Cytochemistry and Ultrastructure of Hyphae and Haustoria of Peronospora parasitica (Pers. ex Fr.) Fr.

The uniform distribution of nuclei, mitochondria, lipid material,protein, and RNA in the hyphae and haustoria of Peronosporaparasitica was demonstrated by staining techniques. Glycogenwas not detected, the only insoluble carbohydrate material detectedby the periodic acid-Schiff reaction being in the fungal wall.The host cell walls reacted more intensely to this stain thanthe hyphal walls. The reaction of haustorial walls varied betweenthe slight staining reaction characteristic of the fungal walls,and the strong reaction of the host cell wall. Callose sheathswere occasionally seen. Fine structure was found to be similar to that of other Oomycetes.Welldeveloped sheaths of a vesicular nature, possibly synonymouswith callose sheaths, were occasionally seen partly surroundinghaustoria.     

Internal Changes in Hyphae of Rhizopus sexualis (Smith) Callen and Mucor hiemalis Wehm. associated with Zygospore Formation

The distribution of nucleic acids, nuclei, mitochondria, andreserve foods in vegetative hyphae, zygophores, and developingzygospores of Rhizopus sexualis and Mucor hiemalis were examinedby differential staining. The extreme tips and growing zones of vegetative hyphae containeda high concentration of RNA and numerous mitochondria. Nucleiwere not present at the extreme tip but were numerous just behindit. In older parts of the hyphae the concentration of RNA waslow and both nuclei and mitochondria were fewer than in thezone of elongation. Glycogen and lipids were present in all parts of the livinghyphae except the extreme tips and were more highly concentratedin the older parts of the hyphae. Young zygophores showed a much lower RNA/DNA ratio than thatfound in the vegetative hyphal tips. Transfer of colonies from20? C to temperatures of less than 10? C, which is known toprevent zygospore initiation, caused some but not all recognizablezygophores of R. sexualis, but not those of M. hiemalis, torevert to the RNA/DNA ratio characteristic of vegetative hyphae.Some zygophores of Rhizopus and most of those of Mucor developedinto sporangiophores at low temperature, retaining the relativelylow RNA/DNA ratio throughout development. It is suggested thata reduction in the RNA/DNA ratio is an early step in the changefrom the vegetative state to the reproductive one. At firstthis step is reversible, but soon becomes irreversible by anadditional step, the nature of which is unknown. For some timeafter this the reproductive hyphae are capable of either producingasexual sporangia or of conjugating to produce zygospores. Onceconjugation has taken place development either ceases or continuesuntil the spore is fully mature, but it cannot under any circumstancesthen be reversed. The development and maturation of the zygospore involves a greatincrease in number of both nuclei and mitochondria and in theconcentration of glycogen and lipids.     

Development of Sporangiophores of Peronospora parasitica (Pers. ex Fr.) Fr.

The morphology of developing sporangiophores of Peronosporaparasitica from wallflower is described, and morphogenesis maybe divided into the following five stages: the sporangiophoreprimordium, unbranched sporangiophore, branched sporangiophore,spore formation and maturation, and formation of the cross wall.The growth of individual sporangiophores in a humidity chamberwas followed under the microscope, and increase in height andincrease in volume measured. The greatest increase in volumewas during spore formation, when the sporangiophore volume mightquadruple within an hour.     

A Cytochemical Study of DNA, RNA, and Protein in the Developing Maize Anther: II. Observations

Changes in acetic-alcohol fixable DNA, RNA, and protein werefollowed in the tapetum, sporogenous tissue, and spores of thedeveloping maize anther using standard cytochemical methodsand microdensitometry. In the tapetum, early nuclear divisionsoccur without prior DNA synthesis, giving a population of IC nuclei. Subsequent synthesis produces the equivalent of 34,000C amounts per pollen sac, 20 times more than is present in thespores before pollen mitosis. The main tapetal RNA synthesisis during the meiotic prophase, with a further period of accumulationin the interval, tetrad to young spores. In the meiocytes, theprincipal accumulation is in the early prophase, with no synthesisduring the meiotic divisions or through the tetrad period. Proteinaccumulation occurs in the tapetum up to mid-meiotic prophase;after this there is a pause, followed by further synthesis frommeiotic metaphase I to the final dissolution of the tissue.In the meiocytes, protein is accumulated through the early prophase;there is no synthesis during the meiotic mitoses or in the tetradperiod, but active accumula-tion occurs in the developing spores. The implications of these observations are discussed in relationto the function of the tapetum.     

Carbohydrate Metabolism During Ascospore Development in Yeast

Carbohydrate metabolism, under sporulation conditions, was compared in sporulating and non-sporulating diploids of Saccharomyces cerevisiae. Total carbohydrate was fractionated into trehalose, glycogen, mannan, and an alkali-insoluble fraction composed of glucan and insoluble glycogen. The behavior of three fractions was essentially the same in both sporulating and non-sporulating strains; trehalose, mannan, and the insoluble fraction were all synthesized to about the same extent regardless of a strain's ability to undergo meiosis or sporulation. In contrast, aspects of soluble glycogen metabolism depended on sporulation. Although glycogen synthesis took place in both sporulating and non-sporulating strains, only sporulating strains exhibited a period of glycogen degradation, which coincided with the final maturation of ascospores. We also determined the carbohydrate composition of spores isolated from mature asci. Spores contained all components present in vegetative cells, but in different proportions. In cells, the most abundant carbohydrate was mannan, followed by glycogen, then trehalose, and finally the alkali-insoluble fraction; in spores, trehalose was most abundant, followed by the alkali-insoluble fraction, glycogen, and mannan in that order.     

Mitochondrial biogenesis during fungal spore germination: respiratory cytochromes of dormant and germinating spores of Botryodiplodia.

The mitochondrial respiratory cytochrome contents of dormant and germinating conidia of Botryodiplodia theobromae were examined. Oxidized versus reduced difference spectra at 77 degrees K of whole mitochondria from physiologically mature germinated spores showed a typical a-band pattern for cytochromes c, b, and a, with absorption maxima at 549, 554 + 559, and 604 nm, respectively, whereas the difference spectrum of the counterpart mitochondrial fraction from dormant spores showed no cytochrome a bands. However, a fraction prepared from dormant spore mitochondria by detergent extraction and (NH4)2SO4 fractionation contained readily detectable quantities of cytochromes c and b (as shown by the a and Soret absorption bands), but it did not contain the a or Soret bands of cytochrome a observed in a counterpart preparation from germinated spores. The pyridine hemochromogen preparation from the dormant spore mitochondria contained no material that is spectroscopically characteristic of a-type heme and protoheme. These results suggest that cytochrome a is not present as a functional molecule in dormant spores. The first spectroscopically detectable cytochromes were observed in whole mitochondria at 210 min of spore germination, and the amount of each of the cytochromes increased with cell growth. A precursor of the heme porphyrin, delta-[4-14C]aminolevulinic acid, was first incorporated (at accelerating rates) into acid-insoluble spore material at 180 min of germination, which appears to be the approximate time of organization of new mitochondria in these spores.     

The Distribution of Cytoplasmic Vesicles, Multivesicular Bodies and Paramural Bodies in Elongating Sporangiophores and Swelling Sporangia of Thamnidium elegans Link

In Thamnidium elegans Link, cytoplasmic vesicles of variablesize were present in large numbers in sporangiophore apicesin agar and in smaller numbers in sporangiophore apices in air.Golgi-like cisternae were associated with small, sub-apicalclusters of vesicles. Apices in agar contained a nucleus andmitochondrion-free tip zone in which vesicles were concentrated.This zone was almost completely absent from apices in air. Inswelling sporangia, vesicles were sparce and were not concentratedagainst the wall. Rates of surface area increase were similarfor sporangiophores elongating, respectively, in agar and inair. Rates of surface area increase during sporangium swellingwere equal to or greater than rates of surface area increaseduring sporangiophore elongation. Vesicles were associated withformation of a secondary wall layer in swollen sporangia. Paramuralbodies and multivesicular bodies were present at all stagesof sporangiophore elongation and sporangium swelling. Isolatedhalo bodies (apical corpuscles) were present in walls at sporangiophoretips, and clusters of similar bodies were present in side wallsof sporangiophores.     

Evidence that the fertilization envelope blocks sperm entry in eggs of Xenopus laevis: interaction of sperm with isolated envelopes.

Single-celled myxamoebae undergo differentiation into either stalk cells or spore cells during a 24-hr period in Dictyostelium discoideum. This study employed ultramicrochemical techniques and enzymatic cycling to assess the presence of cell-specific events in spore and stalk cells. Freeze-dried sections of one organism were assayed in 0.1 μl of reaction mixture. This method was used to determine the extent of localization of trehalose in spore cells and stalk cells during development.Trehalose was low in the early stages of differentiation to about 20 hr when the level started to increase. In developing spore cells, the trehalose level increased sixfold during the last 5 hr of development. Likewise, the entire stalk contained trehalose when the stalk was first formed. At mature sorocarp, trehalose levels were the same in spores and the apex of the stalk. There was a decreasing gradient of trehalose down the stalk. The bottom one-fourth of the stalk was devoid of this disaccharide. Therefore, trehalose was degraded from an area of the stalk where it was localized earlier in development.The results of this investigation negate the assumption that trehalose is never present in the stalk. Although trehalose was found in spore cells, prestalk cells also contained high trehalose levels. The stalk cell-specific trehalose was not retained during differentiation, however, but was apparently degraded in the mature stalk cell.     

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.     

Host-Parasite Relations in Loose Smut of Wheat: III. The Utilization of 14C-Labelled Assimilates

Infection of wheat by Ustilago nuda caused an increased rateof export of radioactivity from the sixth leaf of infected plantsas compared with healthy plants. The ear acted as the most important‘sink’, in both infected and healthy plants. Erythntol,mannitol, and trehalose were present in the infected ears andnodes, but were not present in the healthy plants. Radioactivitywas incorporated into these compounds in the infected ear, andthis was reflected in a lower percentage in the insoluble fractionthan in the healthy ear.     

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.     

Metabolites of the Free-Living Amoeba Phreatamoeba balamuthi Analyzed by 13C- and 31P-NMR Spectroscopy: Occurrence of Phosphoinositol Diphosphates

ABSTRACT. Phreatamoeba balamuthi is a free-living heterotrophic amoeba that lacks mitochondria. Metabolites of axenically-grown cells were characterized by natural-abundance ¹³C-NMR and ³¹P-NMR spectroscopy on acellular perchloric acid extracts. The amoebae were found to contain glycogen and trehalose as storage carbohydrates, together with putrescine and several amino acids, most prominently proline; we propose that proline and trehalose may serve in osmoregulation. Glycerophosphocholine and glycerophosphoethanolamine were present with their phosphomonoester derivatives, phosphocholine and phosphoethanolamine. Along with inorganic phosphate, inorganic pyrophosphate, nucleoside diphosphates, nucleoside triphosphates and NAD, P. balamuthi amoebae also contained unusual phosphoinositol diphosphates in large quantities (0.5 μmol/g wet cells).     

Factors affecting accumulation and degradation of curdlan, trehalose and glycogen in cultures of Cellulomonas flavigena strain KU (ATCC 53703)

Cellulomonas flavigena strain KU (ATCC 53703) is a cellulolytic, Gram-positive bacterium which produces large quantities of an insoluble exopolysaccharide (EPS) when grown in minimal media with a high carbon-to-nitrogen (C/N) ratio. Earlier studies proved the EPS is structurally identical to the linear β-1,3-glucan known as curdlan and provided evidence that the EPS functions as a carbon and energy reserve compound. We now report that C. flavigena KU also accumulates two intracellular, glucose-storage carbohydrates under conditions of carbon and energy excess. These carbohydrates were partially purified and identified as the disaccharide trehalose and a glycogen/amylopectin-type polysaccharide. A novel method is described for the sequential fractionation and quantitative determination of all three carbohydrates from culture samples. This fractionation protocol was used to examine the effects of C/N ratio and osmolarity on the accumulation of cellular carbohydrates in batch culture. Increasing the C/N of the growth medium caused a significant accumulation of curdlan and glycogen but had a relatively minor effect on accumulation of trehalose. In contrast, trehalose levels increased in response to increasing osmolarity, while curdlan levels declined and glycogen levels were generally unaffected. During starvation for an exogenous source of carbon and energy, only curdlan and glycogen showed substantial degradation within the first 24 h. These results support the conclusion that extracellular curdlan and intracellular glycogen can both serve as short-term reserve compounds for C. flavigena KU and that trehalose appears to accumulate as a compatible solute in response to osmotic stress.     

Histochemical observation of the cortical zone of oocyte of Indian wall lizard, Hemidactylus flaviviridis (Rüppel).

The cortical zone of oocytes, which lies just below the follicular epithelium appears in the early stages of development, but reaches its fullest growth in vitellogenic oocytes. In the present studies it was found that the cortical zone of Hemidactylus flaviviridis consists of proteins, lipoproteins, carbohydrates, fatty yolk, RNA and little amount of DNA in mature oocytes along with mitochondria and Golgi bodies. In the early oocyte, this zone is fine granular in nature, but during the yolky stages of oocyte, it becomes filled by the vacuolar structure, which shows in it's the presence of fatty and compound yolk. The L1 and L2 types of lipid globules are also observed in the cortical zone during vitellogenic oocyte.     

Trehalose accumulation in vegetative cells and spores of Myxococcus xanthus.

The disaccharide trehalose is found in the spores and cysts of a variety of organisms. We analyzed developing cells of Myxococcus xanthus for trehalose accumulation. Vegetative cells grown in media with low osmotic strengths contained less than 5 micrograms of trehalose per mg of protein. Spores formed in fruiting bodies accumulated up to 1,100 micrograms of trehalose per mg of protein. Spores formed in liquid culture following the addition of glycerol contained up to 300 micrograms of trehalose per mg of protein. The trehalose contents of both spore types decreased rapidly during the early stages of germination. Trehalase activity was not detected in extracts of dormant or germinating spores. Trehalose accumulation in M. xanthus was also associated with elevated osmotic strength. Vegetative cells accumulated up to 214 micrograms of trehalose per mg of protein when grown in media containing elevated levels of solutes.     

Glycogen and trehalose accumulation during colony development in Streptomyces antibioticus

Streptomyces antibioticus accumulated glycogen and trehalose in a characteristic way during growth on solid medium. Glycogen storage in the substrate mycelium took place during development of the aerial mycelium. The concentration of nitrogen source in the culture medium influenced the time at which accumulation started as well as the maximum levels of polysaccharide stored. Degradation of these glycogen reserves was observed near the beginning of sporulation. The onset of sporogenesis was always accompanied by a new accumulation of glycogen in sporulating hyphae. During spore maturation the accumulated polysaccharide was degraded. No glycogen was observed in aerial non-sporulating hyphae or in mature spores. Trehalose was detected during all phases of colony development. A preferential accumulation was found in aerial hyphae and spores, where it reached levels up to 12% of the cell dry weight. The possible roles of both carbohydrates in the developmental cycle of Streptomyces are discussed.     

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.     

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.     

Carbohydrate Accumulation During the Sporulation of Yeast

The sporulation of Saccharomyces cerevisiae is characterized by an increase in dry weight without cell division. At least 67% of the dry weight increase is due to the synthesis of cellular carbohydrates consisting of trehalose and insoluble components. The insoluble carbohydrates accumulate only during the period preceding the actual formation of visible ascospores. The trehalose accumulates throughout the sporulation cycle and is specifically localized in the ascospore.     

Nucleic acids in coconut water

DNA, RNA and protein present in coconut water are found to bein the soluble form and not associated with any cell organellesi.e., nuclei, mitochondria or ribosomes. DNA and RNA seem tobe degraded or of low molecular weight. That these are not degradedduring isolation is indicated. (Received October 13, 1969; )