Evaluation of the water environments in deoxygenated sickle cells by longitudinal and transverse water proton relaxation rates

The longitudinal and transverse water proton relaxation rates of oxygenated and deoxygenated erythrocytes from both normal adults and individuals with sickle cell disease were measured as a function of temperature at two different frequencies. The simplest model which fits all of the data consists of three different environments for water molecules. The majority of the water (98%) has a correlation time indistinguishable from bulk water (3 × 10^?11 sec). Secondly, there is a small amount of water (1.3–1.5%) present which has a correlation time of 2–4 × 10 ^?9 sec and is apparently independent of the erythrocyte sample studied. Presumably this water is the hydration sphere around the hemoglobin molecules and its correlation time is significantly slower than bulk water. The third environment contains approximately 0.2% of the water present and has a correlation time≥ 10^?7 sec. This third environment is considered tightly bound to the hemoglobin because the water proton correlation time is very similar to the expected rotational correlation time for the hemoglobin molecules. The value of the transverse relaxation rate, f_b(T_2b)^?1, for the tightly bound water fraction decreases in oxy ($\text{S}\text{S}$), deoxy ($\text{A}\text{A}$), and oxy ($\text{A}\text{A}$) erythrocyte samples as the temperature is increased as expected for a rotational correlation time process. In dramatic contrast,f_b (T_2b)^?1 increases almost linearly as the temperature is increased over the whole 4 ° to 37 °C temperature range in samples of deoxy ($\text{S}\text{S}$) erythrocytes. The observation suggests a continual increase in the formation of deoxyhemoglobulin S polymers rather than a sudden transition from a homogeneous solution of deoxyhemoglobin S molecules to a solid gel.     

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.     

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.     

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.     

Gelation of sickle cell hemoglobin in mixtures with normal adult and fetal hemoglobins.

We report the results of thermodynamic and kinetic studies on the gelation of mixtures of sickle cell (S) deoxyhemoglobin with normal human adult (A) and fetal (F) deoxyhemoglobins. The delay time of thermally induced gelation was monitored by the increase in turbidity. At the completion of gelation the solubility was determined by sedimenting the polymers and measuring the supernatant concentration spectrophotometrically. Addition of hemoglobins A or F, at mole fractions from 0 to 0.6, resulted in large increases in both the solubility and the delay time. For a 50:50 mixture of deoxyhemoglobin F with deoxyhemoglobin S, the solubility increased by a factor of 1.8 and the delay time by a factor of 10⁷ relative to pure deoxyhemoglobin S at the same total concentration, while for a 50:50 mixture of deoxyhemoglobins A and S the solubility increased by a factor of 1.4 and the delay time by a factor of 10⁴. The relative delay times were independent of both temperature and total hemoglobin concentration. The data have been analyzed according to theoretical models which treat the effects of temperature, concentration, non-ideality and solution composition on the thermodynamics and kinetics of gelation. The increased solubility in mixtures with deoxyhemoglobin F is fully explained by a model in which only deoxyhemoglobin S molecules polymerize. The effect of fetal hemoglobin (α₂γ₂) and hybrid α₂γβ^S molecules is to increase the solution non-ideality through the contribution of their excluded volume. The smaller increase in the solubility observed in comparable mixtures with deoxyhemoglobin A requires that the hybrid α₂β^Aβ^S molecules copolymerize with the deoxyhemoglobin S. The kinetic results for the mixtures can be quantitatively accounted for using a nucleation model in which the equilibrium properties of the polymer are used to describe the critical nucleus. The very large increases in delay time observed for the $\text{S}\text{F}$ mixtures can be explained by assuming that only α₂β₂^S molecules participate in the formation of a nucleus containing about 25 monomers. As in the thermodynamic analysis, the smaller effect of adding deoxyhemoglobin A can be attributed to the contribution of the hybrid molecules in forming the critical nucleus. Thus the difference between the polymerization properties of mixtures of deoxyhemoglobin S with deoxyhemoglobins A and F can be attributed solely to the copolymerization of the α₂β^Aβ^S hybrid molecule and the absence of any significant copolymerization of the α₂γβ^S hybrid.     

Reversible solubility of deoxyhemoglobin S

The solubility of deoxyhemoglobin S in 1.96 M phosphate is sensitive to changes in oxygenation and temperature in a manner similar to the widely used $\text{in vitro}$ gelation assay. In addition, the pH of the phosphate buffer used in the solubility determination has a profound effect on deoxyhemoglobin S solubility. It is suggested that solubility in 1.96 M phosphate may be a sensitive method of monitoring the aggregation phenomenon of deoxyhemoglobin S.     

The enhancement of the alkaline Bohr effect of some fish hemoglobins with adenosine triphosphate.

The oxygen equilibria of the hemoglobins of one holostean fish, the spotted gar (Lepisosteus osculatus), and of four teleost fish, the carpsucker (Carpiodes carpio), the small mouth buffalo fish (Ictiobus bubalus), the Rio Grande cichlid (Cichlasoma cyanoguttatum), and the redear sunfish (Lepomis microlophus), have been measured as a function of pH in the presence and absence of ATP. The oxygen equilibria of the teleost hemoglobins in the presence of 200 μm ATP can be superimposed within experimental error upon the data obtained in the absence of ATP by a simple downward shift of the pH scale by 0.5 unit. Thus the effects of proton and ATP binding appear equivalent: Both can be interpreted in terms of a two-state allosteric model in which binding occurs preferentially to the low-affinity T-state. The oxygen affinities of each of the teleost hemoglobins approach asymptotically a maximal value at high pH. Although these high affinities are associated with decreased cooperativity of oxygen binding, as reflected by the Hill coefficient n, the asymptotic value of n never appears lower than 1.2 to 1.4. This indicates that the data cannot be completely described in terms of a single high-affinity R-state in alkaline solution: At least two different conformations are required. The oxygen affinity of the spotted gar hemoglobin, like that of each of the teleost hemoglobins, reaches a maximal value (minimal value of log PO₂ for half-saturation) above pH 8, but unlike teleost hemoglobins, the Hill coefficient reaches maximal values of 2.6 to 2.7 at high pH. The data in the absence of ATP are superimposable on the data in its presence by a downward shift of the pH scale by 0.25 unit. The measurement of the Bohr effect ($\text{Δlog}\text{P}{}_{30}\text{ΔpH}$) in the presence and absence of ATP shows that the Bohr effect in each of the hemoglobins is substantially enhanced by organic phosphates, as it is in mammalian hemoglobins. The extent of the enhancement of the Bohr effect by 200 μm ATP for each of the hemoglobins is approximately the same in the range pH 6.7 to 7.3 (increase in $\text{Δlog}\text{P}{}_{50}\text{ΔpH}\text{~ 0.3}$). This is a direct consequence of the equivalence of the linked-function relationship to the effects of ATP and proton binding on oxygenation.     

Proton nuclear magnetic resonance studies of the manganese (II) binding site of concanavalin A. Effect of saccharides on the solvent relaxation rates

The longitudinal relaxation rate ($\text{1}\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>p</mtext>}}$) of water protons was studied in solutions of Mn(II)-concanavalin A at a number of frequencies. These relaxation rates were lowered in the presence of a variety of saccharides which have affinities for concanavalin A which range over two orders of magnitude. A good correlation was found in which saccharides which bind tightly have the greatest effect and saccharides which bind weakly or not at all have little effect on the $\text{1}\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>p</mtext>}}$ values. The temperature dependence of the proton relaxation rates showed that the lowering of these rates in the presence of saccharides was most likely due to a change in the exchange rate of solvent interacting with protein-bound Mn(II), $\text{1}\text{T}{}_{\mathrm{<mtext>m</mtext>}}$.An analysis of the temperature and frequency dependence of the $\text{1}\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>p</mtext>}}$ and $\text{1}\text{T}{}_{\mathrm{<mtext>2</mtext><mtext>p</mtext>}}$ (transverse) solvent proton relaxation rates resulted in evaluation of a number of parameters for solvent water molecules interacting in the first coordination sphere of Mn(II) bound to concanavalin A. The ratio of the number of water molecules (q) to the Mn(II)-proton distance (r) obtained from a computer fit of the data over a limited temperature range is in accord with the findings of Koenig et al. ((1973) Proc. Nat. Acad. Sci.70, 475) and Meirovitch and Kalb ((1973) Biochim. Biophys. Acta303, 258). However, our studies of $\text{1}\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>p</mtext>}}$ and $\text{1}\text{T}{}_{\mathrm{<mtext>2</mtext><mtext>p</mtext>}}$ of water over a more extensive temperature range are best fit with the following conclusions: at low temperatures (<20 °C), the data are consistent with an outer-sphere relaxation process. At higher temperatures (> 30 °C), the water molecule in the inner coordination sphere of the bound Mn(II) begins exchanging more rapidly and contributes to the relaxation processes ($\text{1}\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>p</mtext>}}$ and $\text{1}\text{T}{}_{\mathrm{<mtext>2</mtext><mtext>p</mtext>}}$). The relaxation time of protons in the inner coordination shell, T_1M, contributes over the entire temperature range and produces a frequency dependence in the relaxivity data from 6 to 100 MH_z since the contributions to the correlation times are in the range 10^?9-10^?8 sec.     

Dimeric and tetrameric hemoglobins from the mollusc Scapharca inaequivalvis: The oxidation reaction

The oxidation by ferricyanide of the dimeric (HbI) and tetrameric (HbII) hemoglobins from the bivalve mollusc Scapharca inaequivalvis has been studied in static and kinetic experiments. Both hemoglobins give rise to hemichromes as stable oxidation products.Oxidation of deoxyHbI yields a hemichrome by a simple bimolecular process. No intermediate Met form can be detected during the reaction even in rapid mixing experiments. The HbI hemichrome undergoes a reversible pH-dependent dissociation into monomers. A simple model has been proposed to account for the linkage between proton binding and subunit dissociation.In the case of tetrameric HbII, oxidation yields an intermediate Met form. Thus, the kinetics of the oxidation reaction are always biphasic; the fast reaction is a bimolecular process and yields the Met derivative. The slow reaction is a monomolecular process and corresponds to the conversion of the Met form into the hemichrome: its rate is independent of the state of ligation of the ferrous protein and decreases with increase of pH. The HbII hemichrome is tetrameric when newly formed: it tends to dissociate into lower molecular weight species with the same optical properties. The rate of dissociation is relatively fast at neutral pH ($\text{t}\text{1}\text{2}$ ≈ 12 min) and markedly less at alkaline pH values.The HbI and HbII hemichromes are reduced by dithionite yielding the spectra of the native deoxygenated proteins: in the case of HbII, the tetrameric structure of the native protein is re-acquired.     

Rheological characteristics of desialylated erythrocytes in relation to fibrinogen-induced aggregation

The effect of fibrinogen and sialic acid content of erythrocytes on the aggregation of erythrocytes was quantitatively examined by using a rheoscope combined with a television image analyzer and a computer. (1) The electrophoretic mobility of erythrocytes was proportional to the sialic acid content of erythrocytes (the surface potential of erythrocytes could be expressed by the sialic acid content). (2) The aggregation of erythrocytes was accelerated by increasing fibrinogen concentration in the medium (due to the increased bridging force among erythrocytes) or by decreasing the sialic acid content (due to the reduction of the electrostatic repulsive force among erythrocytes). (3) An empirical equation expressing the velocity of aggregate formation (ν, in μm²/min) by the concentration of fibrinogen ($\text{F}$, in g/dl) and the sialic acid content ($\text{S}$, in μmol/ml red blood cells), log $\text{ν = ?0.065 F}{}^{\mathrm{?1.2}}\text{S + 2.2 F}{}^{0.35}$, was deduced. (4) The contribution of the bridging force of fibrinogen to the erythrocyte aggregation was much greater than that of the electrostatic repulsive force produced by sialic acid on the surface of erythrocytes.     

Kinetics of the polymerization of hemoglobin S: studies below normal erythrocyte hemoglobin concentration.

The kinetics of polymerization of deoxyhemoglobin S have been studied by measuring transverse water proton relaxation times (T₂) in hemoglobin solutions. As seen by other techniques, the kinetic profile consists of a delay time followed by a decrease in T₂ during polymerization. The length of the delay time can be decreased and the rate of change of T₂ can be increased by increasing the concentration of hemoglobin S or non-gelling hemoglobin or ovalbumin. At a total protein concentration of about 210 mg/ml the kinetic profiles in all three cases are indistinguishable suggesting that a non-specific protein-protein interaction may be involved in the kinetics of polymerization. In addition, it is suggested that no polymer formation occurs during the delay period.     

Ligand-dependent aggregation of chicken hemoglobin AI

The hemoglobin A_I component of the white leghorn chicken may potentially provide an animal model for the $\text{in vitro}$ aggregation behavior of human hemoglobin S. In solutions of low ionic strength, it has been found to undergo a striking loss of solubility upon deoxygenation, leading to the formation of macromolecular aggregates. This property is not shared by the other major chicken hemoglobin component, designated A_II. Compositional and NH₂-terminal sequence analysis indicate that extensive primary structural differences reside in the alpha chains of these two hemoglobins. The beta chains appear to be identical. Examination by electron microscopy suggests that the deoxyhemoglobin A_I forms microcrystalline arrays. The A_I component shows diminished reactivity with ¹³CO₂, as judged from ¹³C NMR measurements.     

The mechanism of anion inhibition of pork heart aspartate aminotransferase

The mechanism of anion inhibition of the reaction of the pork heart extramitochondrial aspartate aminotransferase (EC 2.6.1.1) with erythro-β-hydroxy-l-aspartate was investigated. This reaction produces a mixture of complexes, one of which is characterized by an absorption maximum at 492 nm. Spectrophotometric analysis of equilibrium mixtures of aspartate aminotransferase and erythro-β-hydroxy-l-aspartate, in different buffers, indicated that acetate, chloride, and cacodylate were competitive inhibitors of hydroxyaspartate binding. Pyrophosphate, however, was not a competitive inhibitor. Between pH 4.5 and 9.0 the affinity of the enzyme for the monovalent anions decreased as the pH increased. The data indicated that the anion binding group had a pK_a in the range from pH 6 to 7, depending upon the anion studied. From pH 4.5 to 9.0, the substrate dissociation constant and the distribution of enzyme-substrate complexes were both unaffected by pH. By stopped-flow spectrophotometry, an initial rapid relaxation ($\text{t}\text{1}\text{2}\text{= 2–8}\text{ms}$) was associated with an increase in absorbance at 492 nm, and this rate depended upon both substrate and buffer concentrations. A slower relaxation ($\text{t}\text{1}\text{2}\text{= 180}\text{ms}$) was associated with a decrease in the absorbance at 492 nm to approximately 70% of the value attained in the first rapid reaction. The rate of this slower reaction was largely independent of substrate and buffer concentrations. Kinetic analysis of the rates of the first relaxation in several different concentrations of Tris-acetate buffer of pH 8 showed that the rate of association decreased with increasing acetate concentration whereas the reaction rate for dissociation was unaffected. Thus, acetate appears to exert its inhibitory effect by preventing the formation of the enzyme-substrate complex rather than by displacing the substrate from the enzyme.     

Determination of delta psi, delta pH and the proton electrochemical gradient in isolated cholinergic synaptic vesicles

The electrical potential (Δψ) of intact cholinergic synaptic vesicles was measured in the presence and absence of the proton translocator carbonyl cyanide p-trifluoromethoxy-phenylhydrazone (FCCP), and the results were utilized to calculate the vesicular proton chemical gradient (ΔpH) and proton electrochemical potential $\text{(Δ}\text{μ}{}_{\mathrm{<mtext>H</mtext>}}\text{+)}$. At external pH = 7.4 the vesicles maintain a proton electrochemical gradient of $\text{?+20}\text{mV}$ (positive inside) which is composed of $\text{Δψ??80}\text{mV}$ (negative inside) and $\text{Δ}\text{pH}\text{?1.6}$ (acidic inside). The proton chemical gradient (ΔpH) increases as a function of pH_out whereas the vesicular electrical potential (Δψ) is only slightly affected by the external pH. Consequently, $\text{Δ}\text{μ}{}_{\mathrm{<mtext>H</mtext>}}\text{+}$ is larger at basic external pH values ($\text{?+40}\text{mV}$ at pH_out = 9.0) and smaller at acidic external pH values ($\text{Δ}\text{μ}{}_{\mathrm{<mtext>H</mtext>}}\text{+?0}$ at (pH_out = 5.6). The possible physiological role of the electrochemical potentials in maintaining high concentrations of acetylcholine within the cholinergic synaptic vesicle is discussed.     

The rapid intermembraneous transfer of retinoids

The intermembraneous rates of retinoid (all-$\text{trans}$-retinol(al), 11-$\text{cis}$-retinol and all-$\text{trans}$-retinol palmitate) transfer from vesicle to vesicle and vesicle to erythrocyte were studied. The rates of transfer of the retinols(al) were exceedingly rapid. The rates of transfer of the retinols(al) from egg phophatidyl choline based SUV's to bovine erythrocytes had a half-time of approximately 1–2 min. The vesicle to vesicle transfer rate was too rapid to measure by conventional techniques. By contrast, all-$\text{trans}$-retinol palmitate did not undergo transfer at an appreciable rate.     

Membrane leakage of solutes after thermal shock or freezing

Washed human erythrocytes were cooled at different rates from +37 °C to 0 °C in hypertonic solutions of either NaCl (1.2 m) or of a mixture of sucrose (40% $\text{w}\text{v}$) with NaCl (2.53% $\text{w}\text{v}$). Thermal shock hemolysis was measured and the surviving cells were examined for their mass and cell water content and also for net movements of sodium, potassium, and ¹⁴C-sucrose. The results were compared with those obtained from cells in sucrose (40% $\text{w}\text{v}$) initially, cooled at different rates to ?196 °C and rapidly thawed.The cells cooled to 0 °C in NaCl (1.2 m) showed maximal hemolysis at the fastest cooling rate studied (39 °C/min). In addition in the surviving cells this cooling rate induced the greatest uptake of ¹⁴C-sucrose and increase in cell water and cell mass and also entry of sodium and loss of cell potassium. A different dependence on cooling rate was seen with the cells cooled from +37 °C to 0 °C in sucrose (40% $\text{w}\text{v}$) with NaCl (2.53% $\text{w}\text{v}$). In this solution, survival decreased both at slow and fast cooling rates correlating with the greatest uptake of cell sucrose and increase in cell water. There was extensive loss of cell potassium and uptake of sodium at all cooling rates, the cation concentrations across the cell membrane approaching unity.The cells frozen to ?196 °C at different cooling rates in sucrose (40% $\text{w}\text{v}$) initially, also showed sucrose and water entry on thawing together with a loss of cell potassium and an uptake of cell sodium. More sucrose entered the cells cooled slowly (1.8 ° C/min) than those cooled rapidly (318 ° C/min).These results show that cooling to 0 °C in hypertonic solutions (thermal shock) and freezing to ?196 °C both induce membrane leaks to sucrose as well as to sodium and potassium. These leaks are not induced by the hypertonic solutions themselves but are due to the effects of the added stress of the temperature reduction on the membranes modified by the hypertonic solutions. The effects of cooling rate are explicable in terms of the different times of exposure to the hypertonic solutions. These results indicate that the damage observed after thermal shock or slow freezing is of a similar nature.     

Quantum requirements for proton uptake in spinach chloroplasts

Studies of electron and proton transport in chloroplast preparations (Type D) from spinach (Spinacea oleracea L.) yield three basic results. First, in electron transport catalyzed by methyl viologen from water to oxygen at pH 7.6, the quantum requirement for electron transport ($\text{hv}\text{e}{}^{\mathrm{?}}$) was 2.2, while the corresponding requirement for proton transport ($\text{h}\text{v}\text{H}{}^{\mathrm{+}}$) was 1.2. Second, the electron and proton quantum requirements were relatively independent of the individual chloroplast preparation or certain components of the resuspension medium, but did depend upon the reaction medium's initial pH. Third, measurable electron and proton transport did not occur under 715-nm illumination, nor did such activities occur in the presence of DCMU under 645-nm illumination when methyl viologen was used as the electron transport cofactor. These experimental results reconcile the quantum requirement of proton transport with Mitchell's chemiosmotic theory for chloroplast energy transduction and resolve a long standing controversy regarding the quantum requirement in chloroplast thylakoids.     

A respiration-dependent primary sodium extrusion system functioning at alkaline pH in the marine bacterium Vibrioalginolyticus

The membrane potential generated at pH 8.5 by K⁺-depleted and Na⁺-loaded $\text{Vibrio}\text{alginolyticus}$ is not collapsed by proton conductors which, instead, induce the accumulation of protons in equilibrium with the membrane potential. The generation of such a membrane potential and the accumulation of protons are specific to Na⁺-loaded cells at alkaline pH and are dependent on respiration. Extrusion of Na⁺ at pH 8.5 occurs in the presence of proton conductors unless respiration is inhibited while it is abolished by proton conductors at acidic pH. The uptake of α-aminoisobutyric acid, which is driven by the Na⁺-electrochemical gradient, is observed even in the presence of proton conductors at pH 8.5 but not at acidic pH. We conclude that a respiration-dependent primary electrogenic Na⁺ extrusion system is functioning at alkaline pH to generate the proton conductor-insensitive membrane potential and Na⁺ chemical gradient.     

Evidence against proton gradient formation being the cause of chlorophyll fluorescence quenching by N-methylphenazonium methosulfate

In strong illumination, 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU)-poisoned chloroplasts exhibit a high yield of chlorophyll fluorescence while $\text{P-700}$ turnover, proton uptake, and phosphorylation are inhibited and a pH gradient is undetectable. When 10 μM $\text{N-}\text{methylphenazonium}$ methosulfate (PMS) is included, the fluorescence yield in light is substantially reduced, and when 100 μM ascorbate is also included, the yield is diminished approximately to the level in darkness. Only very slight increases in $\text{P-700}$ turnover and proton uptake (but no detectable pH gradient) accompany the fluorescence yield decline.When 10 μM PMS and 15 mM ascorbate are added to poisoned chloroplasts (the oxygen concentration being greatly reduced), $\text{P-700}$ turnover, proton uptake, the pH gradient and phosphorylation all reach high levels. In this case, the yield of chlorophyll fluorescence is low and is the same in both light and dark. Further addition of an uncoupler eliminates proton uptake, the pH gradient and phosphorylation but does not significantly elevate the fluorescence yield. From these observations we suggest that, in DCMU-poisoned chloroplasts, the fluorescence quenching with PMS occurs by a mechanism unrelated to the generation of a phosphorylation potential.With chloroplasts unpoisoned by DCMU, PMS quenches fluorescence and considerably stimulates proton uptake, the pH gradient and phosphorylation. However, in this case, PMS serves to restore net electron transport.     

Differential rates of proton exchange for the guanidinium nitrogens of L-arginine determined by natural-abundance nitrogen-15 nuclear magnetic resonance spectroscopy.

Differential rates of NH proton-exchange reactions have been determined for the guanidinium nitrogens of l-arginine, $\text{1}\text{?}$, in the pH range of 0.5 to 11.5 by natural-abundance nitrogen-15 NMR spectroscopy. Base-catalyzed NH proton exchange of the NH group is found to be two times faster than for the guanidino NH₂ groups. The results can be rationalized by consideration of the contributions of various valence-bond structures to the resonance hybrid of $\text{1}\text{?}$.