Isotopic light scattering of lipid vesicles. Water permeation and effect of alpha-tocopherol

The influence of the index of refraction of the solvent on light scattering properties of lecithin bilayer vesicles is described. Large vesicles (diameter 300 nm) are considered where one lamella separates the intravesicular compartment from the external medium. Stationary and transient cases are distinguished with special emphasis on the isotopic substitution of the solvent, i.e. H2O vs. D2O. Theoretical calculations based on the Mie theory of light-scattering are in accord with results from experiments. The two stationary cases considered serve to calibrate the numerical calculations and illustrate the capability of the method. Transient experiments allow the determination of permeation rates; in particular the D2O/H2O permeability coefficients can be obtained. Single component vesicular lecithin bilayers and ones containing tocopherol are compared. In the crystalline state the incorporation of tocopherol increases the fluidity of the lipid bilayer in parallel with the water permeation rate.     

First direct observation of the water exchange across the membrane of a single-cell green alga on a cellular level

The isotopic water exchange across the membrane of a single-cell alga is made visible by optical differences of H2O and 2H2O. In the near infrared (NIR) (1000 to 2500 nm) H2O shows pronounced absorption bands while 2H2O is almost transparent. Results from in vivo experiments on the diffusive water permeation across the membrane of the spherical freshwater alga Eremosphaera viridis are presented. The evaluation of the isotope-exchange kinetics allows the calculation of the permeability coefficient, Pd, and the approximation of the intracellular diffusion constant, D. The extension of H2O/2H2O-exchange measurements to two dimensions opens new ways to study transport pathways up to the spatial resolution of a microscope. First NIR video images demonstrate the capability of the method.     

Stability of globular proteins in H2O and D2O

In several experimental techniques D2O rather then H2O is often used as a solvent for proteins. Concerning the influence of the solvent on the stability of the proteins, contradicting results have been reported in literature. In this paper the influence of H2O-D2O solvent substitution on the stability of globular protein structure is determined in a systematic way. The differential scanning calorimetry technique is applied to allow for a thermodynamic analysis of two types of globular proteins: hen's egg lysozyme (LSZ) with relatively strong internal cohesion ("hard" globular protein) and bovine serum albumin (BSA), which is known for its conformational adaptability ("soft" globular protein). Both proteins tend to be more stable in D2O compared to H2O. We explain the increase of protein stability in D2O by the observation that D2O is a poorer solvent for nonpolar amino acids than H2O, implying that the hydrophobic effect is larger in D2O. In case of BSA the transitions between different isomeric forms, at low pH values the Nm and F forms, and at higher pH values Nm and B, were observed by the presence of a supplementary peak in the DSC thermogram. It appears that the pH-range for which the Nm form is the preferred one is wider in D2O than in H2O.     

How accurately can we estimate energetic costs in a marine top predator,the king penguin?

King penguins (Aptenodytes patagonicus) are one of the greatest consumers of marine resources. However, while their influence on the marine ecosystem is likely to be significant, only an accurate knowledge of their energy demands will indicate their true food requirements. Energy consumption has been estimated for many marine species using the heart rate-rate of oxygen consumption (f(H) - V(O2)) technique, and the technique has been applied successfully to answer eco-physiological questions. However, previous studies on the energetics of king penguins, based on developing or applying this technique, have raised a number of issues about the degree of validity of the technique for this species. These include the predictive validity of the present f(H) - V(O2) equations across different seasons and individuals and during different modes of locomotion. In many cases, these issues also apply to other species for which the f(H) - V(O2) technique has been applied. In the present study, the accuracy of three prediction equations for king penguins was investigated based on validity studies and on estimates of V(O2) from published, field f(H) data. The major conclusions from the present study are: (1) in contrast to that for walking, the f(H) - V(O2) relationship for swimming king penguins is not affected by body mass; (2) prediction equation (1), log(V(O2) = -0.279 + 1.24log(f(H) + 0.0237t - 0.0157log(f(H)t, derived in a previous study, is the most suitable equation presently available for estimating V(O2) in king penguins for all locomotory and nutritional states. A number of possible problems associated with producing an f(H) - V(O2) relationship are discussed in the present study. Finally, a statistical method to include easy-to-measure morphometric characteristics, which may improve the accuracy of f(H) - V(O2) prediction equations, is explained.     

Application of Fourier transform infrared spectroscopy to studies of aqueous protein solutions.

Modern protein Fourier transform infrared (FT-IR) spectroscopy has proven to be a versatile and sensitive technique, applicable to many aspects of protein characterization. The major practical drawback for the FT-IR spectroscopy of proteins is the large absorbance band of water, which overlaps the amide I resonances. D2O is often substituted for H2O in infrared experiments. Removal of water from protein samples can be complicated and tedious and potentially lead to denaturation, aggregation, or sample loss. Solvent removal by dialysis is difficult for suspensions and sols. A new method called the D2O dilution technique (Ddt) is described which simplifies the sample preparation step and improves the solvent subtraction. The effect of the D2O concentration on the IR spectrum of aqueous solutions of several model proteins was studied. Dilution of aqueous samples with D2O yields good quality spectra. The Ddt has been evaluated for quantitative analysis using standard proteins and its applicability to solutions and suspensions of a genetically engineered malaria antigen is demonstrated. Use of resolution-enhancement techniques with spectra in mixed solvents has also been investigated.     

Deuterium oxide promotes assembly and bundling of FtsZ protofilaments

The assembly and bundling of FtsZ protofilaments play an important role during bacterial cell division. Deuterium oxide (D2O) is known to have strong stabilization effects on the assembly dynamics of several proteins including tubulin, a homologue of FtsZ. Here, we found that D2O enhanced the light-scattering intensity of the assembly reaction, increased sedimentable polymer mass, and induced bundling of FtsZ protofilaments. D2O also increased the stability of FtsZ polymers under challenged GTP conditions and suppressed dilution-induced disassembly of protofilaments. D2O enhances the assembly parameters of FtsZ and microtubules albeit differently. For example, D2O induced bundling of FtsZ protofilaments, whereas it did not induce bundling of microtubules in vitro. In addition, D2O strongly suppressed the GTP hydrolysis rate of microtubules, but it had no effect on the initial rate of GTP hydrolysis of the FtsZ assembly. D2O (80%) also increased the helical content of FtsZ by 25% compared to the helical content of FtsZ in aqueous buffer. D2O was shown to reduce the binding of 4,4'-dianilino-1,1'-binaphthyl-5,5'-disulfonic acid (bis-ANS) to tubulin. In contrast, we found that D2O strongly enhanced the binding of bis-ANS to FtsZ. The results indicated that D2O promotes assembly and bundling of FtsZ protofilaments by increasing hydrophobic interactions between the protofilaments. The results also suggest that the phosphate release rather than the on-site GTP hydrolysis is the rate-limiting step of the GTP turnover reaction.     

On the water and proton permeabilities across membranes from erythrocyte ghosts

The diffusional permeability of water across membranes from bovine and human erythrocyte ghosts was measured by a recently developed method which is based on the different indices of refraction of H2O and 2H2O. Resealed erythrocyte ghosts were prepared by a gel-filtration technique. Pd (2H2O/H2O) values of 1.2 X 10(-3) cm/s (human) and 1.7 X 10(-3) cm/s (bovine) were calculated at 20 degrees C. The activation energies of the water exchange were 23.5 kJ/mol (human) and 25.4 kJ/mol (bovine). Treatment of the ghosts with p-chloromercuribenzenesulfonic acid (PCMBS) led to a 60-70% inhibition of the diffusional water exchange. The pH equilibration across membranes of erythrocyte ghosts was measured by intracellular carboxyfluorescein. The rates of proton flux after pH-jumps (pH 7.3 to pH 6.1) were about 100-fold lower than those of the water exchange and dependent on the kind of anions present (Cl-, NO-3, SO2-4). The activation energies of proton flux were 60-70 kJ/mol. 4,4'-Diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS) inhibited the exchange by 97-98% and lowered the activation energy. The inhibitor of water exchange, PCMBS, increased the proton-permeation rate by a factor of 4-5. It is assumed that the rate-limiting step for the proton permeation is determined by the anion exchange. Under this condition our results are not in accord with one channel as a common pathway for both the passive water and anion transport.     

Evaluation of D10-Leu metabolic labeling coupled with MALDI-MS analysis in studying the response of the yeast proteome to H2O2 challenge

An efficient D10-Leu metabolic-labeling method combined with isotope-ratio quantitation by MALDI-TOF MS was used to probe the response of the yeast proteome to H2O2. Control cultures correct for effects not associated with H2O2 challenge. A stress-response index to H2O2 (SRIH2O2) is defined, and values are reported for seven proteins at 45-225 min following exposure to 0.4 mM H2O2. The time course of protein accumulation in unstressed cells following the H10- to D10-SCD switch suggests that proteome responses at <45 min could be monitored by addition of excess D10-Leu to H10-cultures.     

Polymerization and gelation of fibrinogen in D2O

The solution properties of fibrinogen and the thrombin-induced activation and gelation of fibrinogen in 95% D2O at pH 7.4 were compared to those in H2O under similar conditions. The initial release rates of fibrinopeptides A and B in D2O were slightly slower than those in H2O. However, the values of the Michaelis-Menten parameters Km and V for the release of the two peptides in D2O and H2O in the presence of 0.5 M NaCl were about the same. From turbidity measurements at 450 nm it is obvious that fibrinogen is soluble in a slightly more narrow range of NaCl concentration and that the fibrin gels have a higher degree of lateral aggregation in D2O than in H2O. The variation of fibrinogen concentration, thrombin concentration, pH and ionic a strength have a similar dependence on the final gel structure and clotting time in D2O and H2O. SDS-gel electrophoresis on fibrin samples, which were cross-linked by factor XIII, yielded results where the cross-linking of the gamma-chain appeared to be the same in D2O and H2O. The alpha-chain cross-linking was somewhat faster in D2O than in H2O. When fibrinogen solutions in 95% D2O were incubated at 20 mM CaCl2, a slow gelation of fibrinogen was observed, which was found to be induced by trace amounts of factor XIII. The final gel turbidity appeared to be about the same for this gelation as for that induced by thrombin. The differences in solubility for fibrinogen, kinetics for the enzyme reaction and optical properties for the fibrin gels in D2O and H2O may be explained by differences in electrostatic interactions, hydrogen bonding and hydration of fibrinogen in these two media.     

Fourier transform resonance Raman spectroscopy of phytochrome.

The Pr and Pfr forms of phytochrome in H2O and D2O have been studied by Fourier transform resonance Raman spectroscopy with near-infrared excitation (1064 nm). It is demonstrated that this technique is a powerful method for analyzing the chromophore structures of photosensitive pigments. The high spectral quality allows discussion of vibrational assignments based on an empirical approach using previously published data obtained from model compounds. The reduction in intensity of a high-frequency band assigned to the ring-C/D methine bridge vibration is an indication for the non-coplanarity of the ring D in Pfr. The high intensity of a C-H out-of-plane vibration also supports this hypothesis. In Pr, a broad peak at approximately 1100 cm-1 is assigned to an out-of-plane vibration of a strongly hydrogen-bonded pyrrole C=NH+ group. It is missing in Pfr, suggesting deprotonation of the corresponding ring during the transformation from Pr to Pfr.     

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.     

E.s.r. studies of halogenated pyrimidines in gamma-irradiated alkaline glasses.

The reactions of mobile electrons (em-) and oxygen radical anions (O--) with halogenated bases and nucleosides have been studies in gamma-irradiated alkaline glasses by e.s.r. and specific halogen-ion electrode techniques. It is shown that electrons react with halogenated uracil bases (XUr where X = Cl, Br. I but not F) by dissociative electron attachment to form uracil-5-yl radicals (U-) and halogen anions. The relative rates of reaction of em- with XUr decrease in the sequence BrUr greater than ClUr greater than FUr greater than IUr. Thermal annealing studies carried out on U- in H2O and D2O matrices support the hypothesis that U- in H2O hydrates across the 5-6 double bond in the temperature region 135 degrees-155 degrees K, and deuterates to a much smaller extent in D2O at temperatures above 155 degrees K. Studies on bromouridine and bromodeoxyurinde suggest that em- reacts with the base moieties to form U- type radicals which abstract H- from the sugar moieties of adjacent nucleosides.     

Direct fluorescence measurement of diffusional water permeability in the vasopressin-sensitive kidney collecting tubule.

A fluorescence method has been developed for accurate and instantaneous measurement of transepithelial diffusional water permeability (Pd) in perfused kidney tubules based on the sensitivity of the fluorophore aminonapthelane trisulfonic acid (ANTS) to solution H2O/D2O content. The fluorescence of ANTS was 3.2-fold lower in an H2O buffer than in a D2O buffer. The response of ANTS fluorescence to a change in solution H2O/D2O content occurred in less than 1 ms and was due to a collisional quenching mechanism. Isolated cortical (CCT) and outer medullary (OMCT) collecting tubules from rabbit were perfused with an isosmotic D2O buffer at specified lumen flow rates (2-100 nl/min); tubules were bathed in isosmotic H2O or D2O buffers in which vasopressin (VP) could be added rapidly. Lumen fluorescence was monitored by quantitative epifluorescence microscopy at 380 +/- 5 nm excitation and greater than 530 emission wavelengths. Pd was determined from tubule geometry, lumen flow, ANTS fluorescence, and ANTS fluorescence vs. H2O/D2O calibration relation. The instrument response time for a change in bath H2O/D2O content was less than 4 s. At 37 degrees C, Pd values (mean +/- SE in cm/s x 10(4] were 6.4 +/- 1.0 (-VP, n = 9) and 14.3 +/- 1.1 (+250 microU/ml bath VP, n = 9) in the CCT, and 5.8 +/- 1.0 (-VP, n = 6) and 15.3 +/- 2.0 (+VP, n = 6) in the OMCT; at 23 degrees C, Pd was 5.1 +/- 0.6 (-VP, n = 4) and 7.8 +/- 0.6 (+VP, n = 4) in the CCT.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of horseradish peroxidase-amplified chemiluminescence produced by human neutrophils reveals a role for the superoxide anion in the light emitting reaction

When polymorphonuclear leukocytes and soluble or particulate matter interact, the cells produce chemiluminescence, which is linked to activation of the oxidative metabolism of the cells. A luminol chemiluminescence assay in which the reaction mixture contains a relatively large amount of horseradish peroxidase combined with sodium azide has been proposed to quantitate H2O2 produced by human neutrophils during the respiratory burst (M.P. Wymann, V. von Tscharner, D. A. Deranleau, and M. Baggiolini (1987) Anal. Biochem. 165, 371-378). We found, when comparing the response to concanavalin A and a formylated peptide (formylmethionyl-leucyl-phenylalanine), that neutrophils produce H2O2 that is not detected as chemiluminescence by the horseradish peroxidase-azide-luminol system. Furthermore, the horseradish peroxidase-amplified chemiluminescence response obtained from granule-depleted neutrophil cytoplasts is inhibited by superoxide dismutase, an O2- scavanger. Based on these results, we question the specificity of the described technique for H2O2. The usefulness of the technique in the determining the extracellular and intracellular production of oxidative metabolites is discussed.     

The contribution of the nuclear reaction 1H(n, gamma)2D to the yield of DNA single strand breaks in cultured mammalian cells irradiated by thermal neutrons

The yield of single strand breaks (ssb) in DNA of the HeLa S-3 cells after thermal neutron irradiation was examined using the alkaline sucrose gradient method. The contribution of the 1H(n, gamma)2D reaction to the yield of ssb was determined by substituting D2O for H2O in the irradiated medium. Calculation shows that when cells are irradiated in the H2O medium, the per cent contribution of the contaminating gamma-rays, the nuclear reaction 1H(n, gamma)2D and the other nuclear reactions is 31, 44 and 25 per cent respectively assuming additivity of effects. The estimated number of ssb induced by the nuclear reaction 1H(n, gamma)2D was at least 4.4 times greater than that by 60Co gamma-rays at the same absorbed dose. Two possible interpretations are discussed to explain the high efficiency of the 1H(n, gamma)2D reaction for ssb induction.     

Enzymatic determination of phospholipase D activity with choline oxidase

A new enzymatic method was developed for the assay of phospholipase D [phosphatidylcholine phosphatidohydrolase EC 3.1.4.4] from cabbage leaves using choline oxidase from Arthrobacter globiformis cells. The method was based on the estimation of choline by the following series of enzymatic reactions after ending the phospholipase D reaction: Choline + 202 + h2o Choline oxidase Betaine + 2H2O2 2H2O2 + Phenol + 4-Aminoantipyrine Peroxidase Quinoneimine dye + 4H2O The amount of choline was proportional to the amount of resulting quinoneimine dye with an absorbance maximum at 500 nm. The phospholipase D reaction (choline liberation) was carried out at pH 5.5 in the presence of Ca2+ ions and ended by adding EDTA in conc. Tris-HCl buffer, pH 8, to give a final pH of around 8. The initial rate of the phospholipase D reaction was proportional to the enzyme concentration over the absorbance change range of 0 to 0.25 (equivalent to 0-21 micron of choline) under the optimal reaction conditions.     

Cytochemical localization of glutaraldehyde-resistant NAD(P)H-oxidase in rat hepatocytes

NAD(P)H-oxidase activity was demonstrated in glutaraldehyde-fixed rat hepatocytes by a cerium technique. The activity was observed exclusively on the bile-canalicular plasma membrane of hepatocyte. No reaction product was formed in the absence of NAD(P)H as the substrate. The reaction was inhibited by pCMB (surface sulfhydryl group specific reagent), by heating, by anaerobic incubation and by catalase (H2O2 scavenger), but it was not inhibited by KCN or NaN3. The present results show that bile-canalicular plasma membrane produces H2O2 and the cerium technique for demonstration of H2O2 is therefore an useful method for the subcellular localization of NAD(P)H-oxidase activity in the glutaraldehyde-fixed hepatocyte.     

Investigation of cis/trans ratios of peptide bonds in AVP analogues containing N-methylphenylalanine enantiomers.

The solution conformation of vasopressin analogues, modified at positions 2 and 3 with N-methylphenylalanine or its enantiomer, [D-MePhe2,MePhe3]AVP and [MePhe2,D-MePhe3]AVP, were studied by 2D NMR spectroscopy in H2O/D2O and theoretical calculations (EDMC/ANALYZE). In the case of [MePhe2,D-MePhe3]AVP, the synthesis afforded two products, A and B, which had identical molecular ions and similar retention times on HPLC. This finding was explained by racemization of Cys1, which gave an additional analogue, [D-Cys1,MePhe2,D-MePhe3]AVP (B). The possibility is not excluded of racemization of Cys1 in the remaining analogues of this series. However, only in the case of [MePhe2,D-MePhe3]AVP was this process so distinct that two strong peaks in the HPLC chromatogram were observed. The NMR spectra of all the analogues showed several distinct sets of residual proton resonances. This suggests that the peptides adopt more than two groups of conformations in H2O/D2O. This fact is due to cis/trans isomerization. Two more populated isomers arise from the cis/trans isomerization across the 2-3 peptide bond in [D-MePhe2,MePhe3]AVP and [MePhe2,D-MePhe3]AVP (A) and across the 1-2 peptide bond in [D-Cys1,MePhe2,D-MePhe3]AVP (B).     

Stabilization of tubulin by deuterium oxide

Tubulin is an unstable protein when stored in solution and loses its ability to form microtubules rapidly. We have found that D2O stabilizes the protein against inactivation at both 4 and 37 degrees C. In H2O-based buffer, tubulin was completely inactivated after 40 h at 4 degrees C, but in buffer prepared in D2O, no activity was lost after 54 h. Tubulin was completely inactivated at 37 degrees C in 8 h in H2O buffer, but only 20% of the activity was lost in D2O buffer. Tubulin also lost its colchicine binding activity at a slower rate in D2O. The deuterated solvent retarded an aggregation process that occurs during incubation at both temperatures. Inactivation in H2O buffer was partially reversed by transferring the protein to D2O buffer; however, aggregation was not reversed. The level of binding of BisANS, a probe of exposed hydrophobic sites in proteins, increases during the inactivation of tubulin. In D2O, the rate of this increase is slowed somewhat. We propose that D2O has its stabilizing effect on a conformational step or steps that involve the disruption of hydrophobic forces. The conformational change is followed by an aggregation process that cannot be reversed by D2O. As reported previously [Ito, T., and Sato, H. (1984) Biochim. Biophys. Acta 800, 21-27], we found that D2O stimulates the formation of microtubules from tubulin. We also observed that the products of assembly in D2O/8% DMSO consisted of a high percentage of ribbon structures and incompletely folded microtubules. When these polymers were disassembled and reassembled in H2O/8% DMSO, the products were microtubules. We suggest that the combination of D2O and DMSO, both stimulators of tubulin assembly, leads to the rapid production of nuclei that lead to the formation of ribbon structures rather than microtubules.