THE REVERSIBLE HEAT ACTIVATION INDUCING GERMINATION AND INCREASED RESPIRATION IN THE ASCOSPORES OF NEUROSPORA TETRASPERMA

The heat activation of Neurospora tetrasperma ascospores is a reversible process, since activated spores may be returned to secondary dormancy by preventing respiration, and these secondarily dormant spores may be induced to germinate by reheating. Activation of the spores brings about a large increase in respiration prior to the germination of the spores. As the spores are reversibly activated or deactivated the rate of respiration is increased or is decreased. By poisoning the cells with iodoacetamide it is possible to prevent all germination without greatly inhibiting this increase in respiration. Precisely with the beginning of germination a secondary rise in respiration occurs. The respiration of the spores is cyanide sensitive. The heat activation has a critical temperature at about 49 to 52°C.; and at a constant temperature within this range, the percentage of the spores activated as plotted against the time, follows an S-shaped population curve.     

The Stimulation of Spore Germination in Agaricus bisporus by Organic Acids

Germination of Agaricus bisporus spores is stimulated by vapourdiffusing from dilute solutions of various short-chain fattyacids, especially uo-valeric acid. No increase in germinationwas found in spores treated with succinic acid. All these compoundsinhibited spore germination at concentrations above the optimallevel. An examination of the influence of hydrogen-ion concentrationon germination is also reported. It is suggested that the germination-stimulatingactivity of the acids tested is not a pH effect but is due todirect entry of these compounds into metabolic pathways, particularlythose of fat metabolism. The prominent oil reserves in thesespores suggests a system analogous to that of rust uredospores,the respiration and germination of which is stimulated by short-chainfatty acids, contributing both to the respired carbon dioxideand the for-mation of new cell materials.     

Characteristics of exogenous dormancy of Aspergillus niger conidia]

Aspergillus niger conidia are characterized by exogenous dormancy: the first stage of their germination is accomplished in twice distilled water. However, germ tube formation requires the availability of carbon and nitrogen sources. Exogenous dormancy in A. niger conidia exhibits the following peculiar features: (i) nitrogen-containing substances are active stimulators of germination; (ii) temperature-dependent changes in the lipid bilayer and in the neutral lipid composition of conidia are virtually identical to those occurring in growing mycelium under temperature stress; and (iii) the spore viability threshold does not exceed 45 degrees C; i.e., the spores are more heat-resistant than the mycelium, but they are less heat-resistant than the spores that are in the state of endogenous dormancy. According to the current classification of the types of cell metabolism arrest, the exogenous dormancy of A. niger conidia resembles the pattern of metabolism characteristic of vegetative cells during the idiophase.     

Peculiarities of Exogenous Dormancy of Aspergillus nigerConidia

Aspergillus nigerconidia are characterized by exogenous dormancy: the first stage of their germination is accomplished in twice-distilled water. However, germ tube formation requires the availability of carbon and nitrogen sources. Exogenous dormancy in A. nigerconidia exhibits the following peculiar features: (i) nitrogen-containing substances are active stimulators of germination; (ii) temperature-dependent changes in the lipid bilayer and in the neutral lipid composition of conidia are virtually identical to those occurring in growing mycelium under temperature stress; and (iii) the spore viability threshold does not exceed 45°C; i.e., the spores are more heat-resistant than the mycelium, but they are less heat-resistant than the spores that are in the state of endogenous dormancy. According to the current classification of the types of cell metabolism arrest, the exogenous dormancy of A. nigerconidia resembles the pattern of metabolism characteristic of vegetative cells during the idiophase.     

Endogenous respiration and regulation in a primitive marine fungus

The relationship between the respiration and the presence and utilization of endogenous and exogenous substrates was studied in the non-filamentous obligately marine fungus Thraustochytrium aureum. Using isotopic and manometric methods, it was shown that almost all exogenous glucose is assimilated, whilst almost all the oxygen consumption in the presence of exogenous glucose was due to oxidation of endogenous reserves. In contrast, exogenous glutamate, which cannot serve as the sole carbon source for growth, inhibits respiration of endogenous materials, and is itself rapidly oxidized. The uncoupler 2,4-dinitrophenol stimulates the oxidation of endogenous reserves without affecting the uptake and use of exogenous glucose. These data strongly support the idea of physiologic compartmentation in this organism.     

Endogenous metabolism of fungus spores: stimulation by physical and chemical means

Endogenous respiration of spores of the fungus Myrothecium verrucaria can be stimulated up to over-10 fold by diverse chemicals or by physical treatments. Greatest effects were caused by azide (12-fold at 250 μm) and by 2,4-dinitrophenol (7-fold at 300 μm). Marked stimulation was also caused by 10 μm silver (5-fold), 30 μm pentachlorophenol (6-fold), 10 μm carbonyl cyanide m-chlorophenyl hydrazone (4.5-fold) and 10 μm merthiolate (4-fold). Physical treatments such as heat (50 C), freezing, and sonication at sublethal levels were also stimulatory. Stimulation by azide or dinitrophenol was much greater in young than in old spores, whereas response to other chemicals and to freezing was relatively unaffected by spore age. In older spores the effect of azide was no greater than some other inhibitors. During incubation with azide, the endogenous trehalose reserves decreased and changes in free amino acids occurred, both increases and decreases. Thus anabolic as well as catabolic changes occur as evidenced also by the germination of a few (up to 5%) spores. The mechanisms of stimulation must be varied and complex. Permeability changes in the membrane confining endogenous reserves are proposed as a common initial cause. Additional changes in characteristics of membranes of other subcellular particles, as well as enzymic phenomena such as uncoupling of oxidative phosphorylation, are presumably involved in instances where greater stimulation occurs. The data are consistent with the hypothesis that dormancy in these spores results from separation of substrates from metabolic enzymes and more specifically that metabolites are sequestered rather than enzymes.     

SPORE GERMINATION AND CARBON METABOLISM IN FUSARIUM SOLANI. II. ENDOGENOUS RESPIRATION IN RELATION TO GERMINATION

Cochrane , V. W., Jean C. Cochrane , C. b . Collins , and F. G. Serafin . (Wesleyan U., Middletown, Conn.) Spore germination and carbon metabolism in Fusarium solani. II. Endogenous respiration in relation to germination. Amer. Jour. Bot. 50(8): 806–814. Illus. 1963.—Endogenous oxygen uptake by ungerminated macroconidia of Fusarium solani f. phaseoli is more than doubled by exogenous ammonium ion and is increased about 7-fold by germination. The respiratory quotient is halved by the provision of ammonia, which has essentially no effect on the endogenous formation of carbon dioxide. Stimulation by azide and 2,4-dinitrophenol suggests that the supply of phosphate acceptors regulates the rate of endogenous respiration. Mercurials poison the endogenous respiration, cyanide accelerates it, and iodoacetate, arsenite, fluoride, and chelating agents have little effect. Respiration is little affected by changes in pH, external phosphate, oxygen concentration, and spore density, within the limits tested. Spore lipid concentration is increased by cultivation in a high-glucose medium, but this variation in lipid content of spores docs not affect the endogenous Qo₂, nor does a high lipid content abolish the requirement for exogenous carbon for germination. Lipid utilization during endogenous respiration accounts for 37% of the loss in dry weight; lipid is also utilized during germination, but such utilization amounts to only about 5% of the carbon requirement. Neither mannitol nor nitrogenous compounds are significant substrates of endogenous respiration. The oxidation of the exogenous substrates tested does not measurably affect the concomitant rate of endogenous respiration. It is proposed that endogenous respiration can contribute to the synthetic processes of spore germination, although quantitatively insufficient to support germination without exogenous carbon. It is also questioned whether the respiratory quotient is an adequate index of the substrate of endogenous respiration.     

Germination of spores of mycelial fungi in relation to exogenous dormancy

Comparative analysis of germination of asexual sporulation spores (conidia and sporangiospores) and of specific features of dormancy release was carried out for ascomycete mycelial fungi Aspergillus tamarii VKM F-64 and A. sydowii VKM F-441, as well as for zygomycete fungi Cunninghamella echinulata VKM F-663 and Umbelopsis ramanniana VKM F-582. The spores of these strains were shown to be in a state of exogenous dormancy and differed in lag phase duration and germination rate, which depended on the presence of nutrients in the medium. Only the strain C. echinulata VKM F-663 exhibited 100% spore germination, with the germination rate and lag phase duration not depending on the composition of the medium. While in A. tamarii strain VKM F-64, the total number of spores germinating on rich and poor media was also almost the same, in the absence of nutrients lag phase duration increased and the germination rate decreased. For strains U. ramanniana VKM F-582 and A. sydowii VKM F-441, the degree of spore germination in the absence of nutrients in the medium was considerably lower than on the rich medium, while the lag phase was longer. These data indicate that the spores of C. echinulata VKM F-663 are in the state of exogenous dormancy, which does not require for release any compounds except water. The spores of U. ramanniana strain VKM F-582 and of the Aspergillus strains exhibited another variant of exogenous dormancy, which required for release, apart from water, also the sources of carbon and nitrogen. Thus, the character of dormancy release may differ even within a single genus (Aspergillus).     

Zygospore overwintering and sporulative germination in Triplosporium fresenii (Entomophthoraceae) attacking Aphis spiraecola on citrus in Israel

Triplosporium (Entomophthora) fresenii overwinters on citrus trees in Israel as zygospores which germinate in March and April by means of capillary conidiophores bearing capillispores (anadhesive conidia) in synchronization with spring buildup of Aphis spiraecola populations on citrus. The minimum temperature for zygospore germination in Israel is about 9–10°C. In the zygospore population there is variability regarding time needed to break dormancy and temperature needed for germination, which is gradual, its cumulative curve being sigmoidally shaped. Some evidence suggests that dormancy is of the endogenous type. The variability and the ability to overwinter on trees as resting spores are assumed to give T. fresenii an advantage over other Entomophthoraceae present on the same host in spring.     

Role of Endogenous Growth Regulators in Seed Dormancy of Avena fatua: I. Short Chain Fatty Acids

The hypothesis that endogenous short chain fatty acids (C 6-C 10) are important in maintaining seeds of wild oat (Avena fatua L.) in the dormant state by acting as natural germination inhibitors (Berrie, Buller, Don, Parker, 1979 Plant Physiol 63: 758-764) was investigated. When germination of nondormant seeds was inhibited by treatment with short chain fatty acids, the seeds did not revert to a similar biochemical and physiological state as exhibited by dormant seeds. First, nonanoic acid-induced inhibition of seed germination was not reversed by hormone treatments which normally break dormancy in wild oat seeds. Second, nondormant seeds treated with short chain fatty acids maintained similar relative proportions of the pentose phosphate pathway and the Embden-Meyerhoff-Parnas pathway for respiratory glucose metabolism as that found in the nondormant controls. Seeds imbibed in the presence of nonanoic acid lost more amino acids and proteins into the imbibition solution than did the untreated controls, suggesting membrane damage had occurred. Inasmuch as increasing concentrations of nonanoic acid also progressively reduced the growth of the coleoptile and roots of intact seedlings until all growth ceased and no germination occurred, the inhibition of seed germination could be due to a nonspecific inhibition of growth of the embryo, perhaps because of disruption of membrane structure and function. Finally, no correlation between endogenous levels of short chain fatty acids in seeds or isolated embryonic axes and seed dormancy could be demonstrated.     

Analysis of respiration during germination and enlargement of spores of Bacillus megaterium and of the fungus Myrothecium verrucaria

1. There are certainly two, and probably three, stages in the development of B. megaterium from the spore to inception of cell division. The rapid increase in rate of respiration during the initial 10 minutes on glucose-peptone-yeast extract medium coincides with decrease in optical density and with increase in stainability. From about 10 to 100 minutes, the rate increases linearly, coinciding with swelling of the spores and ending at approximately the time of rupture of the spore case. From about 100 to 180 minutes, there is a second and steeper linear increase in respiration rate coinciding with cell elongation. These physiological and morphological phenomena are discussed as criteria for germination. 2. The rate of respiration of M. verrucaria spores also increases linearly up to about 300 minutes in sucrose-yeast extract medium. No breaks in the curves are observed during formation of the germ tubes. 3. Oxygen uptake follows the parabolic curve See PDF for Equation within the limits of experimental error for both types of spores. 4. It is postulated that metabolism during these stages of linear increase may be regulated by processes occurring at cellular or intracellular surfaces or by synthesis of a limiting enzyme at constant rate.     

Properties of the germination inhibitor of Streptomyces viridochromogenes spores

Germinating spores of Streptomyces viridochromogenes excreted a substance into the surrounding medium which inhibited germination of another sample of the spores. The germination inhibitor (GI) was produced during submerged culture after exponential growth had ceased. The GI was purified 51-fold following extraction from growth liquor with chloroform. It was soluble in alcohol and water and had a molecular weight of less than 1000. The GI blocked growth and respiration of some Gram-positive bacteria and was an inhibitor of the membrane bound, but not solubilized, calcium-dependent ATPase of germinated spores and mycelia of the producing organism. Several sodium-potassium activated ATPases were also inhibited. All four activities (respiration, growth, germination inhibition, ATPase) co-purified during column and thin-layer chromatography. The GI activities released during germination and produced during growth were identical. A role for the GI antibiotic in regulation of dormancy of spores of the producing organism is discussed.     

Pulling the trigger: the mechanism of bacterial spore germination

In spite of displaying the most extreme dormancy and resistance properties known among living systems, bacterial endospores retain an alert environment-sensing mechanism that can respond within seconds to the presence of specific germinants. This germination response is triggered in the absence of both germinant and germinant-stimulated metabolism. Genes coding for components of the sensing mechanism in spores of Bacillus subtilis have been cloned and sequenced. However, the molecular mechanism whereby these receptors interact with germinants to initiate the germination response is unknown. Recent evidence has suggested that in spores of Bacillus megaterium KM, proteolytic activation of an autolytic enzyme constitutes part of the germination trigger reaction.     

Resting Spore Dormancy and Infectivity Characteristics of the Potato Powdery Scab Pathogen Spongospora subterranea

The soil‐borne potato pathogen Spongospora subterranea persists in soil as sporosori, which are aggregates of resting spores. Resting spores may germinate in the presence of plant or environmental stimuli, but direct evidence for resting spore dormancy is limited. A soilless tomato bait plant bioassay and microscopic examination were used to examine features of S. subterranea resting spore dormancy and infectivity. Dried sporosori inocula prepared from tuber lesions and root galls were infective after both short‐ and long‐term storage (1 week to 5 years for tuber lesions and 1 week to 1 year for root galls) with both young and mature root galls inocula showing infectivity. This demonstrated that a proportion of all S. subterranea resting spores regardless of maturity exhibit characteristics of stimuli‐responsive dormancy, germinating under the stimulatory conditions of the bait host plant bioassay. However, evidence for constitutive dormancy within the resting spore population was also provided as incubation of sporosorus inoculum in a germination‐stimulating environment did not fully exhaust germination potential even after 2.4 years. We conclude that S. subterranea sporosori contain both exogenous (stimuli‐responsive) and constitutively dormant resting spores, which enables successful host infection by germination in response to plant stimuli and long‐term persistence in the soil.     

Biochemical Studies of Bacterial Sporulation and Germination XVII. Sulfhydryl and Disulfide Levels in Dormancy and Germination

A fourfold increase in sulfhydryl content upon germination of Bacillus megaterium spores was observed by the standard fluorescein mercuric acetate assay as reported by others. However, assay of ruptured dormant spores or the use of N-ethylmaleimide and a denaturing agent on intact spores showed a constant sulfhydryl level in dormancy and in germination. The apparent increase in sulfhydryl groups observed on germination was shown to be due to inaccessibility of most sulfhydryl groups in the dormant spore to sulfhydryl reagents. The disulfide content of dormant spores showed no change on germination, nor was any evidence found for production of low-molecular-weight sulfhydryl or disulfide compounds during germination.     

The Bacillus anthracis SleL (YaaH) protein is an N-acetylglucosaminidase involved in spore cortex depolymerization

Bacillus anthracis spores, the infectious agents of anthrax, are notoriously difficult to remove from contaminated areas because they are resistant to many eradication methods. These resistance properties are due to the spore's dehydration and dormancy and to the multiple protective layers surrounding the spore core, one of which is the cortex. In order for B. anthracis spores to germinate and resume growth, the cortex peptidoglycan must be depolymerized. This study reports on analyses of sleL (yaaH), which encodes a cortex-lytic enzyme. The inactivation of sleL does not affect vegetative growth, spore viability, or the initial stages of germination, including dipicolinic acid release. However, mutant spores exhibit a slight delay in the loss of optical density compared to that of wild-type spores. Mutants also retain more diaminopimelic acid and N-acetylmuramic acid during germination than wild-type spores, suggesting that the cortex peptidoglycan is not being hydrolyzed as rapidly. This finding is supported by high-pressure liquid chromatography analysis of the peptidoglycan structure used to confirm that SleL acts as an N-acetylglucosaminidase. When sleL is inactivated, the cortex peptidoglycan is not depolymerized into small muropeptides but instead is retained within the spore as large fragments. In the absence of the sleL-encoded N-acetylglucosaminidase, other cortex-lytic enzymes break down the cortex peptidoglycan sufficiently to allow rapid germination and outgrowth.     

Thyroxine signal transduction in liver cells involves phospholipase C and phospholipase D activation. Genomic independent action of thyroid hormone

Background

Many eukaryotes, including plants and fungi make spores that resist severe environmental stress. The micro-organism Dictyostelium contains a single phospholipase C gene (PLC); deletion of the gene has no effect on growth, cell movement and differentiation. In this report we show that PLC is essential to sense the environment of food-activated spores.

Results

Plc-null spores germinate at alkaline pH, reduced temperature or increased osmolarity, conditions at which the emerging amoebae can not grow. In contrast, food-activated wild-type spores return to dormancy till conditions in the environment allow growth. The analysis of inositol 1,4,5-trisphosphate (IP₃) levels and the effect of added IP₃ uncover an unexpected mechanism how PLC regulates spore germination: i) deletion of PLC induces the enhanced activity of an IP₅ phosphatase leading to high IP₃ levels in plc-null cells; ii) in wild-type spores unfavourable conditions inhibit PLC leading to a reduction of IP₃ levels; addition of exogenous IP₃ to wild-type spores induces germination at unfavourable conditions; iii) in plc-null spores IP₃ levels remain high, also at unfavourable environmental conditions.

Conclusions

The results imply that environmental conditions regulate PLC activity and that IP₃ induces spore germination; the uncontrolled germination of plc-null spores is not due to a lack of PLC activity but to the constitutive activation of an alternative IP₃-forming pathway.     

Analysis of the Loss in Heat and Acid Resistance during Germination of Spores of Bacillus Species

A major event in the nutrient germination of spores of Bacillus species is release of the spores'' large depot of dipicolinic acid (DPA). This event is preceded by both commitment, in which spores continue through germination even if germinants are removed, and loss of spore heat resistance. The latter event is puzzling, since spore heat resistance is due largely to core water content, which does not change until DPA is released during germination. We now find that for spores of two Bacillus species, the early loss in heat resistance during germination is most likely due to release of committed spores'' DPA at temperatures not lethal for dormant spores. Loss in spore acid resistance during germination also paralleled commitment and was also associated with the release of DPA from committed spores at acid concentrations not lethal for dormant spores. These observations plus previous findings that DPA release during germination is preceded by a significant release of spore core cations suggest that there is a significant change in spore inner membrane permeability at commitment. Presumably, this altered membrane cannot retain DPA during heat or acid treatments innocuous for dormant spores, resulting in DPA-less spores that are rapidly killed.     

On the presence of calmodulin-like protein in mycobacteria

Abstract Endogenous elemental sulfur (S⁰) has been studied in dormant spores and in spores in the early stages of germination, of Phomopsis viticola . S⁰ was measured by high-pressure liquid chromatography (HPLC). The rapid and almost total disappearance of endogenous S⁰ during the early stages of spore germination was directly related to a sharp increase of the respiratory activity and the ATP concentration. This was followed by the synthesis of DNA, RNA, proteins and lipids. Respiratory activity, S⁰ reduction and germination were inhibited in high concentrations of spores. Endogenous S⁰ disappearance, due to its reduction at the level of the mitochondrial respiratory chain with hydrogen sulfide production, may play a key role in the breaking of dormancy and the induction of germination in spores of P. viticola .