Dimethyl sulfoxide restores contact inhibition-induced growth arrest and inhibits cell density-dependent apoptosis in hamster cells.

Most nontransformed cell lines respond to confluence by arresting the cell cycle in a viable G(1) phase, whereas immortalized cell lines growing in monolayer do not stop cell cycle progression in response to high cell density and are subjected to density-dependent apoptosis. We have examined the effects, in terms of cell growth, apoptosis, and expression of adhesion molecules of culturing contact inhibition-deficient hamster cells in the presence of dimethyl sulfoxide (DMSO). Addition of 1.5% DMSO to the growth medium for 96 h arrested Chinese hamster ovary (CHO) cells in the G(1) phase as a confluent monolayer, associated with a remarkable increase in the expression of the cyclin-dependent kinase inhibitor p27. Cells cultured in DMSO-containing medium showed increased levels of cadherins and alpha5beta1 and beta1 integrin complexes. Cell exposure to DMSO also reduced both cell density-dependent apoptosis and necrosis and resulted in increased Bcl-2 expression. These results converge to indicate that DMSO restores contact inhibition-induced growth arrest and prevents high-density-dependent apoptosis and suggest that the effect of DMSO may be mediated by intracellular signaling triggered by cell-extracellular matrix and cell-cell interactions. Both p27 and bcl-2 appear to be involved in the resumption of growth control accompanying cell adhesion in DMSO-exposed CHO cells.     

Guanine nucleotide regulation of adenylate cyclase in permeabilized cells of Saccharomyces cerevisiae

Adenylate cyclase in permeabilized cells of Saccharomyces cerevisiae was examined. Among various permeabilization procedures, including organic solvents, detergents and other reagents, dimethylsulfoxide (DMSO) and digitonin treatments resulted in the highest recovery of adenylate cyclase activity. Incubation of cells at 30 degrees C with digitonin at 0.01% to 0.1%, or DMSO at 20% to 40% for 15 to 30 min gave optimal adenylate cyclase activity. The enzyme activity in digitonin-permeabilized cells could be supported only by Mn2+, whereas Mg2+ with or without guanine nucleotides did not support cyclase activity. DMSO-permeabilized cells exhibit efficient Mn2+- and Mg2+/Gpp[NH]p-dependent stimulation. Furthermore, digitonin added to yeast membranes at a 1:50 detergent to protein ratio (w/w) abolishes guanyl nucleotide regulation without significantly affecting the Mn2+-supported cyclase activity. The superiority of DMSO is further supported by the fact that recovery of adenylate cyclase activity is better in the DMSO-treated cells than in the digitonin-treated cells. DMSO most probably causes less disturbance of the fabric of the native cell. We conclude that digitonin, but not DMSO, uncouples the catalytic unit of adenylate cyclase from the regulatory GTP binding (ras) proteins.     

Effects of dimethyl sulfoxide (DMSO) on microfilament organization, cellular adhesion, and growth of cultured mouse B16 melanoma cells

Cell shape is involved in a variety of cellular activities including proliferation, adhesion, migration, and transformation. Agents known to promote differentiation, such as retinoic acid, butyrate, and dibutyryl cyclic AMP, induce marked alterations in cell shape which are often accompanied by changes in cell functions. In this paper we study the effects of the differentiating polar solvent dimethyl sulfoxide (DMSO) on cytoskeleton, adhesion, and growth properties of cultured mouse B16 melanoma cells. DMSO induced a progressive reorganization of the cytoskeleton which was fully developed in 4 days of continuous exposure to the agent. DMSO-treated cells developed thick and regularly oriented microfilament bundles of the stress fiber type ending at vinculin-rich areas of focal contact between the ventral membrane and the substratum (interference reflection microscopydark adhesion plaques). Such a rearrangement of the cytoskeleton resulted in increased adhesion to the substratum and inhibition of cell growth in comparison to control untreated cells. Cells which became highly flattened and tightly adherent after exposure to DMSO for 4 days progressively reverted their phenotype to that of control untreated cells within 3 days of DMSO withdrawal. Namely, they lost stress fibers and adhesion plaques, became rounded and less adherent, and increased their growth rate. These results indicate that DMSO can change the transformed appearance of B16 mouse melanoma cells to a phenotype which is typical of a variety of nontransformed cells in culture.     

Expression of human tyrosine kinase, Lck, in yeast Saccharomyces cerevisiae: growth suppression and strategy for inhibitor screening

We report the successful expression and detection of a phosphorylated form of human T cell tyrosine kinase, Lck, in Saccharomyes cerevisiae, which leads to growth suppression of the yeast cells. Expression of an inactive Lck mutant resulted in no phosphorylation and no growth suppression, indicating that cell growth inhibition by Lck is due to the activity of the kinase, consistent with the observed tyrosine-phosphorylation of the Lck and yeast host cell proteins. The addition of a known inhibitor of Lck to the cell culture resulted in recovery of cell growth expressing the active Lck, suggesting that the growth inhibition by lck gene expression can be used to screen inhibitors for the gene product. We have extended such approach to Tob, another potential therapeutic target.     

Potent inhibition of cell density-dependent apoptosis and enhancement of survival by dimethyl sulfoxide in human myeloblastic HL-60 cells

Human myeloblastic cell line HL-60 cells undergo apoptosis during in vitro culture in a cell density-dependent manner, and this cell density-dependent apoptosis was observed when the concentration of cultured cells exceeded 8–10 × 10⁵ cells/ml. Dimethyl sulfoxide (DMSO), a differentiation inducer of HL-60 cells, did not amplify, but rather potently inhibited, this apoptosis. In a low density culture condition, DMSO attenuated proliferation of HL-60 cells in spite of its inhibition of apoptosis. In contrast, DMSO did support cell survival under high cell density conditions, and DMSO-treated HL-60 cells reached an extremely high concentration of 2–3 × 10⁶ cells/ml, a condition which could never be possible in a usual culture environment. Thus, DMSO exerted dual effects on cell proliferation, i.e., growth inhibition and apoptosis inhibition, and the sum of these effects resulted in an apparently distinct phenomenon according to the culture conditions including cell density. J. Cell. Physiol. 174:135–143, 1998. © 1998 Wiley-Liss, Inc.     

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.     

Carbon source-dependent regulation of cell growth by murine protein kinase C epsilon expression in Saccharomyces cerevisiae

Protein kinase C is known to play a role in cell cycle regulation in both lower and higher eucaryotic cells. Since mutations in yeast proteins involved in cell cycle regulation can often be rescued by the mammalian homolog and since significant conservation exists between PKC-signalling pathways in yeast and mammalian cells, cell cycle regulation by mammalian PKC isoforms may be effectively studied in a simpler genetically-accessible model system such as Saccharomyces cerevisiae. With this objective in mind, we transfected S. cerevisiae cells with a plasmid (pYECepsilon) coding for the expression of murine protein kinase C epsilon (PKCepsilon) under the control of a galactose-inducible promoter. Unlike mock-transfected cells, yeast cells transformed with pYECepsilon expressed, in a galactose-dependent manner, an 89 kDa protein that was recognized by a human PKCepsilon antibody. Extracts from these pYECepsilon-transfected cells could phosphorylate a PKCepsilon substrate peptide in a phospholipid/phorbol ester-dependent manner. Moreover, this catalytic activity could be inhibited by a fusion protein in which the regulatory domain of murine PKCepsilon was fused in frame with GST (GST-Repsilon), further confirming the successful expression of murine PKCepsilon. Induction of PKCepsilon expression by galactose in cells transformed with pYECepsilon increased Ca++ uptake by the cells approximately 5-fold and resulted in a dramatic inhibition of cell growth in glycerol. However, when glucose was used as the carbon source, PKCepsilon expression had no effect on cell growth. This was in contrast to what was observed upon bovine PKCalpha or PKCbeta-I expression in yeast, where expression of these PKC isoforms strongly and moderately inhibited growth in glucose, respectively. Visualization of the cells by phase contrast microscopy indicated that murine PKCepsilon expression in the presence of glycerol resulted in a significant increase in the number of yeast cells exhibiting very small buds. Since overall growth of the cells was dramatically decreased, the data suggests that PKCepsilon expression potently inhibits the progression of yeast cells through the cell cycle after the initiation of budding. In addition, a small amount of the PKCepsilon-expressing yeast cells (1-2%) exhibited gross alterations in cell morphology and defects in both chromosome segregation and septum formation. This suggests that for those cells which do complete DNA synthesis, murine PKCepsilon expression may nevertheless inhibit yeast cell growth by retarding and/or imparing cell division. Taken together, the data suggests murine PKCepsilon expression potently reduces the growth of yeast cells in a carbon source-dependent fashion by affecting progression through multiple points within the cell cycle. This murine PKCepsilon-expressing yeast strain may serve as a very useful tool in the elucidation of mechanism(s) by which external environmental signals (possibly through specific PKC isoforms) regulate cell cycle progression in both yeast and mammalian cells.     

海藻酸微囊替代DMSO和FBS的STO细胞冷冻保存研穷

目的：改进现有的细胞冷冻保存方法,建立一个不舍二甲基亚砜（DMSO）和血清（FBS）的高效冷冻保存方法,为细胞治疗等临床实践提供优质细胞。方法：海藻酸微囊包埋鼠胚成纤维细胞（STO细胞）后用不含DMSO和FBS的冷冻保存液进行冷冻保存。,设四个对照组：添加10％DMSO和20％FBS的组、仅添加10％DMSO的组、仅添加20％FBS、DMSO和FBS均不添加组。在冷冻前后对各实验组细胞用台盼兰染色,进行细胞计数,计算细胞存活率,同时利用溴乙锭的二聚物（EthD）、钙黄绿素-AM（Calcein—AM）进行染色观察细胞的形态,且进一步验证细胞存活率;解冻复苏后用MTT法评估细胞的增殖速度和生长活力。结果：冷冻保存30天后对各组的细胞数量、细胞存活率、细胞形态和解冻复苏后细胞的生长活力进行比较发现,海藻酸微囊包埋冷冻组的细胞数、细胞存活率、细胞形态和生长活力均与添加DMSO和FBS的组之间无显著性差异,而与其它三个对照组呈显著性差异。结论：使用海藻酸微囊替代DMSO和FBS保存STO细胞,能有效的维持细胞形态、数量、存活率,同时不影响细胞的生长活力,从而建立了一个不含DMS0和FBS的高效冷冻保存方法。     

Interactions of dimethyl sulfoxide and granulocyte-macrophage colony-stimulating factors on the growth and maturation of HL-60 cells

We have studied the interactions of dimethyl sulfoxide (DMSO), Giant Cell Tumor (GCT) cell-conditioned medium (GCT CM), and highly purified granulocyte-macrophage colony-stimulating factors (GM-CSF) on the growth and maturation of a highly passaged population of HL-60 cells. DMSO produced dose-dependent inhibition of HL-60 growth in liquid and semisolid media. Growth was partially to completely restored by the addition of GCT CM to cultures. Experiments in which cell volume, cell cycle kinetics, tritiated thymidine (3HTdr) incorporation, cell number, and nitroblue tetrazolium (NBT) reduction were compared during culture indicated that DMSO inhibited the spontaneous increase in cell volume and flow of cells through the cell cycle which occurred in the first day of culture, the increase in 3HTdr incorporation which was detectable by day 2; and the increment in cell counts which occurred by day 3. These effects were opposed by GCT CM. In contrast, the DMSO-induced increase in NBT reduction which occurred by day 6 was not influenced by GCT CM. The major principle opposing DMSO was GM-CSF, since (1) highly purified GM-CSF from GCT cells and recombinant GM-CSF from COS cells transfected with the Mo cell GM-CSF gene overcame greater than 50% of DMSO inhibition; and (2) conditioned media from cells not producing CSF, G-CSF from GCT cells, and recombinant G-CSF from Escherichia coli transfected with the G-CSF gene from 5,637 cells were inactive. DMSO had little or no effect on the elaboration of autostimulatory activity by HL-60 cells. DMSO is a useful agent for inhibiting the spontaneous growth of HL-60 cells and restoring their dependence on GM-CSF, a property which may be mediated through the effects of DMSO on cell cycle kinetics and/or maturation.     

Reversible G1 arrest in the cell cycle of human lymphoid cell lines by dimethyl sulfoxide

Proliferation of human B- and T-lymphoid cell lines including Raji and Akata cells was found to be arrested at the G1 stage in the cell cycle by dimethyl sulfoxide (DMSO). The G1 arrest by DMSO occurred gradually and was completed within 96 h after addition of 1.5% DMSO concomitantly with a decrease in growth rate. Progression of G1-phase cells containing a larger amount of RNA into S-phase began 9-12 h after removal of DMSO. At 24 h, the DNA pattern of the cell cycle was similar to that of nontreated log-phase cells. The expression of six differentiation markers on the lymphoid cells was not appreciably changed by treatment with DMSO. On the other hand, the expression of transferrin receptor (one of the growth-related markers) on G1-phase cells 96 h after addition of DMSO was decreased to one-fourth that on log-phase cells and was completely restored 24 h after removal of DMSO. These results indicate that DMSO, known as an inducer of differentiation in several myeloid cell lines, acts as an agent inducing G1 arrest in the cell cycle of the lymphoid cells.     

Modulation of trophoblast stem cell and giant cell phenotypes: analyses using the Rcho-1 cell model

Trophoblast giant cells are located at the maternal-embryonic interface and have fundamental roles in the invasive and endocrine phenotypes of the rodent placenta. In this report, we describe the experimental modulation of trophoblast stem cell and trophoblast giant cell phenotypes using the Rcho-1 trophoblast cell model. Rcho-1 trophoblast cells can be manipulated to proliferate or differentiate into trophoblast giant cells. Differentiated Rcho-1 trophoblast cells are invasive and possess an endocrine phenotype, including the production of members of the prolactin (PRL) family. Dimethyl sulfoxide (DMSO), a known differentiation-inducing agent, was found to possess profound effects on the in vitro development of trophoblast cells. Exposure to DMSO, at non-toxic concentrations, inhibited trophoblast giant cell differentiation in a dose-dependent manner. These concentrations of DMSO did not significantly affect trophoblast cell proliferation or survival. Trophoblast cells exposed to DMSO exhibited an altered morphology; they were clustered in tightly packed colonies. Trophoblast giant cell formation was disrupted, as was the expression of members of the PRL gene family. The effects of DMSO were reversible. Removal of DMSO resulted in the formation of trophoblast giant cells and expression of the PRL gene family. The phenotype of the DMSO-treated cells was further determined by examining the expression of a battery of genes characteristic of trophoblast stem cells and differentiated trophoblast cell lineages. DMSO treatment had a striking stimulatory effect on eomesodermin expression and a reciprocal inhibitory effect on Hand1 expression. In summary, DMSO reversibly inhibits trophoblast differentiation and induces a quiescent state, which mimics some but not all aspects of the trophoblast stem cell phenotype.     

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.     

Suppressive effect of delta 9-tetrahydrocannabinol in vitro on phagocytosis by murine macrophages

Incubation of normal mouse peritoneal cells consisting of over 90% phagocytizing macrophages with delta 9-tetrahydrocannabinol (THC) resulted in a inhibition of phagocytic function. The THC in a dose-related manner suppressed the percentage of macrophages per culture which ingested yeast and the average number of yeast particles ingested by the phagocytizing macrophages. The vehicle used to suspend the THC in vitro, i.e., DMSO, had no detectable effect on macrophage function. Suppression of phagocytosis with no effects on viability or cell number occurred with doses of 10 micrograms or less THC per milliliter culture medium. Measurable suppression also occurred after 24- to 48-hr treatment of the macrophages with the THC. This compound had little if any detectable effect on phagocytosis when added directly to the cultures shortly before testing for phagocytosis. Further studies concerning the effects of THC on macrophage function appear warranted.     

Effect of tunicamycin on germ tube and yeast bud formation in Candida albicans

Tunicamycin is an antimicrobial agent which inhibits the first reaction of the dolichol pathway leading to N-glycosylation of proteins. The effect of tunicamycin on the growth of the dimorphic fungus Candida albicans differed depending on the growth phase of the organism. Addition of tunicamycin to stationary phase yeast cells inhibited the resumption of growth of those cells in either morphology, as cultures failed to initiate either yeast bud or germ tube formation. When tunicamycin was added to growing cells, growth was inhibited but not immediately. When it was added to germ tube cultures, nuclear division and septum formation continued for some time before ceasing. Addition of the drug to exponential phase yeast cultures resulted in an approximately 45% increase in cell number before cell division ceased and yeast accumulated in both budded and unbudded stages of the cell cycle. Accumulation of trichloroacetic acid precipitable radiolabelled protein and nucleic acid continued unchanged for some time following addition of tunicamycin; however, after a while a reduced rate of accumulation was noted.     

Expression of death receptor 4 induces caspase-independent cell death in MMS-treated yeast

DR4, a tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) receptor, is a key element in the extrinsic pathway of TRAIL/TRAIL receptor-related apoptosis that exerts a preferential toxic effect against tumor cells. However, TRAIL and DR4 are expressed in various normal cells, and recent studies indicate that DR4 has a number of non-apoptotic functions. In this study, we evaluated the effects of human DR4 expression in yeast to determine the function of DR4 in normal cells. The expression of DR4 in yeast caused G1 arrest, which resulted in transient growth inhibition. Moreover, treatment of DR4-expressing yeast with a DNA damaging agent, MMS, elicited drastic, and sustained cell growth inhibition accompanied with massive apoptotic cell death. Further analysis revealed that cell death in the presence of DNA damage and DR4 expression was not dependent on the yeast caspase, YCA1. Taken together, these results indicate that DR4 triggers caspase-independent programmed cell death during the response of normal cells to DNA damage.     

Flocculence of Saccharomyces cerevisiae cells is induced by nutrient limitation, with cell surface hydrophobicity as a major determinant.

Initiation of flocculation ability of Saccharomyces cerevisiae MPY1 cells was observed at the moment the cells stop dividing because of nitrogen limitation. A shift in concentration of the limiting nutrient resulted in a corresponding shift in cell division and initiation of flocculence. Other limitations also led to initiation of flocculence, with magnesium limitation as the exception. Magnesium-limited S. cerevisiae cells did not flocculate at any stage of growth. Cell surface hydrophobicity was found to be strongly correlated with the ability of the yeast cells to flocculate. Hydrophobicity sharply increased at the end of the logarithmic growth phase, shortly before initiation of flocculation ability. Treatments of cells which resulted in a decrease in hydrophobicity also yielded a decrease in flocculation ability. Similarly, the presence of polycations increased both hydrophobicity and the ability to flocculate. Magnesium-limited cells were found to be strongly affected in cell surface hydrophobicity. A proteinaceous cell surface factor(s) was identified as a flocculin. This heat-stable component had a strong emulsifying activity, and appears to be involved in both cell surface hydrophobicity and in flocculation ability of the yeast cells.     

Flocculence of Saccharomyces cerevisiae cells is induced by nutrient limitation, with cell surface hydrophobicity as a major determinant.

Initiation of flocculation ability of Saccharomyces cerevisiae MPY1 cells was observed at the moment the cells stop dividing because of nitrogen limitation. A shift in concentration of the limiting nutrient resulted in a corresponding shift in cell division and initiation of flocculence. Other limitations also led to initiation of flocculence, with magnesium limitation as the exception. Magnesium-limited S. cerevisiae cells did not flocculate at any stage of growth. Cell surface hydrophobicity was found to be strongly correlated with the ability of the yeast cells to flocculate. Hydrophobicity sharply increased at the end of the logarithmic growth phase, shortly before initiation of flocculation ability. Treatments of cells which resulted in a decrease in hydrophobicity also yielded a decrease in flocculation ability. Similarly, the presence of polycations increased both hydrophobicity and the ability to flocculate. Magnesium-limited cells were found to be strongly affected in cell surface hydrophobicity. A proteinaceous cell surface factor(s) was identified as a flocculin. This heat-stable component had a strong emulsifying activity, and appears to be involved in both cell surface hydrophobicity and in flocculation ability of the yeast cells.     

The effect of cryopreservation on the cytogenetic characteristics of a cell subline of skin fibroblasts from the Indian muntjac

After thawing cells, previously cryopreserved in the presence of dimethyl sulfoxide (DMSO), a decrease in their viability and increase in unscheduled DNA synthesis was observed. In 7 days, these parameters restored to the control level. Cryopreservation without DMSO resulted in the decrease in both cell viability and replicative and unscheduled DNA synthesis. In 14 days, these characteristics were seen to return to the normal level. Cryopreservation of cells without DMSO and their preservation in liquid nitrogen induced the frequency of chromosomal aberrations, mostly chromosomal breaks. The frequency of chromosomal aberrations increased with the duration of cell preservation in liquid nitrogen. The normal level was achieved following 7 days after cell thawing. Cells treated with DMSO only (without cryopreservation) display an increased number of chromosomal and chromatid breaks and translocations. Nonrandom distribution of chromosomal aberrations was observed, with particular chromosomes being involved in the appearance of dicentrics and translocations. The data obtained indicate that cryoprotective activity of DMSO is probably associated with the cell repair systems. The detected antimutagenic and mutagenic activity of DMSO may presumably reflect various conditions for its interaction with cells (with or without cryopreservation), as well as it may be specific for the muntjac cell line used in the present work.     

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)