Functional preservation of the mammalian kidney. IV. Functional effects of perfusion with dimethyl sulfoxide (DMSO) at normothermia

Rabbit kidneys were perfused at 37 °C with various concentrations of DMSO in a K⁺-Mg²⁺-rich perfusate. The effects of DMSO on various functional parameters of the rabbit kidney perfused for 60 min were compared with the functional effects of perfusion without DMSO under the same conditions. DMSO produced deviations in vascular resistance and perfusate flow rate from control values. In kidneys perfused with 1.4 and 2.8 m DMSO these vascular changes resulted in changes in GFR at relatively unchanged filtration fractions. The closely parallel relationship between changes in GFR and urine flow rate in all groups indicates that perfusion per se or perfusion with DMSO may shift the regulation of urine flow rate from tubular reabsorption, which obtains in the in vivo situation, to glomerular filtration. This view was supported by the relatively unchanged parameters of Na⁺ reabsorption and fractional water excretion during perfusion with all concentrations of DMSO. Additionally, DMSO perfusion resulted in significantly greater weight gains than those observed in kidneys perfused without DMSO, and significantly depressed clearances of PAH, with 2.1 and 2.8 m DMSO.     

Biochemical and morphological differentiation of the human colonic epithelial cell line SW620 in the presence of dimethylsulfoxide.

In vitro models of intestinal cell differentiation provide an important adjunct for studying normal and abnormal intestinal epithelial cell differentiation. The studies reported herein describe morphologic and biochemical changes in the colonic epithelial cell line SW620 following dimethylsulfoxide (DMSO) incubation. Cells cultured in the presence of DMSO showed striking changes in morphology characterized by enlargement, elongation, and formation of process-like structures by light microscopy and a propensity to form microvillus-like structures by electron microscopy. These changes were accompanied by significant differences in the expression of the cell surface markers CD4 (HIV gp120 receptor), CD44 (hyaluronate receptor), and KS1 (adenocarcinoma/epithelial specific antigen). There was a marked decrease in CD4 expression (38% to 2%), an increase in CD44 expression (4% to 50%) and a decrease in KS1 expression (98% to 66%) as detected by flow cytometry following incubation of SW620 cells in DMSO. Parallel changes in the expression of these markers were seen by metabolic and surface labeling studies. Although SW620 cells were infected by HIV-1, DMSO-treated SW620 cells could not be infected. DMSO-induced changes in surface expression of CD4, CD44, and KS-1 were reversible over time upon removal of DMSO from the culture medium. Secretory component, sucrase, neuron-specific enolase, chromogranin-A, and mucin were not detectable in SW620 cells with or without DMSO treatment. SW620 cells provide a useful model for studying specific biochemical and molecular events involved in intestinal epithelial cell differentiation and function.     

Formation of multinuclear cells induced by dimethyl sulfoxide: inhibition of cytokinesis and occurrence of novel nuclear division in Dictyostelium cells

Our previous studies showed that 10 percent dimethyl sulfoxide (DMSO) induces the formation of actin microfilament bundles in the cell nucleus together with the dislocation of cortical microfilaments from the plasma membrane. The present study investigated the effects of DMSO on diverse activities mediated by cellular microfilaments as the second step toward assessing potential differences between nuclear and cytoplasmic actins of dictyostelium mucoroides. DMSO was found to reversibly inhibit cell-to- glass as well as cell-to-cell adhesion, cell locomotion, and cell multiplication, whereas cytoplasmic streaming and phagocytosis were not obviously inhibited. Also, 5 percent DMSO inhibited cytokinesis but did not totally inhibit cell growth thus leading to the development of giant cells more than 10 times larger than normal cells. Transmission electron microscopy using serial thin sections showed the occurrence of multinucleation in the DMSO- induced giant cells. After the removal of DMSO, the giant multinuclear cells underwent multiple cytoplasmic cleavage producing normal-sized mononuclear cells. The nuclear division in the DMSO-induced giant cells was unique in that no spindle microtubules were formed, and vesicles appeared inside the nucleus forming a transverse partition of the nuclear envelope. The presence of actin filaments in those nuclei was demonstrated by a binding study with skeletal muscle myosin subfragment-1, and their possible involvement in this mode of nuclear division is discussed.     

Bcl-XL induction during terminal differentiation of friend erythroleukaemia cells correlates with delay of apoptosis and loss of proliferative capacity but not with haemoglobinization

Friend murine erythroleukaemia (F-MEL) cells are a useful model for studying the processes that regulate erythroid differentiation since exposure of these cells to chemical inducers (DMSO or HMBA) results in commitment to terminal cell division and synthesis of haemoglobin. This study examined the relationship between differentiation and apoptosis in DMSO sensitive and resistant F-MEL cells. Clear apoptosis was not observed in DMSO-treated sensitive F-MEL (strain 745A) cells during the induction of differentiation. In contrast, DMSO-induced 745A cells exhibited delayed apoptosis compared to uninduced cells. Since the Bcl-2 family members play a major role in the control of apoptosis and/or differentiation, we determined their expression before and after DMSO or HMBA treatment. Neither untreated nor chemically-induced 745A cells expressed the Bcl-2 protein. The levels of Bax and Bad proteins remained relatively constant during DMSO-induced differentiation. DMSO or HMBA treatment of 745A cells induced a marked increase of Bcl-XL expression during the late phase of differentiation which persisted even when the cells began to die. This upregulation of Bcl-XL was independent of cell density but was correlated with cell arrest in G0/G1. DMSO treatment induced a similar delay of apoptosis and enhancement of Bcl-XL expression in F-MEL (strain TFP10) cells which fail to synthesize haemoglobin in the presence of DMSO. Dexamethasone, which blocks DMSO-induced differentiation of F-MEL cells, prevented the induction of Bcl-XL. Inhibitors such as imidazole or succinylacetone, which inhibit haemoglobin synthesis but not commitment to terminal cell division, did not suppress Bcl-XL induction in DMSO-induced cells. Taken together, these results indicate that DMSO treatment of F-MEL cells induces a marked increase in Bcl-XL expression suggesting a role for this anti-apoptotic protein in the process of erythroid differentiation in F-MEL cells. Moreover, induction of Bcl-XL during this process seems to be associated with loss of proliferative capacity rather than with haemoglobin synthesis.     

Effects of dimethylsulfoxide on the ultrastructure of fixed cells

It has been reported that the use of dimethylsulfoxide (DMSO) as a solvent for fixatives enhances preservation of cellular ultrastructure. By contrast, we have shown that DMSO alters the ultrastructural integrity of glutaraldehyde fixed cells. The cell membrane, nuclear envelope, endoplasmic reticulum, ribosomes, microtubules and intracytoplasmic organelles are most susceptible to the action of DMSO. We hypothesize that DMSO exerts intracellular alterations via its interaction with remnant interfacial water in fixed cells. DMSO-induced alterations of these and related cellular components may result in the formation of artefactual structures and networks. Thus, it appears that DMSO containing glutaraldehyde neither accelerates fixation nor enhances stabilization of cellular ultrastructure. For these reasons, addition of DMSO to fixatives is not recommended.     

Effects of dimethylsulfoxide on the ultrastructure of fixed cells

It has been reported that the use of dimethylsulfoxide (DMSO) as a solvent for fixatives enhances preservation of cellular ultrastructure. By contrast, we have shown that DMSO alters the ultrastructural integrity of glutaraldehyde fixed cells. The cell membrane, nuclear envelope, endoplasmic reticulum, ribosomes, microtubules and intracytoplasmic organelles are most susceptible to the action of DMSO. We hypothesize that DMSO exerts intracellular alterations via its interaction with remnant interfacial water in fixed cells. DMSO-induced alterations of these and related cellular components may result in the formation of artefactual structures and networks. Thus, it appears that DMSO containing glutaraldehyde neither accelerates fixation nor enhances stabilization of cellular ultrastructure. For these reasons, addition of DMSO to fixatives is not recommended.     

Differing effects of inducers of differentiation on the ribonucleotide pool sized of Friend leukemia cells.

Friend leukemia cells differentiate when any one of a variety of cryoprotective agents are added to their suspension culture media. While dimethyl sulfoxide (DMSO), dimethylacetamide (DMA) and tetramethylurea (TMU) induce a comparable degree of erythroid maturation their effects on the acid soluble ribonucleotide pools differ. DMSO induced differentiation is accompanied by a 70–80% reduction in pool size while DMA and TMA cause only a 15–20% reduction. Furthermore, inhibition of DMSO-induced differentiation by BUdR does not prevent the DMSO-induced reduction in pool size. These data suggest that the decline in pool size is a toxic effect unrelated to differentiation and these effects should be considered when the biological effects of DMSO-induced differentiation are considered.     

5-Azacytidine increases the synthesis of embryonic hemoglobin (E2) in murine erythroleukemic cells

The addition of 5-azacytidine to erythroleukemic cells which were induced to differentiate with DMSO or BA altered the expression of the hemoglobins. After the addition of 5-azacytidine there was an increase in hemoglobin synthesis especially in the embryonic E2 band. The beta-globin increased in synthesis after 5-azacytidine treatment. The level of hemoglobin synthesis in DMSO-induced cells is less than BA-induced cells while the effect of the 5-azacytidine stimulation was greater with DMSO induction than with BA induction.     

Comparison of the effects of adenine-ribose with adenosine for maintenance of ATP concentrations in 5-day hypothermically perfused dog kidneys

The quality of preservation of kidneys is dependent upon a number of factors, one of which may be the concentration of adenine nucleotides in the tissue during long-term perfusion preservation. In this study we have investigated how adenine (5 mM) and ribose (5 mM) in combination affect the concentration of adenine nucleotides in dog kidney cortical tissue after 5 days of continuous hypothermic perfusion preservation. These results were compared to kidneys perfused with adenosine and without any added purine precursors of adenine nucleotide synthesis. Additionally, we investigated how these conditions affected renal tissue slice function after 5 days of preservation and how adenine plus ribose affected renal function after autotransplantation in the dog. Adenosine is nearly completely degraded during 5 days of perfusion but there was little loss of adenine (10%). The adenosine triphosphate concentration in kidney cortical tissue was higher in adenine/ribose-perfused kidneys (1.41 +/- 0.19 mumol/g) than in adenosine-perfused kidneys (0.71 +/- 0.1 mumol/g) after 5 days of preservation. Tissue slices prepared from kidneys preserved in the presence of adenine plus ribose were metabolically more functional (slice volume control and electrolyte pump activity) than slices from adenosine-perfused kidneys. Adenine plus ribose had no detrimental effects on kidneys preserved for 3 days as tested in the autotransplant model but did not yield successful 5-day preservation. Because of some potentially detrimental factors in using adenosine as an adenine nucleotide synthesis precursor, we have now switched to the combination of adenine and ribose for perfusion preservation of kidneys both in the laboratory and in the clinic.     

Early inhibition of phospholipid synthesis in dimethyl sulfoxide (DMSO) treated Friend erythroleukemia (FL) cells.

Phosphate metabolism in Friend erythroleukemia cells undergoing DMSO-induced differentiation was studied. Thirty minutes after the cells were exposed to DMSO in medium at pH 7, an inhibition of 39% in the incorporation of phosphate into phospholipids was observed. This decrease was not due to a change in the precursor pools since phosphate uptake and the phosphorylation of the organic soluble compounds were only inhibited 13%. Inhibition of phospholipid synthesis preceded inhibition of RNA and protein synthesis and reached a maximum after 24 hours of DMSO treatment. At this time, the phospholipid content of the cells was also decreased as compared to that of the control untreated cells. Phospholipid synthesis remained at a level significantly lower than in the controls over the 4-day observation period, at which time 85% of the treated cells were benzidine positive. Separation of the different phospholipids by chromatography on thin layer silicate gel plates showed that, after one hour of DMSO treatment, more than 80% of the radioactivity was in phosphatidylcholine, phosphatidylserine and phosphatidylethanolamine. Phosphatidylethanolamine was the most inhibited. Incorporation of inositol into phospholipid was also significantly decreased. However, there was little variation in the phospholipid composition of the treated and non-treated cells other than a decrease in the percent of sphingomyelin after 48 hours of DMSO treatment. These changes in phospholipid metabolism may initiate the first step in the complex differentiation process. The phospholipids are important components of membranes and the inducers are known to influence their fluidity.     

Assessment of Renal Function in Patients with Unilateral Ureteral Obstruction Using Whole-Organ Perfusion Imaging with 320-Detector Row Computed Tomography

Background

Obstructed nephropathy is a common complication of several disease processes. Accurate evaluation of the functional status of the obstructed kidney is important to achieve a good outcome. The purpose of this study was to investigate renal cortical and medullary perfusion changes associated with unilateral ureteral obstruction (UUO) using whole-organ perfusion imaging with 320-detector row computed tomography (CT).

Methodology/Principle Findings

Sixty-four patients with UUO underwent whole-organ CT perfusion imaging. Patients were divided into 3 groups, mild, moderate, and severe, based on hydronephrosis severity. Twenty sex- and age-matched patients without renal disease, who referred to abdominal CT, were chosen as control subjects. Mean cortical and medullary perfusion parameters of obstructed and contralateral kidneys were compared, and mean perfusion ratios between obstructed and contralateral kidneys were calculated and compared. Mean cortical or medullary blood flow (BF) and blood volume (BV) of the obstructed kidneys in the moderate UUO and BF, BV, and clearance (CL) in the severe UUO were significantly lower than those of the contralateral kidneys (p < 0.05). The mean cortical or medullary BF of the obstructed kidney in the moderate UUO, and BF, BV, and CL in the severe UUO were significantly lower than those of the kidneys in control subjects (p < 0.05). Mean cortical or medullary BF of the non-obstructed kidneys in the severe UUO were statistically greater than that of normal kidneys in control subjects (p < 0.05). An inverse correlation was observed between cortical and medullary perfusion ratios and grades of hydronephosis (p < 0.01).

Conclusions/Significance

Perfusion measurements of the whole kidney can be obtained with 320-detector row CT, and estimated perfusion ratios have potential for quantitatively evaluating UUO renal injury grades.     

Differentiation of human trophoblast cells in vitro is inhibited by dimethylsulfoxide

Dimethyl sulfoxide (DMSO) exerts a number of biological effects, the most frequently cited being induction of cell differentiation. The compound also increases invasiveness and metastatic potential. In contrast to the many reports of DMSO-induced cell differentiation, we report here that DMSO inhibits the morphological differentiation of human cytotrophoblast cells to syncytiotrophoblast, as revealed by immunofluorescence staining for desmosomal protein and nuclei. Cytotrophoblast cells treated with DMSO under differentiation-inducing conditions remained mononucleated with intense desmosomal staining. The effect was dose dependent, with a maximal effect seen at 1.5% DMSO. Concentrations of ≤0.5% had no effect and concentrations >2% were cytotoxic. In addition to these morphological changes, DMSO inhibited secretion of human chorionic gonadotropin in a dose-dependent manner. At a concentration of 1.5%, DMSO inhibited secretion by 70%. If cytotrophoblast cells were cultured in the presence of DMSO and then switched to DMSO-free medium, they proceeded to differentiate normally. While the precise mechanism of action remains unknown, judicious use of DMSO may be a useful tool for studying and manipulating the differentiation of human trophoblast cells in vitro. The findings also indicate that care should be used in interpreting results obtained using DMSO as a carrier in drug and inhibitor studies. J. Cell Biochem. 65:460–468. © 1997 Wiley-Liss Inc.     

Amiloride in differentiation and commitment of Friend erythroleukemia cells

Dimethylsulfoxide (DMSO) converts almost all of the undifferentiated murine erythroleukemia cells (MEL or Friend cells, clone 745A) in a culture to differentiated cells that contain high levels of hemoglobin and that stop growing after a limited number of cell divisions. Contrary to other reports--that amiloride strongly inhibits DMSO-induced differentiation in MEL cells--in this laboratory, inhibition by amiloride, tested with DMSO over a range of concentrations in two kinds of media and at various cell densities, was found to be only weak or absent. Similarly, amiloride did not inhibit induction by N,N'-hexamethylene bis-acetamide (HMBA). As expected from previous findings with other cell systems, amiloride inhibited protein synthesis and cell multiplication.     

Effects of cyclic AMP on the growth of differentiating and undifferentiated Friend erythroleukemic cells.

Elevated concentrations of cyclic AMP elicit only minor reductions in growth rate and saturation density in undifferentiated Friend erythroleukemic cells. During the course of dimethylsulfoxide (DMSO)-induced differentiation, Friend cells convert from a cyclic AMP-tolerant state to a phenotype characterized by a high degree of sensitivity to cyclic AMP-mediated growth arrest. Conversion to cyclic AMP sensitivity is detectable after 30 hours growth in medium containing 2% DMSO, and either 0.5 mM 8-Br-cyclic AMP or 5 nM cholera toxin. Cultures of differentiating Friend cells achieved a stationary phase density that was approximately 8-fold higher than the cell density observed in parallel, differentiating cultures treated with 0.5 mM 8-Br-cyclic AMP. Temporally, the appearance of cyclic AMP-sensitivity corresponds to the early expression of in vitro erythroid differentiation (Ross et al., '74), but growth arrest does not alter the subsequent accumulation of hemoglobin in non-dividing DMSO-induced cells. Since growth arrest is preceded by a round of cell division, these observations are consistent with the concept that DMSO must be present during DNA replication for the subsequent expression of hemoglobin synthesis (McClintock and Papaconstantinou, '74; Levy et al., '75; Harrison, '76).     

A SEM analysis of DMSO treated hydra polyps

Summary— Scanning electron microscopy revealed that exposure of hydra polyps to DMSO at concentrations used for permeabilizing tissue results in striking changes in epithelial cell morphology. Epithelial cells from treated polyps rounded up in shape and formed numerous large blebs at the cell surface. Along the borders of epithelial cells numerous small projections became detectable. The DMSO-induced changes at the cell surface corresponded to drastic changes in the intracellular organization. No evidence could be found for DMSO induced opening of cell junctions and/or opening of the interstitial space. The results demonstrate that DMSO affects the morphology and intracellular organization of hydra epithelial cells. Thus, caution is necessary in interpreting cell behavior in DMSO treated tissue.     

Differential response of three types of actin filament bundles to depletion of cellular ATP levels

The effect of low levels of ATP on actin filament bundles in PtK2 cells was investigated by using 2-deoxyglucose, together with either sodium cyanide, sodium azide, or 2,4-dinitrophenol. Three actin filament systems were examined: stress fibers, cleavage rings, and dimethyl-sulfoxide (DMSO)-induced actin bundles in the nucleus. Of the three, only stress fibers disassembled when the ATP production was inhibited. The disassembly progressed slowly with the cells losing all stress fibers after about 90 min, but remaining in flat interconnected sheets. Mitotic cells that had progressed as far as metaphase when inhibitors were added, assembled cleavage rings. The process of cytokinesis took place in these cells but at a rate 5 to 10 times slower than normal, and disassembly of the cleavage ring was inhibited after the completion of cytokinesis. DMSO-induced nuclear actin bundles did not disassemble in cells depleted of ATP even when DMSO was eliminated from the medium. The peripheral aggregates of contractile proteins present in these cells became redistributed, however, and the cells flattened in the low ATP environment when DMSO was removed. Nuclear actin bundles did not form in DMSO-treated cells if the ATP inhibitors were present for as little as 5 min prior to DMSO exposure. Thus, the three types of actin filament bundles are affected in different ways by low intracellular levels of ATP. Stress fibers are most sensitive and cleavage rings, the least.