The gelation of deoxyhemoglobin S in erythrocytes as detected by transverse water proton relazation measurements

At 37 °C, when samples of blood, washed erythrocytes, or isolated hemoglobin from individuals with sickle cell disease are deoxygenated, the transverse water proton relaxation time is sharply decreased. In similar samples from normal adults homozygous for hemoglobin A, only a slight decrease in t₂ is observed upon deoxygenation at 37 °C. In samples containing deoxyhemoglobin S the value of t₂ increases as the temperature is decreased from 37 °C to 4 °C, in contrast to samples containing oxyhemoglobin S, oxyhemoglobin A, or deoxyhemoglobin A where t₂ decreases as the temperature decreases. It is suggested that this decrease in t₂ observed in samples of deoxyhemoglobin S at 37 °C is the result of an increase in the amount of preferentially oriented water at macromolecular interfaces which occurs under conditions known to produce deoxyhemoglobin S gelation. Conditions which reverse deoxyhemoglobin S gelation such as lowering the temperature to 4 °C decrease the amount of preferentially oriented water which results in an increase in the value of t₂. Thus, measurement of the transverse water proton relaxation time can be used to monitor the gelation of deoxyhemoglobin S inside the erythrocyte.     

Conformational features of cell-bound drugs as detected by selective proton relaxation rate investigations

The nonselective and selective longitudinal relaxation rates were measured for procaine protons in the presence of model lipid membranes, biological membranes and whole cells. Unlike the nonselective relaxation rates, the selective rate was shown to be particularly sensitive in detecting binding interactions with macromolecular cell constituents. It was shown that the aromatic moiety of procaine is involved in binding the cell plasma membrane.     

Inhibitory effect of deoxyhemoglobin A2 on the rate of deoxyhemoglobin S polymerization.

From a consideration of the primary sequence of hemoglobin A₂ and the reported 5 å molecular contacts between deoxyhemoglobin S molecules in a crystal, it is predicted that hemoglobin A₂ might act as an inhibitor of the polymerization of deoxyhemoglobin S in a manner similar to hemoglobin. F. This has been tested experimentally by measuring the rate of change of the transverse water proton relaxation times (T₂) in equimolar mixtures of hemoglobin S and one of the non-gelling hemoglobins A, F or A₂. Hemoglobins A₂ and F have far more pronounced inhibitory effects on the rate of polymerization than does hemoglobin A. These molecules contain several amino acid differences from hemoglobin A beta chains which are located in the 5 Å molecular crystal contacts and these altered crystal contacts result in a much stronger inhibition of the rate of polymerization. Since hemoglobin A₂ is a normal hemoglobin found in small amounts in all adult red cells, increased delta chain synthesis may have potential importance in therapy for sickle cell disease.     

Effect of oxygen concentration on trasverse water proton relaxation times in erythrocytes homozygous and heterozygous for hemoglonin S.

The transverse water proton relaxation times (T₂) of erythrocytes homozygous and heterozygous for hemoglobin S have been measured as a function of oxyhemoglobin concentration at 37 °C. An immediate decrease in T₂ is observed in S/S erythrocytes as the amount of oxyhemoglobin is decreased and the maximum change is observed at 50% deoxyhemoglobin S. In heterozygous erythrocytes, the T₂ remains unchanged until a critical level of deoxyhemoglobin is attained. The critical level of deoxyhemoglobin is a function of the percentage of hemoglobin S in the heterozygous erythrocytes. A Hill plot of the data obtained from S/S erythrocytes gives an n value of around 2.4. These results suggest that the measurement of T₂ is sensitive to the very early stages of the polymerization process. This suggestion is supported by calculations; our T₂ measurements are sensitive to a range of correlation times expected for hemoglobin monomers at one extreme and linear polymers of seven hemoglobin molecules at the other extreme.     

Hydrogen exchange kinetics of human hemoglobins. The pH dependence of solvent accessibility in cyanomet-, oxy-, and deoxyhemoglobin.

The hydrogen exchange kinetics of human oxy-, deoxy-, and cyanomethemoglobin have been measured as a function of pH by the tritium tracer method. At 5 degrees C and in phosphate buffer both liganded and unliganded forms of ferrohemoglobin exhibit deviations from the regular pH dependence of exchange that is characteristic of cyanomethemoglobin. In oxyhemoglobin, the deviation from the normal exchange pattern is centered at pH 7.4 and is in the direction of increased exchange or solvent accessibility. The effect in deoxyhemogloin, while occurring at the same pH and being of the same order of magnitude, is in the opposite direction, thus suggesting a pH-induced conformational transition leading to a less accessible structure. The width of these pH-induced deviations in solvent accessibility is approximately 1 pH unit in both cases. We propose a model in which specific interactions between charged groups in both froms of ferrohemoglobin account for these deviations.     

Effect of pH and proton buffer on oscillations of ion fluxes in rat erythrocytes

The pH-dependence of ionophore-induced oscillations of transmembrane H+ and K+ fluxes in rat erythrocytes has been studied. It is stated that the oscillations are strongly depressed at pH lower than 6.9 and higher than 7.3. Proton buffers of different nature (Tris/HCl, Mops and glycylglycine) are shown to effectively inhibit the oscillatory process. The significance of H+ concentration in unstirred layers adjacent to the membrane in the mechanism of oscillations is suggested.     

Simultaneous measurements of proton motive force, delta pH, membrane potential, and H+/O ratios in intact Escherichia coli.

An instrument is described that enables the simultaneous monitoring of proton motive force (PMF), membrane potential (delta psi), the delta pH across a membrane, oxidase activity, proton movements, and H+/O ratios. We have studied the relationship existing among these parameters of energy transduction as a critical condition is changed during an experiment. The major findings are: (a) In the pH range of 4.5 to 7.5, increasing the external pH causes an increase in delta psi, internal pH, and oxidase activity, a decrease in H+/O ratio, and a peak-plateau in PMF from pH 5.5 to 6.6 where delta pH is converted to delta psi. (b) An increase in [K+] from 1 to 100 mM, in the presence of 0.5 microM valinomycin, causes the conversion of delta psi to delta pH, a gradual decline in PMF and an increase in H+/O ratio, internal pH, and oxidase activity. (c) Increasing valinomycin concentration from 0 to 2.5 microM, in the presence of 50 mM [K+], causes a decline in delta psi from 125 to 0 mV, and an increase in delta pH from 35 to 70 mV. From 2.5 to 10 microM, the delta pH and the PMF (which it solely represents), stay constant, H+/O ratio increases mainly from 0 to 0.5 microM and much more slowly from 2.5 to 10 microM. (d) Oxygen at only 10% of its concentration in air-saturated buffer can support the generation of 90% or more of the delta psi, delta pH, and PMF generated in an air-saturated solution. (e) The return of extruded protons to the cell (referred to here as "suck-back") represents a complicated process driven by delta psi and influenced by a variety of factors. (f) H+/O ratios measured by the kinetic technique used here are much higher than those measured by standard oxygen pulse techniques.     

Crystallization of deoxyhemoglobin S by fiber alignment and fusion.

Fibers of deoxyhemoglobin S obtained directly from lysed sickled red blood cells have been compared with fibers from chromatographically pure deoxyhemoglobin S solutions of known chemical composition. Electron micrographs of negatively stained specimens reveal that the molecular packing within the fibers remains largely invariant with changes in pH, ionic strength, Mg²⁺ concentration, 2,3-diphosphoglycerate concentration, temperature or the method of deoxygenation.When solutions of chromatographically pure deoxyhemoglobin S are stirred, the fibers align into well defined fascicles. After several hours of stirring, long needles and twisted ribbons develop and in a relatively short time replace the fascicles in solution. With continued stirring all forms are replaced by small crystals. By use of electron microscopy and low-angle X-ray diffraction we have found these crystals to have cell parameters indistinguishable from those of crystals grown in polyethylene glycol and citrate/phosphate buffer at pH 5 to 6 (Wishner et al., 1975a).Our evidence indicates that crystal formation in stirred solutions of deoxyhemoglobin S is the result of a progressive alignment and fusion of the fibers, and that the molecular arrangement within the fibers is closely related to that within the crystal. The remarkable pH invariance of the molecular packing within the fiber and crystal structures is consistent with the dominance of hydrophobic bonding between molecules. The β6-valine contact observed by Wishner et al. (1975b) is apparently the pathological contact responsible for the polymerization of deoxyhemoglobin S in vivo. On the basis of our observations and knowledge of the crystal structure we propose that the deoxyhemoglobin S fiber consists of eight molecular double strands, four of which run in each direction along the length of the fiber.     

Field-dispersion profiles of the proton spin-lattice relaxation rate in chloroplast suspensions. Effect of manganese extraction by EDTA,Tris, and hydroxylamine

Proton spin-lattice relaxation rates (R₁) have been measured in a variety of dark-adapted chloroplast suspensions over a range of field strengths between 1 and 15 kG (4–5 MHz). When the effects of EDTA or Tris washing on chloroplast relaxivities are compared, the pool of Mn associated with oxygen evolution is seen not to contribute significantly to relaxivity. Instead, nearly all of the observed relaxivity, which is characterized by a paramagnetic maximum near 20.7 MHz in the field dispersion profile of R₁, appears to arise from contaminating non-functional Mn(II) that can be removed by EDTA during the isolation procedure. These observations, which contradict previous reports ascribing chloroplast relaxivity to the water-oxidizing system, require a reevaluation of proposed models, derived from NMR studies, of the state of Mn in the water-splitting reaction.Chloroplasts from which loosely bound non-functional Mn has been removed by EDTA washing do show an enhancement of relaxivity when exposed to NH₂OH at concentrations known to inactivate water oxidation. This NH₂OH-induced relaxivity is comprised of Mn(II) in two distinct paramagnetic sites. One site is chelatable by EDTA, whereas the other site is not. This finding suggests that some Mn(II) tightly bound to thylakoid membranes can contribute to relaxivity after inactivation of the oxygen-evolving reaction.     

Interaction among substrates, inhibitors and Mn2+ bound to glutamine synthetase as studied by NMR relaxation rate measurements

The interaction of Mn2+ with the substrate glutamate and several transition state analog inhibitors of glutamine synthetase has been studied. With Mn2+ bound to the tight binding site, the frequency and temperature dependence of the paramagnetic contribution to solvent water proton relaxation rates demonstrate changes in the structure of the metal ion environment induced by substrate or inhibitor binding. The water proton relaxation rate data also show differences in the metal ion environment in the presence of glutamate compared to methionine sulfoximine, a structural analog of an intermediate in the reaction mechanism. Additionally, the distance between the metal ion and the phosphorus atom of an inhibitor, 2-amino-4-phosphonobutyric acid, was estimated (approximately 5 A) using NMR measurements. These data are in accord with our recent hypothesis that the role of the metal ion is to stabilize the tetrahedral adduct formed on the reaction pathway.     

Effect of light intensity on proton extrusion by roots of intact maize plants

Shading of maize plants ( Zea mays L. cv. Blizzard) reduced net H⁺ extrusion by roots and increased K⁺ release, whereas there was no significant effect on anion efflux in deionized water. With lower light intensity the concentrations of carbohydrates in the roots decreased, but ATP levels and energy charge remained unchanged. Also, shading raised the tissue pH of roots and made the cytoplasmic pH of root cells drop. There was a significant influence of light intensity on H⁺ uptake by roots from an acidified test solution and CCCP (carbonylcyanide-3-chlorophenylhydrazone)-in-duced H⁺ uptake was modified by shading.
It is concluded that low light intensity does not limit active H⁺ release by plasmalemma ATPase activity in the root cells, but that a reduced carbohydrate supply brings about a change in biochemical reactions which alter the membrane permeability for protons. An increased passive reflux of H⁺ into the cells rather than a reduced H⁺ ATPase activity explains the decrease of net H⁺ release by roots of intact maize plants under low light intensity.     

The state of water in biological systems as studied by proton and deuterium relaxation.

Careful experiments on the measurement of the intensity of the deuterium NMR signal for 2-H2 O in muscle and in its distillate were performed, and they showed that all 2-H2 O muscle is "NMR visible". The spin-lattice relaxation time (T1) of the water protons in the muscle and liver of mice and in egg white has been studied at six frequencies ranging from 4.5 to 6.0 MHz over the temperature range of +37 to --70 degrees C. T1 values of deuterons in 2H2 O of gastrocnemius muscle and liver of mice have been measured at three frequencies (4.5, 9.21 and 15.35 MHz) over the temperature range of +37 to --20 degrees C. Calculations on T1 for both proton and deuteron have been made and compared with the experimental data. It is suggested that the reduction of the T1 values compared to pure water and the frequency dependence of T1 are due to water molecules in the hydration layer of the macromolecules, and that the bulk of water molecules in the biological tissues and egg white undergoes relaxation like ordinary liquid water.     

Equilibrium and water proton relaxation rate enhancement properties of formyltetrahydrofolate synthetase-manganous ion-substrate complexes.

Binding of Mn(pi)-nucleotide complexes to the enzyme formyltertrahydrofolate synthetase (EC 6.3.4.3) from Clostridium cylindrosporum has been examined in the presence and absence of other substrates by solvent proton relaxation mearurements. MnADP and MnATP form ternary complexes with the enzyme with highly enhanced proton relaxation rates for water. The enhancement parameters, epsilont, for the MnADP and MnATP ternary complexes are 19.8 and 12.5, respectively at 24.3 MHZ and 25 degrees. Titration curves with constant total concentrations of enzyme and Mn(pi) with variable nucleotide concentration are similar to those observed in similar titrations with the endp and MnATP are 175 muM and 64 muM, respectively at 25 degrees. Addition of tetrahydrofolate to solutions of the MnADP OR MnATP ternary complexes lowers the observed relaxation enhancement markedly. An analysis of titration curves with constant total concentrations of enzyme, Mn(pi), and nucleotide with variable tetrahydrofolate concentration gives the dissociation constant for tetrahydrofolate from the respective quaternary complexes. The affinity of the enzyme for tetrahydrofolate is increased 6-fold when MnADP is present at the active site whereas a 3-fold increase is observed with MnATP present. Furthermore, there is a 20-fold increase in the enzyme's affinity for tetrahydrofolate when both MnADP and the third substrate, formate, are present. The observed relaxation rate of water for solutions of the complex, enzyme-MnADP-tetrahydrofolate-formate, is deenhanced with respect to the rate observed for the simple aquo-Mn(pi) solution. Addition of nitrate to solutions of the above complex increases the affinity of the enzyme for tetrahydrofolate and MnADP by an additional factor of 5 and lowers the relaxation rate further to a value which approaches that for solutions of the enzyme and substrates which lack the paramagnetic cation.     

Water proton relaxation rate enhancements and association constants for Mn(II) to serum proteins determined by NMR T1 measurements

The water proton relaxation rate enhancement of Mn(II) bound to bovine serum albumin (BSA) and the association constant for manganese to BSA have already been determined, but such determinations have not been done for human serum albumin (HSA) and other human serum proteins and also for human serum. In this work, NMR T1 values in aqueous solutions of serum proteins and serum were measured versus increasing concentration of Mn(II). Proton relaxation rate enhancements (epsilon*) caused by different manganese concentrations were determined for each solution and 1/epsilon* was fitted against concentrations of Mn(II). Proton relaxation rate enhancements (epsilonb) of Mn(II) bound to albumin, gamma-globulin, (alpha+beta)-globulins and serum were found to be 13.69, 3.09, 8.62, and 10.87, respectively. Free and bound manganese fractions, resulted from each addition of Mn(II) to the sample, were determined by using corresponding (epsilon*) and the epsilonb values. Association constants for Mn(II) to HSA and gamma-globulin were calculated as 1.84 x 10(4) M(-1) and 2.35 x 10(4) M(-1), respectively. Present data suggest that the proton relaxation rate enhancement of Mn(II) in serum is caused by Mn(II) bound to various serum constituents. Data also suggest that association constants for Mn(II) to gamma-globulin are nearly the same as that to HSA.     

Effects of pH, 2,3-diphosphoglycerate and salts on gelation of sickle cell deoxyhemoglobin

Gelation of fully deoxygenated sickle cell hemoglobin was assayed by (1) determination of the temperature at which viscosity increased sharply and (2) a high-speed sedimentation equilibrium method in which three zones are seen. These are a pre-gelation zone, a narrow transition zone exhibiting aggregation, followed by a phase change and a zone of gelation. Only the first zone is seen with deoxyhemoglobin A and CO hemoglobins A and S up to about 0·35 g protein/ml. Minimal gelling temperatures by the viscosity method and, by ultracentrifugation, minimal gelling concentrations determined at the onset of aggregation and at the phase change showed: (a) lowering the pH toward 6·7 favors gelation; (b) deoxyhemoglobin S gels more readily in 6 mm-2,3-diphosphoglycerate than in its total absence; (c) 1 m-NaCl and l m-KCl inhibit gelation. The known favoring of gelation by warming is confirmed by the equilibrium method and is about 2% change in minimal gelling concentration per degree.The effects of pH and high ionic strengths are consistent with contributions of specific polar interactions to gel structure. The effect of 2,3-diphosphoglycerate probably depends on known structural changes which this cofactor induces rather than on alteration of the allosteric quaternary structure equilibrium.