Processing of Digestive Vacuoles in Tetrahymena and the Effects of Dichloroisoproterenol1

The digestive-lysosomai system in Telrahymena has been extensively studied; however, the various vacuole stages and the existence of a required processing period prior to defecation have not been clearly denned, in this study the presence of such a required processing period and the rate of DV defecation in Tetrahymena thermophila were determined. Like the cycle in Paramecium. a digestive cycle in Tetrahymena consisted of two periods: the processing period was 45 min and the defecation period was ?2 h, making the complete cycle ?3 h. During the defecation period vacuole egestion followed the kinetics of a first-order rate reaction and had a rate constant of 0.0187/min and a t1/2 of 37 min (82 min into the cycle). Using the naphthol AS-TR phosphate-hexazotized rosanilin method to visualize acid phosphatase activity at the light microscopic level, DVs became positive beginning at 10 min. The number of positive DVs increased to a maximum of 13% when DVs were 20-min old and declined to 5-7% beyond 30 min. Although dichloroisoproterenol (DCI) has been reported by others to stimulate vacuole defecation, we found it inhibited the defecation rate. The extent of inhibition depended on the age of the DVs when exposed to DCI. Vacuole formation was completely blocked in cells pre-exposed to 40 μ DCI for only 10 min; however, upon further exposure, cells could recover from this inhibition. The time required for complete recovery increased with increasing DCI concentrations. If DCI was given to cells simultaneously with latex beads, it was found to exert a dose-dependent inhibitory effect on DV formation. These results showed the heterophagic pathway of the digestive-lysosomal system in Telrahymena to be similar to that of Paramecium, though it was less efficient in the former cell.     

Modulation of the digestive-lysosomal system in Paramecium caudatum. I. Effects of temperature

The heterophagic pathway of the digestive-lysosomal system in axenically grown Paramecium caudatum is divisible into vacuole formation, vacuole acidification-condensation, lysosomal fusion-digestion and defecation. These four processes can be separated in time, thus permitting the study of the effects of temperature on each process. The optimal growth temperature for this cell was 27 degrees C. The rate of digestive vacuole (DV) formation at varying temperatures was represented by a skewed bell-shaped curve having an optimum between 28 and 30 degrees C. The time course for the acidification-condensation step was lengthened below 26 degrees C, but was not accelerated above this temperature. The rate but not the extent of vacuole condensation was decreased at 19 and 22 degrees C. Temperature increase above 22 degrees C shortened, slightly, the duration of the lysosomal fusion-digestion process, whereas below 22 degrees C small temperature decreases greatly extended this period. Within a given experiment the rates of defecation were proportional to temperatures above 17 degrees C. However, these rates varied widely among different experiments. Interestingly, the activation energies for both the formation and defecation processes averaged 19 kcal/mol. Furthermore, Paramecium appeared to readily adapt to environmental temperature changes, since the length of the processing periods and the rates of defecation were similar in cells with or without a 24 h acclimation. These results indicated that the four processes in the digestive cycle in P. caudatum are distinct but each is energy-dependent.     

Characteristics of the digestive vacuole membrane of the alga-bearing ciliate Paramecium bursaria

Cells of the ciliate Paramecium bursaria harbor symbiotic Chlorella spp. in their cytoplasm. To establish endosymbiosis with alga-free P. bursaria, symbiotic algae must leave the digestive vacuole (DV) to appear in the cytoplasm by budding of the DV membrane. This budding was induced not only by intact algae but also by boiled or fixed algae. However, this budding was not induced when food bacteria or India ink were ingested into the DVs. These results raise the possibility that P. bursaria can recognize sizes of the contents in the DVs. To elucidate this possibility, microbeads with various diameters were mixed with alga-free P. bursaria and traced their fate. Microbeads with 0.20μm diameter did not induce budding of the DVs. Microbeads with 0.80μm diameter produced DVs of 5-10μm diameter at 3min after mixing; then the DVs fragmented and became vacuoles of 2-5μm diameter until 3h after mixing. Each microbead with a diameter larger than 3.00μm induced budding similarly to symbiotic Chlorella. These observations reveal that induction of DV budding depends on the size of the contents in the DVs. Dynasore, a dynamin inhibitor, greatly inhibited DV budding, suggesting that dynamin might be involved in DV budding.     

Phagosomal acidification in Paramecium: effects on lysosomal fusion

Phagosomes of paramecia and amoeba and endosomes of fibroblasts and other mammalian cells are acidified prior to lysosomal fusion. The question, whether the phagosomal acidification process in paramecia is required for phagosome-lysosome fusion, was studied using ionophores, weak bases, and cytochalasin B (CB) in combination with monoclonal antibodies, acid phosphatase (AcPase) cytochemistry, and lysosome morphometry. Digestive vacuoles (DVs) of known ages were treated and examined. In untreated cells, lysosome binding to the membrane of the acidified DV increased linearly with age and reached a maximum before lysosome-DV fusion. When the fusion of the acidosomes with the very young DVs was prevented by CB, causing a block in the normal vacuole-pH drop, lysosome binding to the DVs as well as the rate and extent of lysosome-DV fusion were all greatly reduced. These effects of CB were reversible. When present prior to acidification, three ionophores and two weak bases did not inhibit the acidosome-DV fusion but raised the phagosomal pH and reduced both the rates of DV acidification and of lysosome-DV fusion. However, when added after acidification but prior to lysosome-DV fusion, five of the six perturbants studied did not inhibit this fusion but prolonged the period when DVs remained AcPase positive. Lastly, lysosome-DV fusion rates were found to be related to acidification rates. We conclude that an inhibition in acidosome-DV fusion or a reduction in both the acidification rate and vacuolar-pH drop would inhibit lysosome-DV fusion.     

Dendritic-cell-specific ICAM3-grabbing non-integrin is essential for the productive infection of human dendritic cells by mosquito-cell-derived dengue viruses

Dengue virus (DV) is a mosquito-borne flavivirus that causes haemorrhagic fever in humans. DV primarily targets immature dendritic cells (DCs) after a bite by an infected mosquito vector. Here, we analysed the interactions between DV and human-monocyte-derived DCs at the level of virus entry. We show that the DC-specific ICAM3-grabbing non-integrin (DC-SIGN) molecule, a cell-surface, mannose-specific, C-type lectin, binds mosquito-cell-derived DVs and allows viral replication. Conclusive evidence for the involvement of DC-SIGN in DV infection was obtained by the inhibition of viral infection by anti-DC-SIGN antibodies and by the soluble tetrameric ectodomain of DC-SIGN. Our data show that DC-SIGN functions as a DV-binding lectin by interacting with the DV envelope glycoprotein. Mosquito-cell-derived DVs may have differential infectivity for DC-SIGN-expressing cells. We suggest that the differential use of DC-SIGN by viral envelope glycoproteins may account for the immunopathogenesis of DVs.     

Phagosome formation in Paramecium: roles of somatic and oral cilia and of solid particles as revealed by video microscopy

The roles of somatic and oral cilia and solid particles during digestive vacuole (DV) formation in Paramecium multimicronucleatum were investigated using video-enhanced and immunofluorescence microscopy. Membrane incorporation into DVs was found to increase linearly with increasing particle concentration. The rate of discoidal vesicle transport to the cytopharynx was not affected by particles, showing that particles are not required for membrane trafficking to the cytopharynx. However, the presence of particles leads to an increased membrane fusion between the cytopharyngeal membrane and the discoidal vesicles. When live cells lost their somatic cilia on the left-ventral side anterior to the oral region due to deciliation, membrane incorporation into newly formed DVs was strongly inhibited. Using video-enhanced microscopy, latex beads were seen to be loaded along the quadrulus on the dorsal surface of the buccal cavity, but few beads were seen next to the dorsal and ventral peniculi. Particle sequestration into a pre-formed nascent digestive vacuole (NDV) was studied in Triton X-100-permeabilized cells whose ciliary beating was reactivated by the addition of Mg-ATP. Both beat frequency and the percentage of cells containing bead-labeled NDV were dependent on the Mg-ATP concentration: the higher the beat frequency, the higher the percentage of cells with a bead-labeled NDV. These results suggest that ciliary beating is probably the only mechanism required for particle accumulation in the NDV, while a coordinated beating of the somatic cilia on the left-ventral side anterior to the oral region as well as the quadrulus moves particles into the NDV. The beating of the peniculi may somehow prevent the backward flow of particles out of the NDV.     

Effects of dimethylsulfoxide (DMSO) on the digestive-lysosomal system in Paramecium caudatum

The effects of DMSO (dimethylsulfoxide) on cell growth and on the digestive-lysosomal system of axenically grown Paramecium caudatum were studied. A general protocol of exposing cells to different concentrations of DMSO at the beginning of each of the four processes in the digestive cycle enabled us to analyze the effect of DMSO at each step. Vacuole formation and the beginning of a digestive cycle were initiated by adding latex beads to the cells. Maximum cell densities at stationary phase of growth were found to be inversely proportional to DMSO between 0.5 and 1.75%, and the duration of the generation time was exponentially proportional. At 2% DMSO cellular division was completely blocked, and above 2% it was cytotoxic. P. caudatum survived for 8 h in 4% DMSO and died instantaneously in 10%. This inhibitory effect on growth was reversible, though this reversibility might depend on the duration and level of DMSO exposure. DMSO exerted a dose- and time-dependent inhibitory effect on the rate of DV formation but had little effect on the acidification-condensation and the lysosome fusion-digestion processes. The size of the DV formed was also reduced, and this effect was dose-but not time-dependent; vacuole size reduction occurred immediately with DMSO exposure, and no further reduction was observed during exposures of up to 24 h. DMSO at 3 and 4% inhibited vacuole defecation, but the cells could overcome this inhibition when exposed to DMSO for longer periods.(ABSTRACT TRUNCATED AT 250 WORDS)     

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 effect of puromycin and cycloheximide on vacuole formation and exocytosis in Tetrahymena pyriformis GL-9

It has been shown that both puromycin and cycloheximide, at concentrations of 434 and 100 g/ml respectively, produce a marked inhibition of vacuole formation and exocytosis in Tetrahymena pyriformis GL-9. These effects were analysed in a quantitative manner. At the same time as these inhibitions occurred the incorporation of 1-C¹⁴ leucine into trichloroacetic acid precipitable material was inhibited by 90% and 100% respectively over a 40 min period. This inhibition of protein synthesis by cycloheximide occurred almost immediately, whereas the inhibition of vacuole formation and egestion was delayed. The results suggested that the latter processes were dependent upon a continuing supply of proteinaceous material, of which there was only a small store within the cell. Cycloheximide inhibited exocytosis completely under the conditions employed (with 100% inhibition of protein synthesis) whereas puromycin (with a 90% inhibition of protein synthesis) only inhibited it by about 50%. This suggested that the amount of newly synthesized protein required for the exocytic egestion process was very small in relation to the total cell requirement for protein synthesis. The entry of both inhibitors into the cell was by means other than vacuole formation. Puromycin appeared to have some effect on vacuole formation which was unconnected with protein synthesis. Microscopic observations of living cells indicated that oral apparatus function and endocytic vacuole formation were probably both affected by the inhibitors. Chloramphenicol, at 200 g/ml, had little effect on vacuole formation by starved cells with an exposure of an hour. The uptake of 1-C¹⁴ leucine from the growth medium was found to be a selective process, giving a concentration of about 2000 times into the cells over a 1 hr period. The results are discussed.     

Subunit E isoform 1 of vacuolar H+-ATPase OsVHA enables post-Golgi trafficking of rice seed storage proteins

Dense vesicles (DVs) are Golgi-derived plant-specific carriers that mediate post-Golgi transport of seed storage proteins in angiosperms. How this process is regulated remains elusive. Here, we report a rice (Oryza sativa) mutant, named glutelin precursor accumulation8 (gpa8) that abnormally accumulates 57-kDa proglutelins in the mature endosperm. Cytological analyses of the gpa8 mutant revealed that proglutelin-containing DVs were mistargeted to the apoplast forming electron-dense aggregates and paramural bodies in developing endosperm cells. Differing from previously reported gpa mutants with post-Golgi trafficking defects, the gpa8 mutant showed bent Golgi bodies, defective trans-Golgi network (TGN), and enlarged DVs, suggesting a specific role of GPA8 in DV biogenesis. We demonstrated that GPA8 encodes a subunit E isoform 1 of vacuolar H⁺-ATPase (OsVHA-E1) that mainly localizes to TGN and the tonoplast. Further analysis revealed that the luminal pH of the TGN and vacuole is dramatically increased in the gpa8 mutant. Moreover, the colocalization of GPA1 and GPA3 with TGN marker protein in gpa8 protoplasts was obviously decreased. Our data indicated that OsVHA-E1 is involved in endomembrane luminal pH homeostasis, as well as maintenance of Golgi morphology and TGN required for DV biogenesis and subsequent protein trafficking in rice endosperm cells.

A subunit of the vacuolar H⁺-ATPase regulating endomembrane luminal pH homeostasis plays a fundamental role in post-Golgi trafficking of rice seed storage proteins.     

Glucose Utilization Rates in Single Neurons and Neuropil Determined by Injecting Nontracer Amounts of 2-Deoxyglucose

Abstract: A nontracer amount of 2-deoxyglucose (DG) was intravenously injected into rats, which were frozen 2 and 4 min later in liquid nitrogen. The freeze-dried samples of cell bodies of anterior horn cells, dorsal root ganglion cells, and cerebellar Purkinje cells, as well as the neuropil adjacent to anterior horn cell bodies, were prepared. Their contents of glucose, glucose 6-phosphate, DG, and 2-deoxyglucose 6-phosphate were microassayed using an enzymatic amplification reaction, NADP cycling. Based on the resulting data and theoretical equations previously described, glucose utilization rate (GUR) and apparent distribution volumes (DVs) of glucose and DG were determined. Anterior horn cell bodies had the highest GUR and their neuropil the lowest, although apparent DVs of glucose and DG were similar in both. This indicates that the glucose supply was equally balanced in all, but that the cell bodies had higher functional activity supported by hexokinase (and other enzymes) related to their energy demands. Dorsal root ganglion cells showed the lowest 2-deoxyglucose 6-phosphate formation rate, but their GUR was slightly higher than that of neuropil because of their markedly large DV of glucose, thus demonstrating that the abundant glucose supply supports the neuronal function. Purkinje cells indicated GUR and apparent DVs similar to molecular and granular layers.     

The effect of concanavalin A on egestion of food vacuoles in Tetrahymena

The ability of concanavalin A (conA) to disrupt food vacuole elimination at the cytoproct of Tetrahymena pyriformis, strain GL-C, was investigated using fluorescence microscopy and thin section electron microscopy. ConA was found to induce "tails" in Tetrahymena. These tails were specifically stained by fluorescent conA. Thin section observations of conA-treated cells revealed that these tails were the result of abnormal egestion of food vacuole contents at the cytoproct. Tail formation appears to result from an inhibition of endocytosis of food vacuole membrane during egestion. Instead, the food vacuole membrane appears to be cast out of the cell, along with the contents of the vacuole. The mechanism of this inhibition may be related to an apparent absence of microtubules or microfilamentous mat in the cytoproct region of conA-treated cells. Although conA is ingested into food vacuoles in large amounts, conA appears to affect endocytosis only from outside the cell; ingested conA does not appear to be effective. ConA may exert its influence by binding to the cytoproct region. The ability of conA to induce tail formation is inhibited by sugars specific to it. Numerous membranous vesicles are found in association with the oral cilia and cytoproct region of conA-treated cells. These vesicles may be the conA-binding material reported to be secreted by Tetrahymena.     

Cloning and sequencing of a protein involved in phagosomal membrane fusion in Paramecium

An mAb was raised to the C5 phagosomal antigen in Paramecium multimicronucleatum. To determine its function, the cDNA and genomic DNA encoding C5 were cloned. This antigen consisted of 315 amino acid residues with a predicted molecular weight of 36,594, a value similar to that determined by SDS-PAGE. Sequence comparisons uncovered a low but significant homology with a Schizosaccharomyces pombe protein and the C-terminal half of the beta-fructofuranosidase protein of Zymomonas mobilis. Lacking an obvious transmembrane domain or a possible signal sequence at the N terminus, C5 was predicted to be a soluble protein, whereas immunofluorescence data showed that it was present on the membranes of vesicles and digestive vacuoles (DVs). In cells that were minimally permeabilized but with intact DVs, C5 was found to be located on the cytosolic surface of the DV membranes. Immunoblotting of proteins from the purified and KCl-washed DVs showed that C5 was tightly bound to the DV membranes. Cryoelectron microscopy also confirmed that C5 was on the cytosolic surface of the discoidal vesicles, acidosomes, and lysosomes, organelles known to fuse with the membranes of the cytopharynx, the DVs of stages I (DV-I) and II (DV-II), respectively. Although C5 was concentrated more on the mature than on the young DV membranes, the striking observation was that the cytopharyngeal membrane that is derived from the discoidal vesicles was almost devoid of C5. Approximately 80% of the C5 was lost from the discoidal vesicle-derived membrane after this membrane fused with the cytopharyngeal membrane. Microinjection of the mAb to C5 greatly inhibited the fusion of the discoidal vesicles with the cytopharyngeal membrane and thus the incorporation of the discoidal vesicle membranes into the DV membranes. Taken together, these results suggest that C5 is a membrane protein that is involved in binding and/or fusion of the discoidal vesicles with the cytopharyngeal membrane that leads to DV formation.     

Localization of vacuolar transport receptors and cargo proteins in the Golgi apparatus of developing Arabidopsis embryos

Using immunogold electron microscopy, we have investigated the relative distribution of two types of vacuolar sorting receptors (VSR) and two different types of lumenal cargo proteins, which are potential ligands for these receptors in the secretory pathway of developing Arabidopsis embryos. Interestingly, both cargo proteins are deposited in the protein storage vacuole, which is the only vacuole present during the bent-cotyledon stage of embryo development. Cruciferin and aleurain do not share the same pattern of distribution in the Golgi apparatus. Cruciferin is mainly detected in the cis and medial cisternae, especially at the rims where storage proteins aggregate into dense vesicles (DVs). Aleurain is found throughout the Golgi stack, particularly in the trans cisternae and trans Golgi network where clathrin-coated vesicles (CCVs) are formed. Nevertheless, aleurain was detected in both DV and CCV. VSR-At1, a VSR that recognizes N-terminal vacuolar sorting determinants (VSDs) of the NPIR type, localizes mainly to the trans Golgi and is hardly detectable in DV. Receptor homology-transmembrane-RING H2 domain (RMR), a VSR that recognizes C-terminal VSDs, has a distribution that is very similar to that of cruciferin and is found in DV. Our results do not support a role for VSR-At1 in storage protein sorting, instead RMR proteins because of their distribution similar to that of cruciferin in the Golgi apparatus and their presence in DV are more likely candidates. Aleurain, which has an NPIR motif and seems to be primarily sorted via VSR-At1 into CCV, also possesses putative hydrophobic sorting determinants at its C-terminus that could allow the additional incorporation of this protein into DV.     

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.     

Ultrastructural Organization of Bovine Chromaffin Cell Cortex—Analysis by Cryofixation and Morphometry of Aspects Pertinent to Exocytosis

We have analyzed ultrathin sections from isolated bovine chromaffin cells grown on plastic support, after fast freezing, by quantitative electron microscopy. We determined the size and intracellular distribution of dense core vesicles (DVs or chromaffin granules) and of clear vesicles (CVs). The average diameter of DVs is 356 nm, and that of CVs varies between 35–195 nm (average 90 nm). DVs appear randomly packed inside cells. When the distance of the center of DVs to the cell membrane (CM) is analyzed, DV density is found to decrease as the CM is approached. According to Monte Carlo simulations performed on the basis of the measured size distribution of DVs, this decay can be assigned to a “wall effect.” Any cortical barrier, regardless of its function, seems to not impose a restriction to a random cortical DV packing pattern. The number of DVs closely approaching the CM (docked DVs) is estimated to be between 364 and 629 (average 496), i.e., 0.45 to 0.78 DVs/μm² CM. Deprivation of Ca²⁺, priming by increasing [Ca²⁺]_i, or depolarization by high [K⁺]_e for 10 s (the effect of which was controlled electrophysiologically and predicted to change the number of readily releasable granules [RRGs]) does not significantly change the number of peripheral DVs. The reason may be that (a) structural docking implies only in part functional docking (capability of immediate release), and (b) exocytosis is rapidly followed by endocytosis and replenishment of the pool of docked DVs. Whereas the potential contribution of DVs to CM area increase by immediate release can be estimated at 19–33%, that of CVs is expected to be in the range of 5.6–8.0%.     

Effects of Dichloroisoproterenol on Macromolecular Synthesis and Differentiation in Tetrahymena vorax

ABSTRACT. The effect of dichloroisoproterenol on macrostomal cell formation in Tetrahymena vorax was examined and the drug was found to be 50% inhibitory at a concentration of 88 μM. Cellular uptake and incorporation of a variety of radiolabelled precursors was monitored in the presence of dichloroisoproterenol. The results demonstrate a strong, concentration-dependent inhibitory effect on RNA and protein biosynthesis, with a lesser inhibition observed for lipid biosynthesis. These data indicate that dichloroisoproterenol's reported effects on vacuole formation and processing in Tetrahymena are nonspecific with regard to phagocytic processes, but result from a general suppression of macromolecular synthesis.     

Acid hydrolases and their release in food vacuole-less mutants of Tetrahymena thermophila.

Mutants (NP1 and PSJ5) of Tetrahymena thermophila strains B and D 1968 exist that are unable to construct a functional oral apparatus and form food vacuoles at 37 C but which do so normally at 30 C. Food vacuole-less cells starved in dilute salt solution released similar amounts of acid phosphatase, beta-N-acetyl-glucosaminidase and alpha-glucosidase activity into the medium as wildtype cells during an 8-h period. Actively growing, food vacuole-less cells had approximately 50% less total protein, acid phosphatase, beta-N-acetyl-glucosaminidase, and alpha-glucosidase per cell than wildtype cells after 72-h growth. During this time food vacuole-less cells released significant amounts of the 3 acid hydrolases into the growth medium. For each hydrolase, the total activity released from growing, food vacuole-less cells was less, on a per cell basis, tahn the amount released from food vacuole formers. The proportion of the total activity secreted by the mutant and the wildtype cells was the same for acid phosphatase and beta-N-acetyl-glucosaminidase and somewhat lower for alpha-glucosidase. It is concluded that the release of a significant amount of acid hydrolase activity from Tetrahymena is independent of food vacuole formation and may be analogous to the secretory activity of other nonphagocytic eukaryotic cells.     

On Food Vacuoles in Tetrahymena pyriformis GL

SYNOPSIS. The following problems concerning food vacuoles were studied by in vivo observations of Tetrahymena: (A) Formation of food vacuoles . The process may be divided into 4 stages. Stage 1—gradual growth of the limiting membrane of the open food vacuole (of short duration). Stage 2—"filling up" of the fully expanded vacuole (of long duration). Stage 3—"closing off" of the vacuole (of brief duration). Stage 4—initial movement of the detached vacuole away from the cy-tostome. The possible role of the oral components (apart from membranellar beating) in the process is discussed. (B) Change of pH in the food vacuole . After ingestion of heat-killed yeast stained with indicator dyes (neutral red, bromcresol purple, bromcresol green, bromphenol blue), the observed color changes indicate that pH is neutral in the forming vacuole as well as in newly formed vacuoles; that a pH value of 6.0–5.5 is reached after ∼ 5 min; and that the lowest pH value between 4.0 and 3.5 is reached after 1 hr. Before egestion the pH again increases. (C) Length of the digestive cycle . A determination of the time required to deplete the cells of labeled vacuoles formed during a short exposure, was attempted. Defecation was observed after 1/2 hr and it was frequent after 2 hr. About 25% and 50% of the labeled vacuoles were removed after 1 hr and 2 hr, respectively; however, labeled vacuoles may still be seen in some cells 6 hr after ingestion. The conclusion is that the digestive cycle lasts ∼ 2 hr and that egestion of undigestible material is a random process.     

Timing of swarmer cell cycle morphogenesis and macromolecular synthesis by Hyphomicrobium neptunium in synchronous culture.

The swarmer cycle of Hyphomicrobium neptunium consists of a temporal sequence of discrete developmental events. To time morphogenesis and to investigate modulations in macromolecular synthesis, we attempted methods for synchronous culture. During synchrony, swarmer maturation occurred over 32%, hyphal growth occurred over 36%, and bud maturation occurred over 32% of the time required to complete the swarmer cycle. Daughter cells were released after 265 min. Deoxyribonucleic acid replication was discontinuous, having a G1 period of approximately 180 min. In addition, ribonucleic acid and protein syntheses were depressed during the earlier phases of development.