Antistress effect of dimethyl sulfoxide in the rat

Administration of scavenger of hydroxyl radicals--dimethylsulfoxide (1 g/kg intraperitoneally, daily for 3 weeks) did not lead to any significant changes in animals behaviour in the open field and in visceral functions (arterial pressure, respiratory rate, heart rate) but prevented shifts of these characteristics caused by chronic 3-week emotional-pain stress. In rats injected with dimethylsulfoxide, an increase was observed of superoxide dismutase activity in the brain and blood serum. Molecular mechanisms are discussed of antistress action of dimethylsulfoxide (scavenge of hydroxyl radicals, activation of superoxide dismutase) and possible role of hydroxyl radicals in realization of damaging action of stress on the organism.     

Cryoprotection by dimethyl sulfoxide and dimethyl sulfone

Preservation of cells and tissues at low temperatures requires the presence of effective cryoprotectants with low toxicity to which cells are relatively permeable. Two similar compounds, dimethyl sulfoxide (DMSO) and dimethyl sulfone (DMSO2), exhibit both features for cryoprotectants, yet DMSO is a very effective cryoprotectant while DMSO2 is ineffective. This anomaly was investigated by relating observations on the phase behavior of DMSO and DMSO2 in aqueous solutions to the recovery of human lymphocytes frozen in the presence of these compounds. The lack of cryoprotection in the presence of DMSO2 appears to be due to the precipitation of DMSO2 from the solution at subzero temperatures. The observation of reduced cell recovery after freezing with increasing concentrations of DMSO2 implies that cell damage is related to the amount of solid DMSO2 present. Precipitation of DMSO2 occurs both intra- and extracellularly, but it is argued that intracellular precipitation of DMSO2 is the damaging phenomenon. Cryoprotective compounds are normally selected based on the criteria of low toxicity and permeability to the plasma membrane. An additional condition, solubility, must be included for interpretation of experimental data and for development of effective protocols for cryopreservation.     

Organization of dimethyl sulfoxide reductase in the plasma membrane of Escherichia coli.

Dimethyl sulfoxide reductase is a trimeric, membrane-bound, iron-sulfur molybdoenzyme induced in Escherichia coli under anaerobic growth conditions. The enzyme catalyzes the reduction of dimethyl sulfoxide, trimethylamine N-oxide, and a variety of S- and N-oxide compounds. The topology of dimethyl sulfoxide reductase subunits was probed by a combination of techniques. Immunoblot analysis of the periplasmic proteins from the osmotic shock and chloroform wash fluids indicated that the subunits were not free in the periplasm. The reductase was susceptible to proteases in everted membrane vesicles, but the enzyme in outer membrane-permeabilized cells became protease sensitive only after detergent solubilization of the E. coli plasma membrane. Lactoperoxidase catalyzed the iodination of each of the three subunits in an everted membrane vesicle preparation. Antibodies to dimethyl sulfoxide reductase and fumarate reductase specifically agglutinated the everted membrane vesicles. No TnphoA fusions could be found in the dmsA or -B genes, indicating that these subunits were not translocated to the periplasm. Immunogold electron microscopy of everted membrane vesicles and thin sections by using antibodies to the DmsABC, DmsA, DmsB subunits resulted in specific labeling of the cytoplasmic surface of the inner membrane. These results show that the DmsA (catalytic subunit) and DmsB (electron transfer subunit) are membrane-extrinsic subunits facing the cytoplasmic side of the plasma membrane.     

Lipid membrane structure and interactions in dimethyl sulfoxide/water mixtures.

In this paper we have investigated via x-ray diffraction the influence of dimethyl sulfoxide (DMSO), known for its biological and therapeutic properties, on the structure of lipid membranes of dipalmitoylphosphatidylcholine (DPPC) in excess of the solvent (DMSO/water) at mole DMSO fractions XDMSO in (0.1) and under equilibrium conditions. At small XDMSO </= 0.133 the repeat distance d is reduced remarkably, whereas wide-angle x-ray diffraction pattern remains almost unchanged with the increase in XDMSO. It agrees well with previous study (Yu and Quinn, 1995). At 0.133 < XDMSO < 0.3 the repeat period d reduces slowly; however, an orthorombic in-plane lattice of hydrocarbon chains transfers to a disordered quasihexagonal lattice. The increase in XDMSO from 0.3 up to approximately 0.9 leaves d almost unchanged, whereas it leads to less disordered packing of hydrocarbon chains. At XDMSO approximately 0.9, Lbeta' phase transfers into interdigitated phase. The chain-melting phase transition temperature of DPPC membranes increases by several degrees with the increase of DMSO concentration. It points to a strong concentration-dependent solvation of membrane surface by DMSO. Thus DMSO strongly interacts with the membrane surface, probably displacing water and modifying the structure of the lipid bilayer. It appears to determine some of the properties of DMSO as a biologically and therapeutically active substance.     

Spin label reduction kinetics,a procedure to study the effect of drugs on membrane permeability: The effects of monosodium urate,dimethyl sulfoxide and amphotericin B

A method is presented to study the effect of drugs on membrane permeability. It is based on the reduction of a spin label trapped in the internal aqueous compartment(s) of membranes by ascorbate ions added to the bulk aqueous phase. The decay of the electron spin resonance signal of the spin label as a function of time gives an indication of the effect of added agents on the permeability of membranes. To demonstrate the technique, the effect on model membranes of egg phosphatidylcholine of the gout-implicated compound monosodium urate, the aprotic solvent dimethyl sulfoxide and the polyene antibiotic amphotericin B were examined. Monosodium urate did not affect the permeability, casting doubt on a proposed mechanism whereby the agent disrupts the membranes via hydrogen bonding. Dimethyl sulfoxide promoted a gradual increase in rate of solute passage across cholesterol-containing model membranes. Amphotericin B had pronounced effect on the permeability of cholesterol-containing membranes, causing nearly total loss of paramagnetism immediately after addition. Some aspects of the mechanism of action of the drugs are discussed as well as the advantages and disadvantages of the method. The experiments also allow the evaluation of the effect of surface charge and cholesterol on the dimensions of model membranes.     

Cytochemical demonstration of adenylate cyclase in cardiac muscle: effect of dimethyl sulfoxide.

Adenylate cyclase (AC) activity was evaluated after perfusion fixation of rat and dog myocardium with 4% paraformaldehyde (PFA), 2% glutaraldehyde (GA) or a combination of both, in cacodylate buffer. Dimethyl sulfoxide (DMSO) was added to the fixatives and its effect on the preservation of cell organelles and enzyme activity was determined. Adenylate cyclase activity was preserved best after fixation with 4% paraformaldehyde but this fixative did not provide for optimal maintenance of structure. Prefixation with 2% glutaraldehyde and 5% dimethyl sulfoxide provided the most effective preservation of both structural and enzymatic integrity. Precipitation of lead diphosphoimide was the morphologic indicator of sites of adenylate cyclase activity. The most intense precipitate was in the lumen of junctional sarcoplasmic reticulum in close contact with T-tubules and in subsarcolemmal cisternae. Evidence of activity was also seen on the intracellular aspect of the sarcolemmal membrane and in the nexus segment of the intercalated discs. Alloxan was effective as an inhibitor of adenylate cyclase activity only if the concentration of the activating substance sodium fluoride (NaF) was 20 mM or lower.     

Mitochondrial morphology and function impaired by dimethyl sulfoxide and dimethyl Formamide

In this work, the effects of two non-ionic, non-hydroxyl organic solvents, dimethyl sulfoxide (DMSO) and dimethyl formamide (DMF) on the morphology and function of isolated rat hepatic mitochondria were investigated and compared. Mitochondrial ultrastructures impaired by DMSO and DMF were clearly observed by transmission electron microscopy. Spectroscopic and polarographic results demonstrated that organic solvents induced mitochondrial swelling, enhanced the permeation to H⁺/K⁺, collapsed the potential inner mitochondrial membrane (IMM), and increased the IMM fluidity. Moreover, with organic solvents addition, the outer mitochondrial membrane (OMM) was broken, accompanied with the release of Cytochrome c, which could activate cell apoptosis signaling pathway. The role of DMSO and DMF in enhancing permeation or transient water pore formation in the mitochondrial phospholipid bilayer might be the main reason for the mitochondrial morphology and function impaired. Mitochondrial dysfunctions induced by the two organic solvents were dose-dependent, but the extents varied. Ethanol (EtOH) showed the highest potential damage on the mitochondrial morphology and functions, followed by DMF and DMSO.     

Denaturation of RNA with dimethyl sulfoxide

The denaturation of single-stranded and double-stranded RNA's in solutions with varying proportions of dimethyl sulfoxide has been followed by changes in absorbancy, optical rotation, and—with a double-stranded form of bacteriophage of MS2 RNA— infectivity for bacterial spheroplasts. By these criteria the RNA's studied, including the synthetic polynucleotide rG:rC, are completely denatured at room temperature in high concentrations of this solvent. In lower concentrations, the T_m of the RNA preparation is decreased only slightly as the dimethyl sulfoxide concentration is raised until a critical concentration is reached. The T_m falls sharply with small further increases in dimethyl sulfoxide concentration. Sedimentation studies can be conducted directly in these media. The determination of sedimentation velocity in 99% dimethyl sulfoxide containing 0.001M EDTA provides a reliable estimate of RNA molecular weights.     

The effect of dimethyl sulfoxide on cholesterol and bile acid metabolism in rats

The effect of DMSO on cholesterol and bile acid metabolism was studied in rats. Male Sprague-Dawley rats were randomly assigned to one of two groups and given either tap water or 2% DMSO (v/v) in tap water to drink for 9 days. Both food (stock rat diet) and water were available ad libitum. Animals in both groups gained weight equally throughout the study. They also had similar liver weights (g/100 g body wt) at the end of the study (control: 5.0 +/- 0.1 (N = 6) vs DMSO: 4.9 +/- 0.1 (N = 6]. The activity of hepatic cholesterol 7 alpha-hydroxylase (pmole/mg/min), the rate-limiting enzyme of bile acid biosynthesis, was significantly (P less than 0.005) reduced in the treated animals (control: 9.7 +/- 1.0 (N = 6) vs DMSO: 4.3 +/- 0.7 (N = 6)). Plasma cholesterol (mg/dl) was significantly (P less than 0.005) elevated in the treated animals (control: 90 +/- 3 (N = 6) vs DMSO: 107 +/- 4 (N = 6)), a finding consistent with the reduced CH-7 alpha hydroxylase activity in this group. DMSO treatment did not affect either microsomal cholesterol content or hepatic glutathione content. Thus, this study has shown that DMSO treatment per se can affect cholesterol and bile acid metabolism. However, the precise mechanisms whereby DMSO exerts the observed effects are not known.