Wirkung von terpenderivaten (helminthosporol,helminthosporsäure,dihydrohelminthosporsäure und steviol) auf die antheridienbildung in Anemia phyllitidis

Summary Helminthosporol, helminthosporic acid, dihydrohelminthosporic acid, and steviol have been tested for their ability to induce antheridium formation in Anemia phyllitidis. All helminthosporol derivatives posses a limited but real activity. Steviol proved to be inactive.All the substance tested have a significant effect on the cell division rate of the prothallia.     

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.     

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.     

Growth effects of 2-thiouracil and possibility of selective inhibition of floral differentiation inChenopodium rubrum L.

The effect of 2-thiouracil on vegetative growth and floral differentiation was investigated inChenopodium rubrum plants grown in water cultures. Between the low concentrations of the agent, stimulating vegetative growth and floral differentiation, and those inhibiting both these processes, a narrow concentration range was found (1.10^?5 m to 2.10^?5 m), where growth was inhibited selectively. At a concentration of 1.10^?4 m a selective inhibition of development was found when 2-thiouracil was applied at the beginning of photoperiodic induction. Inhibition of development was strong regardless of whether 2-thiouracil was applied before, during or closely after 4 days of photoperiodic induction; the degree of growth inhibition, however, changed in dependence on photoperiodic induction. The strongest relative inhibition of development, calculated as a ratio between development and growth, was observed always at the beginning of photoperiodic induction. Investigation of plant growth as well as the anatomical and autoradiographic study after the application of 2-thiouracil indicate that the inhibition becomes evident at the end of 4 days of application by an overall growth inhibition and a decrease of mitotic activity. Reversal by uracil was possible after simultaneous application of 2-thiouracil. The nature of the selective inhibition is discussed and two possible interpretations of the data obtained are analyzed: a) different response of growth processes in apices and young vegetative organs respectively with regard to different participation of cell division and elongation, b) specific inhibition of floral differentiation.     

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 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.     

Die Wirkung von Phytohormonen auf Keimung und Entwicklung von Farnprothallien

Zusammenfassung Bei allen untersüchten Gametophyten der Schizaeaceen (6 Arten) können die nativen, für die Auslösung der Antheridienbildung verant-wortlichen Hormone (Antheridogene) durch Gibberelline ersetzt werden. Eine Analyse dieses Zelldifferenzierungsprozesses wurde an Prothallien von Anemia phyllitidis durchgeführt.Die durch Gibberelline ausgelöste Umdifferenzierung vegetativer Zellen zu Antheridienmutterzellen wird durch eine Reduktion der Zellteilungsrate eingeleitet.Voraussetzung für die Auslösung der Antheridienbildung ist das Erreichen eines bestimmten Entwicklungszustands der Prothallien. Dieses physiologische Alter ist um so höher, je geringer die applizierte Gibberellinkonzentration ist. Als Kennwert dieser Wechselbeziehung wurde eine kritische Zellzahl definiert.Diese kritische Zellzahl ist weitgehend unabhängig von der Wachstumsgeschwindigkeit der Prothallien.Die enge Korrelation zwischen Hormontiter und Zeitpunkt der Antheridienanlage beruht zumindest teilweise auf einer Sensibilitätsänderung definierter Prothalliumbereiche gegenüber Gibberellinen im Verlauf der Ontogenese. Eine mit dem physiologischen Alter zunehmende Empfindlichkeit konnte nachgewiesen werden.

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Effect of phytohormones on germination and development of fern prothalliaII. Analysis of the correlations between the concentration of gibberellic acid, induction of antheridia, and physiological age of the prothallium cells of Anemia phyllitidis L.

Summary Gametophytes of six species of the family Schizaeaceae were exposed to gibberellins. In all six species gibberellin can replace the natural hormones inducing the formation of antheridia (antheridogens). This process of cell differentiation was analyzed in detail in gametophytes of Anemia phyllitidis.After an induction by gibberellic acid the formation of antheridia is preceded by a slow-down of the rate of cell division.The induction of antheridia is possible only after a certain state of development of the prothalli has been reached. This critical physiological age is highest at lowest gibberellin concentrations. The relationship can be characterized by a critical cell number (as defined in the paper).This criterion is independent of the growth rate of the gametophytes.The close correlation between hormone titer and time of induction indicates an at least change is sensitivity toward gibberellins in certain defined regions of the prothalli during the course of ontogenesis. With increasing physiological age an increase in sensitivity has been measured.

     

Prolindehydrogenase aus keimenden farnsporen

A soluble enzyme which converts proline to glutamic acid using NAD as coenzyme was isolated from young prothallia and spores of the fern Anemia phyllitidis. The purification was about 36-fold. The pH optimum is between 10·2 and 10·7; the K_m for proline is 4·6 × 10⁻⁴ M and for NAD 3·4 × 10⁻⁴ M. There are no multiple forms of this enzyme, as proved by gel electrophoresis.     

Engineering thermophilic Geobacillus thermoglucosidasius for riboflavin production

The potential advantages for fermentation production of chemicals at high temperatures are attractive, such as promoting the rate of biochemical reactions, reducing the risk of contamination and the energy consumption for fermenter cooling. In this work, we de novo engineered the thermophile Geobacillus thermoglucosidasius to produce riboflavin, since this bacterium can ferment diverse carbohydrates at an optimal temperature of 60°C with a high growth rate. We first introduced a heterogeneous riboflavin biosynthetic gene cluster and enabled the strain to produce detectable riboflavin (28.7 mg l⁻¹). Then, with the aid of an improved gene replacement method, we preformed metabolic engineering in this strain, including replacement of ribC_Gtg with a mutant allele to weaken the consumption of riboflavin, manipulation of purine pathway to enhance precursor supply, deletion of ccpN_Gtg to tune central carbon catabolism towards riboflavin production and elimination of the lactate dehydrogenase gene to block the dominating product lactic acid. Finally, the engineered strain could produce riboflavin with the titre of 1034.5 mg l⁻¹ after 12-h fermentation in a mineral salt medium, indicating G. thermoglucosidasius is a promising host to develop high-temperature cell factory of riboflavin production. This is the first demonstration of riboflavin production in thermophilic bacteria at an elevated temperature.     

Cell number,cell growth,antheridiogenesis, and callose amount is reduced and atrophy induced by deoxyglucose in <Emphasis Type="Italic">Anemia phyllitidis</Emphasis> gametophytes

Fluorescence staining and morphometrical measurements revealed that callose was a component of newly formed cell plates of symmetrically dividing cells and asymmetrically dividing antheridial mother cells during gibberellic acid-induced antheridiogenesis as well as in walls of young growing cells of Anemia phyllitidis gametophytes. Callose in cell walls forms granulations characteristic of pit fields with plasmodesmata. 2-deoxy-d-glucose (DDG), eliminated callose granulations and reduced its amount estimated by measurements of fluorescence intensity. This effect was accompanied by reduction of antheridia and cell numbers as well as size and atrophy of particular cells and whole gametophytes. It is suggested that inhibition of glucose metabolism and/or signalling, might decrease callose synthesis in A. phyllitidis gametophytes leading to its elimination from cell plates of dividing cells and from walls of differentiating ones as well as from plasmodesmata resulting in inhibition of cytokinesis, cell growth and disruption of the intercellular communication system, thus disturbing developmental programs and leading to cell death.     

Importance of malate synthase in the glyoxylate cycle of <Emphasis Type="Italic">Ashbya gossypii</Emphasis> for the efficient production of riboflavin

The glyoxylate cycle is an anabolic pathway that is necessary for growth on nonfermentable carbon sources such as vegetable oils and is important for riboflavin production by the filamentous fungus Ashbya gossypii. The aim of this study was to identify malate synthase in the glyoxylate cycle of A. gossypii and to investigate its importance in riboflavin production from rapeseed oil. The ACR268C gene was identified as the malate synthase gene that encoded functional malate synthase in the glyoxylate cycle. The ACR268C gene knockout mutant lost malate synthase activity, and its riboflavin production and oil consumption were 10- and 2-fold lower, respectively, than the values of the wild-type strain. In contrast, the ACR268C gene-overexpressing strain showed a 1.6-fold increase in the malate synthase activity and 1.7-fold higher riboflavin production than the control strain. These results demonstrate that the malate synthase in the glyoxylate cycle has an important role not only in riboflavin production but also in oil consumption.     

Insertional disruption of the nusB (ssyB) gene leads to cold-sensitive growth of Escherichia coli and suppression of the secY24 mutation

Summary The Escherichia coli gene ssyB was cloned and sequenced. The ssyB63 (Cs) mutation is an insertion mutation in nusB, while the nusB5 (Cs) mutation suppresses secY24, indicating that inactivation of nusB causes cold-sensitive cell growth as well as phenotypic suppression of secY24. The correct map position of nusB is 9.5 min rather than I I min as previously assigned. It is located at the distal end of an operon that contains a gene showing significant homology with a Bacillus subtilis gene involved in riboflavin biosynthesis.     

Effect of oxygen on the per‐cell extracellular electron transfer rate of Shewanella oneidensis MR‐1 explored in bioelectrochemical systems

Extracellular electron transfer (EET) is a mechanism that enables microbes to respire solid‐phase electron acceptors. These EET reactions most often occur in the absence of oxygen, since oxygen can act as a competitive electron acceptor for many facultative microbes. However, for Shewanella oneidensis MR‐1, oxygen may increase biomass development, which could result in an overall increase in EET activity. Here, we studied the effect of oxygen on S. oneidensis MR‐1 EET rates using bioelectrochemical systems (BESs). We utilized optically accessible BESs to monitor real‐time biomass growth, and studied the per‐cell EET rate as a function of oxygen and riboflavin concentrations in BESs of different design and operational conditions. Our results show that oxygen exposure promotes biomass development on the electrode, but significantly impairs per‐cell EET rates even though current production does not always decrease with oxygen exposure. Additionally, our results indicated that oxygen can affect the role of riboflavin in EET. Under anaerobic conditions, both current density and per‐cell EET rate increase with the riboflavin concentration. However, as the dissolved oxygen (DO) value increased to 0.42 mg/L, riboflavin showed very limited enhancement on per‐cell EET rate and current generation. Since it is known that oxygen can promote flavins secretion in S. oneidensis, the role of riboflavin may change under anaerobic and aerobic conditions. Biotechnol. Bioeng. 2017;114: 96–105. © 2016 The Authors. Biotechnology and Bioengineering Published by Wiley Periodicals, Inc.     

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     

Metabolic engineering of thermophilic Bacillus methanolicus for riboflavin overproduction from methanol

The growing need of next generation feedstocks for biotechnology spurs an intensification of research on the utilization of methanol as carbon and energy source for biotechnological processes. In this paper, we introduced the methanol-based overproduction of riboflavin into metabolically engineered Bacillus methanolicus MGA3. First, we showed that B. methanolicus naturally produces small amounts of riboflavin. Then, we created B. methanolicus strains overexpressing either homologous or heterologous gene clusters encoding the riboflavin biosynthesis pathway, resulting in riboflavin overproduction. Our results revealed that the supplementation of growth media with sublethal levels of chloramphenicol contributes to a higher plasmid-based riboflavin production titre, presumably due to an increase in plasmid copy number and thus biosynthetic gene dosage. Based on this, we proved that riboflavin production can be increased by exchanging a low copy number plasmid with a high copy number plasmid leading to a final riboflavin titre of about 523 mg L⁻¹ in methanol fed-batch fermentation. The findings of this study showcase the potential of B. methanolicus as a promising host for methanol-based overproduction of extracellular riboflavin and serve as basis for metabolic engineering of next generations of riboflavin overproducing strains.     

Identification and characterization of a brilliant yellow pigment produced by Bordetella pertussis

Culture supernatants of Bordetella pertussis are a brilliant yellow; however, the structure and biological role of the responsible pigment have not been investigated. In this study, a brilliant yellow‐colored fraction was extracted from culture supernatants of B. pertussis and analyzed by HPLC. UV–visible spectral analysis and mass spectrometry identified the brilliant yellow pigment as riboflavin. Riboflavin production was high in lag and early log phases and riboflavin was found to enhance growth of B. pertussis in low‐density cultures. Riboflavin production is not regulated by the BvgAS system. In addition, it was found that other Bordetella species, such as B. parapertussis , B. holmesii and B. bronchiseptica, also release riboflavin into their culture supernatants. This is the first report that B. pertussis secrets riboflavin to the extracellular space and that riboflavin may promote its growth. The mechanism may be associated with pathogenesis of B. pertussis .

     

Apoptin: Specific killer of tumor cells?

In the early 1990s it was discovered that the VP3/Apoptin protein encoded by the Chicken Anemia virus (CAV) possesses an inherent ability to specifically kill cancer cells. Apoptin was found to be located in the cytoplasm of normal cells while in tumor cells it was localized mainly in the nucleus.¹ These differences in the localization pattern were suggested to be the main mechanism by which normal cells show resistance to Apoptin-mediated cell killing. Although the mechanism of action of Apoptin is presently unknown, it seems to function by the induction of programmed cell death (PCD) after translocation from the cytoplasm to the nucleus and arresting the cell cycle at G₂/M, possibly by interfering with the cyclosome.² In addition, cancer specific phosphorylation of Threonine residue 108 has been suggested to be important for Apoptin’s function to kill tumor cells.³ In contrast to the large number of publications reporting that nuclear localization, induction of PCD and phosphorylation of Apoptin is restricted to cancer cells, several recent studies have shown that Apoptin has the ability to migrate to the nucleus and induce PCD in some of the normal cell lines tested. There is evidence that high protein expression levels as well as the cellular growth rate may influence Apoptin’s ability to specifically kill tumor cells. Thus far both in vitro and in vivo studies indicate that Apoptin is a powerful apoptosis inducing protein with a promising prospective utility in cancer therapy. However, here we show that several recent findings contradict some of the earlier results on the tumor specificity of Apoptin, thus creating some controversy in the field. The aim of this article is to review the available data, some published and some unpublished, which either agree or contradict the reported “black and white” tumor cell specificity of Apoptin. Understanding what factors appear to influence its function should help to develop Apoptin into a potent anti-cancer agent.     

A novel cottong ovule culture: Induction, growth, and characterization of submerged cotton fibers (Gossypium hirsutum L.)

Summary The growth of submerged cotton (Gossypium hirsutum L.) fibers from cultured ovules has been investigated. The results indicate that exogenous plant hormone levels regulate the induction of submerged fiber growth. The age of ovules at induction is also important. Cell diameter, wall thickness, and cell length of submerged fibers were measured and compared with air-grown fibers and fibers grown in vivo (produced by cotton plants grown in the greenhouse). Various cellwall thickening patterns were observed among submerged fibers, while only one predominant cell-wall deposition pattern was produced in air-grown fibers and in fibers produced in vivo. The diameter of submerged fibers was about the same as that of air-grown fibers but about 22% less than that of fibers grown, in vivo. It appears that the secondary cell wall thickenings are initiated earlier in submerged fibers. The cell-wall thickness of submerged fibers, at 41 d post anthesis (DPA), was 51% greater than that of fibers grown in vivo, whereas the cell-wall thickness of air-grown fibers was 42% less than that of fibers produced in vivo. The cell length of submerged fibers was approximately half that of fibers grown in vivo. and the air-grown fiber length was about two-thirds of fibers grown in vivo. The age of ovules at induction affects the outcome of the air-grown fiber-cell length, but does not appear to affect the length of submerged fiber cells. To produce submerged fiber growth, we found that the optimal age of ovules at induction was 0 DPA, and the optimal medium (with a GA₃ of 0.5 μM and an IAA range of 5-20 μM) depends on the time of ovule induction (−2 to+2DPA). We conclude that conditions leading to submerged cotton fiber growth have great potential for (a) direct monitoring of growth and making precise, detailed measurements during fiber growth and development; (b) producing cellulose and fibers in vitro more efficiently than earlier ovule-culture methods; and (c) using these unique cultures to obtain a better understanding of signal transduction and gene expression leading to growth, development, and programmed cell death in the life history of the cotton fiber.