ was clearly the least effective. Gametophytes of each species are 100 times more sensitive to their own antheridiogen than to the antheridiogen of the other species. AMO-1618 (1 millimolar), fenarimol (1 mm), and ancymidol (0.1 mm) had essentially no effect on light-induced germination. The latter two did, however, inhibit gametophyte development.     

Endoreplication in Anemia phyllitidis coincides with the development of gametophytes and male sex

Analyses of DNA content using fluorescence microcytophotometry showed that development of Anemia phyllitidis gametophytes coincided with endoreduplication process. The level of this process shown by the number of endopolyploid cells studied at the I–V arbitrarily established cellular gametophyte stages, was 3%, while at the VI–VII and VII* (male stages) were 10.5 and 4%, respectively. This process coincided with decreased mitotic activity of cells and concerned the cells with their profile area between 1100 and 13000 µm². However, the correlation between cell size and its polyploidisation level was detected only for 12% of these cells. Endoreduplication during development of A. phyllitidis gametophytes seems to be connected with the end of cell cycle followed by the exit of cells from the cell cycle and with subsequent switch of proliferation to the postmitotic differentiation and/or to the endocycle. Endoreplication of A. phyllitidis gametophytes is a function of age, size and number of cells as well as type of gametophyte morphogenesis, which probably maintains the functional copies of genes whose number is restricted by elimination of cells from gametophytes by their death.     

Effects of 5-bromo-deoxyuridine on chloroplast structure in gametophytes of Anemia phyllitidis L. Sw.

Application of 5-bromo-2-deoxyuridine causes servere changes in the ultrastructure of chloroplasts. These modifications include an increase of thylakoid layers ("giant"-grana), coiling of thylakoids, and lastly vacuolization of the entire membrane system of the chloroplast. Such observations can be correlated with types of membrane aberrations reported for natural mutants.     

Aphidicolin Inhibition of DNA Synthesis and Germination in Spores of Anemia phyllitidis L. Sw

Aphidicolin inhibits DNA synthesis and nuclear division in spores of Anemia phyllitidis. In spite of blocked DNA replication, spores germinate under continuous dark conditions, if induced by addition of 5 × 10⁻⁵ grams per milliliter gibberellic acid. Differentiation of aphidicolin-treated prothallia indicate the existence of a prepattern in the dry spore which is realized independent of cell division during early events of spore germination.     

The Effect of Gabaculine on Germination and Gametophyte Morphogenesis of Anemia phyllitidis L.Sw.

Gabaculine, applied to germinating spores of the fern Anemiaphyllitidis in concentrations between 10^–4 M and 10^–6M inhibits chlorophyll synthesis together with considerablesimplification of chloroplast ultrastructure. Though gabaculinereduced phytochrome-induced morphogenetic effects (cell shape,inhibition of hormonal antheridium induction), the rate of redlight-induced spore germination, however, has not been affectedby the inhibitor. This indicates significant differences betweenthe two types of photomorphogenetic reactions regarding theirdependency on phytochrome homeostasis. (Received April 21, 1986; Accepted October 22, 1986)     

Effect of red light and gibberellic acid on lipid metabolism in germinating spores of the fern Anemia phyllitidis

The spores of the fern Anemia phyllitidis contain abundant quantities of lipid as reserve material. Germination of these spores can be induced either by red light or, even in the dark, by gibberellic acid. The effects of both these factors on lipid degradation, lipase and isocitrate lyase activities, and on the fatty acid composition have been studied in the course of the germination process. During germination in darkness with gibberellic acid, the fatty acid composition remained similar to that in the ungerminated spore. In contrast, when spores were germinated in red light, α-linolenic acid was synthesized. Little activity of lipase and isocitrate lyase could be detected in the dry spore. Red light or gibberellic acid affected a dramatic increase of the activities of these enzymes. Lipid breakdown and lipase activity were more active in red light, however. Permanent stimuli were necessary for growth and complete lipid degradation. Induction of germination simultaneously with both factors revealed an additivity of the effects of red light and gibberellic acid.     

Studies on morphology and metabolism of prothalli during GA3-induced formation of antheridia in Anemia phyllitidis

In Schizaeaceae ferns, including Anemia phyllitidis, formation of antheridia is known to be induced by exogenously applied gibberellic acid. Also present studies show that GA₃ (10⁻⁵ mol·dm⁻³) modifies the development of gametophytes of Anemia phyllitidis. Simultaneously with formation of antheridia, they exhibit lower number of cells but only slightly lowered profile areas and lengths of prothalli. Growth in size of individual cells compensates for lowered division frequency. Cytophotometric measurements reveal no essential changes in the DNA content in vegetative cells of the control and GA₃-stimulated gametophytes. It remains at haploid level and therefore it is assumed that cell cycle is blocked at G1 phase. Application of GA₃ increases the total amount of proteins. CZE (Capillary Zone Electrophoresis) separation of peptides extracted from control and GA₃-treated prothalli indicates the differences in the ratio of their particular forms. In GA₃-treated gametophytes the activities of acid and basic phosphatases, contents of carbohydrates (glucose, starch), chlorophyll, the number of chloroplasts and dry mass of prothalli are increased. GA₃-intensified metabolism, evidenced in gametophytes of A. phyllitidis, may be interpreted as a stimulatory mechanism which influences metabolic pathways involved in forming, developing and maturing of male sex organs.     

Inhibition of GA3-induced antheridiogenesis in Anemia phyllitidis by peptidic extracts from male sex organs of Chara

Low molecular weight peptidic component extracted from maturing male sex organs of Chara tomentosa, capable of inducing increased condensation of chromosomes and profound changes in the cell cycle progression, was applied to gametophytes of Anemia phyllitidis. Morphogenetic effects were studied with regard to cell divisions and GA₃-induced antheridiogenesis. As compared with both the GA ₃ ⁻ and GA ₃ ⁺ control samples, the extract-treated prothallia exhibited considerably lowered number of cells and altered morphology. Antheridial differentiation in prothallia of A. phyllitidis was severely inhibited when peptidic extract was added to medium containing GA₃. Considering endocytotic uptake, evidenced in root meristems, and those effects which have been observed in plant and human cells, the activity of extracts obtained from male sex organs of Chara may be interpreted as inhibitory influence acting via repression or modification of the genetic device of the cells rather, than a direct consequence of the retardation of cell division cycles.     

Effects of Gibberellins and Their Methyl Esters on Dark Germination and Antheridium Formation in Lygodium japonicum and Anemia phyllitidis

The effects of GA₃, GA₄ and GA₉ and their methyl esters on darkspore germination and antheridium formation of the ferns Lygodiumjaponicum and Anemia phyllitidis were investigated. Althoughall induced both germination and antheridium formation in Lygodium,only the gibberellins induced these effects inAnemia. (Received August 28, 1986; Revision received November 14, 1986. )     

Antheridiogen production and response in Polypodiaceae species

Antheridiogen chemicals secreted by living fern gametophytes have been shown to influence production of male gametangia and thus mating systems in a large number of terrestrial fern species. Antheridiogens have not previously been thought to be prevalent in the Polypodiaceae, a large family composed mostly of tropical epiphytes. This study presents bioassay methods more sensitive than previously used to detect antheridiogen and demonstrates that antheridiogens are also operative in the Polypodiaceae and in epiphytic species. Seven species in six genera (Campyloneurum angustifolium, C. phyllitidis, Lepisorus thunbergianus, Microgramma heterophylla, Phlebodium aureum, Phymatosorus scolopendria, and Polypodium pellucidum) were tested for the presence of an antheridiogen system. All species tested except P. aureum were induced to produce antheridia precociously by their own antheridiogen and by that of Pteridium aquilinum (APt). Phlebodium aureum responded to APt and promoted antheridium formation in Onoclea sensibilis but did not respond to its own antheridiogen. Spores of all species except P. aureum were induced to germinate in darkness by antheridiogen of the same species and by APt and to form antheridia in the dark, further enhancing the possibility of intergametophytic mating.     

Wirkung von hemmstoffen der DNS-, RNS- und proteinsynthese auf wachstum und antheridienbildung in prothallien von Anemia phyllitidis L.

Summary A number of inhibitors of DNA-, RNA-, and protein synthesis were applied to prothallia of Anemia phyllitidis, and their effects were investigated with regard to cell division and inhibition of antheridium formation (after induction by gibberellin A₃). All compounds tested cause a significant inhibition of growth accompanied by teratologies typical for each inhibitor. Only 5-bromouracil proved to be inactive, even at a concentration of 8×10^-4m.None of the inhibitors blocked the induction of the biplanar growth form in continuous light.With the exception of 5-bromodeoxyuridine and 5-iododeoxyuridine all the antimetabolites investigated cause a significant lag in antheridium formation. The result of an analysis of this inhibition on the basis of the critical cell number (Schraudolf, 1966a) demonstrates that this time lag is clearly a direct consequence of the retardation of cell division caused by the inhibitors. There is no inhibition of the induction process proper. So therefore it appears highly improbable that antheridium induction in Anemia by gibberellins is based on a specific gene activation in the sense of Jacob and Monod.The results presented in this paper demonstrate that the production of a time lag in the realisation of a process of differentiation or morphogenesis is not sufficient evidence to permit definite conclusions to be drawn about the basic mechanism of induction; the effect of inhibition of cell division caused by the inhibitors must be excluded or at least taken in to account.The possible function of gibberellins as realisators of already present but inactive m-RNA is discussed.5-Bromo- and 5-iododeoxyuridine do not cause a time lag in antheridium formation; both inhibitors, however, cause a deformation of the cell pattern of the antheridia. The degree of this deformation depends on inhibitor concentration as well as on exposure time. Probably a competition exists between these halogensubstituted pyrimidines and thymidine for incorporation into DNA.     

同形鳞毛蕨成精子囊素系统的初步研究

研究了同形鳞毛蕨成精子囊素对该种和水蕨孢子萌发和配子体发育的影响,结果表明：同形鳞毛蕨配子体能产生成精子囊素,该成精子囊素能抑制同种孢子的萌发,抑制作用随配子体成熟度的增加而增强;同形鳞毛蕨成精子囊素还可促进同种孢子发育为雄配子体;光照条件下,同形鳞毛蕨成精子囊素对水蕨孢子萌发和配子体发育影响不大,黑暗条件下,同形鳞毛蕨成精子囊素能显著的促使水蕨孢子提早萌发,但都不影响其孢子最终萌发率和配子体的性别分化,表明同形鳞毛蕨和水蕨的成精子囊素不属于同一系统。