Effect of endocytosis upon acid phosphatase activity ofTetrahymena pyriformis

Summary Increased endocytosis inTetrahymena pyriformis, produced by presenting starved cells with either peptone-yeast extract medium or killed yeast cell suspension, results in increased cellular acid phosphatase activity.Tetrahymena, grown in peptone-yeast extract medium, showed increased acid phosphatase activity after phagocytosis of yeast cells. This increase was not apparent until about one hour after presentation and was maximal at about 2.5 hours.Tetrahymena, grown on yeast suspension, showed little increase in acid phosphatase activity on presentation with peptone-yeast extract medium. These results may indicate that endocytosis, of either particles or solutes, produces an adaptive increase in acid phosphatase activity (presumably lysosomal in nature) which is related to feeding.Histochemical examination failed to localise the increase in acid phosphatase activity cellularly, but small particles, of about 1 diameter, which showed acid phosphatase activity and were presumably lysosomes were noted. Closely orientated yeast cells showed varying intensities of lead deposition, from absence to intense staining. This suggests that newly ingested yeast cells may be ingested initially in a single phagosome and that thereafter one or more lysosomes may fuse with them.     

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.     

Some enzymatic properties of vacuolar alkaline phosphatase from yeast

Candida utilis alkaline phosphatase has been detected in vacuoles. Liberation of the vacuoles was carried out by protoplast disruption under isotonic conditions. The polybase DEAE-dextran was used to induce damage to the yeast plasmalemma. The vacuoles were purified by centrifugation on sorbitol-Ficoll gradients. Alkaline phosphatase from a purified fraction of vacuoles was characterized after gel filtration on Sephadex G-200. We have found 15 mU of enzyme activity per 10⁸ vacuoles. This enzyme activity elutes on Sephadex G-200 at a volume-to-void-volume ratio of 1.65. The approximate molecular weight is 1.35×10⁵. TheK _m value forp-nitrophenyl-phosphate is 2.5×10^–3 M. The pH for maximum activity is 8.9, and the enzyme is stable at pH values between 7.0 and 9.0. Rapid inactivation occurs at temperatures above 45°C. The enzyme catalyzes the hydrolysis of phosphomonoester bonds of a wide variety of molecules, especially polyphosphates. Thus, vacuolar polyphosphates are probably the natural substrate of this enzyme. Orthophosphate, arsenate, ethylenediaminetetraacetate, molybdate, and borate act as inhibitors. Fluoride is not an inhibitor, and the activity is not affected byp-hydroxymercuribenzoate. Some metal ions also affect the activity of vacuolar alkaline phosphatase. This may indicate that this enzyme is a metalloprotein.     

A cytochemical study of the leaf-gland enzymes of insectivorous plants of the genus Pinguicula

Summary Cytochemical methods have been used to study the distribution of acid phosphatase, esterase, ribonuclease, amylase and protease activity in the stimulated and unstimulated leaf glands of Pinguicula grandiflora, P. vulgaris, P. lusitanica, and P. caudata. Two gland types are present, stalked and sessile. The stalked glands bear a muco-polysaccharide secretion droplet, and are concerned with capture of the prey; the sessile glands are specialised for digestion. In unstimulated glands of both classes, acid phosphatase, esterase and ribonuclease activity is associated with the anticlinal walls of the head cells, which have a characteristic spongy inner surface, comparable with that of transfer cells. Acid phosphatase and esterase activity was also detected in the vacuoles of the head cells of the sessile glands. Substrate film tests showed that amylase is readily released from the stalked glands but not from the sessile ones, while in contrast proteolytic activity is mainly associated with the sessile glands.On stimulation by suitable nitrogenous materials, the glands begin to sectete fluid onto the leaf surface within 1 hr. During the process the enzymes held in the spongy walls are discharged, and activity is also lost from the intracellular sites in the sessile glands.Digestion on the leaf surface and resorption of the products has been followed autoradiographically after feeding of ¹⁴C-labelled protein. Within 2 hr, digestion products enter the leaf, and move towards the margin in the vascular system. Movement out of the leaf begins within 12 hr. Microautoradiographs showed a concentration of products around the bases of the sessile glands and in the cells of the gland head, showing that these glands are involved in resorption as well as secretion.A possible mechanism of gland function is discussed.     

Ultrastructural Localization of Acid Phosphatase in Feeding Tokophrya infusionum*

A combined cytochemical and electronmicroscopic study of feeding Tokophrya revealed that it has 2 sources of acid phosphatase. One is from the prey, Tetrahymena, supplying newly formed food vacuoles with large amounts of enzyme. The other source is in Tokophrya itself, the enzyme being found in small vesicles, small dense elongate bodies surrounded by a membrane, or in residue vacuoles. It seems that the 2 former small structures contain insignificantly small amounts of phosphatase; however, large deposits of lead phosphate are present in residue vacuoles, former food vacuoles. Since Tokophrya has no cytopyge these vacuoles are not excreted. On the contrary, when feeding is resumed, they merge with food vacuoles, presumably supplying them with acid phosphatase. Whether this enzyme ultimately is derived from the prey Tetrahymena and persists undegraded in the residue vacuoles, or whether it is synthesized by Tokophrya cannot be determined from present work.     

Phosphatase activity in the heterotrophic dinoflagellate Pfiesteria shumwayae

The ELF-97 phosphatase substrate was used to examine phosphatase activity in four strains of the estuarine heterotrophic dinoflagellate, Pfiesteria shumwayae. Acid and alkaline phosphatase activities also were evaluated at different pH values using bulk colorimetric methods. Intracellular phosphatase activity was demonstrated in P. shumwayae cells that were actively feeding on a fish cell line and in food limited cells that had not fed on fish cells for 3 days. All strains, whether actively feeding or food limited showed similar phosphatase activities. P. shumwayae cells feeding on fish cells showed ELF-97 activity near, or surrounding, the food vacuole. Relatively small, spherical ELF-97 deposits were also observed in the cytoplasm and sometimes near the plasma membrane. ELF-97 fluorescence was highly variable among cells, likely reflecting different stages in digestion and related metabolic processes. The location of enzyme activity and supporting colorimetric measurements suggest that, as in other heterotrophic protists, acid phosphatases predominate in P. shumwayae and have a general catabolic function.     

Electron cytochemical studies on autophagy in the gut epithelial cells of the locust,Schistocerca gregaria

Synopsis Autophagic vacuoles containing mitochondria, endoplasmic reticulum and granules in various states of digestion have been demonstrated in the gut epithelial cells of the desert locust. The number and size of these vacuoles was found to increase with starvation. The presence of acid phosphatase activity within the autophagic vacuoles, shown by an azo dye and a lead salt method, indicates that they may be classified as autolysosomes.     

Ultrastructure of Thraustochytrium sp. zoospores

Summary Acid phosphatase distribution in the biflagellate zoospores of a marine fungus Thraustochytrium, resembling T. motivum Goldstein, was examined utilizing ultrastructural cytochemistry. Acid phosphatase activity was found in the Golgi saccules, Golgi vesicles, multivesicular bodies, endoplasmic reticulum, and autophagic vacuoles.Extensive autolysis of cellular structures occurs in the zoospores. Organelles or portions of the cytoplasm are segregated from the rest of the cytoplasm by acid phosphatase-positive vesicles and lamellae. These vesicles and lamellae coalesce around a portion of cytoplasm forming an enclosing double membraned sac. One of the membranes, probably the inner, is disrupted, releasing the hydrolytic enzymes which initiate digestion of the enclosed cytoplasm. These cytolysomes eventually fuse with larger cytolysomes where digestion is presumably completed. The final fate of the digestive residues and the large cytolysomes has not been determined.Contribution No. 501, Virginia Institute of Marine Science, Gloucester Point, Virginia 23062, U.S.A.Supported in part by the Oceanographic Section, National Science Foundation, Grant # GA-31014, to Dr. Frank O. Perkins.     

Golgi associated acid phosphatase in muscle and nerve cells fromArion ater (L.)

Summary Golgi associated acid phosphatase has been demonstrated within muscle and nerve cells from the sub-epithelial layers of the crop, intestine, and digestive gland ofArion ater. Enzyme activity was detected in the saccules, vacuoles, and vesicles of the Golgi apparatus of both nerve ganglia and muscle cells. Other vacuolar sources of acid phosphatase could also be distinguished within the cytoplasm of these cells.     

LYTIC ACTIVITIES IN RENAL PROTEIN ABSORPTION DROPLETS : An Electron Microscopical Cytochemical Study

The digestive cycle following reabsorption of hemoglobin by cells of the proximal convoluted tubules in mouse kidney and the uptake of ferritin by glomerular mesangial cells in the kidney of normal and nephrotic rats were investigated by electron microscopical histochemical procedures. Mouse kidneys, sampled at closely spaced time points between 1 to 48 hours after intraperitoneal injection of hemoglobin, and rat (normal and nephrotic) kidneys, sampled at 30 minutes, 2 hours, and 48 hours after intravenous injection of ferritin, were fixed in glutaraldehyde, cut at 50 µ on a freezing microtome, incubated for acid phosphatase and thiolacetate-esterase, and postfixed in OsO₄. Satisfactory preservation of fine structure permitted the localization of the enzymatic reaction products on cell structures involved in uptake and digestion of exogenous proteins. The latter were identified either by their density (hemoglobin) or their molecular structure (ferritin). It was found that lysosomal enzymic activities and incorporated exogenous proteins occur together in the same membrane-bounded structures. In the cells of the proximal convolution, lytic activities become demonstrable within 1 hour after hemoglobin injection, appear first in apical vacuoles filled with hemoglobin, and persist in fully formed protein absorption droplets. At the end of the lytic cycle (~48 hours post injection), the cells have an increased population of polymorphic bodies which exhibit lytic activities. In smaller numbers, identical bodies occur in controls. It is concluded that they represent remnants of previous digestive events. The means by which the resorptive vacuoles acquire hydrolytic activities remain unknown. Fusion of newly formed vacuoles with residual bodies was not seen, and hemoglobin incorporation into such bodies was only occasionally encountered. Acid phosphatase activity was found sometimes in the Golgi complex, but enzyme transport from the complex to the resorbing vacuoles could not be established. Autolytic vacuoles containing mitochondria or mitochondrial remnants were frequently found during the early stages of hemoglobin resorption, but no definite conclusions about the mechanism involved in the segregation of endogenous material were obtained. In nephrotic rats ferritin was segregated in membrane-bounded bodies mainly in the mesangial cells and to a lesser extent in epithelial and endothelial cells. Most of these sites were marked by the reaction products of acid phosphatase and organophosphorus-resistant esterase and therefore identified as lysosomes connected with the digestion of incorporated exogenous proteins.     

Physiological responses of pressed baker’s yeast cells pre-treated with citric, malic and succinic acids

Summary The dough-leavening power of baker’s yeast, Saccharomyces cerevisiae, is strongly influenced by conditions under which the pressed yeast is maintained prior to bread dough preparation. In this study, the influence of the yeast cell’s pre-treatment with organic acids (malic, succinic, and citric acids) was investigated at a wide range of pH values when the pressed yeast samples were exposed to 30 °C. Increased fermentative activity was observed immediately after pre-treatment of the cells with organic acids. When the pH of the pressed yeast containing added citric acid was raised from 3.5 to 7.5, increases in both fermentative and maltase activities were obtained. Improvements in viability and levels of total protein were also observed during storage in the presence of citric acid, notably at pH 7.5. Glycerol-3-phosphate dehydrogenase activity and levels of internal glycerol also increased in the presence of citrate. On the other hand, pressed yeast samples containing succinic acid at pH 7.5 showed decreased viability during storage despite the maintenance of high levels of fermentative activity, similar to pressed yeast containing malic acid at pH 4.5 and 7.5. Decreases in intracellular levels of trehalose were observed during storage in all cases. Overall, the results of this study revealed the potential benefits of adding organic acids to pressed yeast preparations for baking purposes.     

Cytochemische Untersuchungen zur intrazellulÄren Verdauung beim azellulÄren SchleimpilzPhysarum confertum

Zusammenfassung Der azellulÄre SchleimpilzPhysarum confertum besitzt ein intrazellulÄres Verdauungssystem, das dem der meisten tierischen Organismen weitgehend Ähnlich ist. Das Leitenzym dieses Systems ist nach cytochemischen Untersuchungen saure Phosphatase. Als Bildungsort dieser Hydrolase kommen der Golgiapparat und das Endoplasmatische Retikulum in Frage. Von hier werden die Verdauungsenzyme mit Hilfe primÄrer Lysosomen zu den Nahrungsvakuolen transportiert. Nach Konfluation der primÄren Lysosomen mit den Nahrungsvakuolen entstehen sekundÄre Lysosomen, in denen die Verdauung stattfindet. Die hydrolisierten Stoffe scheinen dann mikropinocytotisch aus den sekundÄren Lysosomen ins Cytoplasma abtransportiert zu werden. Die Verfütterung von Substanzen mit unterschiedlichem NÄhrwert hat ergeben, da\ saure Hydrolasen auch in solche Vakuolen abgegeben werden, die für den Schleimpilz unverdauliche Stoffe (Siliciumdioxyd) beinhalten. Allerdings wird der Inhalt dieser Vakuolen schon nach wenigen Stunden in optisch unverÄnderter Form nach au\en abgegeben. Verdauliche Partikel wie Aleuronkörner oder Hefezellen werden dagegen vollstÄndig aufgelöst und sind nach 18–26 Stunden nicht mehr nachweisbar.

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Cytochemical studies on intracellular digestion in the acellular slime moldPhysarum confertum

Summary The acellular slime moldPhysarum confertum possesses a digestive system which can be compared to that of normal animal cells. The system could be demonstrated morphologically and cytochemically by the localization of acid phosphatase activity. The Golgi apparatus and the endoplasmic reticulum proved to be involved in the formation of digestive enzymes. From these cell organells the hydrolases are transported to food vacuoles by primary lysosomes. Primary lysosomes and food vacuoles confluate to secundary lysosomes in which digestion takes place. The hydrolyzed contents of the secondary lysosomes seem to be distributed throughout the cytoplasm by micropinocytotically formed vesicles. The application and absorption of substances differing in their degree of digestibility revealed that acid hydrolases are also released into vacuoles which contain indigestible material,i.e., silicon dioxide. However, the contents of these vacuoles are defecated soon after their formation has occurred; in contrast, the hydrolisation and resorption of digestible food particles (aleuron and yeast) could be observed over a periode of at least 18–26 hours.

     

Ultracytochemical localization of dihydroorotate dehydrogenase in mitochondria and vacuoles ofSaccharomyces cerevisiae

The coenzyme-independent dihydroorotate dehydrogenase (EC 1.3.3.1) linking the pyrimidine biosynthetic pathway to the respiratory chain, was ultracytochemically localized by the tetrazolium method in derepressed exponential-phase cultures ofSaccharomyces cerevisiae. Biochemical analysis showed a considerable variation of this enzyme activity in inverse proportion to the aeration of the yeast cultures. The assay also showed that after prefixation of yeast cells with 1% glutaraldehyde at 0°C for 20 min, approximately one-half of the enzyme activity was preserved. The cytochemical reaction mixture contained dihydroorotate (2 mmol/L), thiocarbamyl nitroblue tetrazolium (0.44 mmol/L), phenazine methosulfate (0.16 mmol/L) and KCN (1.7 mmol/L) in Tris-HCl buffer (100 mmol/L) of pH 8.0. The osmicated formazan deposits featured envelopes of mitochondria and of nuclei and were prominent in the mitochondrial inclusions and in the vacuolar membranes. The latter sites of dihydroorotate dehydrogenase activity represent biosynthetic activity in yeast vacuoles, still generally assumed to function as yeast lysosomes and storage organelles. In the light of the generally observed invasions of juvenile yeast vacuoles into mitochondria, the enzymic sites observed in mitochondrial inclusion were considered as evidence of the interactions of yeast vacuoles and mitochondria. Transfer of vacuolar membranes with dihydroorotate dehydrogenase activity into mitochondrial matrix is suggested.     

Protein Uptake and Digestion in Bloodstream and Culture Forms of Trypanosoma brucei*

SYNOPSIS. The mechanisms of ferritin uptake and digestion differ in bloodstream and culture forms of Trypanosoma brucei. Ferritin enters bloodstream forms from the flagellar pocket by pinocytosis in large spiny-coated vesicles. These vesicles become continuous with straight tubular extensions of a complex, mostly tubular, collecting membrane system where ferritin is concentrated. From the collecting membrane system the tracer enters large digestive vacuoles. Small spiny-coated vesicles, which never contain ferritin, are found in the Golgi region, fusing with the collecting membrane system, and around the flagellar pocket. Acid phosphatase activity is present in some small spiny-coated vesicles which may represent primary lysosomes. This enzymic activity is also found in the flagellar pocket, pinocytotic vesicles, the collecting membrane system, the Golgi (mature face), and digestive vacuoles of bloodstream forms. About 50% of the acid phosphatase activity of blood forms is latent. The remaining nonlatent activity is firmly cell-associated and probably represents activity in the flagellar pocket. The structures involved in ferritin uptake and digestion are larger and more active in the short stumpy than in the long slender bloodstream forms. The short stumpy forms also have more autophagic vacuoles. No pinocytotic large, spiny-coated vesicles or Golgi-derived, small spiny-coated vesicles are seen in culture forms. Ferritin leaves the flagellar pocket of these forms and enters small smooth cisternae located just beneath bulges in the pocket membrane. The tracer then passes through a cisternal collecting membrane network, where it is concentrated, and then into multivesicular bodies. In the culture forms, acid phosphatase activity is localized in the cisternal system, multivesicular bodies, the Golgi (mature face), and small vesicles in the Golgi and cisternal regions. The flagellar pocket has no acid phosphatase activity, and almost all the activity is latent in these forms. The culture forms do not release acid phosphatase into culture medium during 4 days growth. Uptake of ferritin by all forms is almost completely inhibited by low temperature. These differences among the long slender and short stumpy bloodstream forms and culture forms are undoubtedly adaptive and reflect different needs of the parasite in different life cycle stages.     

Ultrastructure and cytochemistry of glycogen-containing vacuoles in gastrodermal cells in developing hydranths of a hydromedusan coelenterate

Hydranth buds from the colonial hydroid Sertularia pumila (Hydromedusae) were observed by electron microscopy during their development. Before hydranth expansion, the gastrodermal columnar digestive cells had large numbers of vacuoles. These vacuoles contained many membranous components as well as α-glycogen and dense ring- and crescent-shaped bodies. The rings and crescents were not osmiophilic, but did react to periodic acid oxidation in the PA-TSC-SP test for carbohydrate. These structures were digestible by α-amylase and pullulanase. The chemical analyses and the close association of the rings and crescents to α-glycogen particles showed that they may be a highly condensed form of glycogen. Golgi bodies in association with the gastrodermal vacuoles had acid phosphatase activity. This enzyme was only slightly active in the vacuoles. It is suggested that the vacuoles arc primarily storage organelles with a potential for digestion.     

Acid phosphatase activity during the interaction of the nematophagous fungus Duddingtonia flagrans with the nematode Panagrellus sp

The use of Duddingtonia flagrans, a nematode-trapping fungus, has been investigated as a biological control method against free living larvae of gastrointestinal nematodes of livestock animals. This fungus captures and infects the nematode by cuticle penetration, immobilization and digestion of the internal contents. It has been suggested that this sequence of events occurs by a combination of physical and enzymatical activities. This report characterizes the acid phosphatase activity during the interaction of D. flagrans with the free-living nematode Panagrellus sp. The optimum pH for the hydrolysis of the acid phosphatase substrate p-nitrophenyl phosphate was 2.2, 2.8 and 5.4 from D. flagrans alone and 2.2 and 5.4 for Panagrellus sp alone, fungus-nematode interaction in liquid medium and fungus-nematode interaction in solid medium. Different acid phosphatase activity bands were detected by SDS-PAGE. Maximum acid phosphatase activity of the fungus or nematode alone and of the fungus-nematode interaction occurred within 70 min of incubation in the presence of the substrate 4-methylumbelliferyl phosphate. The activity of this enzyme was significantly higher for the fungus-nematode interaction when compared to the organisms alone, indicating a synergistic response. Furthermore, structures appeared in the hyphae after 30 min, nematodes were observed adhered after 40 min and many were captured by the typical fungus traps after 70 min of interaction. The participation of acid phosphatase activity and its importance during the interaction of the fungus with the nematode were discussed.     

Cytochemical and biochemical determination of acid phosphatase activity in yeasts]

Optimal conditions of the cytochemical assay for acid phosphatase in protoplasts and whole cells of S. cerevisiae have been described. Dimethyl sulfoxide was used to increase the permeability of the yeast cell envelope. In the yeast cells, grown up to the end of the exponential phase, acid phosphatase is shown to be located mainly in the central vacuole and on the cell envelope surface. A considerable activity of acid phosphatase is demonstrable on the surface of the plasma membrane and within adjacent vesicles that represent, presumably, part of the endoplasmic reticulum. Acid phosphatase can be considered as a marker enzyme for yeast cell vacuoles.     

Symbiotic Chlorella sp. of the ciliate Paramecium bursaria do not prevent acidification and lysosomal fusion of host digestive vacuoles during infection

Summary. Each symbiotic Chlorella sp. of the ciliate Paramecium bursaria is enclosed in a perialgal vacuole derived from the host digestive vacuole, and thereby the alga is protected from digestion by lysosomal fusion. Algae-free cells can be reinfected with algae isolated from algae-bearing cells by ingestion into digestive vacuoles. To examine the timing of acidification and lysosomal fusion of the digestive vacuoles and of algal escape from the digestive vacuole, algae-free cells were mixed with isolated algae or yeast cells stained with pH indicator dyes at 25 ± 1 °C for 1.5 min, washed, chased, and fixed at various time points. Acidification of the vacuoles and digestion of Chlorella sp. began at 0.5 and 2 min after mixing, respectively. All single green Chlorella sp. that had been present in the host cytoplasm before 0.5 h after mixing were digested by 0.5 h. At 1 h after mixing, however, single green algae reappeared in the host cytoplasm, arising from those digestive vacuoles containing both nondigested and partially digested algae, and the percentage of such cells increased to about 40% at 3 h. At 48 h, the single green algae began to multiply by cell division, indicating that these algae had succeeded in establishing endosymbiosis. In contrast to previously published studies, our data show that an alga can successfully escape from the host’s digestive vacuole after acidosomal and lysosomal fusion with the vacuole has occurred, in order to produce endosymbiosis. Correspondence and reprints: Biological Institute, Faculty of Science, Yamaguchi University, Yoshida 1677-1, Yamaguchi 753-8512, Japan.     

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     

A CYTOCHEMICAL STUDY OF ACID PHOSPHATASE AND NUCLEASE ACTIVITY IN THE PLASTID OF CLOSTERIUM ACEROSUM1

Acid phosphatase activity in Closterium acerosum has been studied using the Gomori and the azo dye procedures. A modification of the Gomori method was used for detecting the distribution of acid nucleases. The plastid is the major site of acid phosphatase activity luhich may be primarily within pyrenoids, between pyrenoids, or throughout the plastid. The Gomori procedure showed activity within the pyrenoids or in the central core of the plastid, whereas the azo dye method showed activity throughout with an occasional tendency to be localized near the ends. No other cytoplasmic activity was ob-served but evidence for occasional activity in the nucleus is presented. Alkaline phosphatase could not be detected. Acid nuclease activity, which results in the degradation of DNA, RNA, and RNA-Core, has been found in both the nucleus and the plastid. Plastid activity is heat labile, whereas nuclear activity is only slightly diminished after 5 min at 100 C. The results arc interpreted as indicating at least 2 acid phosphatases and 2 nucleases in C. acerosum. The findings are discussed with respect to the distribution of similar enzymes in other organisms.