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.     

Processing of digestive vacuoles in Tetrahymena and the effects of dichloroisoproterenol

The digestive-lysosomal system in Tetrahymena has been extensively studied; however, the various vacuole stages and the existence of a required processing period prior to defecation have not been clearly defined. 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 approximately 2 h, making the complete cycle approximately 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 preexposed to 40 microM 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.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

Effects of dimethyl sulfoxide on Tetrahymena pyriformis GL. Fine structural changes and their reversibility.

Fine-structural changes are induced in Tetrahymena by exposure to 7.5% dimethyl sulfoxide (DMSO) in the presence of growth medium. Some of these changes (nucleolar, mitochondrial, peroxisomal) resemble those seen during starvation, in agreement with the previously reported inhibitory effect of DMSO on food-vacuole formation; however, changes such as helical formations of polyribosomes indicate additional internal actions of the reagent. The effects vary to some extent within the same group of cells, suggesting that sensitivity to the reagent may differ with the stage in the cell cycle. The structural changes induced by a 1-hr exposure to DMSO are reversible, but recovery of the cells after removal of the reagent is slower than that seen after starvation. The observations suggest that the recovery is associated with renewed synthesis.     

Nonlysosomal vesicles (acidosomes) are involved in phagosome acidification in Paramecium

Although acidification of phagocytic vacuoles has received a broadened interest with the development of pH-sensitive fluorescent probes to follow the pH changes of vacuoles and acidic vesicles in living cells, the mechanism responsible for the acidification of such vacuoles still remains in doubt. In previous studies of the digestive vacuole system in the ciliate Paramecium caudatum we observed and described a unique population of apparently nonlysosomal vesicles that quickly fused with the newly released vacuole before the vacuole became acid and before lysosomes fused with the vacuole. In this paper we report the following: (a) these vesicles, named acidosomes, are devoid of acid phosphatase; (b) these vesicles accumulate neutral red as well as acridine orange, two observations that demonstrate their acid content; (c) cytochalasin B given 15 s after exposure of the cells to indicator dye-stained yeast will inhibit the acidification of yeast-containing vacuoles; and that (d) we observed using electron microscopy, that fusion of acidosomes with the vacuole is inhibited by cytochalasin B. We conclude that the mechanism for acidification of phagocytic vacuoles in Paramecium resides, at least partially if not entirely, in the acidosomes.     

Effects of Dimethyl Sulfoxide on Tetrahymena pyriformis GL. Fine Structural Changes and Their Reversibility*

SYNOPSIS. Fine-structural changes are induced in Tetrahymena by exposure to 7.5% dimethyl sulfoxide (DMSO) in the presence of growth medium. Some of these changes (nucleolar, mitochondrial, peroxisomal) resemble those seen during starvation, in agreement with the previously reported inhibitory effect of DMSO on food-vacuole formation; however, changes such as helical formations of polyribosomes indicate additional internal actions of the reagent. The effects vary to some extent within the same group of cells, suggesting that sensitivity to the reagent may differ with the stage in the cell cycle. The structural changes induced by a 1-hr exposure to DMSO are reversible, but recovery of the cells after removal of the reagent is slower than that seen after starvation. The observations suggest that the recovery is associated with renewed synthesis.     

Growth inhibitory effects of dimethyl sulfoxide and dimethyl sulfone on vascular smooth muscle and endothelial cells in vitro

Summary The growth of bovine aortic smooth muscle and endothelial cells was studied after exposure to dimethyl sulfoxide (DMSO) or its major metabolite, dimethyl sulfone (DMSO₂). Both compounds caused a dose-dependent inhibition of cell growth as determined by [³H]thymidine incorporation and by counting the number of cells with time of exposure in culture. The IC₅₀ of DMSO (concentration which produces 50% inhibition of growth) was 1% for smooth muscle cells and 2.9% for endothelial cells. Similarly, the IC₅₀ of DMSO₂ was also 1% for smooth muscle cells, but was 1.8% for endothelial cells. After a 4-d exposure to either compound, the growth inhibition of smooth muscle cells was completely reversible at 1%, partially reversible at 2 to 3% and completely irreversible at 4%. By comparison, inhibition of endothelial cell growth was completely reversible up to 4% of either compound. It is concluded that the growth of smooth muscle cells was similarly inhibited by DMSO, and DMSO₂, but that smooth muscle cells were more susceptible than endothelial cells to the growth inhibitory effects of these compounds. In addition, DMSO₂ was a more potent inhibitor of cell growth than DMSO and its growth inhibition was less reversible than that produced by DMSO.     

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.     

Dimethyl sulfoxide inhibits the expression of early growth-response genes and arrests fibroblasts at quiescence

We have previously shown that dimethyl sulfoxide (DMSO) treatment of mouse embryo fibroblasts (MEF) at the early hours of mitogenic stimuli resulted in the inhibition of DNA and protein synthesis; delayed treatment of serum-stimulated cells with DMSO had little effect on the synthesis of these macromolecules. Here, we demonstrate the specific inhibition of expression of early growth response genes by DMSO in serum-stimulated MEF. The expression of interleukin 6, and of oncogenes c-myc and c-fos were inhibited when the cells were treated with 2% DMSO from the beginning of serum-stimulated growth but not after 3 h of mitogenic stimuli. Although the actin gene is an early serum-response gene, its expression was not affected by DMSO. The synthesis of another serum-induced protein, the plasminogen activator inhibitor-1 was blocked during concurrent and delayed (after 3 h of stimulation) treatment of serum-stimulated fibroblasts with DMSO. The expression of glyceraldehyde-3-phosphate dehydrogenase gene was not affected by DMSO. These results indicate that the expression of non-growth-related genes are either not affected or affected nonspecifically both at early and late stages of serum-induced growth of mouse embryo fibroblasts. The serum-induced expression of c-fos gene was abolished by DMSO treatment of MEF while the phorbol 12-myristate 13-acetate-induced expression of fos gene was not, indicating that the PMA signaling pathway was refractory to DMSO. Treatment of cells with medium containing 2% DMSO for 24-48 h prevents them from progression into cell cycle by preventing the expression of genes involved in G0-G1 transition of quiescent cells.     

Effects on growth, hemoglobin metabolism and paralogous gene expression resulting from disruption of genes encoding the digestive vacuole plasmepsins of Plasmodium falciparum

Four of the plasmepsins of Plasmodium falciparum are localised in the digestive vacuole (DV) of the asexual blood stage parasite (PfPM1, PfPM2, PfPM4 and PfHAP), and each of these aspartic proteinases has been successfully targeted by gene disruption. This study describes further characterisation of the single-plasmepsin knockout mutants, and the creation and characterisation of double-plasmepsin knockout mutants lacking complete copies of pfpm2 and pfpm1 or pfhap and pfpm2. Double-plasmepsin knockout mutants were created by transfecting pre-existing knockout mutants with a second plasmid knockout construct. PCR and Southern blot analysis demonstrate the integration of a large concatamer of each plasmid construct into the targeted gene. All mutants have been characterised to assess the involvement of the DV plasmepsins in sustaining growth during the asexual blood stage. Analyses reaffirmed that knockout mutants Deltapfpm1 and Deltapfpm4 had lower replication rates in the asexual erythrocytic stage than the parental line (Dd2), but double-plasmepsin knockout mutants lacking intact copies of either pfpm2 and pfpm1, or pfpm2 and pfhap, had normal growth rates compared with Dd2. The amount of crystalline hemozoin produced per parasite during the asexual cycle was measured in each single-plasmepsin knockout to estimate the effect of each DV plasmepsin on hemoglobin digestion. Only Deltapfpm4 had a statistically significant reduction in hemozoin accumulation, indicating that hemoglobin digestion was impaired in this mutant. In the single-plasmepsin knockouts, no statistically significant differences were found in the steady state levels of mRNA from the remaining intact DV plasmepsin genes. Disruption of a DV plasmepsin gene does not affect the accumulation of mRNA encoding the remaining paralogous plasmepsins, and Western blot analysis confirmed that the accumulation of the paralogous plasmepsins in each knockout mutant was similar among all clones examined.     

Sustained Food Vacuole Formation by Axenic Paramecium tetraurelia and the Inhibition of Membrane Recycling by Alcian Blue

It is believed that the uptake mechanism of some nutrients by Paramecium tetraurelia primarily involves transport through the cell surface, whereas the uptake of other compounds appears to be restricted to bulk transport during food vacuole (phagosome) formation. In this study, we established that, in axenically grown cells, food vacuole formation occurred at continuous rates over long periods. This information allows quantitation of the volume of media taken up by bulk transport. India ink and latex beads were shown to be inert food vacuole markers and carmine was found to have an initial stimulatory effect on phagosome formation rates. Cultures grown for 3.5 h or longer with the glycocalyx stain Alcian Blue, contained only three phagosomes/cell, whereas cells cultured with the other markers contained 15 phagosomes/cell. Electron microscopy of fecal material that accumulated at the bottom of Alcian Blue-grown cells demonstrated the presence of membranes, suggesting that the vacuolar membrane was eliminated during defecation. Neither cell lysis nor the formation of autophagous vacuoles was detected in Alcian Blue-grown cells, indicating that the stain was not cytotoxic at the concentrations used. Thus it appeared that the binding of Alcian Blue to the digestive vacuole membrane resulted in a loss of the vacuole membranes from the cell which reduced the amount of membranes retrieved and recycled and hence eventually reduced the rate of phagosome formation. Alcian Blue-treated cultures exhibited decreased rate of growth and final density, which is consistent with a decrease in bulk transport of nutrients resulting from reduced membranes of digestive cycle organelles available in the cell.     

Sustained food vacuole formation by axenic Paramecium tetraurelia and the inhibition of membrane recycling by Alcian Blue.

It is believed that the uptake mechanism of some nutrients by Paramecium tetraurelia primarily involves transport through the cell surface, whereas the uptake of other compounds appears to be restricted to bulk transport during food vacuole (phagosome) formation. In this study, we established that, in axenically grown cells, food vacuole formation occurred at continuous rates over long periods. This information allows quantitation of the volume of media taken up by bulk transport. India ink and latex beads were shown to be inert food vacuole markers and carmine was found to have an initial stimulatory effect on phagosome formation rates. Cultures grown for 3.5 h or longer with the glycocalyx stain Alcian Blue, contained only three phagosomes/cell, whereas cells cultured with the other markers contained 15 phagosomes/cell. Electron microscopy of fecal material that accumulated at the bottom of Alcian Blue-grown cells demonstrated the presence of membranes, suggesting that the vacuolar membrane was eliminated during defecation. Neither cell lysis nor the formation of autophagous vacuoles was detected in Alcian Blue-grown cells, indicating that the stain was not cytotoxic at the concentrations used. Thus it appeared that the binding of Alcian Blue to the digestive vacuole membrane resulted in a loss of the vacuole membranes from the cell which reduced the amount of membranes retrieved and recycled and hence eventually reduced the rate of phagosome formation. Alcian Blue-treated cultures exhibited decreased rate of growth and final density, which is consistent with a decrease in bulk transport of nutrients resulting from reduced membranes of digestive cycle organelles available in the cell.     

Sequential study on the influence of adriamycin on cell proliferation and ultrastructure of cultured mammary tumor cells

The time-dependent cytocidal and growth inhibitory effects of Adriamycin (ADM) on monolayer cultures of 7,12-dimethylbenz[a]anthracene (DMBA)-induced mammary tumor cells were analyzed. The inhibitory effect on cell proliferation was assessed by colony formation in soft agar. Growth inhibition and [3H]thymidine labeling indices clearly demonstrate a dose-dependent antimitotic and cytotoxic effect of the drug. At low concentrations (10(-9)-10(-8) M), 90-100% of cells survived 24-hr exposure. At a higher concentration (10(-5) M), 75-80% of cells survived after 8-hr exposure; by 72 hr only 20-30% of the cells remained. Autoradiographic examination of the pulse-labeled cultures demonstrated no change in the proportion of cells in S-phase during the first 4 hr of treatment. Subsequently DNA synthesis was completely abolished and remained inhibited for the duration of the experiment (72 hr). Clonogenic assay revealed a complete arrest of growth in cells exposed to 10(-5) M ADM and greater than 60% inhibition of cell proliferation at 10(-7) M. Ultrastructural changes were not observed in cells during the first 4 hr of treatment; however, after 8 hr most surviving cells exhibited alterations in nuclear chromatin. The surviving cells showed mitochondrial degeneration, myelin body formation, and vacuolization of the endoplasmic reticulum. This study shows the potential usefulness of the primary culture system in drug evaluation. In addition, serial observation of the effects of ADM revealed a cell subpopulation of the primary culture with differential sensitivity to the drug.     

Digestive system membranes: freeze-fracture evidence for differentiation and flow in Paramecium

Freeze-fractured membranes of digestive vacuoles of randomly feeding Paramecium caudatum exhibit dramatic differences in intramembrane particle (IMP) number and distribution on both E- and P-fracture faces. By pulse-feeding latex spheres to cells we have demonstrated that these differences are related to the age of the digestive vacuoles, and that the membranes of such vacuoles undergo a specific sequence of changes during the digestive cycle. Young digestive vacuoles (DV-I; less than or equal to 6 min), nascent vacuoles still connected to the cytopharynx, and discoidal vesicles, from which vacuole membrane is derived, all have a highly particulate E face and a less particulate P face. As early as 3 min after feeding, a second category of digestive vacuoles (DV-II) can be recognized, which are both considerably smaller in diameter and lack particles on their E face. These findings suggest that the endocytic removal of DV-I membrane material associated with the formation of DV-II vacuoles involves a concomitant and selective removal of E-face particles, as essentially no changes are seen in the density of P-face particles on the two types of vacuoles. Beginning at 10 min the first DV-III vacuoles are encountered. These are both larger than the DV-II vacuoles and possess very prominent E-face particles, which resemble those on the E face of the numerous lysosomes bordering the digestive vacuoles. DV-III vacuoles also exhibit a substantial increase in P-face particles. These membrane changes closely parallel, and are probably correlated with, the physiological events occurring within the vacuole lumen: concentration of food, killing of prey, and digestion. Calculations of the amount of membrane removed from DV-I to form DV-II and of the increase in membrane surface area during the transition from DV-II to DV-III indicate that as much as 90% of the initial phagosome (DV-I) membrane can be removed before digestion begins. The enlargment of DV-II must be caused by fusion with adjacent lysosomes which also contribute the new populations of IMPs to the DV- III membrane. The appearance of numerous endocytic structures on older DV-III vacuoles suggests that membrane is retrieved from DV-III before defecation.     

Critical roles for the digestive vacuole plasmepsins of Plasmodium falciparum in vacuolar function

Knockout mutants of Plasmodium falciparum lacking pfpm1, pfpm2 and pfhap (triple-PM KO), and mutants lacking all four digestive vacuole (DV) plasmepsins (pfpm4, pfpm1, pfpm2 and pfhap; quadruple-PM KO), were prepared by double cross-over integration effecting chromosomal deletions of up to 14.6 kb. The triple-PM KO was similar to the parental line (3D7) in growth rate, morphology and sensitivity to proteinase inhibitors. The quadruple-PM KO showed a significantly slower rate of growth in standard medium, which manifested as delayed schizont maturation accompanied by reduced formation of haemozoin. In amino acid-limited medium, the reduction in growth rate of the quadruple-PM KO was pronounced. The sensitivity of both the triple- and quadruple-PM KOs to six different HIV aspartic proteinase inhibitors was comparable to that of 3D7, thus establishing that the DV plasmepsins were not the primary targets of the antimalarial activity of these clinically important compounds. Electron microscopic analysis revealed the presence of multilamellar bodies resembling ceroid in the DV of the quadruple-PM KO, and intermediates of the autophagic pathway accumulated as determined by Western blot analysis. Thus, the DV plasmepsins, although not essential, contribute significantly to the fitness of the parasite and are required for efficient degradation of endosomal vesicles delivered to the DV.     

Effect of dimethylsulfoxide on the morphology and proliferation of the tumor NGUK-1 cell line

The effects of low doses of dimethyl sulfoxide (DMSO) on the growth and morphology of tumour NGUK-1 strain cells from neurinoma were studied. DMSO produced a dose-dependent reduction in the proliferative capacity. 3% and 5% DMSO concentration inhibited the mitotic activity in the culture and the entry of cells into S-phase of the cell cycle, which was demonstrated by decreased mitotic and thymidine-labelling index. Electron microscopic studies at these DMSO concentrations have revealed large cisterns of rough endoplasmic reticulum with electron dense fine granules. Nucleoli had a spongy structure. DMSO induced stimulation of protein synthesis in cells. At greater DMSO concentrations almost all the cells died. At a 1% concentration DMSO had no effect on cellular morphology and proliferation of in vitro propagated tumour cells.     

Phagosome fusion vesicles of Paramecium. II. Freeze-fracture evidence for membrane replacement

Phagosome fusion vesicles (PFVs), a new population of relatively large granules in Paramecium caudatum which fuse with the first stage of digestive vacuoles (DV-I) shortly after these vacuoles are released from the cytopharynx (their site of formation), have been studied by using the freeze-fracture technique. Identification of PFVs is possible in the resulting replicas at all sites where they are commonly found in thin sections, at the cytopharynx, bound but not fused with nascent digestive vacuoles and fused with released vacuoles in the cell's posterior end. These PFVs have membranes which do not resemble the membranes of the forming digestive vacuole membrane or the discoidal vesicle membranes from which vacuole membrane is derived. Their smooth E-fracture face with only 50 to 100 intramembrane particles (IMPs) per micrometers 2 and particulate P-face (approximately 2500 IMPs/micrometers) do resemble the second vacuole stage (DV-II) which is characterized by a smaller diameter and acid pH. Evidence is presented for PFV fusion with the DV-I and for membrane replacement, at least in part, as the DV-I becomes a DV-II. Membrane replacement entails first adding PFVs to the DV-I and then removing the original discoidal vesicle-derived membrane as tubules as the vacuole condenses. Implications of the possible role of PFVs in forming intravacuolar symbiotic relationships are also discussed.     

Distribution of Acid Phosphatase in Paramecium caudatum: Its Relations with the Process of Digestion

SYNOPSIS. The distribution of acid phosphatase was investigated at the ultrastructural level in Paramecium caudatum. Acid phosphatase occurs in endoplasmic reticulum, Golgi apparatus, food vacuoles, autophagic vesicles, vacuolar and dense bodies. Some slight deposits are also seen in the mitochondria.
These observations point out that this hydrolase activity is related to digestive processes. The enzyme, originating from the endoplasmic reticulum and Golgi apparatus reaches the food vacuole or autophagic vesicle likely via the reticulum. The digestion of the bacteria or of the enclosed organelle gives rise to electronopaque material which is later found in dense bodies. These dense bodies are likely secondary lysosomes and it is possible that they may fuse with the young food vacuole or with autophagic vesicles.     

Reciprocal regulation of adult rat hepatocyte growth and functional activities in culture by dimethyl sulfoxide

Hepatocyte DNA synthesis, initiated by epidermal growth factor (EGF), is reversibly inhibited by 2% dimethyl sulfoxide (DMSO). At that concentration, both the survival of the cells in culture and the expression of differentiated functions are prolonged. DMSO does not affect thymidine uptake or EGF receptor binding. Moreover, EGF receptor binding is maintained at 84% of initial 12 hr binding when cells are cultured for several days in the presence of DMSO, whereas specific receptor binding declines to 49% of initial binding under standard culture conditions without DMSO. Studies of hepatocyte functional activity indicate that, during early culture, total cellular export protein synthesis, specific albumin synthesis, and glycogen synthesis are enhanced in the presence of DMSO. Dexamethasone is required for the effect of DMSO on survival, and although dexamethasone alone enhances hepatocyte DNA synthesis in the presence of EGF, it does not reverse the inhibitory effect of 2% DMSO on DNA replication. The correlation of prolonged survival with growth inhibition supports the hypothesis that hepatic growth and differentiated functional activity may be reciprocally regulated.