A dolichyl phosphate-cleaving acid phosphatase from Tetrahymena pyriformis.

Tetrahymena pyriformis contains an enzyme which hydrolyzed dolichyl phosphate. This activity was solubilized from lyophilized samples of this organism and was relatively stable when stored frozen. The soluble enzyme preparation had an acid pH optimum and hydrolyzed both dolichyl and phytanyl phosphates at equivalent rates. The polyprenylphosphate phosphatase activity was compared with the acid phosphatases which hydrolyzed p-nitrophenyl phosphate and marked differences were found. Dolichyl phosphate hydrolysis required Mg2+ for maximum activity while the bulk of the phosphatase activity was not effected by the absence of this ion. Other differences were that the polyprenylphosphate phosphatase was relatively insensitive to inhibitors such as tartrate and vanadium oxide sulfate which had a pronounced effect on the rate of p-nitrophenyl phosphate hydrolysis. The two activities also appeared to have different subcellular distributions. The polyprenylphosphate phosphatase was markedly inhibited by ethoxy formic anhydride, a reagent which is active against enzymes containing a histidine residue at their active site, while p-nitrophenyl phosphate hydrolysis was unaffected. The polyprenylphosphate phosphatase may be important in regulating the level of dolichyl phosphate in T. pyriformis and thus the rate of glycoprotein synthesis. It is also a useful tool which is capable of liberating dolichol from dolichyl phosphate under mild conditions which will permit the further characterization of the polyprenols.     

The relationship between energy-dependent phagocytosis and the rate of oxygen consumption in Tetrahymena.

The induction of high rates of food vacuole formation in Tetrahymena pyriformis increased the rate of respiration in exponentially growing cells by 17% and in starving cells by 47.5%. The increased rate of oxygen uptake was caused by phagocytosis itself, as shown by comparing the rates of respiration of a Tetrahymena mutant exposed to particles at the permissive or restrictive temperatures for food vacuole formation. During cell division, heat-synchronized cells in rich, particle-supplemented medium showed a significant decrease in the rate of respiration. Furthermore, dimethyl sulphoxide, in concentrations sufficient to block food vacuole formation, suppressed the rate of respiration to a level similar to that of starved cells. Cytochalasin B, fowever, did not reduce the rate of oxygen uptake despite the inability of the cells to complete the formation of food vacuoles during treatment; a possible explanation for this finding is discussed. There was a strong correlation between formation of food vacuoles and a high metabolic rate in Tetrahymena.     

The Induction of Endocytosis in Starved Tetrahymena pyriformis

SYNOPSIS. The formation of digestive vacuoles by starved Tetrahymena pyriformis could be induced by mixtures of latex particles and a variety of potentially digestible solutes. Latex particles themselves had little effect in inducing vacuole formation. Protein, polypeptide, and RNA were highly effective inducers, while glutamate, amino acid mixtures, polysacharides, and glucose were moderately effective. Sodium-β-glycerophosphate had a slight effect and sodium acetate was ineffective. The possible stimulus to endocytosis is discussed. The endocytic response to inducers does not appear to be an all-or-none phenomenon and varies with the concentration of inducer. The stimulatory effect for protein-related inducers seems to be produced by a large number of stimulatory molecules acting upon a single cell and the magnitude of the response appears to be related to molecular size.     

Isolation and partial characterization of vacuoles from tobacco protoplasts

Protoplasts from suspension-cultured cells of Nicotiana glutinosa L. were lysed in 0.3 molar sorbitol in 2 millimolar ethylenediaminetetraacetate-tris(hydroxymethyl) aminomethane (pH 7.5) to release intact vacuoles. The vacuoles were purified by centrifugation in a Ficoll step gradient. About 11% of the vacuoles and 13% of the acid phosphatase activity was recovered in the purified vacuole fraction, suggesting that the vacuole is the major site for acid phosphatase in these cells. NADH-cytochrome c reductase, malate dehydrogenase, and cytochrome c oxidase activities were reduced during vacuole purification. The majority of the adenosine 5′-triphosphate (ATP) hydrolytic activity of purified vacuoles was associated with nonspecific acid phosphatase and not with a transport ATPase. As judged by acid phosphatase distribution and electron microscopy, the effective density of vacuoles in a sucrose gradient was low (less than 1.1 grams per cubic centimeter), although an unequivocal estimate of the vacuole or tonoplast density was not possible from the experiments conducted.     

Encystment-inducing factors in the ciliate Euplotes elegans

Although starvation is considered one of the most important induces of ciliate encystment, its nature has been unclear. Euplotes is a well-known ciliate genus, but the relationship in Euplotes between encystment and food has not been reported. The encystment of Euplotes elegans is facilitated when it is transferred to Chalkley's solution without bacteria as food. A higher ciliate density also facilitates encystment. Thus, starvation and ciliate density needed to be examined. Ciliates were inoculated into 3 treatments: Chalkley's solution with formaldehyde-fixed bacteria as nutritive particles (FFB group), with polystyrene latex particles as non-nutritive particles (PLP group), and without particles (control group). Cysts appeared fastest and ciliate numbers increased in the FFB group. Although the encystment kinetics of the PLP group was similar to that of the control group, the encystment rate of the PLP group was lower than that of the control group in the earliest phase. This suggests that the ciliates were temporarily deceived into feeding on PLP, because they had food vacuoles containing PLP during the earliest phase of incubation. A cell-free old culture solution from a stationary phase, which probably contained excreted substances from high-density ciliates, also facilitated encystment.     

Studies on Feeding and Digestion in Protozoa. III. Acid Phosphatase Activity in Food Vacuoles of Paramecium multimicronucleatum

SYNOPSIS. Acid phosphatase activity was studied in total mounts and sections of agnotobiotic Paramecium multimicronucleatum by the alpha-naphthyl phosphate-hexazotized rosanilin method. Timing was achieved by India ink marking of food vacuoles. Enzyme activity is present in small endoplasmic granules and in the greatest part of food vacuoles. Following an inactive stage (stage I) of an average length of 5 min the activity appears at the periphery of the vacuole, in most cases in the form of granules (stage II). A high activity level (stage III) is attained within 1 1/2 min and maintained for the most part of the vacuolar cycle. The activity disappears only in the latest vacuoles before egestion (stage IV). The appearance of activity is not concurrent with but succeeding to the maximum of vacuolar acidity as ascertained by feeding Congo red stained killed yeast cells. On the basis of these results the food vacuoles may be looked upon as belonging to the lysosomes sensu lato.     

Concanavalin A and the in vitro induction in macrophages of vacuolation and lysosomal enzyme synthesis

Concanavalin A (ConA) induced extensive vacuolation in mouse peritoneal macrophages. Electron microscopic observations on thin sections reveal that the vacuoles are essentially empty except for minute vesicles attached to their inner periphery. The vacuoles consist of irregular structures and are heterogeneous in size distribution. ConA-induced vacuoles exhibit high acid phosphatase activity, suggesting fusion between vacuoles and lysosomes. Induction of acid phosphatase in ConA-treated macrophages was studied under several cultivation conditions. ConA-treated macrophage cultures responded in increase in acid phosphatase activity early after exposure to the lectin, a significant increase recorded already after 1 h. When cultivated in 1% serum medium for 48 h, ConA-treated macrophages exhibit twice the activity of acid phosphatase at zero time as well as that of non-treated control cultures. The effect of ConA on thioglycolate-stimulated mouse peritoneal macrophages was also studied. Vacuole formation resulting from lectin binding and internalization is discussed in terms of possible lectin effects on membrane fluidity, fusion capacity, surface to volume conservation during vacuole formation, fusion of vacuoles with lysosomes and intravacuolar lysosomal enzyme activities. The phenomenon of lysosomal enzyme induction as a result of ConA treatment is being correlated with enzyme induction due to other stimuli.     

Electron microscopic and biochemical research on the vacuoles formed in the erythrocytes of frogs as affected by neutral red and novocaine

No lysosomes were found in the frog intact erythrocytes with electron microscope. Under the influence of neutral red (NR-8.7.10(-5) M) and novocaine (N-4.6.10(-3) M) segregation zones (vacuoles) including these substances are formed. Using electron microscopy and morphometry the action of NR and N for 5 minutes up to 48 hours was found to provoke the formation of four types of vacuoles differing in their morphology: with electron-transparent content, with amorphous inclusions and membrane whorls. The dynamics of vacuole formation, of their changes and amount were followed depending on the time of exposition of these substances. Biochemical investigation of both NR and N isolated vacuoles showed in these some activities of lysosomal marker enzymes--acid phosphatase and N-acetyl-beta,D-glucosaminidase. Ultrastructural investigation of acid phosphatase localization in the isolated vacuoles revealed the histochemical reaction product mainly in electron-translucent vacuoles (primary lysosomes) and partly in electron dense ones (secondary lysosomes). On the ground of the above studies a conclusion is made that in frog erythrocytes treated with NR and N lysosome formation is induced to be followed by the induced autophagocytosis and heterophagocytosis. Some possible ways of the vacuolar system formation in frog erythrocytes and the origin of lysosomal hydrolases are discussed.     

DIGESTION AND THE DISTRIBUTION OF ACID PHOSPHATASE IN BLEPHARISMA

Suspensions of Blepharisma intermedium were fed latex particles for 5 min and then were separated from the particles by filtration. Samples were fixed at intervals after separation and incubated to demonstrate acid phosphatase activity. They were subsequently embedded and sectioned for electron microscopy. During formation of the food vacuole, the vacuolar membrane is acid phosphatase-negative. Within 5 min, dumbbell-shaped acid phosphatase-positive bodies, possibly derived from the the acid phosphatase-positive Golgi apparatus, apparently fuse with the food vacuole and render it acid phosphatase-positive. A larger type of acid phosphatase-positive, vacuolated body may also fuse with the food vacuole at later stages. At about 20 min after formation, acid phosphatase-positive secondary pinocytotic vesicles pinch off from the food vacuoles and approach a separate system of membrane-bounded spaces. By 1 hr after formation, the food vacuole becomes acid phosphatase-negative, and the undigested latex particles are voided into the membrane-bounded spaces. The membrane-bounded spaces are closely associated with the food vacuole at all stages of digestion and are generally acid phosphatase-negative. Within the membrane-bounded spaces, dense, pleomorphic, granular bodies are found, in which are embedded mitochondria, paraglycogen granules, membrane-limited acid phosphatase-containing structures, and Golgi apparatuses. The granular bodies may serve as vehicles for the transport of organelles through the extensive, ramifying membrane-bounded spaces.     

盘基网柄菌细胞分化和凋亡中酸性磷酸酶的定位

利用电镜酶细胞化学方法,观察盘基网柄菌细胞分化和凋亡过程中酸性磷酸酶的变化。在细胞丘阶段,酶反应颗粒出现在线粒体内自噬空泡内,随着内自噬空泡的逐渐增大,线粒体内的酶反应颗粒逐渐增多,线粒体内嵴结构不断破坏,直至遍布整个空泡化的线粒体内;当细胞发育至前孢子细胞时,由于嵴结构被完全破坏,酶反应颗粒主要集中在前孢子细胞空泡的单层膜上,空泡化的线粒体内酶反应颗粒逐渐消失。在凋亡的柄细胞中,自噬泡内酶反应强烈,凋亡中期的前柄细胞的细胞核中出现酶反应颗粒,均匀分布在细胞核中,直至细胞核与自噬泡融合。在孢子细胞外被与质膜间也观察到非溶酶体酸性磷酸酶。所得结果证实:线粒体内自噬小泡具有消化功能;自噬泡内酶活性与细胞器消亡有关;细胞核中的酸性磷酸酶可能作为一种非溶酶体酸性磷酸酶参与细胞核中核蛋白的脱磷酸化过程,与发育相关基因表达有关     

Kinetics of fusion of the cytoplasmic granules with phagocytic vacuoles in human polymorphonuclear leukocytes. Biochemical and morphological studies

This study on human neutrophils was conducted to measure the kinetics of degranulation of the different cytoplasmic granules into phagocytic vacuoles, and to relate the timing of these events to the burst of respiration that accompanies phagocytosis by these cells. Purified neutrophils were incubated with latex particles opsonized with human immunoglobulin (Ig)G, and phagocytosis was stopped at timed intervals. The cells were examined by electron microscopy to document the sequence of degranulation of the cytoplasmic granules. The azurophil granules and lyosomes were identified by histochemical staining for peroxidase and acid phosphatase, respectively. Phagocytic vacuoles were separated from cell homogenates by floatation on sucrose gradients and assayed for contained lactoferrin, myeloperoxidase, and acid hydrolases. The conclusions drawn from the biochemical and morphological studies were in agreement and indicated: particle uptake and vacuole closure can be completed within 20 s; both the specific and azurophil granules fuse with the phagocytic vacuole much earlier than is generally appreciated, with half-saturation times of 39 s (99% confidence limits, 15-72); oxygen consumption has kinetics similar to those of the fusion of these granules with the phagosome; degranulation of the acid hydrolases beta- glucuronidase, N-acetyl-beta-glucosaminidase (biochemical assays), and acid phosphatase (biochemical assay and electron microscopic cytochemistry) have kinetics of degranulation that are similar to each other but totally different from and much slower than that of myeloperoxidase with half-saturation times of between 354 and 682 s (99% confidence limits, 246-883). This suggests that the acid hydrolases are not co-located with myeloperoxidase in the azurophil granule but are contained in distinct lysosomes, or "tertiary granules".     

Sucrose phosphatase associated with vacuole preparations from red beet, sugar beet, and immature sugarcane stem

The specific phosphatase, sucrose phosphate phosphohydrolase (sucrose phosphatase, EC 3.1.3.24) was present in vacuole preparations from storage tissue of red beet (Beta vulgaris L.), sugar beet (Beta vulgaris L. cultivar Kawemono), and immature sugarcane (Saccharum spp. hybrid, cultivar NCO 310). In red beet vacuole preparations the specific activity of sucrose phosphatase, using the naturally occurring vacuole marker, betanin, as reference, was higher than the specific activity of cytoplasmic markers, phosphoenolpyruvate carboxylase and glucose 6-phosphate dehydrogenase, suggesting that sucrose phosphatase is associated with the vacuoles. High speed centrifugation of lysed vacuoles did not result in precipitation of the enzyme indicating that the enzyme is not tightly bound to the tonoplast. Sucrose phosphatase was more sensitive to inhibition by sodium vanadate and less sensitive to ammonium molybdate than was the nonspecific phosphatase which was also present in the extracts. Sucrose phosphatase might be part of the group translocator proposed recently to operate in the tonoplast of sugarcane and red beet.     

Analog modeling of glucagon-induced autophagy in rat liver. II. Evaluation of iron labeling as a means for identifying telolysosome, autophagosome and autolysosome populations.

To evaluate the potential usefulness of iron labeling as a means for identifying the telolysome, autophagosome and autolysosome populations of rat liver, animals treated with Jectofer (iron-citric acid-sorbitol complex), or with Jectofer followed by glucagon, have been studied with a variety of biochemical and morphological methods. Differential centrifugation studies of liver homogenates revealed that the sedimentation velocity and mechanical fragility of acid phosphatase bearing particles increase with the duration of Jectofer treatment and that iron accumulates in the mitochondrial and nuclear fractions. Rate sedimentation studies confirmed the change in sedimentation velocity, which was shown to be due in part to a marked increase in particle density. Quantitative morphological analysis of liver M + L and N + M + L fractions revealed a nearly complete absence of pericanalicular dense bodies after 6–7 days of Jectofer treatment. In these fractions a new type of particle containing fine electron dense granules was seen. The mean volume of these particles was decreased and their number increased when compared to dense bodies but the general morphology and overall size distribution of the two particle classes were similar. In animals given both Jectofer and glucagon, autophagic vacuole formation was similar to that found in animals receiving only glucagon. However, the increase in osmotic fragility of acid phosphatase bearing particles usually seen after glucagon administration occurred at a significantly slower rate. Examination of paniculate fractions revealed the presence of autophagic vacuoles with (autolysosomes) and without (autophagosomes) fine dense granules. The number of autolysosomes and their relative proportion in the autophagic vacuole population were correlated with an increase in the osmotic fragility of the acid phosphatase bearing particles in the same fraction. Organelle degeneration was observed more frequently in autolysosome profiles. These results support the contention that iron labeling can be used to separate the principal particle populations participating in the autophagic response induced by glucagon.     

Regio- and stereo-specific nitrile hydrolysis by the nitrile hydratase from Rhodococcus AJ270

Abstract Acid phosphatase activity was measured in individual cells by determining their optical densities through a scanning confocal laser microscope. The naphthol AS-TR (3-hydroxy-2-naphtoic acid 4'-chloro-2'-methylanilide) phosphate-hexazotized para-rosanilin method was used to visualise the acid phosphatase content in the light microscope. Evidence was obtained that the amount of enzyme varied in exponential growth phase cells as the fission age increased. By comparing the acid phosphatase activity with the rate of food vacuole formation, it appeared that the amount of enzyme inside the cells decreased in early clonal life, whereas the rate of food uptake increased. It was assumed that the reduction of acid phosphatase content could lead to a more extended life of vacuoles and to a decreased membrane recycling rate. In turn, the reduced supply of membrane available for food vacuole formation could partly be responsible for the decrease of the food uptake rate observed after the initial increase.     

Developmental features of calcium oxalate crystal sand deposition inBeta vulgaris L. Leaves

Summary Sugar beet (Beta vulgaris L.) leaf has a layer of cells extended laterally between the palisade parenchyma and spongy mesophyll that develop numerous small crystals (crystal sand) within their vacuoles. Solubility studies and histochemical staining indicate the crystals are calcium oxalate. The crystals are deposited within the vacuoles early during leaf development, and at maturity the cells are roughly spherical in shape and 2 to 3 times larger than other mesophyll cells. Crystal deposition is preceeded by formation of membrane vesicles within the vacuole. The membranes are synthesizedde novo in the vacuole and have a typical trilaminate structure as viewed with the TEM. The membranes are formed within paracrystalline aggregates of tubular particles (6–8nm outer diameter) as membrane sheets, but are later organized into chambers or vesicles. Calcium oxalate is then precipitated within the membrane chambers. The tubular particles involved in membrane synthesis are usually present in the vacuoles of mature crystal cells, but in very small amounts.     

Ultrastructural aspects of histolytic processes in the salivary gland cells during metamorphic stages in Rhynchosciara hollaenderi (Diptera, Sciaridae).

The cytoplasm of Rhynchosciara hollaenderi late larval, prepupal and pupal salivary gland cells was studied at the ultrastructural level. In the second half of the 4th instar, evidence of an intensive secretory activity is visible in the form of numerous secretory granules in the apical area of the cells. At the same stage, the endoplasmic reticulum cisternae adjacent to Golgi groups are active in the transfer of vesicular elements. At later stages this activity rapidly diminishes. Before the appearance of the DNA puffs, i.e. at the end of the 4th instar, mitochondria begin to show a granular deposit and normal mitochondria decrease in number. These with the granular deposit form clusters and initiate formation of single autophagic vacuoles before the appearance of the DNA puffs. Later, at the time, when the 2B puff opens, the autophagic vacuoles appear in great number. Simultaneously with the formation of the autophagic vacuoles the presence of acid phosphatase in the Golgi vesicles and in autophagic vacuoles was shown. In the last stages investigated (late pupae) acid phosphatase is present free in the cytoplasm and at the same time disappearance of free ribosomes, pycnosis of polytene chromosomes and breakage of nuclear membranes occur. It is concluded that the histolysis of the salivary gland cells begins before the large DNA puffs appear, then it becomes very intensive and continues after these puffs undergo regression.     

Peptidase activity in Tetrahymena.

This report strongly suggests that two compartments in Tetrahymena thermophila contain peptidase activity: the cytoplasm and the outer cell surface. Determinations of amino acid concentrations in the extracellular medium upon incubation of cells with peptides suggest that the surface-bound peptidase activity hydrolyses di- and tri-phenylalanine equally fast on a molar basis. Growth experiments designed to characterize the in vivo peptidase specificities showed that both T. thermophila and T. pyriformis can use L-leucyl-L-leucine, but not L-leucyl-D-leucine as a leucine donor. These results are independent of whether the cells form food vacuoles or not.     

Isolation of protoplasts and vacuoles from cell suspension cultures of Coleus blumei Benth.

In order to study the accumulation and transport of rosmarinic acid in suspension cells of Coleus blumei we established an efficient method to isolate protoplasts and vacuoles. Protoplasts were disrupted by an osmotic shock in a medium with basic pH containing ethylenediamine tetraacetic acid. The resulting vacuoles were purified on a two-step Ficoll gradient. The comparison of the rosmarinic acid contents of cells, protoplasts and vacuoles showed that the depside is localized in the vacuole. Data concerning the yield and purity of the vacuoles are presented. In addition we show that at the physiological pH of the cytoplasm rosmarinic acid is present almost exclusively as an anion and cannot pass a membrane by simple diffusion. We therefore propose a carrier system for the transport of rosmarinic acid into the vacuole.Abbreviations EDTA ethylenediamine tetraacetic acid - HEPES 2-[4-(2-hydroxyethyl)-1-piperazinyl]ethane sulfonic acid - HPLC high performance liquid chromatography - MES morpholinoethane sulfonic acid - NADP⁺ ß-nicotinamide adenine dinucleotide phosphate - PEG polyethylene glycol - RA rosmarinic acid - Tris Tris(hydroxymethyl)aminomethane     

Timing of perialgal vacuole membrane differentiation from digestive vacuole membrane in infection of symbiotic algae Chlorella vulgaris of the ciliate Paramecium bursaria

Each symbiotic Chlorella of the ciliate Paramecium bursaria is enclosed in a perialgal vacuole derived from the host digestive vacuole to protect from lysosomal fusion. To understand the timing of differentiation of the perialgal vacuole from the host digestive vacuole, algae-free P. bursaria cells were fed symbiotic C. vulgaris cells for 1.5min, washed, chased and fixed at various times after mixing. Acid phosphatase activity in the vacuoles enclosing the algae was detected by Gomori's staining. This activity appeared in 3-min-old vacuoles, and all algae-containing vacuoles demonstrated activity at 30min. Algal escape from these digestive vacuoles began at 30min by budding of the digestive vacuole membrane into the cytoplasm. In the budded membrane, each alga was surrounded by a Gomori's thin positive staining layer. The vacuoles containing a single algal cell moved quickly to and attached just beneath the host cell surface. Such vacuoles were Gomori's staining negative, indicating that the perialgal vacuole membrane differentiates soon after the algal escape from the host digestive vacuole. This is the first report demonstrating the timing of differentiation of the perialgal vacuole membrane during infection of P. bursaria with symbiotic Chlorella.     

The Correlation of Digestive Vacuole pH and Size with the Digestive Cycle in Paramecium caudatum1

ABSTRACT. The temporal changes in the size and pH of digestive vacuoles (DV) in Paramecium caudatum were reevaluated. Cells were pulsed briefly with polystyrene latex spheres or heat-killed yeast stained with three sulfonphthalein indicator dyes. Within 5 min of formation the intravacuolar pH declined from ～7 to 3. With the exception of a transient and early increase in vacuolar size, vacuole condensation occurred rapidly and paralleled the acidification so that vacuoles reached their lowest pH and minimal size simultaneously. Neutralization and expansion of vacuole size began when vacuoles were GT8 min old. No labeled vacuoles were defecated prior to 21 min after formation but almost all DV were defecated within 1 h so that the digestive cycle of individual vacuoles ranged from 21 to 60 min. Based on these size and pH changes, the presence of acid phosphatase activity, and membrane morphology, digestive vacuoles can be grouped into four stages of digestion. The DV-I are GT6 min old and undergo rapid condensation and acidification. The DV-II are between 4 to 10 min old and are the most condensed and acidic vacuoles. The DV-III range in age from 8 to ～20 min and include the expanding or expanded vacuoles that result from lysosomes fusing with DV-II. The DV-IV are GD21 min old, and since digestion is presumably completed, they can be defecated. The rise in intravacuolar pH that accompanies vacuole expansion suggests that lysosomes play a role in vacuole neutralization in addition to their degradative functions. The acidification and condensation processes in DV-I appear to be unrelated to lysosomal function, as no acid phosphaiase activity has been detected at this stage, but may be related to phagosomal functions important in killing food organisms, denaturing proteins prior to digestion, and preparing vacuole membrane for fusion with lysosomes.