Isolation and Preliminary Characterization of Developmental Mutants from Microsporum gypseum

Developmental mutants affected in either sporulation or spore germination have been isolated from Microsporum gypseum with the aid of nitrosoguanidine or as spontaneously occurring mutants. The time course levels of several proteins temporally associated with conidial development have been assayed in the wild-type and mutant strains. The spore germination characteristics of two of the mutants are described. The relationship of alkaline protease accumulation to tyrosinase accumulation and spore germination is discussed.     

Synthesis of teichoic acids. VII. Synthesis of teichoic acids during spore germination

The synthesis of teichoic acids has been examined during germination in Bacillus licheniformis ATCC 9945 and in B. subtilis W-23. Teichoic acids are absent from the spores of both organisms. B. licheniformis spores lack the enzymes responsible for teichoic acid synthesis. The appearance of these enzymes during germination is correlated with the appearance of teichoic acids in the cell. The appearance of teichoic acid-synthesizing enzymes and of teichoic acids in the cell are inhibited by the addition of chloramphenicol to the germination medium. In B. subtilis W-23 the situation is similar for the synthesis of polyribitolphosphate. The synthesis of glucosyl polyribitolphosphate is only partially inhibited by chloramphenicol, puromycin, and penicillin, and uridine diphosphate-d-glucose polyribitol-phosphate glucosyl transferase can be demonstrated in spores. The possible implications of some of these observations are discussed.     

Genetic and biochemical characterization of the galactose gene cluster in Kluyveromyces lactis.

We isolated and identified mutant strains of Kluyveromyces lactis that are defective for the Leloir pathway enzymes galactokinase, transferase, and epimerase, and we termed these loci GAL1 , GAL7 , and GAL10 , respectively. Genetic data indicate that these three genes are tightly linked, having an apparent order of GAL7 - GAL10 - GAL1 . This same gene order has been observed in Saccharomyces cerevisiae. Strains harboring gal7 mutations have elevated levels of beta-galactosidase, coded by an unlinked gene, galactokinase, and epimerase activities under uninduced conditions. We investigated the genetic basis of this constitutive gene expression and found no recombinants between the constitutive and Gal- phenotypes among 76 tetrads, suggesting that either GAL7 or a tightly linked gene codes for a regulatory function. This is the second gene that has been shown to specifically coregulate expression of the genes coding for beta-galactosidase and the Leloir pathway enzymes.     

Constitutive synthesis of enzymes of the protocatechuate pathway and of the beta-ketoadipate uptake system in mutant strains of Pseudomonas putida.

Mutant Pseudomonas putida strains that produce constitutive levels of the beta-ketoadipate uptake system are selected by the sequential transfer of cultures between mineral growth media supplemented with the noninducing growth substrate succinate and growth media containing beta-ketoadipate as the sole carbon and energy source. The mutant strains also produce constitutively three catabolic enzymes that give rise to beta-ketoadipate from the metabolic precursor beta-carboxy-cis, cis-muconate, and thus a single regulatory gene appears to govern the expression of the enzymes as well as the uptake system. The three enzymes that convert beta-carboxy-cis, cis-muconate to beta-ketoadipate are induced to higher levels when the orgainisms are grown with p-hydroxybenzoate (a compound that is catabolized via beta-ketoadipate); the beta-ketoadipate uptake system is partially repressed when the cells are grwon at the expense of p-hydroxybenzoate. The transferase that acts upon beta-ketoadipate remains inducible in the constitutive mutant strains. Thus a minimum of three biosynthetic controls must be exerted over the expression of the five genes. Since the regulatory mutation does not alter the expression of the gene for the transferase, the physiological target of the selection procedure appears to be mutant strains that produce the uptake system constitutively. Levels of the uptake system are higher in uninduced constitutive mutant cultures than in induced cultures of the wild type. Hence procedures analogous to the one we employed may be of general use in obtaining mutant strains that produce high levels of uptake systems.     

Starch phosphorylase enzymes in developing and germinating pea seeds

Phosphorylase has been fractionated during development and germination of seeds of smooth and wrinkled-seeded peas. The total phosphorylase levels have been compared. In addition, a number of other pea tissues and other legumes have been examined. Some kinetic properties of the two enzymes present have been measured. Both enzymes have been further purified by affinity chromatography on Sepharose 4B-starch columns and by sequential gel filtration in the absence and presence of amylopectin. The MW and sub-unit structures of the two enzymes have been examined and their possible roles discussed.     

Enzymatic activities of Microsporum canis and Microsporum gypseum strains.

The presence of 11 enzymatic activities, detected by qualitative methods, and 19 enzymes, semi-quantitatively detected by API ZYM system, in strains belonging to Microsporum canis and Microsporum gypseum has been studied. No pronounced differences were noted between Microsporum canis and Microsporum gypseum, although Microsporum gypseum presented in some cases more intense enzymatic activities than Microsporum canis.     

Correlation between intracellular cAMP levels and phospholipids of Microsporum gypseum.

Atropine, a modulator of cAMP has been used to examine the relationship between phospholipids and intracellular levels of cAMP in Microsporum gypseum. A decreased phospholipid content was observed in atropine grown cells as a result of reduced levels of intracellular cAMP. This decline was caused by the inhibitory effect of atropine on adenylate cyclase. Lowered phospholipid content was supported by decreased [14C]acetate incorporation as well as reduced activities of key enzymes of phospholipid biosynthesis. In vitro supplementation of atropine in control cells also caused inhibition in lipid synthesis indicating similar effects of atropine and its metabolites. These results in conjunction with our previous report, in which enhanced levels of cAMP resulted in increased phospholipid synthesis, suggest a direct correlation between phospholipid biosynthesis and intracellular levels of cAMP in M. gypseum.     

Vitamin E is essential for seed longevity and for preventing lipid peroxidation during germination

Tocopherols (vitamin E) are lipophilic antioxidants synthesized by all plants and are particularly abundant in seeds. Despite cloning of the complete suite of tocopherol biosynthetic enzymes and successful engineering of the tocopherol content and composition of Arabidopsis thaliana leaves and seeds, the functions of tocopherols in plants have remained elusive. To address this issue, we have isolated and characterized two VITAMIN E loci (VTE1 and VTE2) in Arabidopsis that when mutated result in tocopherol deficiency in all tissues. vte1 disrupts tocopherol cyclase activity and accumulates a redox-active biosynthetic intermediate, whereas vte2 disrupts homogentisate phytyl transferase activity and does not accumulate pathway intermediates. Mutations at either locus cause significantly reduced seed longevity compared with the wild type, indicating a critical role for tocopherols in maintaining viability during quiescence. However, only vte2 mutants exhibited severe seedling growth defects during germination and contained levels of lipid hydroperoxides and hydroxy fatty acids elevated up to 4- and 100-fold, respectively, relative to the wild type. These data demonstrate that a primary function of tocopherols in plants is to limit nonenzymatic lipid oxidation during seed storage, germination, and early seedling development. The vte mutant phenotypes also explain the strong selection for retention of tocopherol biosynthesis during the evolution of seed-bearing plants.     

Nicotinamidase activity is important for germination

It has been suggested that nicotinamide must be degraded during germination; however, the enzyme responsible and its physiological role have not been previously studied. We have identified an Arabidopsis gene, NIC2, that is expressed at relatively high levels in mature seed, and encodes a nicotinamidase enzyme with homology to yeast and bacterial nicotinamidases. Seed of a knockout mutant, nic2-1, had reduced nicotinamidase activity, retarded germination and impaired germination potential. nic2-1 germination was restored by after-ripening or moist chilling, but remained hypersensitive to application of nicotinamide or ABA. Nicotinamide is a known inhibitor of NAD-degrading poly(ADP-ribose) polymerases (PARP enzymes) that are implicated in DNA repair. We found reduced poly(ADP)ribosylation levels in nic2-1 seed, which were restored by moist chilling. Furthermore, nic2-1 seed had elevated levels of NAD, and germination was hypersensitive to methyl methanesulphonate (MMS), suggesting that PARP activity and DNA repair responses were impaired. We suggest that nicotinamide is normally metabolized by NIC2 during moist chilling or after-ripening, which relieves inhibition of PARP activity and allows DNA repair to occur prior to germination.     

Isolation and Characterization of Microsporum gypseum Lysosomes: Role of Lysosomes in Macroconidia Germination

Three types of lysosomes containing either acid protease, alkaline protease, or phosphodiesterase were isolated from a Microsporum gypseum macroconidial homogenate on Ficoll gradients. The acid protease was contained in an assimilative lysosome since its activity was affected by the complexity of the exogenous nitrogen source. Ultracentrifugation and electron microscopy revealed that the alkaline protease-containing vesicles were associated with the spore coat material prior to macroconidial germination. During macroconidial germination, zones of spore coat hydrolysis were seen surrounding these vesicles. Other larger vesicles, believed to contain the phosphodiesterase, were also observed in the spore coat during macroconidial germination.     

Aspetti Enzimatici Della Maturazione e Germinazione dei Semi di Ricino

Abstract

Enzyme levels during ripening and germination of castor bean seeds. — During the development of the endosperm of castor bean seeds two distinct phases can be recognized: pre-maturation and germination. The former is characterized, metabolically, by the rapid conversion of carbohydrates into lipids, and storage proteins. The latter is characterized by the reconversion of these storage materials into sugars. Both these processes are dependent upon the activity of the glycolytic pathway; for this reason the behaviour of some enzymes of this pathway and, in general, of the carbohydrate metabolism have been studied during the two phases. The changes (during the evolution of the seeds) of the following enzymes have been studied:

Gl-6-P-dehydrogenase, 6-P-gluconate dehydrogenase, P-glucomutase, Hexokinase Hexoseisomerase, Aldolase, alcaline and acid Phosphatase, Pyrophosphatase and ATP-ase.

All these activities have been measured in the 20.000 × g supernatant fraction of cell homogenates.

The results show that all the enzymes activities measured increase rapidly during the period of accumulation of storage materials. In the following period all of these activities decrease until the stage of ripeness of the seed. During the first few days of germination the activities increase again rapidly. A particular behaviour is the one of Fr-1-6-P-phosphatase (the enzyme cleaving the phosphate bond in C ¹ position). This enzyme reaches during germination a level much higher than the maximal observed during the ripening process. This might be an important fact correlated with the inversion of the glycolytic reactions during germination.     

Biochemical changes during fungal sporulation and spore germination. I. Phenyl methyl sulfonyl fluoride inhibition of macroconidial germination in Microsporum gypseum

Macroconidia of Microsporum gypseum release free amino acids into the medium during germination. A single alkaline protease is also found in the germination supernatant fraction. The purified protease is capable of hydrolyzing isolated spore coats in vitro. Phenyl methyl sulfonyl fluoride (PMSF) is an effective inhibitor of the protease. Incorporation of PMSF at 10(-4)m into the germination system inhibits spore germination and the release of free amino nitrogen. Addition of PMSF after germ tube emergence is completed has no effect on subsequent outgrowth. The addition of exogenous purified protease to quiescent spores results in more than a 2.5-fold increase in germinated spores. It is concluded that spore coat proteolysis is an essential event in the germination of dermatophyte macroconidia. A model system to explain macroconidial germination response to inhibition, temperature shift, and addition of protease is presented.     

ENZYMES OF PHOSPHOINOSITIDE METABOLISM DURING RAT BRAIN DEVELOPMENT

—The activities of four enzymes concerned with inositol lipid metabolism have been determined in homogenates of rat brains of different ages. The enzymes are CDP-diglyceride inositol phosphatidate transferase, phosphatidylinositol kinase, diphosphoinositide kinase and triphosphoinositide phosphomonoesterase. The activities of all the enzymes increased with age. Phosphatidylinositol kinase activity rose most sharply well before myelination, reaching a maximum at about 6 days of age. Diphosphoinositide kinase and triphosphoinositide phosphomonoesterase activities increased most rapidly during myelination. The increase in CDP-diglyceride inositol phosphatidate transferase showed no definite association with any period of development. It is concluded that triphosphoinositide metabolism is associated with myelin or a closely related structure.     

Changes in Microsporum gypseum Mycelial Wall and Spore Coat Glycoproteins During Sporulation and Spore Germination

Ethylenediamine-soluble glycoproteins were extracted from isolated Microsporum gypseum hyphal walls during sporulation and from spore coats before and after germination. This study was carried out to identify a sporulation-specific cell wall protein that possibly served as a substrate for the alkaline protease which initiated the macroconidial germination of this fungus. Analyses revealed that water-insoluble glycoprotein accounted for 10% of the ungerminated spore coat but only for 4 to 5% of the mycelial wall dry weight. This fraction was modified in its amino acid composition during sporulation, and it decreased in protein content during spore germination. Water-soluble glycoprotein, which accounted for approximately 3 to 3.5% of either the spore coat or mycelial wall dry weight, was of similar amino acid composition from both sources and did not decrease in protein content upon spore germination. The water-insoluble glycoprotein was found to be rich in leucine, aspartic acid, glycine, glutamic acid, and phenylalanine residues. The water-soluble glycoprotein was rich in proline, threonine, glycine, serine, glutamic acid, and alanine.     

Activity of antioxidant system enzymes and lipid peroxidation product content in the liver and thymus of rats in the early stages of irradiation]

The activity of enzymes of the antioxidation system and the content of some lipid peroxidation products in the liver and thymus of irradiated (0.21 C/kg) rats have been investigated. Glutathione reductase and glutathione transferase activity in the liver and thymus of rats decreased during the first 24 h after irradiation. There was a phase change in the catalase activity during the initial postirradiation period. The content of malonic dialdehyde increased immediately after irradiation and somewhat decreased during the first 24 h. In 24 h, there observed a radiation-induced increase in the diene conjugate content in the liver and thymus of rats, against the background of low activity of such antioxidation system enzymes as glutathione transferase, glutathione reductase and catalase.     

Regulation of De-N-Glycosylation Enzymes in Germinating Radish Seeds

The activities of the de-N-glycosylation enzymes endo-N-acetyl- [beta]-D-glucosaminidase (ENGase; EC 3.2.1.96) and peptide-N4- (N-acetyl-[beta]-D-glucosaminyl) asparagine amidase (PNGase; EC 3.5.1.52) were monitored during germination and postgerminative development in radish (Raphanus sativus L. cv Flamboyant). The ENGase activity was detected only during postgermination, whereas the PNGase activity was present at high levels in both stages. When germination was inhibited with abscisic acid or cycloheximide, PNGase activity was detected at a basic level and ENGase activity was not detected at all. PNGase is present as an active protein in dry seeds and is apparently synthesized during seed formation. Conversely, the absence of ENGase in dry seeds suggests that its activity is dependent on the protein synthesis that occurs during and after germination. Treatment with gibberellic acid confirmed the production of both de-N-glycosylation enzymes after germination, and demonstrated a temporal delay between the production of the two enzymes during this period. Our results suggest that the two de-N-glycosylation enzymes are differentially regulated during plant development.     

Alteration in protein kinase(s) level affects the phospholipid content in M. gypseum with modulated levels of calcium/cyclic AMP

Protein kinase(s) have been identified for the first time in Microsporum gypseum. It phosphorylated exogenous protein acceptors preferentially histone IIs and casein and are mainly localized in the cytosolic fraction of M. gypseum. Alterations in protein kinase activity was observed in calcium/aminophylline and atropine (cAMP modulators) grown cells which is due to the modulation in the Ca²⁺/cAMP levels. Alteration in the protein kinase(s) activity finally affected the total phospholipid content in these modulated cells of M. gypseum. These observations suggest a correlation between the activity of protein kinase(s) and phospholipid synthesis in M. gypseum. This protein kinase(s) has a broad substrate specificity and is a seryl-threonyl type protein kinase(s) as it phosphorylates exogenous (histone) and endogenous proteins at serine and threonine residues.     

Physiological and Biochemical Changes Associated with Macroconidial Germination in Microsporum gypseum

A study was made of the metabolic processes associated with macroconidial germination in Microsporum gypseum. The optimum conditions for stimulation of endogenous respiration, changes in chemical composition as germination proceeds, and the uptake and synthetic fates of amino acids, glucose, and uracil were investigated. The assimilation and conversion of (14)C-glucose, (14)C-amino acids, and (14)C-uracil into the cell pool and into trichloroacetic acid-precipitable material were studied during the early stages of germination (i.e., prior to germ-tube emergence). The macroconidia were not metabolically inert for any significant period of time after exposure to germination conditions. Rather, the spores rapidly assimilated all metabolites and slowly converted them into macromolecules. Investigations of the effect of inhibitors of nucleic acid and protein synthesis prior to germ-tube emergence and during early germ-tube elongation suggested significant changes in metabolism and cell permeability may be correlated with the emergence of germ tubes. Radioactivity of incorporated glucose was found to be associated largely with the lipid fractions of the macroconidia early in germination.     

Methylamine metabolism in a pseudomonas species

The mechanism by which a nonphotosynthetic bacterium Pseudomonas sp. (Shaw Strain MA) grows on the one-carbon source, methylamine, was investigated by comparing enzyme levels of cells grown on methylamine, to cells grown on acetate or succinate. Cells grown on methylamine have elevated levels of the enzymes serine hydroxymethyl transferase, serine dehydratase, malic enzyme, glycerate dehydrogenase and malate lyase (CoA acetylating ATP-cleaving). These enzymes, in conjunction with a constitutive glyoxylate transaminase, can account for the net conversion of two one-carbon units into acetyl CoA. Cells grown on acetate or methylamine, but not succinate, contain the enzyme isocitrate lyase; while cells grown on acetate or succinate, but not methylamine, contain significant levels of malate synthetase. These findings suggest that the acetyl CoA derived from one-carbon units in methylamine grown cells, condenses with oxalacetate to yield citrate and then isocitrate, followed by cleavage to succinate and glyoxylate. Thus, growth on methylamine is accomplished by the net synthesis of succinate from two molecules of methyamine and two molecules of CO₂.