Effect of D2O on maize plasmalemma ATPase and electron transport coupled proton pumping.

Heavy water (D2O) has been used as a putative inhibitor of the plasma membrane H(+)-ATPase and the plasma membrane redox system. Concentrations above 50% D2O inhibited H+ secretion and the plasma membrane redox system of Zea mays L. roots. Inhibition of H+ secretion by vanadate was reduced in presence of D2O. The plasma membrane of roots was transiently depolarized after the addition of heavy water in concentrations above 5%. The repolarization of the plasma membrane that takes place while the H+ secretion is still reduced by heavy water indicates that, despite the overall inhibiting effect of D2O, the plant is still able to regulate the membrane potential.     

D2O inhibition of interphase thymocyte death]

Using the method of flow cytometry and biochemical analysis it was shown that D2O, an agent that stabilizes microtubules, prevented the internucleosome fragmentation of DNA in thymocytes exposed to gamma radiation and dexamethasone in vitro. It was also found that D2O is ineffective with respect to Ca2+/Mg2(+)-dependent nuclease. The transfer of irradiated cells from a medium containing 90% of D2O to a normal one caused rapid DNA degradation; the fragmentation process ceased with the irradiated cells being transferred from H2O to heavy water. The results obtained permit us to assume that the disturbance of microtubules is not a trigger mechanism of DNA degradation by apoptosis, but is some intermediate stage of cell death preceding the chromatin fragmentation proper.     

Deuterium oxide (heavy water) arrests the cell cycle of PtK2 cells during interphase.

Deuterium oxide (D2O, heavy water) exerts an antiproliferative effect on a variety of cells in vitro and on some organisms. This effect is mainly ascribed to a tubulin-mediated antimitotic action. We evaluated the morphology, the mitotic activity, and the dynamics of the cell cycle of PtK2 cells grown in vitro in the presence of 75% D2O for up to eight weeks by microspectrophotometric DNA measurements as well as flow cytometric analysis and a determination of mitotic indices. Substitution of heavy water for water in the culture medium initially increased the mitotic index by a (pro-) metaphase block but after 2 to 3 days of incubation no mitotic figures were seen. Analysis of cells grown for 6 days in medium containing 75% D2O revealed accumulation of cells in S/G2-phase. Extended treatment stabilized the high level of cells in this specific phase, when compared to normal growing cells. Cells grown for 1 to 6 weeks in the presence of D2O remained non-proliferating, nevertheless, they were able to divide again after recovery in non-deuterated medium. The time needed for resumption of the mitotic activity was proportional to the duration of deuterium oxide exposure. Cells incubated for 8 weeks in 75% D2O did not recommence mitotic activity. Light and electron microscopic examination revealed characteristic morphological changes of size and ciliation in PtK2 cells subjected to prolonged deuteration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deuterium oxide effects upon three parameters characterizing the activity of glycerol-extracted muscle: phosphate release, ATP-induced shortening, and 22Na+ distribution

ATP splitting activity is progressively reduced with increasing heavy water (D2)) concentration. In contrast, sarcomere shorteining inhibition produced by D2O does not significantly depend on its concentration. Even at low concentration, the presence of D2O does reduce the excessive accumulation of radioactive sodium within glycerinated frog muscle. These heavy water effects on muscular contraction and soidum distribution can be interpreted to indicate adsorbed water within the cells. Evaluation of these experimental results in terms of Gibbs free enthalpy of binding at the adsorption sites of D20 or H20 is in good agreement with the data in the literature.     

Effect of heavy water on the viability of bacteria

Influence of heavy water (D2O) on the membrane energization, the efflux of hydrogen ions and the respiration of bacteria E. coli M-17 was studied. As has been shown, heavy water of a low concentration (0.05-0.20% v/v) activates and of a high concentration (above 10%) inhibits the absorption of lipophilic cation tetraphenylphosphonium (TPP+) and of oxygen by cells. The return of these characteristics to the initial levels after the removal of D2O points to a reversible action of D2O. A protective effect of D2O towards membrane energization and rate of respiration on dried cells was observed. This fact is in agreement with the data on viability of bacteria. The indicated protective action increases at the stage of rehydration in the presence of D2O.     

Medium Isotope Effect in [3H]Diazepam Binding to Benzodiazepine Receptors of Synaptic Membranes

Replacement of H2O by D2O resulted in significantly higher amount of [3H]diazepam specifically bound to synaptic membranes. The isotope effect arises from increased number of binding sites in D2O and is associated with a stronger solvation of membrane receptors by heavy water.     

Modifications of sodium channel gating in Myxicola giant axons by deuterium oxide, temperature, and internal cations.

In dialyzed Myxicola axons substitution of heavy water (D2O) externally and internally slows both sodium and potassium kinetics and decreases the maximum conductances. Furthermore, this effect is strongly temperature dependent, the magnitude of the slowing produced by D2O substitution decreasing with increasing temperature over the range 3-14 degrees C with a Q10 of approximately 0.71. The relatively small magnitude of the D2O effect, combined with its strong temperature dependence, suggests that the rate limiting process producing a conducting channel involves appreciable local changes in solvent structure. Maximum conductances in the presence of D2O were decreased by approximately 30%, while the voltage dependences of both gNa and gK were not appreciably changed. In contrast to the effects of heavy water substitution on the ionic currents, membrane asymmetry currents were not altered by D2O, suggesting that gating charge movement may preceed by several steps the final transformation of the Na+ channel to a conducting state. In Myxicola axons the effect of temperature alone on asymmetry current kinetics can be well described via a simple temporal expansion equivalent to a Q10 of 2.2, which is somewhat less than the Q10 of GNa activation. The integral of membrane asymmetry current, representing maximum charge movement, is however not appreciably altered by temperature.     

Examination of microgravity effects on spontaneous Ca2+ oscillations in AtT20 pituitary cells using heavy water

Effects of heavy water (D2O) on various organisms have been extensively studied and a majority of D2O actions were generally ascribed to the viscosity (1.23 times of H2O) and a larger inter-molecule force of D2O that may eventually alternate molecular structure of various enzymes and ion channels. It is reported that chronic application of D2O induces toxic effects and the 35% substitution of whole body water with D2O induced fatal effects in the mouse. Mitosis of a fertile egg of sea urchin was completely inhibited by 75% D2O but the paused segmentation was recovered after rinse of D2O. In addition, we also observed that neuronal development of the Lymnaea stagnalis was reversibly inhibited by D2O (M. Sakakibara, unpublished data). However, mechanism of the toxicity of D2O and the effects of D2O on cellular events have not been fully understood. The spontaneous oscillation in cytosolic free Ca2+ concentration is one of the typical physiological events in living secretory cells. We previously demonstrated that the Ca2+ oscillations are regulated by voltage-sensitive Ca2+ channels (VSCC), Ca2+ ATPases, and Ca(2+)-induced Ca2+ release from intracellular stores. To analyze the site(s) of action of D2O in the living cellular systems, the present study examined effects of D2O on the Ca2+ mobilization and resting membrane potentials in AtT20 mouse pituitary cells.     

A simple and easy method for the monitoring of environmental pollutants using oligotrophic bacteria

Sphingomonas paucimobilis KPS01, an oligotrophic bacterium isolated from soil, may be a useful tool for monitoring heavy metals. Previous methods relying on counting of viable cells require a relatively long time and some skill; we have developed a method based on optical density (O.D.) measurements which is significantly faster and does not require skilled personnel. The results of the O.D. and viable count methods were consistent; both methods detected heavy metals at concentrations ranging from 10-3 to 10-5 mmol l-1 and identified heavy metal contamination in 13 of 18 river water samples. Our results demonstrate that biological detection using this O.D. method and S. paucimobilis KPS01 may be useful for routine environmental monitoring of heavy metals, particularly in water sources.     

Visualizing ocular lens fluid dynamics using MRI: manipulation of steady state water content and water fluxes

Studies using various MRI techniques have shown that a water-protein concentration gradient exists in the ocular lens. Because this concentration is higher in the core relative to the lens periphery, a gradient in refractive index is established in the lens. To investigate how the water-protein concentration profile is maintained, bovine lenses were incubated in different solutions, and changes in water-protein concentration ratio monitored using proton density weighted (PD-weighted) imaging in the absence and presence of heavy water (D(2)O). Lenses incubated in artificial aqueous humor (AAH) maintained the steady state water-protein concentration gradient, but incubating lenses in high extracellular potassium (KCl-AAH) or low temperature (Low T-AAH) caused a collapse of the gradient due to a rise in water content in the core of the lens. To visualize water fluxes, lenses were incubated in D(2)O, which acts as a contrast agent. Incubation in KCl-AAH and low T-AAH dramatically slowed the movement of D(2)O into the core but did not affect the movement of D(2)O into the outer cortex. D(2)O seemed to preferentially enter the lens cortex at the anterior and posterior poles before moving circumferentially toward the equatorial regions. This directionality of D(2)O influx into the lens cortex was abolished by incubating lenses in high KCl-AAH or low T-AAH, and resulted in homogenous influx of D(2)O into the outer cortex. Taken together, our results show that the water-protein concentration ratio is actively maintained in the core of the lens and that water fluxes preferentially enter the lens at the poles.     

Aggregation and adsorption at the air-water interface of bacteriophage phiX174 single-stranded DNA

We study the phase behavior of phage phiX174 single-stranded DNA in very dilute solutions in the presence of monovalent and multivalent salts, in both water (H(2)O) and heavy water (D(2)O). DNA solubility depends on the nature of the salts, their concentrations, and the nature of the solvent. The appearance of attractive interactions between the monomers of the DNA chains in the bulk of the solution is correlated with an adsorption of the chains at the air-water interface. We characterize this correlation in two types of aggregation processes: the condensation of DNA induced by the trivalent cation spermidine and its salting out in the presence of high concentrations (molar and above) of monovalent (sodium) cations, both in water and in heavy water. The overall solubility of single-stranded DNA is decreased in D(2)O compared to H(2)O, pointing to a role of DNA hydration in addition to electrostatic factors in the observed phase separations. DNA adsorption involves attractive van der Waals forces, and these forces are also operating in the bulk aggregation process.     

Heavy water inhibition of the transport of alkaline cations across the muscle membrane. I. A comparison of different types of sodium transfer

The sodium efflux from the frog sartorius muscle into the media of different ion composition, prepared with ordinary and heavy water, was measured by radiotracer and flame-emission techniques. About the half of the sodium in muscles was substituted for lithium. The ouabain-sensitive, as well as external potassium- and external sodium-dependent components of the efflux were found to be totally inhibited in D2O, whereas the residual efflux observed in sodium- and potassium-free magnesium medium was diminished in D2O only by one half. A conclusion is made that the decrease in sodium efflux in D2O is due to the inhibition of sodium transfer through the Na, K-ATPase transport system.     

Effect of heavy water on protein flexibility

The effects of heavy water (D(2)O) on internal dynamics of proteins were assessed by both the intrinsic phosphorescence lifetime of deeply buried Trp residues, which reports on the local structure about the triplet probe, and the bimolecular acrylamide phosphorescence quenching rate constant that is a measure of the average acrylamide diffusion coefficient through the macromolecule. The results obtained with several protein systems (ribonuclease T1, superoxide dismutase, beta-lactoglobulin, liver alcohol dehydrogenase, alkaline phosphatase, and apo- and Cd-azurin) demonstrate that in most cases D(2)O does significantly increase the rigidity the native structure. With the exception of alkaline phosphatase, the kinetics of the structure tightening effect of deuteration are rapid compared with the rate of H/D exchange of internal protons, which would then assign the dampening of structural fluctuations in D(2)O to a solvent effect, rather than to stronger intramolecular D bonding. Structure tightening by heavy water is generally amplified at higher temperatures, supporting a mostly hydrophobic nature of the underlying interaction, and under conditions that destabilize the globular fold.     

PIP₂ modulation of Slick and Slack K⁺ channels

The use of heavy water (D(2)O) as a solvent is commonplace in many spectroscopic techniques for the study of biological macromolecules. A significant deuterium isotope effect exists where hydrogen-bonding is important, such as in protein stability, dynamics and assembly. Here we illustrate the use of D(2)O in additive screening for the production of reproducible diffraction-quality crystals for the Salmonella enteritidis fimbriae 14 (SEF14) putative tip adhesin, SefD.     

H/D isotope effects on protein hydration and interaction in solution

An approach has been suggested to study the H/D isotope effect on protein-water and protein-protein intermolecular interactions by determining the content of non-freezing water using low-temperature (1)H NMR in mixed (H2O/D2O) water solutions. Direct data are obtained on the amount of H2O adsorbed (absolute hydration) in presence of the heavy isotope (deuterium D), and isothermals of H2O/D2O fractionation at protein surface groups are presented for temperatures between -10 degrees C and -35 degrees C and solutions of varying composition. The fractionation factor, phi = [x/(1 - x)]/[x(0)/(1 - x(0))], where x and x(0) are the fractions of deuterons in hydration and bulk water, respectively, appeared to be extremely high: phi > 1 at 0.03 < x(0) < 0.10. The high values of phi indicate a decrease in apparent hydration of protein molecules. A probable reason of the effect can be an inter-protein molecular solvent-mediated interaction induced by D2O. The excess of phi over 1 appears to provide a quantitative estimate of the fraction of hydration water affected by such interaction.     

Effect of deuterium oxide on actomyosin motility in vitro.

Actin filament velocities in an in vitro motility assay system were measured both in heavy water (deuterium oxide, D(2)O) and water (H(2)O) to examine the effect of D(2)O on the actomyosin interaction. The dependence of the sliding velocity on pD of the D(2)O assay solution showed a broad pD optimum of around pD 8.5 which resembled the broad pH optimum (pH 8.5) of the H(2)O assay solution, but the maximum velocity (4.1+/-0.5 microm/s, n=11) at pD 8.5 in D(2)O was about 60% of that (7.1+/-1.1 microm/s, n=11) at pH 8.5 in H(2)O. The K(m) values of 95 and 80 microM and V(max) values of 3.2 and 5.1 microm/s for the D(2)O and H(2)O assay were obtained by fitting the ATP concentration dependence of the velocity (at pD and pH 7.5) to the Michaelis-Menten equation. The K(m) value of actin-activated Mg-ATPase activity of myosin subfragment 1 (S1) was decreased from 50 microM [actin] in H(2)O to 33 microM [actin] in D(2)O without any significant changes in V(max) (9.4 s(-1) in D(2)O and 9.3 s(-1) in H(2)O). The rate constants of ADP release from the acto-S1-ADP complex measured by the stopped flow method were 361+/-26 s(-1) (n=27) in D(2)O and 512+/-39 s(-1) (n=27) in H(2)O at 6 degrees C. These results suggest that the decrease in the in vitro actin-myosin sliding velocity in D(2)O results from a slowing of the release of ADP from the actomyosin-ADP complex and the increase in the affinity of actin for myosin in the presence of ATP in D(2)O.     

Measurement of pancreatic islet cell proliferation by heavy water labeling

We describe a sensitive technique for measuring long-term islet cell proliferation rates in vivo in rats. Pancreatic islets were isolated and the incorporation of deuterium ((2)H) from heavy water ((2)H(2)O) into the deoxyribose moiety of DNA was measured by GC-MS. The results of heavy water labeling and BrdU staining were compared. The two methods were highly correlated (r = 0.9581, P < 0.001). Based on long-term heavy water labeling, approximately 50% of islet cells divided in rats between 8 and 15 wk of age. Of interest, long-term BrdU administration suppressed proliferation of islet cells significantly, but not of bone marrow cells. Physiological evidence further supported the validity of the method: older animals (24 wk old) had 60% lower islet cell proliferation rates than younger rats (5 wk old), and partial (50%) pancreatectomy increased proliferation by 20%. In addition, cholecystokinin-8 treatment significantly stimulated proliferation in pancreatectomized rats only. In summary, heavy water labeling is a quantitative approach for measuring islet cell proliferation and testing therapeutic agents.     

Possibility of wide-angle neutron scattering in the study of proteins and nucleic acids in solutions

A method is proposed for calculating wide-angle neutron scattering curves of biopolymers at any fraction of heavy water (D2O) in solution. The method permits to accurately take into account the phenomenon of deuteroexchange. By this method neutron scattering curves of proteins and DNA have been calculated. The calculations have shown that at optimal fractions of D2O in solution the profiles of neutron scattering curves and their sensitivity to conformational rearrangements in protein molecules turned out to differ very little from those of corresponding X-ray curves. Thus the neutron scattering curves do not contain any additional information (as compared with those contained in X-ray scattering curves) on the structure of proteins in solution. On the contrary, neutron and X-ray scattering curves of DNA differ significantly at all fractions of D2O in solution and therefore the methods of wide-angle neutron and X-ray scattering could become mutually complementary in studying the structure of nucleic acids in solution.     

Untersuchungen zum Wirkungsmechanismus von Indolyl-3-Essigsäure mit Hilfe von schwerem Wasser

Summary The auxin-induced cell elongation and the formation of indoleacetyl-aspartic acid (IAAsp) of pea epicotyl sections and Agrostemma hypocotyl sections are inhibited by heavy water. The formation of IAAsp requires a specific enzyme. The lack of IAAsp in D₂O-treated plant tissues may be due to an influence of D₂O on the induction or on the synthesis of that enzyme. Treatment of plant sections with synthetic IAAsp has no effect on the growth of the sections in D₂O. Indole-3-acetic acid (IAA) increases the incorporation of ³²P-orthophosphate into ribosomal and soluble RNA of pea epicotyl sections in H₂O but not in D₂O. The synthesis of ribosomal RNA is decreased by heavy water.The effects of IAA and D₂O on the soluble proteins of pea sections have been studied by PAA-gel electrophoresis. D₂O does not change the pattern of protein bands in comparison with the H₂O-control, but prevents the probably IAA-induced alteration of the Rf-value of one protein band on the pherogram. It is assumed that the inhibition of auxin-induced reactions in the D₂O-medium is due to the stabilizing effect of heavy water on allosteric proteins. The results of this work support the hypothesis that IAA acts as allosteric effector.     

Heavy Water and Hydrostatic Pressure Effects on Tetrahymena pyriformis1

SYNOPSIS. Heat-synchronized cultures of Tetrahymena pyriformis strain GL subjected to pulses of high hydrostatic pressure (10,000 psi for 2 min) had increasing division delays during the 1st 40 min after the last heat shock (40 min after heat treatment). Pressure treatment during the subsequent 10-min interval disrupted cell synchrony. Comparable pressures applied to the cells at later stages, before the 1st synchronous division, caused negligible division delay. Continuous exposure to 10% (v/v) heavy water hardly affected division; higher concentrations delayed or blocked division. Ten-min pulses with heavy water (40%, 50%, 70%) resulted in increasing division delays depending on the stage of the cell cycle during which the heavy water was applied. Amelioration of the division-delaying effects of pressure was observed in cells treated simultaneously with pressure (3,000 psi for 30 min), and 30% D₂O. The results are consistent with the hypothesis that some of the pressure and D₂O effects could be attributed to changes in the sol-gel state of the cytoplasm.