Idoxuridine in Herpes Zoster: Further Evaluation of Intermittent Topical Therapy

In a randomized double-blind controlled trial of the value of intermittent topical idoxuridine in treating herpes zoster in 118 patients idoxuridine 5% in 100% dimethyl sulphoxide (DMSO), applied four-hourly for four days, significantly shortened the vesicular phase, healing time, and duration of pain; idoxuridine 25% applied two-hourly produced no greater benefit. The only side effects were transient tender erythema in three patients and “urticarial” oedema in two patients with dermographia.     

The influence of different freezing procedures and different cryoprotective agents on the immunological capacity of frozen-stored lymphocytes

The influence of a series of factors on the frozen storage of lymphocytes was investigated. The cells were frozen using different freezing programmes, using the cryoprotectants dimethyl sulphoxide and glycerol in different concentrations in the freezing medium, and with variations in the period of exposure of cells to cryoprotectants before freezing and after thawing. Cell viability was evaluated by quantitative measurements of the cell-mediated immune response after stimulation with phytohemagglutinin, pokeweed mitogen, concanavalin A, and allogenic cells in mixed lymphocyte cultures. The factors investigated were found to have an important effect on the immune response, so that careful investigation and exact specification of the freezing system are necessary before frozen cells are used in blast-transformation tests. The best freezing programme had a duration of approximately 40 min with a smooth progression through the temperature range where phase transition takes place. The optimum dimethyl sulphoxide concentration in this programme was 8–10%. Dimethyl sulphoxide had no toxic effect on the cells, and no equilibration period was necessary prior to freezing. An equilibration period of 15 min with 10% glycerol was even better than the optimum programme with dimethyl sulphoxide.     

Stabilization of Na+, K+-adenosine triphosphatase by dimethyl sulfoxide under inactivation by urea]

Hydrophobic agents, e.g. methanol, ethanol, isopropanol, acetone and dioxane were shown to induce irreversible inactivation of Na+, K+-adenosine triphosphatase beginning with their concentrations of 20 to 35%, whereas dimethyl sulphoxide exerted similar effect only at concentration of 50% and higher. Urea also irreversibly inactivated Na+, K+-adenosine triphosphatase, beginning with a concentration of about 20%. It was found that, dimethyl sulphoxide contrary to the other hydrophobic agents studied, protected Na+, K+-adenosine triphosphatase against the inactivating (denaturing) action of urea. The highest stabilizing effect of dimethyl sulphoxide was displayed at concentrations from 20 to 30%.     

Studies on horseradish peroxidase in dimethyl sulphoxide/water mixtures. The activation of hydrogen peroxide and the binding of fluoride.

We studied the variation in spectra and in reactivity towards H2O2 of solutions of horseradish peroxidase in dimethyl sulphoxide/water mixtures, obtained by diluting stock solutions of the enzyme in either water or dimethyl sulphoxide, and assayed the enzyme activity and studied the binding of F- by the peroxidase in 65% (v/v) dimethyl sulphoxide. A broadly similar pattern of changes is observed whether one starts from water or from dimethyl sulphoxide; the changes are essentially reversible, though hysteresis is observed. When the dimethyl sulphoxide content of the solvent mixture is increased, the peroxidase retains its ability to activate H2O2 up to 74% (v/v) dimethyl sulphoxide. The peroxidase in 65% (v/v) dimethyl sulphoxide binds F- together with a proton (or the equivalent loss of HO-), as already established for aqueous solutions. We point out that the occurrence in such solutions of both the ability to activate H2O2 and the inability to bind F- without taking up H+ or losing HO- supports the proposed mechanism for activating H202, whereby the protein binds the substrate in the form of the much more reactive HO2-.     

Studies on haemin in dimethyl sulphoxide/water mixtures.

The nature of the complexes and equilibria shown by solutions of protohaemin in dimethyl sulphoxide/water mixtures and in the presence of acid and base were studied by u.v.-visible spectrophotometry. In neutral solutions containing from 40 to 100% dimethyl sulphoxide, haemin is present as a monomeric complex in which the Cl-ion is not coordinated. Only a single pH-dependent equilibrium pK12 is observed over the range 40-80% dimethylsulphoxide, corresponding to formation of the mu-oxo dimer. As the dimethyl sulphoxide content is lowered below 35%, so the single equilibrium (pK12) is replaced by two equilibria (pK1 and pK2); with solutions of 5 microM-haemin, pK1 decreases (from pK12 7.55 in 65% dimethyl sulphoxide to pK1 approx. 1.5 in 0.01% dimethyl sulphoxide), whereas pK2 hardly changes (from pK12 7.55 in 65% to pK2 approx. 7.5 in 0.01%).     

Chromatographic separation of methionine,methionine sulphoxide,methionine sulphone,and their products of oral microbial metabolism

The metabolic pathways of methionine sulphoxide and methionine sulphone were investigated employing a combination of gas chromatography, thin-layer chromatography, paper chromatography, and radioactive methods of analyses. Gas chromatographic analysis demonstrated that methionine, methionine sulphoxide, and methionine sulphone all yielded qualitatively similar volatile sulphur compounds, namely, methyl mercaptan, dimethyl disulphide, and small amounts of dimethyl sulphide. The study indicated that the principal pathway of methionine sulphoxide and methionine sulphone metabolism is mediated via methionine which gives rise to methyl mercaptan, part of which is oxidized to dimethyl disulphide. Whereas methionine sulphoxide was readily reduced to methionine, the reduction of methionine sulphone proceeded at a considerably slower rate.     

Fatty acid utilization during development of the rat

The effects of dimethyl sulphoxide and glycerol on ox brain microsomal Na(+)+K(+)-stimulated adenosine triphosphatase (EC 3.6.1.3), K(+)-stimulated p-nitrophenyl phosphatase and K(+)-dependent muscle pyruvate kinase (EC 2.7.1.40) were studied. Dimethyl sulphoxide at concentrations below 20% (v/v) was found to stimulate the p-nitrophenyl phosphatase and pyruvate kinase by increasing their affinity for K(+) but to inhibit the Na(+)+K(+)-stimulated adenosine triphosphatase. The latter enzyme activity was also inhibited by glycerol, which like dimethyl sulphoxide, stimulated the K(+)-activated p-nitrophenyl phosphatase at a wide range of concentrations. The solvent effects were promptly reversed by dilution. Similarity was found between glycerol and dimethyl sulphoxide, on one hand, and ATP, on the other, in their stimulatory effect and their ability to increase the ouabain- and oligomycin-sensitivity of the K(+)-stimulated p-nitrophenyl phosphatase. However, only the solvents, not the ATP, increased the binding of K(+) by the microsomes. From the above findings it is suggested that solvents may act on K(+)-dependent enzymes by altering the state of solvation of the activating cation as well as by changing the enzyme structure.     

Dimethyl sulphoxide: A review of its applications in cell biology

Dimethyl sulphoxide is a water miscible solvent that has wide applications in cell biology. It acts as a cryoprotective agent in a variety of cells and tissues allowing prolonged storage at subzero temperatures. The action of dimethyl sulphoxide on the stability of the liquid matrix of cell membranes appears to be responsible for its effects and this appears also to be true for related effects on membrane permeability and fusion. Dimethyl sulphoxide is also known to act as an inducer of cellular differentiation and as a free radical scavenger and radioprotectant. A review of the underlying molecular basis of all these effects of dimethyl sulphoxide is presented.     

Isolation and analysis of lignin-carbohydrate complexes from Lolium multiflorum

Lignin-carbohydrate complexes were extracted from grass cell walls by a variety of solvents. The yield of complexes was greatly enhanced if the sample was finely milled in a ball mill; dimethyl sulphoxide and N alkali extractions gave the highest yields. Hydrolysis showed that the carbohydrate fraction of the alkali-extracted complex contained mainly xylose (ca. 70%) and arabinose (ca. 20 %) whereas the dimethyl sulphoxide extracted complex contained glucose (ca. 50 %), xylose (ca. 30%), arabinose (ca. 12 %) and galactose (ca. 5 %). The UV spectrum of the dimethyl sulphoxide extracted complex showed lignin absorbance at 280 nm, but, in addition, ester bonding was also observed by the presence of a secondary absorbing region near 325 nm. This secondary absorbing region was absent from the spectrum of the alkali-extracted complexes. Fractionation of the complexes by ethanol precipitation gave a major component which appeared homogeneous by molecular sieve chromatography and had a MW of ? 150,000.     

Chemolithotrophic potential of a Hyphomicrobium species,capable of growth on methylated sulphur compounds

The yield of Hyphomicrobium EG on dimethyl sulphoxide, dimethyl sulphide and methylamine, considering the metabolic pathways of these compounds, suggested that the organism gained energy from the oxidation of the sulphur moiety of the former compounds. Indeed, a comparison of chemostat cultures of Hyphomicrobium EG grown on methylamine in the presence and absence of sulphide or thiosulphate proved this obligate methylotroph to be a chemolithoheterotroph. The apparent Y_sulphide and Y_thiosulphate were comparable, being 8–10 g dry weight/mol. In batch cultures thiosulphate concentrations up to 10 mM had a stimulatory effect on the growth rate of Hyphomicrobium EG, whereas higher concentrations increased the organisms doubling time.Enzyme- and respiration data showed that the organism had constitutive enzymes for the breakdown of dimethyl sulphoxide although they were clearly regulated to need. Addition of sulphide or thiosulphate to methylamine-limited chemostat cultures of Hyphomicrobium EG not only resulted in the induction of enzymes necessary for their breakdown, but also caused the enzymes for dimethyl sulphoxide metabolism, especially methyl mercaptan oxidase, to be induced. The formation of H₂O₂, a product of the latter enzyme, was reflected in the relatively high catalase activities during growth on dimethyl sulphoxide and in the organisms inability to grow on this compound in the presence of a catalase inhibitor.Abbreviations DMSO dimethyl sulphoxide - DMS dimethyl sulphide - MM methyl mercaptan - TMAO trimethylamine N-oxide - D dilution rate - GSH redticed glutathione - DCPIP 2,6-dichlorophenolindophenol - PMS phenazine methosulphate - PES phenazine ethosulphate - RubPCase ribulose 1,5-bisphosphate carboxylase - PEPCase phosphoenol pyruvate carboxylase - Wurster's blue (TMPD) N,N,N,N-tetramethyl-p-phenylenediamine     

The modulation of membrane structure and stability by dimethyl sulphoxide (Review)

Dimethyl sulphoxide is a widely used agent in cell biology. It is well known as a cryoprotectant, cell fusogen and a permeability enhancing agent. These applications depend, to a greater or lesser extent, on the effect of dimethyl sulphoxide on the stability and dynamics of biomembranes. The aim of this review is to examine progress of the research which has been directed towards studies of the interactions between dimethyl sulphoxide and membranes, particularly that with the lipid components of cell membranes, as seen in its effects on model membrane systems. Models are proposed to explain the mechanism whereby dimethyl sulphoxide may mediate its effects on biological functions by its effects on the stability and properties of the membrane lipid matrix.     

Effect of dimethyl sulphoxide and some antibiotics on cultured human T-lymphoma cells as measured by microcalorimetry

The influence of dimethyl sulphoxide (I), penicillin/streptomycin (II), gentamicin (III), and amphotericin B (IV) on growing human T-lymphoma cells was measured by microcalorimetry. There was a dose-dependent decrease in the heat production rate of the cells after 24 h of incubation with I in concentrations ranging from 0-2% (v/v). At 3.6%, about half of the cells died. II and III had no effect on the cells after incubation for 6 days, at concentrations from 1 to 10 times that of the normal (50-500 IU/ml; 50-500 micrograms/ml). IV was used in combination with II (50 IU/ml; 50 micrograms/ml) and III (50 micrograms/ml), respectively, at concentrations between 0.25 and 7.5 micrograms/ml. After 6 days of incubation, the results were similar to those obtained with II and III separately.     

Influence of dimethyl sulphoxide on intermediate filament proteins in human rhabdomyosarcoma cell lines: modulation at subcellular level

Summary The effects of dimethyl sulphoxide have been investigated on differentiation in human rhabdomyosarcoma cell lines obtained from typically malignant, poorly differentiated tumours. The expression of cell differentiation marker proteins (desmin and vimentin) was assessed in cell lines A-204, A-673 and RD, and the modifications in expression after 3, 8 and 24 h of induction with 1.25% dimethyl sulphoxide were recorded. Protein expression in both the cytoplasm and cytoskeleton was significantly altered by treatments lasting 8 and 24 h, the most noteworthy changes being increased desmin and decreased vimentin expression. The results clearly indicate that dimethyl sulphoxide induced changes typical of differentiation in rhabdomyosarcoma cell lines A-673 and RD; less marked changes were observed in line A-204.     

Chromosome doubling procedures of onion (<Emphasis Type="Italic">Allium cepa</Emphasis> L.) gynogenic embryos

A novel approach for chromosome doubling that consists of treating embryos instead of parts of micropropagated plants was investigated. Following 2-year trials, amiprofos-methyl (APM) was found to be superior to oryzalin on the basis of a lower toxicity, and we were able to narrow the range of concentrations of APM. The addition of 2% dimethyl sulphoxide (DMSO) and 1% Triton X-100 to 25 microM APM had no effect in all treatments. A final experiment with 6,658 embryos demonstrated that a 2-day treatment in liquid media supplemented with 50 microM APM was the most successful with respect to chromosome doubling-36.7% of the plants were diploid-but the survival rate was reduced to 52.5% of that of the non-treated control. A 2-day treatment in liquid medium supplemented with 25 microM APM or a 2-day treatment on solid medium with 50 microM APM resulted in the production of diploids at a frequency of 28.9% and 21.3%, respectively. These may represent alternative methods for chromosome doubling since compared to the untreated control these two treatments reduced the survival rate by only about 24%. Final ploidy and fertility of the large proportion of induced mixoploid plants (up to 30.3%) need to be evaluated in further studies.     

Osmotically inactive volume, hydraulic conductivity, and permeability to dimethyl sulphoxide of human mature oocytes

Controlled ovarian stimulation during an in vitro fertilization cycle usually produces large numbers of oocytes and, consequently, it is likely that more embryos will be generated than can be transferred in a given cycle. It is desirable to freeze-bank surplus oocytes before insemination to avoid the ethical and legal complications of disposing of or storing embryos. Although many attempts have been made to cryopreserve human oocytes, to date, post-thaw survival has been poor, and viable pregnancies after in vitro fertilization have been rare. A possible explanation for the lack of success is that the freezing methods have been adapted from animal studies but have not been optimized for the human oocyte. In this study, video microscopy was used to determine the volumetric responses of mature human oocytes to changes in osmolarity during preparation for freezing. A Boyle van't Hoff plot of data collected in static experiments with fresh human oocytes gave a value of 0.19 +/- 0.01 (mean +/- SEM) for the osmotically inactive volume. Dynamic measurements during exposure to dimethyl sulphoxide at room temperature (22 degrees C) were analysed by a two-parameter transport model and produced values of 1.30 x 10(-6) cm atm-1 s-1 for the hydraulic conductivity of the plasma membrane and 3.15 x 10(-5) cm s-1 for dimethyl sulphoxide permeability (chi-squared = 0.43, df = 20) of fresh human oocytes. Oocytes that had failed to fertilize had a slightly lower hydraulic conductivity and dimethyl sulphoxide permeability and, after exposure to 1.5 mol dimethyl sulphoxide l-1, these cells appeared to become permeable to normally impermeable solutes. These permeability properties have been used to design a protocol for the addition and removal of dimethyl sulphoxide to control the magnitude of volumetric changes.     

Dimethyl sulphoxide reduction by micro-organisms.

Dimethyl sulphoxide (DMSO) was reduced to dimethyl sulphide by a wide variety of micro-organism, including prokaryotes and eukaryotes, aerobes and anaerobes. Dimethyl sulphone was not reduced by any of the organisms tested. Cell-free extracts of Escherichia coli reduced DMSO using reduced pyridine nucleotides as electron donors. Activity was greater in anaerobically grown cells than in those grown aerobically. Two other sulphoxides, methionine sulphoxide and tetramethylene sulphoxide, substantially inhibited DMSO reduction by extracts. Mutants of E. coli, which were unable to reduce biotin sulphoxide to biotin, were tested for their ability to reduce DMSO in whole cells and extracts. These mutants were in four different gene loci, bisA to bisD. DMSO reductase activity of the mutants was generally less than that of the wild-type strain, and activity depended upon the gene locus involved, the growth medium and the growth conditions. Only the bisA mutant had very low activity under all conditions. All of the bis mutants were able to grow using methionine sulphoxide as a sulphur source, indicating that biotin sulphoxide and methionine sulphoxide are reduced by different enzyme systems. DMSO may be reduced by both of these enzyme systems.     

Effect of dimethyl sulphoxide on the crystal structure of porcine pepsin

The structure of porcine pepsin crystallized in the presence of dimethyl sulphoxide has been analysed by X-ray crystallography to obtain insights into the structural events that occur at the onset of chemical denaturation of proteins. The results show that one dimethyl sulphoxide molecule occupies a site on the surface of pepsin interacting with two of its residues. An increase in the average temperature factor of pepsin in the presence of dimethyl sulphoxide has been observed indicating protein destabilization induced by the denaturant. Significant increase in the temperature factor and weakening of the electron density have been observed for the catalytic water molecule located between the active aspartates. The conformation of pepsin remains unchanged in the crystal structure. However, the enzyme assay and circular dichroism studies indicate that dimethyl sulphoxide causes a slight change in the secondary structure and complete loss of activity of pepsin in solution.     

The glucan components of the cell wall of baker''s yeast (Saccharomyces cerevisiae) considered in relation to its ultrastructure

1. Commercial pressed baker's yeast, and cell walls prepared from it, were extracted in various ways and the products examined by a number of techniques, including infrared spectroscopy and electron microscopy. 2. The glucan components of the walls cannot be extracted from intact yeast cells by 3% (w/v) sodium hydroxide at 75 degrees , but at least one-third of the glucan of cell wall preparations is dissolved under these conditions, and more will dissolve after ultrasonic treatment. 3. If intact cells are given a preliminary treatment with acid the wall glucans dissolve in dilute aqueous alkali. 4. Acid conditions as mild as sodium acetate buffer, pH5.0, for 3hr. at 75 degrees are sufficient for this preliminary treatment; the glucan then dissolves in 3% sodium hydroxide at 75 degrees leaving a very small residue, which contains chitin and about 1% of the initial glucan of the wall. Dissolution is hindered by exclusion of air, or by a preliminary reduction with sodium borohydride, suggesting that some degradation of the glucan by alkali is taking place. 5. After treatment with 0.5m-acetic acid for 24hr. at 90 degrees the glucan dissolves slowly at room temperature in 3% sodium hydroxide, or in dimethyl sulphoxide. The extraction with acetic acid removes glycogen and a predominantly beta-(1-->6)-linked glucan (not hitherto recognized as a component of baker's yeast), but none of the beta-(1-->3)-glucan, which remains water-insoluble. 6. Without treatment with acid, the glucan is not significantly soluble in dimethyl sulphoxide, but can be induced to dissolve by ultrasonic treatment. 7. These results are interpreted by postulating the presence of an enclosing membrane, composed of chitin and glucan, that when intact acts as a semipermeable membrane preventing the escape of the alkali- and dimethyl sulphoxide-soluble fraction of the glucan. Mild acid treatments damage this membrane, and ultrasonic and ballistic disintegration disrupt it. 8. Some support for this hypothesis is given by the effects of certain enzyme preparations, which have been found to render a substantial part of the glucan extractable by dimethyl sulphoxide.     

Bupivacaine hydrochloride induces muscle fiber necrosis and hydroxyl radical formation-dimethyl sulphoxide reduces hydroxyl radical formation

We induced acute skeletal muscle necrosis in rats using bupivacaine hydrochloride and found that both 2,5- and 2,3-dihydroxybenzoic acid significantly increased in skeletal muscle. A single administration of dimethyl sulphoxide, a free radical scavenger, significantly lowered concentrations of 2,5- and 2,3-dihydroxybenzoic acid. These results suggest that dimethyl sulphoxide is an effective hydroxyl radical scavenger and may be useful in the treatment of myopathy.     

Effect of capsaicin and dimethyl sulphoxide (DMSO) on ion transport in isolated skin of frog (Rana esculenta L.)

The effects ofcapsaicin, dimethyl sulphoxide and pH changes on transport of sodium and/or chlorine ions in an isolated frog skin, were studied using electrophysiological methods, adapted to evaluation of ionic currents occurring in the epithelial tissues and organs. The experiment consisted in measuring potential difference (PD in mV) of an isolated skin of the aquatic frog, Rana esculenta L., placed in a Ussing apparatus. The ionic transport processes were modified through incubation of the tissue in Ringer solution and in Ringer solution supplemented with amiloride, bumetanide, and also with dimethyl sulphoxide. The direct effect of capsaicin and dimethyl sulphoxide (DMSO) on frog skin was assessed while these compounds were added to the Ussing chamber with a pipette and a peristaltic pump. Adaptive reactions of the tissue were assessed following at least 60-min exposure to those compounds. It has been demonstrated that amiloride-inhibited sodium ion transport and acidification of the incubation medium (pH 6.4) inhibited mechanically induced epithelium reactions. Both compounds, capsaicin and DMSO modified ionic transport processes depending on the mechanical stimulation.