Effects of intracellular trehalose content on Streptomyces griseus spores.

The disaccharide trehalose is accumulated as a storage product by spores of Streptomyces griseus. Growth on media containing excess glucose yielded spores containing up to 25% of their dry weight as trehalose. Spores containing as little as 1% of their dry weight as trehalose were obtained during growth on media containing a limiting amount of glucose. Spores containing low levels of trehalose accumulated this sugar when incubated with glucose. The increase in trehalose content coincided with increases in spore refractility, heat resistance, desiccation resistance, and the time required for spore germination in complex media. Trehalose is accumulated by a wide variety of actinomycetes and related bacteria and may be partially responsible for their resistance properties.     

Regulation of trehalose metabolism by Streptomyces griseus spores.

Spores of Streptomyces griseus contain trehalose and trehalase, but trehalose is not readily hydrolyzed until spore germination is initiated. Trehalase in crude extracts of spores, germinated spores, and mycelia of S. griseus had a pH optimum of approximately 6.2, had a Km value for trehalose of approximately 11 mM, and was most active in buffers having ionic strengths of 50 to 200 mM. Inhibitors or activators or trehalase activity were not detected in extracts of spores or mycelia. Several lines of evidence indicated that trehalose and trehalase are both located in the spore cytoplasm. Spores retained their trehalose and most of their trehalase activity following brief exposure to dilute acid. Protoplasts formed by enzymatic removal of the spore walls in buffer containing high concentrations of solutes also retained their trehalose and trehalase activity. Protoplasts formed in buffer containing lower levels of solutes contained low levels of trehalose. The mechanism by which trehalose metabolism is regulated in S. griseus spores is unresolved. A low level of hydration of the cytoplasm of the dormant spores and an increased level of hydration during germination may account for the apparent inactivity of trehalase in dormant spores and the rapid hydrolysis of trehalose upon initiation of germination.     

Cryopreservation of entrapped monoxenically produced spores of an arbuscular mycorrhizal fungus

A study was conducted to quantify the ability of entrapped, monoxenically produced spores of an arbuscular mycorrhizal fungus to germinate and reproduce the fungal life cycle after cryopreservation. No germination was obtained after incubation of entrapped spores in glycerol and mannitol and subsequent cryopreservation at −70 °C, regardless of the concentration of cryoprotectants and duration of incubation. Incubation for 1 d in 0.5 M sucrose, and for 1 and 2 d in 0.5 M trehalose, led to spore germination after cryopreservation at −70 °C. Lower cryopreservation temperatures were tested with entrapped spores incubated for 1 d in 0.5 M trehalose. The highest germination rate, estimated by the percentage of potentially infective beads (%PIB), was obtained at −100 °C. A %PIB of 95% (water agar medium) to 100% (Strullu–Romand medium) was obtained at this temperature. Thereafter, %PIB rapidly decreased at −140 and −180 °C. Heavy sporulation and high internal root colonization were obtained after re-association of the entrapped spores, incubated for 1 d in 0.5 M trehalose and subsequently cryopreserved at −100 °C, with transformed carrot roots. This demonstrates the ability of entrapped spores to reproduce the fungal life cycle following cold treatment.     

Trehalose breakdown in germinating spores of Mucor rouxii

Germinating spores of Mucor rouxii rapidly broke down their large (23% of the dry weight) trehalose reserve. More than 50% of this trehalose was broken down to ethanol. About one-third of the trehalose was converted to glycerol, which started to leak out of the spores after some 20 min germination. The synthesis of glycerol was not associated with any major change in glycerol 3-phosphatase activity in the spores. Since its rate of leaking was much smaller and the internal concentration reached was much higher in spores subjected to osmotic stress, glycerol might play a role in the initial water uptake and swelling of the germinating spores.     

Role for trehalase during germination of spores in the fission yeast Schizosaccharomyces pombe

Spores from Schizosaccharomyces pombe contain neutral and acid trehalases. When spores from strains disrupted for ntp1(+), which encodes neutral trehalase, were induced to germinate, the onset of the process was markedly delayed as compared to wild-type spores. Further outgrowth was also reduced. Dormant spores lacking neutral trehalase contained twice the amount of trehalose present in wild-type spores and mobilised the intracellular pool of trehalose at a slower rate during germination. Inhibition by phloridzin of the sporulation-specific acid trehalase in ntp1-disrupted spores arrested germination completely while prompting no effect on wild-type spores. These results suggest that the two trehalase enzymes may support the utilisation of trehalose during germination but neutral trehalase is required for a more rapid and efficient process.     

The effect of ultraviolet radiation on the germination of Nosema algerae Vávra and Undeen (Microsporida: Nosematidae) spores

Spores of Nosema algerae Vávra and Undeen were subjected to various dosages of 254 nm ultraviolet radiation (UV). Very high dosages of UV were required to block germination. Germination was normal immediately after UV dosages of 0.2 to 1.0 J/cm2, followed by a delayed effect in which both percentage germination and the intrasporal concentration of trehalose decreased with time after UV exposure. Although a few spores were germinated, most of them were inactivated (rendered temporarily unable to germinate) by exposure to UV of 1.1 J/cm2. Ultraviolet radiation between 1.1 and 3.4 J/cm2 stimulated spores to germinate. However, spores were completely unable to germinate immediately after exposure to dosages above 3.8 J/cm2. Ammonia had little effect on stimulation by UV but was inhibitory to germination after stimulation had occurred. These results demonstrate that UV behaves like a germination stimulus and are discussed in terms of the hypothesis that germination is initiated by the breakdown of barriers between trehalose and trehalase.     

Role of trehalose in the spores of Streptomyces

Abstract Dormant spores of Streptomyces antibioticus contain large amounts of trehalose (11–12% of dry weight) and can be subjected to a dehydration treatment without a significant loss of viability. Loss of dehydration resistance coincided with a decrease in the trehalose level of the spores, under different conditions of incubation. The viability of dehydration-sensitive cells was enhanced by the presence of exogenous trehalose during dehydration. The morphology and functional activity of isolated membranes of S. antibioticus can be retained when dehydrated in the presence of trehalose. It is suggested that, in dormant spores of S. antibioticus , trehalose may serve to protect cellular components during dehydration by acting as a substitute for water.     

Utilization of trehalose during Dictyostelium discoideum spore germination

An analysis of metabolism by measurement of respiratory quotient values indicates that reduced substances, such as lipids and/or amino acids, are the primary respiratory substrates of dormant Dictyostelium discoideum spores. The spores appear to consume both reduced substances and carbohydrates during the swelling stage of germination. The respiration of emerged myxamoebae is again dominated by the consumption of reduced substances. The pool of trehalose remains largely intact during heat-induced activation and also during postactivation lag. The initiation of spore swelling is accompanied by a decrease in the trehalose pool; the majority of trehalose is consumed before late spore swelling. Upon placing heat-activated spores under restrictive environmental conditions, swelling and trehalose hydrolysis are both prevented. Release from these conditions results in rapid swelling and hydrolysis of trehalose. Trehalase, the enzyme responsible for trehalose breakdown, is present in dormant spores at basal levels. This preformed enzyme is responsible for the hydrolysis of trehalose even though there is a significant increase in trehalase activity with the emergence of myxamoebae. RNA and protein synthesis inhibitors do not prevent trehalose hydrolysis or spore swelling. It is concluded that oxidation of reduced substances occurs in dormant, activated, and swollen spores, as well as in emerged myxamoebae of D. discoideum. Carbohydrate utilization dominates over the oxidation of reduced substances only during the swelling stage of germination.     

Metabolism of endogenous trehalose by Streptomyces griseus spores and by spores or cells of other actinomycetes.

The disaccharide trehalose is accumulated as a storage product by spores of Streptomyces griseus. Nongerminating spores used their trehalose reserves slowly when incubated in buffer for several months. In contrast, spores rapidly depleted their trehalose pools during the first hours of germination. Extracts of dormant spores contained a high specific activity of the enzyme trehalase. The level of trehalase remained relatively constant during germination or incubation in buffer. Nongerminating spores of Streptomyces viridochromogenes, Streptomyces antibioticus, and Micromonospora echinospora and nongrowing spherical cells of Arthrobacter crystallopoietes and Nocardia corallina also maintained large amounts of trehalose and active trehalase. These trehalose reserves were depleted during spore germination or outgrowth of spherical Arthrobacter and Nocardia cells into rods.     

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.     

Water potential,glycerol synthesis,and water content of germinating Phycomyces spores

During early germination, the sporangiospores of Phycomyces blakesleeanus synthesized large amounts of glycerol. Glycerol started leaking out of the spores after some 20 min germination. Simultaneously the water content of the spores greatly increased. Water uptake was accompanied by disapperance of the phase contrast halo and an increase in spore cross-sectional area which all occurred during the same period between 10 and 30 min germination. When spores were incubated in 0.5 or 1 M sucrose, glycerol accumulated in the spores to much higher concentrations and the increase in cellular water content was greatly reduced and retarded. Glycerol synthesis and the concomitant lowering of spore osmotic potential was not the only mediator of spore swelling since equally important glycerol concentrations loaded into dormant spores did not cause spore water uptake or swelling. Also the swelling of the spores was less affected than water uptake by decreases in ambient water potential. Apparently also cell wall loosening was involved in the swelling phenomenon which might have important implications for cellular metabolism.     

Biochemical aspects of basidiospore maturation in Agaricus bisporus at various temperatures

Phosphatidylethanolamine is the main phospholipid of Agaricus bisporus basidiospores obtained under sterile conditions from young basidiomes with closed partial veils. Storing the basidiospores for five months at room temperature resulted in a complete loss of their germinating capacity. Conversely, storing them at a low temperature increased their germination rate by 15-20%. At both temperature levels, the phosphatidylcholine ratio significantly increased during storage to the level found in mature basidiospores. In addition, a drastic (8-10-fold) decrease in trehalose content occurred after two months of storage at room temperature. The trehalose content decreased only 1.5-fold at low temperatures. The involvement of trehalose and lipids in the retention of spore viability is discussed.     

Water availability affects the growth,accumulation of compatible solutes and the viability of the biocontrol agent Epicoccum nigrum

Growth of the biocontrol fungus Epicoccum nigrum was more sensitive to ionic solute water stress (NaCl) than non-ionic (glycerol) on potato dextrose-based media at –0.5, –3.0 and –5.5 MPa water potentials. Subsequent physiological manipulation of growth of E. nigrum in glycerol-modified media to –3.0 MPa water potential resulted in a significant increase in the accumulation of compatible solutes in both mycelial liquid cultures and spores, but no enhanced accumulation of the desiccation protectant trehalose, when compared to unmodified media (–0.5MPa). The main solute accumulated was glycerol, followed by arabitol. In temporal studies over 20 days maximum accumulation of glycerol occurred in 5-d old cultures with water stressed cultures having 250× greater amounts than those from unmodified medium. The arabitol content was also higher in mycelium and spores produced under water stress. The difference was maximum after 15 days growth. Glucose content decreased over time in mycelial colonies but increased in spores. The germination of conidia from the two treatments was similar, regardless of compatible solute content, even at –9.25 MPa water potential stress. However, germ tube extension was significantly increased at this water potential level. The production of E. nigrum spores at –3.0 MPa water potential resulted in improved survival when stored fresh at 4 and 25 °C. However, freeze-drying severely affected the viability of spores produced on both media (–0.5 or 3.0 MPa). Accumulation of compatible solutes may assist the fungus in better ecological competence and establishment in the phyllosphere, where water availability is often limited.This revised version was published online in October 2005 with corrections to the Cover Date.     

The Effect of Ultraviolet Radiation on the Germination of Nosema algerae Vávra and Undeen (Microsporida: Nosematidae) Spores1

Spores of Nosema algerae Vávra and Undeen were subjected to various dosages of 254 nm ultraviolet radiation (UV). Very high dosages of UV were required to block germination. Germination was normal immediately after UV dosages of 0.2 to 1.0 J/cm², followed by a delayed effect in which both percentage germination and the intrasporal concentration of trehalose decreased with time after UV exposure. Although a few spores were germinated, most of them were inactivated (rendered temporarily unable to germinate) by exposure to UV of 1.1 J/cm². Ultraviolet radiation between 1.1 and 3.4 J/cm² stimulated spores to germinate. However, spores were completely unable to germinate immediately after exposure to dosages above 3.8 J/cm². Ammonia had little effect on stimulation by UV but was inhibitory to germination after stimulation had occurred. These results demonstrate that UV behaves like a germination stimulus and are discussed in terms of the hypothesis that germination is initiated by the breakdown of barriers between trehalose and trehalase.     

Characterization of spores of Bacillus subtilis which lack dipicolinic acid

Spores of Bacillus subtilis with a mutation in spoVF cannot synthesize dipicolinic acid (DPA) and are too unstable to be purified and studied in detail. However, the spores of a strain lacking the three major germinant receptors (termed Deltager3), as well as spoVF, can be isolated, although they spontaneously germinate much more readily than Deltager3 spores. The Deltager3 spoVF spores lack DPA and have higher levels of core water than Deltager3 spores, although sporulation with DPA restores close to normal levels of DPA and core water to Deltager3 spoVF spores. The DPA-less spores have normal cortical and coat layers, as observed with an electron microscope, but their core region appears to be more hydrated than that of spores with DPA. The Deltager3 spoVF spores also contain minimal levels of the processed active form (termed P(41)) of the germination protease, GPR, a finding consistent with the known requirement for DPA and dehydration for GPR autoprocessing. However, any P(41) formed in Deltager3 spoVF spores may be at least transiently active on one of this protease's small acid-soluble spore protein (SASP) substrates, SASP-gamma. Analysis of the resistance of wild-type, Deltager3, and Deltager3 spoVF spores to various agents led to the following conclusions: (i) DPA and core water content play no role in spore resistance to dry heat, dessication, or glutaraldehyde; (ii) an elevated core water content is associated with decreased spore resistance to wet heat, hydrogen peroxide, formaldehyde, and the iodine-based disinfectant Betadine; (iii) the absence of DPA increases spore resistance to UV radiation; and (iv) wild-type spores are more resistant than Deltager3 spores to Betadine and glutaraldehyde. These results are discussed in view of current models of spore resistance and spore germination.     

Biochemistry of spore germination in Phycomyces

Abstract The constitutionally dormant spores of Phycomyces blakesleeanus can be activated by heat shock or treatment with several monocarboxylic acids. Activation is followed first by a general stimulation of metabolism, e.g. respiration, protein-, RNA- and cell-wall synthesis, and subsequently by nuclear division and germ-tube emergence. Initial germination is not dependent on RNA synthesis and can even start without protein synthesis. The first common effect of different activating treatments is a transient rise in cyclic AMP (cAMP) content, caused by a change in phosphodiesterase activity after heat activation, and by unknown factors during activation by acids. cAMP transiently activates trehalase and glycerol-3-phosphatase in the spores. The activation of these enzymes causes a quick turnover of trehalose into glycerol. During the same period, the water status of the cells is altered so dramatically that perhaps this may explain at least part of the stimulation of metabolism in the germinating spore.     

Trehalose catabolism in microsporidia Nosema grylli spores

Some differences in trehalose catabolism were found for terrestrial and aquatic microsporidian species (Undeen, Van der Meer, 1999). In microsporidia species from aquatic hosts, the spore extrusion causes the intrasporal trehalose hydrolysis by trehalase that is followed by the drastic rise of reducing sugars (glucose) concentration. On the contrary, in tested terrestrial microsporidian species, total and reducing sugars remain unchanged through the germination. In this study we demonstrate by means of the enzymatic and paper chromatography methods, that in spores of microsporidia Nosema grylli, infecting fat bodies of crickets Gryllus bimaculatus, neither an increase of glucose concentration nor a reduction in intrasporal trehalose content takes place during the spore discharge. In this respect N. grylli is close to other terrestrial species. However, we have revealed in N. grylli spores activity of alpha,alpha-trehalase (EC 3.2.1.28) with acid pH-optimum like it was found by other authors in spores of aquatic microsporidia N. algerae. This result differs from the neutral pH-optimum (7.0) of trehalse of other terrestrial microsporidia N. apis. Concentration of trehalose in N. grylli spores reduces during long-term storage. All attempts to detect an activity of trehalose phosphorylase (synthase) (K phi 2.4.1.64), other potential key enzyme for trehalose catabolism in N. grylli spores have failed. The absence of changes of the sugar content in terrestrial microsporidian spores during the extrusion indicates, that the main physiological role of trehalose hydrolysis by trehalase in these species is catabolism of energy reserves for providing the long-term survival in the environment.     

Trehalose degradation and glucose efflux precede cell ejection during germination of heat-resistant ascospores of Talaromyces macrosporus

Talaromyces macrosporus forms ascospores that survive pasteurization treatments. Ascospores were dense (1.3 g ml(-1)), relatively dry [0.6 g H(2)O (g dry weight)(-1)] and packed with trehalose (9-17% fresh weight). Trehalose was degraded to glucose monomers between 30 and 100 min after heat activation of the spores. The maximal activity of trehalase was calculated as 400-520 nmol glucose formed min(-1) (mg protein)(-1) as judged by measurements of the trehalose content of spores during germination. During early germination, glucose was released from the cell (10% of the cell weight or more). The intracellular concentration of glucose only peaked briefly. After 160-200 min, the protoplast encompassed by the inner cell wall was ejected through the outer cell wall in a very quick process. Subsequently, respiration of spores increased strongly. The data suggested that trehalose is primarily present for the protection of cell components as glucose is released from the cell. Then, an impenetrable outer cell wall is shed before metabolic activity increases.     

Free proline content and sensitivity to desiccation and heat during yeast sporulation and spore germination.

Ascospores of a strain of Saccharomyces cerevisiae Hansen were less sensitive to desiccation and heat than vegetative cells. Desiccation resistance was acquired earlier during sporulation and lost later during spore germination than heat resistance. As spores matured, resistance to both stresses increased. With the exception of the first few hours in sporulation medium, when proline appeared to be utilized, the intracellular free proline content increased during sporulation and decreased during spore germination. Not all the proline lost could be detected in the germination medium, indicating that some was metabolically utilized by the germinating spores. Since exogenous proline supplied to vegetative or sporulating cells before desiccation increased their survival, it is suggested that the high level of free proline in mature spores may protect against desiccation stress.     

Trehalose as an endogenous reserve in spores of the fungus Myrothecium verrucaria

Mandels, G. R. (U.S. Army Natick Laboratories, Natick, Mass.), Rasma Vitols, and Frederick W. Parrish. Trehalose as an endogenous reserve in spores of the fungus Myrothecium verrucaria. J. Bacteriol. 90:1589-1598. 1965.-Gross analysis of Myrothecium verrucaria spores showed approximately 3% fat, 33% carbohydrate, and 9.5% nitrogen. The water-soluble carbohydrates were trehalose, glucose, mannitol, and an unidentified phosphorylated compound. Water-soluble amino acids include leucine or norleucine (or both), valine, gamma-amino-n-butyric acid, beta-amino-n-butyric acid, ergothionine, glutamic acid, glutamine, glycine, aspartic acid, asparagine, cystine, and cystathionine. Ergosterol was also present. alphaalpha-Trehalose is the major reserve (20% of the dry weight), although approximately 30% of it appeared to be at the spore surface and was released by nonlethal treatment with 0.1 n HCl. Treatment with toluene or exposure to heat sufficient to kill the spores (20 min at 60 C) caused rapid liberation of all of the trehalose. Although spores could utilize exogenous trehalose with no appreciable lag, some stimulus, such as exposure to heat (10 min at 55 C), incubation with azide, or germination on exogenous substrates, was necessary to effect utilization of trehalose reserves. Spores have trehalase, but it is apparently at the spore surface, since it is inactivated by acid treatment which does not kill the spores. The metabolic pathway for utilization of trehalose is not known, but presumably it is not mediated by trehalase. The involvement of mannitol is indicated, since it tends to increase as trehalose decreases, although the changes are not quantitatively equivalent.