Intracellular and extracellular CM-cellulase and β-glucosidase activity during germination of Polysphondylium pallidum microcysts

Germinating microcysts of Polysphondylium pallidum possess the ability to digest carboxymethyl cellulose to its glucose subunits. This CM-cellulase activity, which is cycloheximide-sensitive, increases several-fold intracellularly during germination and is excreted into the extracellular medium. Augmentation of the extracellular level of cellulase enhances emergence of amoebae from microcysts, suggesting that this activity is critical for germination. The inhibition of -glucosidase activity with d-gluconic acid lactone also inhibits emergence, implicating this enzyme in germination as well.     

CELL CYCLE EVENTS IN THE HYDROCORTISONE REGULATION OF ALKALINE PHOSPHATASE IN HELA S3 CELLS

The increase in alkaline phosphatase in asynchronous cultures of HeLa S₃ cells grown in medium supplemented with hydrocortisone is characterized by a lag period of 10–12 hr. Present studies utilizing synchronous cell populations indicate: (a) a minimum of 8–10 hr of incubation with hydrocortisone is necessary for maximum induction of alkaline phosphatase; (b) the increase in enzyme activity produced by hydrocortisone is initiated exclusively in the synthetic phase of the cell cycle; (c) alkaline phosphatase activity does not vary appreciably over a normal control cell cycle. Radioactive hydrocortisone is rapidly distributed into HeLa cells irrespective of their position in the cell cycle, indicating that inductive effects are not governed by selective permeability during the cell cycle. Hydrocortisone-1,2-[³H] diffuses back from the cell into the medium when the cells are incubated in fresh medium containing no hydrocortisone, and the alkaline phosphatase induction, under these conditions, is completely reversible.     

Hyphal tip growth inPhytophthora

Germinating cysts and isolated walls from germinating cysts incorporated¹⁴C-UDPG into wall material of which 22.5 and 15% respectively were insoluble in boiling 1 N HCl, indicating that part of the synthetase activity is located in the wall itself. A combination of Urografin and Ficol density gradients was used to separate various intracellular fractions. A consistent separation of -glucanase and UDPG-transferase enriched fractions was achieved. The -glucanase fraction contained dictyosome vesicles and fragments along with some plasma membranes. The UDPG-transferase fraction was relatively rich in membranes resembling rough and smooth ER. The results suggest the two enzymes are transported to the wall by different intracellular routes, and two types of vesicle may be involved. Alkaline phosphatase, -glucosidase and acid phosphatase were found extracellularly and their distribution in density gradients determined. The results of histochemical staining for acid phosphatase, alkaline phosphatase and polysaccharide are described and compared with the biochemical data. -1,3-glucanase, found intra- and extracellularly, induced distorted growth of germ tubes and also removed most of the apical wall when added to the incubation medium. None of these responses were observed with cellulase. Determinations of the osmotic pressure of germinating cysts and incubation medium revealed that the turgor of germinating cysts amounts to about 1.8 at under the conditions used.     

Cell-wall-hydrolysing enzymes in wall formation as measured by pollen-tube extension

Summary Cell-wall-softening enzymes affect the plasticity of the tip wall of pollen tubes and modity tube elongation. Length of pear pollen tubes is increased by the addition of -1,3-glucanase at the beginning of in-vitro germination. The longer tubes after 3 hours are primarily the result of earlier germination. Application of -1,4-glucanase or pectinase to germinating pollen does not affect germination but enhances the growth rate of 1-hour-old pollen tubes. The stimulating effects of -1,4-glucanase and pectinase are additive. Denatured enzymes had no effect. Proteinase, pectin esterase, acid phosphatase and -amylase only inhibited growth and germination. Replacing the medium 1 hour after germination begins stops pollen-tube growth; growth can be restored by adding cellulase-pectinase mixtures to the replacement medium. These results provide evidence that cellulase and pectinase are important in pollen-wall extension, and that callose-hydrolyzing enzymes are involved in pollen germination but not wall extension.A contribution of the Florida Agricultural Experiment Station, Journal Series No. 3069.     

Localization of alkaline phosphatase inBacillus intermedius cells

Alkaline phosphatase, an enzyme secreted byBacillus intermedius S3-19 cells to the medium, was also detected in the cell wall, membrane, and cytoplasm. The relative content of alkaline phosphatase in these cell compartments depended on the culture age and cultivation medium. The vegetative growth ofB. intermedius on 0.3% lactate was characterized by increased activity of extracellular and membrane-bound phosphatases. The increase in lactate concentration to 3% did not affect the activity of membrane-bound phosphatase but led to a decrease in the activity of the extracellular enzyme. Na₂HPO₄ at a concentration of 0.01 % diminished the activity of membrane-bound and extracellular phosphatases. CoCl₂ at a concentration of 0.1 mM released membrane-bound phosphatase into the medium. By the onset of sporulation, phosphatase was predominantly localized in the medium and in the cell wall. As is evident from zymograms, the multiple molecular forms of phosphatase varied depending on its cellular localization and growth phase.     

Effect of manganese on alkaline phosphatase production in Bacillus sp. RK11

Summary Bacillus sp. RKll, an alkalophilic isolate from soil, produces an extracellular alkaline phosphatase. In the absence of Mn²⁺ in a complex medium, no alkaline phosphatase production or sporulation by the organism was detected. No other divalent metal could be substituted for Mn²⁺ in enzyme production or in sporulation. Manganous sulphate (70 mol) gave highest enzyme production although spore numbers continued to increase with manganous concentrations above this level. Maximum alkaline phosphatase production occurred when the metal was present at the time of inoculation but maximum spore numbers were detected when the metal was added 8–12h after inoculation. Inorganic pyrophosphatase was not associated with extracellular alkaline phosphatase, but it was detected intracellularly. Ninety-five percent of the alkaline phosphatase was detected extracellularly.     

Differentiating Intracellular from Extracellular Alkaline Phosphatase Activity in Soil by Sonication

Differentiating intracellular from extracellular enzyme activity is important in soil enzymology, but not easy. Here, we report on an adjusted sonication method for the separation of intracellular from extracellular phosphatase activity in soil. Under optimal sonication conditions [soil:water ratio  =  1/8 (w/v) and power density  =  15 watt ml^-1], the activity of alkaline phosphomonoesterase (phosphatase) in a Haplic Cambisol soil increased with sonication time in two distinct steps. A first plateau of enzyme activity was reached between 60 and 100 s, and a second higher plateau after 300 s. We also found that sonication for 100 s under optimal conditions activated most (about 80%) of the alkaline phosphatase that was added to an autoclaved soil, while total bacteria number was not affected. Sonication for 300 s reduced the total bacteria number by three orders of magnitude but had no further effects on enzyme activity. Our results indicate that the first plateau of alkaline phosphatase activity was derived from extracellular enzymes attached to soil particles, and the second plateau to the combination of extracellular and intracellular enzymes after cell lysis. We conclude that our adjusted sonication method may be an alternative to the currently used physiological and chloroform-fumigation methods for differentiating intracellular from extracellular phosphatase activity in soil. Further testing is needed to find out whether this holds for other soil types.     

Effect of a juvenile hormone analogue on phosphatase activity in pupae of the stable fly, Stomoxys calcitrans.

The alkaline phosphatase activity of stable fly pharate pupae treated with 10 ng of an insect juvenile hormone analogue (JHA), Stauffer R-20458, or untreated pupae was rhythmic and peaked 48 and 96 hr after larval-pupal apolysis. Those treated with 10 μg were not rhythmic and peaked at 48 and 120 hr. Acid phosphatase activity showed a general increase throughout pupal-adult transformation and was three- to four-fold higher than alkaline phosphatase activity. At 24 and 48 hr after larval-pupal apolysis, acid phosphatase was lower in the treated animals, but at 72 and 120 hr, it was higher. Neither inhibition nor enhancement of acid and alkaline phosphatase activity or by three other JHAs could be demonstrated in vitro.     

Phosphate Starvation Triggers Production and Secretion of an Extracellular Lipoprotein in Caulobacter crescentus

Life in oligotrophic environments necessitates quick adaptive responses to a sudden lack of nutrients. Secretion of specific degradative enzymes into the extracellular medium is a means to mobilize the required nutrient from nearby sources. The aquatic bacterium Caulobacter crescentus must often face changes in its environment such as phosphate limitation. Evidence reported in this paper indicates that under phosphate starvation, C. crescentus produces a membrane surface-anchored lipoprotein named ElpS subsequently released into the extracellular medium. A complete set of 12 genes encoding a type II secretion system (T2SS) is located adjacent to the elpS locus in the C. crescentus genome. Deletion of this T2SS impairs release of ElpS in the environment, which surprisingly remains present at the cell surface, indicating that the T2SS is not involved in the translocation of ElpS to the outer membrane but rather in its release. Accordingly, treatment with protease inhibitors prevents release of ElpS in the extracellular medium suggesting that ElpS secretion relies on a T2SS-secreted protease. Finally, secretion of ElpS is associated with an increase in alkaline phosphatase activity in culture supernatants, suggesting a role of the secreted protein in inorganic phosphate mobilization. In conlusion, we have shown that upon phosphate starvation, C. crescentus produces an outer membrane bound lipoprotein, ElpS, which is further cleaved and released in the extracellular medium in a T2SS-dependent manner. Our data suggest that ElpS is associated with an alkaline phosphatase activity, thereby allowing the bacterium to gather inorganic phosphates from a poor environment.     

Studies on the cell cycle of Myxobacter AL-1

The properties of seven enzymes were studied in extracts from Myxobacter AL-1. The enzymes were isocitrate dehydrogenase (E.C. 1.1.1.42), succinate dehydrogenase (E.C. 1.3.99.1), alkaline phosphatase (E.C. 3.1.3.1), -glucosidase (E.C. 3.2.1.20), -glucosidase (E.C. 3.2.1.21), -galactosidase (E.C. 3.2.1.23), and N-acetyl-glucosaminidase (E.C. 3.2.1.30). Four of these enzymes: isocitrate dehydrogenase, -glucosidase, -glucosidase, and -galactosidase are cytosolic enzymes. Succinate dehydrogenase was found to be located on the cytoplasmic membrane system, whereas alkaline phosphatase and N-acetyl-glucosaminidase were considered as enzymes which bind the outer membranes resp. the cell wall. During the cell cycle, all enzymes have a pattern of discontinuous activity increase. Succinate dehydrogenase and isocitrate dehydrogenase exhibit a stepwise increase of activity, whereas the other enzymes follow the pattern of a peak enzyme.     

Localization of alkaline phosphatase in cells of Bacillus intermedius

Alkaline phosphatase, an enzyme secreted by Bacillus intermedius S3-19 cells to the medium, was also detected in the cell wall, membrane, and cytoplasm. The relative content of alkaline phosphatase in these cell compartments depended on the culture age and cultivation medium. The vegetative growth of B. intermedius on 0.3% lactate was characterized by increased activity of extracellular and membrane-bound phosphatases. The increase in lactate concentration to 3% did not affect the activity of membrane-bound phosphatase but led to a decrease in the activity of the extracellular enzyme. Na2HPO4 at a concentration of 0.01% diminished the activity of membrane-bound and extracellular phosphatases. CoCl2 at a concentration of 0.1 mM released membrane-bound phosphatase into the medium. By the onset of sporulation, phosphatase was predominantly localized in the medium and in the cell wall. As is evident from zymograms, the multiple molecular forms of phosphatase varied depending on its cellular localization and growth phase.     

Production of phosphatates by fungi isolated from desert soils

Twelve fungal cultures isolated from Indian desert soils belonging toAspergillus, Penicillium, Acrophialophora andAlternaria were found to produce both acid and alkaline phosphatases in liquid medium, their amounts varying from culture to culture. Maximum production of these enzymes was observed withA. niger. In general, acid phosphatase activity was much higher as compared to alkaline phosphatase. The optimum incubation period for the production of these enzymes was found to be 14 d and thereafter it started declining. There was a significant and positive correlation between biomass production and acid phosphatase activity but not with alkaline phosphatase.     

Glycosidases in pear pollen tube development

During the in vitro germination of pear pollen, several hydrolaseswere released into the medium. They were apparently eluted fromthe pollen grain, since the activity was the same when germinationwas inhibited. These enzymes, once released, had no role intube growth, since resuspension of pollen in fresh medium after1.5 hr of incubation did not result in a change of the subsequenttube growth. Homogenates of the pollen suspension at differentstages of development showed no significant changes in phosphatase,ß-glucosidase, or ß-galactosidase activity.However, patent ß-glucosidase activity measured directlyin suspensions of intact pollen did increase after germinationin proportion to tube wall development. Nojirimycin, a specificinhibitor of glucosidases, reduced this ß-glucosidaseactivity by 75% at 10^–5M and significantly reduced growthrate at 10^–4 M. (Received December 19, 1978; )     

Effect of cryogenic preservation (−80 °C) on polymorphonuclear neutrophil integrity as determined by biochemical analysis

The effect of cryopreservation on plasma membrane and granule associated enzymes of polymorphonuclear neutrophils (PMNs) was studied. The activity of PMNs to generate superoxide anions during phagocytosis was very sensitive to cryopreservation and exhibited approximately 60% inhibition in 24 hr. The total enzyme activity was not as affected during 1-month cryopreservation as that observed with the extracellular release of enzymes. Acid p-nitrophenyl phosphatase and peroxidase were released slightly from frozen and thawed PMNs. However, the extracellular release of LDH, a cytosol marker, and β-glucuronidase and lysozyme, granuleassociated enzymes, increased with cryopreservation time. The degree of release of these enzymes was LDH > β-glucuronidase > lysozyme. A considerable amount of LDH was extracellularly released after 1-month storage. Frozen and thawed PMNs became sensitive to hypotonic solutions, although fresh, nonfrozen PMNs were very resistant to hypotonic lysis. The hypotonic fragility increased even after 1 hr of cryopreservation.Addition of ATP to the preservation medium did not improve enzyme activity, enzyme release, or stimulated superoxide anion generation but increased the hypotonic fragility of PMNs. However, albumin showed protective effects against cryopreservation injury to the O₂^?-generating system, the extracellular enzyme release, and osmotic fragility.     

Cystic fibrosis: leakage of lysosomal enzymes and of alkaline phosphatase into the extracellular space

Nine lysosomal enzymes and alkaline phosphatase have been assayed with two different ultramicro techniques in the intra- and extracellular space of fibroblast cultures derived from the skin of cystic fibrosis patients, cystic fibrosis carriers, and normal controls, respectively. Evidence has been obtained for a multiple leakage of lysosomal enzymes and of alkaline phosphatase into the medium of fibroblast cultures from cystic fibrosis patients and carriers. The situation is comparable to a certain extent, to that observed in I-cell-disease (mucolipidosis II). This multiple leakage results in the decrease of intracellular activity of several lysosomal enzymes in cultures from cystic fibrosis patients and carriers and due to the coordinate regulation of the synthesis of the “leaky enzymes” in an overshooting of the intracellular alkaline phosphatase activity in cultures from cystic fibrosis patients. It also explains the retarded catabolism of certain molecules, such as the Tamm-Horsfall glycoprotein, in cystic fibrosis cells. It is speculated that the basic defect in cystic fibrosis leads to abnormal recognition sites on lysosomal enzymes and on alkaline phosphatase, and in consequence to the leakage of these enzymes into the extracellular space. The present findings allow one to develop methods for the pre- and postnatal diagnosis of cystic fibrosis with cell cultures, and for the detection of cystic fibrosis carriers with the peripheral blood.     

Synthesis and release of proteases byBacteroides fragilis

Protease production byBacteroides fragilis ATCC 25285 was determined in batch and continuous cultures. During exponential growth in batch culture, the majority of proteolysis was cell associated. However, as the bacteria reached stationary phase, most of the intracellular proteases were released into the culture medium. Measurements of alkaline phosphatase and -galactosidase, which are respectively periplasmic and cytoplasmic marker enzymes inB. fragilis, showed that secretion of proteases in the stationary phase was a discrete event and was not associated with a general release of cytoplasmic contents. When the bacterium was grown in continuous culture, cell-associated protease activity increased concomitantly with dilution rate (D=0.03–0.23/h). The ratio of intracellular to whole cell protease activity also increased with growth rate (11 at D=0.03/h; 11.7 at D=0.23/h). Extracellular protease activity was detected only in trace amounts in continuous cultures at the lowest dilution rate. Determinations of the distribution of extracellular protease activity in batch culture after 48 h incubation showed that the majority of proteolysis (ca. 90%) was soluble. Nevertheless, a proportion was associated with particulate fractions, which had high specific activities.     

Phosphate regulation of phosphatases in submerged cultures of Claviceps purpurea 129 producing clavine alkaloids

Summary Claviceps purpurea strain 129 was cultivated under submerged conditions in a sucrose-citrate medium containing high (36.8 mM) or low (1.84 mM) KH₂PO₄ concentrations. The permeabilized cells and culture supernatants contained alkaline and acid phosphatases. In the medium containing a high phosphate concentration, the synthesis of extracellular phosphatases was repressed, but that of cellular phosphatases was not. Extracellular phosphatases, especially alkaline phosphatases, were derepressed by transferring the mycelium into a phosphate-free medium. This derepression was inhibited by cycloheximide. In the presence of cycloheximide, the activities of the cellular phosphatases decreased markedly, indicating turnover of these enzymes. The cellular acid phosphatase was inhibited by phosphate (0.025 M–0.1 M) and NaF (0.01 M) while the cellular alkaline phosphatase was only inhibited by phosphate. Both cellular and extracellular alkaline phosphatases were more sensitive to repression by phosphate than the acid phosphatases. The alkaloid synthesizing enzymes were: a) present in mycelia grown in high levels of phosphate and b) activated by decreasing the intracellular phosphate level.     

Regulation of gene expression by pH of the growth medium in Aspergillus nidulans

Summary In the fungus Aspergillus nidulans the levels of a number of enzymes whose location is at least in part extracellular (e.g. acid phosphatase, alkaline phosphatase, phosphodiesterase) and of certain permeases (e.g. that for -amino-n-butyrate) are controlled by the pH of the growth medium. For example, at acidic pH, levels of acid phosphatase are high and those of alkaline phosphatase are low whereas at alkaline pH the reverse is true. Mutations in five genes, palA, B, C, E and F, mimic the effects of growth at acid pH whereas mutations in pacC mimic the effects of growth at alkaline pH. palA, B, C, E and F mutations result in an intracellular pH (pH_in) which is more alkaline than that of the wild type whereas pacC mutations result in a pH_in more acidic than that of the wild type. This indicates that these mutations exert their primary effects on the regulation of gene expression by pH rather than on the pH homeostatic mechanism but that the expression of at least some component(s) of the pH homeostatic mechanism is subject to the pH regulatory system. It is suggested that pacC might be a wide domain regulatory gene whose product acts positively in some cases (e.g. acid phosphatase) and negatively in others (e.g. alkaline phosphatase). The products of palA, B, C, E and F are proposed to be involved in a metabolic pathway leading to synthesis of an effector molecule able to prevent the (positive and negative) action of the pacC product.These genes are, to our knowledge, the first examples of genes involved in the regulation of extracellular enzyme and permease synthesis by the pH of the growth medium to be described in any organism.