Inhibition of the Na,K-ATPase of canine renal medulla by several local anesthetics

The ATPase activity of Na,K-ATPase-enriched membranes from canine renal medulla was determined in the absence of local anesthetic and in the presence of procaine, chloroprocaine, bupivacaine, mepivacaine, lidocaine, and two quaternary derivatives of lidocaine (QX-222 and QX-314) at 37( composite function)C. Chloroprocaine (IC(50)= 13 mM) had slightly greater potency than procaine (IC(50)= 17.7 mM). Bupivacaine (IC(50)= 6.7 mM) was more potent than its congener mepivacaine (IC(50)> 10 mM, the solubility limit). QX-222 (IC(50)> 600 mM) and QX-314 (IC(50)= 132 mM) had less potency than lidocaine (IC(50)= 30.4 mM). This study supports the interpretation that the uncharged forms of local anesthetics are much more potent inhibitors of Na,K-ATPase activity than the cationic forms.

Effects of local anaesthetics on the activity of the Na,K-ATPase of canine renal medulla

The purpose of this study is to characterize the effects of local anaesthetics on Na,K-ATPase activity. The ATPase activity of Na, K-ATPase-enriched membranes from canine renal medulla was determined in the absence and in the presence of lidocaine, procaine, tetracaine, benzocaine, bupivacaine, prilocaine, and procainamide at 37 and 25 degrees C. All of these local anaesthetics, except benzocaine, inhibit the activity of the Na,K-ATPase of canine renal medulla at both 25 and 37 degrees C. Benzocaine inhibits Na,K-ATPase activity at 37 degrees C, but stimulates activity at 25 degrees C. The influence of lidocaine on stimulation of Na,K-ATPase activity by Na(+) and K(+) was investigated. Lidocaine increases the apparent K(0.5) of the Na,K-ATPase for both Na(+) and K(+) and decreases the V(max) values for both ions. IC(50) values for lidocaine increase with increasing concentrations of both Na(+) and K(+). The data indicate that lidocaine diminishes the affinity of the Na,K-ATPase for Na(+) and K(+) and that binding of Na(+) or K(+) decreases the potency of lidocaine as an inhibitor of the Na,K-ATPase. Lidocaine markedly decreases the affinity of the Na,K-ATPase for ouabain, but only slightly diminishes the maximum amount of ouabain bound. Unprotonated lidocaine is apparently a more potent inhibitor than is the protonated form.

Effects of general anaesthetics on the activity of the Na,K-ATPase of canine renal medulla

Several previous studies have reported inhibition of Na,K-ATPase activity by chlorpromazine, phenobarbital and pentobarbital, thiopental, and monoketones. The purpose of this study is to investigate the influences of other general anaesthetics on Na,K-ATPase activity. The ATPase activity of Na,K-ATPase-enriched membranes from canine renal medulla was determined at 37 degrees C in the absence and in the presence of hexanol, diethylether, halothane, and propofol. The influence of hexanol on stimulation of Na,K-ATPase activity by Na+ and K+ was investigated. Hexanol, diethylether, halothane, and propofol inhibited the activity at 37 degrees C of the Na,K-ATPase of canine renal medulla. The IC50 values at 37 degrees C were: hexanol, 12.3 mM; diethylether, 170 mM; halothane, 7.35 mM; propofol, 0.127 mM. Hexanol increased the K0.5 of the Na,K-ATPase for K+ at 37 degrees C, but did not affect the K0.5 for Na+. At lower [K+] hexanol was a more potent inhibitor than at higher [K+].

Different anesthetic sensitivities of skeletal and cardiac isoforms of the Ca-ATPase

We have previously shown that low levels of the volatile anesthetic halothane activate the Ca-ATPase in skeletal sarcoplasmic reticulum (SR), but inhibit the Ca-ATPase in cardiac SR. In this study, we ask whether the differential inhibition is due to (a) the presence of the regulatory protein phospholamban in cardiac SR, (b) different lipid environments in skeletal and cardiac SR, or (c) the different Ca-ATPase isoforms present in the two tissues. By expressing skeletal (SERCA 1) and cardiac (SERCA 2a) isoforms of the Ca-ATPase in Sf21 insect cell organelles, we found that differential anesthetic effects in skeletal and cardiac SR are due to differential sensitivities of the SERCA 1 and SERCA 2a isoforms to anesthetics. Low levels of halothane inhibit the SERCA 2a isoform of the Ca-ATPase, and have little effect on the SERCA 1 isoform. The biochemical mechanism of halothane inhibition involves stabilization of E2 conformations of the Ca-ATPase, suggesting direct anesthetic interaction with the ATPase. This study establishes a biochemical model for the mechanism of action of an anesthetic on a membrane protein, and should lead to the identification of anesthetic binding sites on the SERCA 1 and SERCA 2a isoforms of the Ca-ATPase.

An autoinhibitory peptide from the erythrocyte Ca-ATPase aggregates and inhibits both muscle Ca-ATPase isoforms

We have studied the effects of C28R2, a basic peptide derived from the autoinhibitory domain of the plasma membrane Ca-ATPase, on enzyme activity, oligomeric state, and E1-E2 conformational equilibrium of the Ca-ATPase from skeletal and cardiac sarcoplasmic reticulum (SR). Time-resolved phosphorescence anisotropy (TPA) was used to determine changes in the distribution of Ca-ATPase among its different oligomeric species in SR. C28R2, at a concentration of 1-10 microM, inhibits the Ca-ATPase activity of both skeletal and cardiac SR (CSR). In skeletal SR, this inhibition by C28R2 is much greater at low (0.15 microM) than at high (10 microM) Ca2+, whereas in CSR the inhibition is the same at low and high Ca2+. The effects of the peptide on the rotational mobility of the Ca-ATPase correlated well with function, indicating that C28R2-induced protein aggregation and Ca-ATPase inhibition are much more Ca-dependent in skeletal than in CSR. In CSR at low Ca2+, phospholamban (PLB) antibody (functionally equivalent to PLB phosphorylation) increased the inhibitory effect of C28R2 slightly. Fluorescence of fluorescein 5-isothiocyanate-labeled SR suggests that C28R2 stabilizes the E1 conformation of the Ca-ATPase in skeletal SR, whereas in CSR it stabilizes E2. After the addition of PLB antibody, C28R2 still stabilizes the E2 conformational state of CSR. Therefore, we conclude that C28R2 affects Ca-ATPase activity, conformation, and self-association differently in cardiac and skeletal SR and that PLB is probably not responsible for the differences.

Differential effects of general anesthetics on the quaternary structure of the Ca-ATPases of cardiac and skeletal sarcoplasmic reticulum

The effects of the general anesthetics hexanol, halothane, and diethyl ether on Ca-ATPase activity and on the oligomeric state of the Ca-ATPase of sarcoplasmic reticulum (SR) from cardiac and skeletal muscle were investigated. The effects of these general anesthetics on Ca-ATPase activity were similar in cardiac and skeletal SR and were characterized by stimulation of Ca-ATPase activity at lower concentrations of anesthetics and inhibition at higher concentrations. The distribution of the Ca-ATPase among its oligomeric states was estimated from the time-resolved phosphorescence anisotropy (TPA) decay of SR in which Ca-ATPase was covalently labeled with erythrosin isothiocyanate (ERITC) or with erythrosin iodoacetamide (ERIA). In contrast to the similar responses of Ca-ATPase activity, there were marked differences in the responses to general anesthetics of the TPA decay between cardiac and skeletal SR. In cardiac SR hexanol, halothane, and diethyl ether caused pronounced increases in the limiting anisotropy at very long times (r infinity), which indicate increases in the fraction of oligomers too large to rotate on the millisecond time scale of the experiments. In skeletal SR, by contrast, there were no significant changes in r infinity in response to the three general anesthetics. This difference between cardiac and skeletal SR in response to general anesthetics is not due to the presence of phospholamban in cardiac SR, since SR from AT-1 cells, which have the SERCA2a isoform of Ca-ATPase, but only trace levels of phospholamban, have increases in r infinity in response to the general anesthetics that resemble those in cardiac SR. Experiments with cardiac SR labeled with ERIA give similar results, showing that the results with ERITC are not an artifact of the labeling procedure. Increasing the ionic strength with LiCl diminished the proportion of large immobile oligomers of cardiac Ca-ATPase under control conditions but enhanced the formation of large oligomers in response to hexanol.

Phospholamban-dependent effects of C12E8 on calcium transport and molecular dynamics in cardiac sarcoplasmic reticulum

We have studied the effects of the nonionic detergent C12E8 on Ca-ATPase enzymatic activity and oligomeric state (detected by time-resolved phosphorescence anisotropy, TPA) in skeletal and cardiac sarcoplasmic reticulum (SR). In skeletal, SR, C12E8 inhibits the CA-ATPase, both at high (micromolar and above) and low (submicromolar) Ca. In cardiac SR, C12E8 inhibits at high Ca but activates at low Ca. Thus C12E8 activates enzymatic activity only in cardiac SR and only under conditions (submicromolar Ca) where phospholamban (PLB) regulates (inhibits) the enzyme [Lu, Y.-Z., & Kirchberger, M.A. (1994) Biochemistry 33, 5056-5062]. TPA of skeletal SR at low and high Ca demonstrates that C12E8 induces aggregation of ATPase monomers and small oligomers. C12E8 also aggregates the Ca-ATPase in cardiac SR at high Ca. In cardiac SR at low Ca, the Ca-ATPase is already highly aggregated, and C12E8 partially dissociates these aggregates. Thus the TPA results provide a simple physical explanation for the functional effects: C12E8 inhibits the ATPase when it aggregates the enzyme (skeletal SR at high and low Ca; cardiac SR at high Ca), and the detergent activates when it dissociates ATPase oligomers (cardiac SR at low Ca). C12E8 stabilizes the E2P conformation of the Ca-ATPase with respect to the E2 conformation, and this stabilization is PLB-dependent. Both the physical and functional effects of C12E8 on the Ca-ATPase are PLB-dependent, with C12E8 reversing the effects of PLB. The results provide insight into the mechanism by which PLB regulates the Ca-ATPase in cardiac SR.

Anesthetics alter the physical and functional properties of the Ca-ATPase in cardiac sarcoplasmic reticulum

We have studied the effects of the local anesthetic lidocaine, and the general anesthetic halothane, on the function and oligomeric state of the CA-ATPase in cardiac sarcoplasmic reticulum (SR). Oligomeric changes were detected by time-resolved phosphorescence anisotropy (TPA). Lidocaine inhibited and aggregated the Ca-ATPase in cardiac SR. Micromolar calcium or 0.5 M lithium chloride protected against lidocaine-induced inhibition, indicating that electrostatic interactions are essential to lidocaine inhibition of the Ca-ATPase. The phospholamban (PLB) antibody 2D12, which mimics PLB phosphorylation, had no effect on lidocaine inhibition of the Ca-ATPase in cardiac SR. Inhibition and aggregation of the Ca-ATPase in cardiac SR occurred at lower concentrations of lidocaine than necessary to inhibit and aggregate the Ca-ATPase in skeletal SR, suggesting that the cardiac isoform of the enzyme has a higher affinity for lidocaine. Halothane inhibited and aggregated the Ca-ATPase in cardiac SR. Both inhibition and aggregation of the Ca-ATPase by halothane were much greater in the presence of PLB antibody or when PLB was phosphorylated, indicating a protective effect of PLB on halothane-induced inhibition and aggregation. The effects of halothane on cardiac SR are opposite from the effects of halothane observed in skeletal SR, where halothane activates and dissociates the Ca-ATPase. These results underscore the crucial role of protein-protein interactions on Ca-ATPase regulation and anesthetic perturbation of cardiac SR.

Self-association accompanies inhibition of Ca-ATPase by thapsigargin

Recent studies have demonstrated a relationship between the activity of the Ca-ATPase of sarcoplasmic reticulum and its state of self-association. In the present study, the effects of thapsigargin (TG), a toxin that specifically inhibits the Ca-ATPase of rabbit skeletal muscle sarcoplasmic reticulum membrane, were studied by detecting the time-resolved phosphorescence anisotropy (TPA) decay of the Ca-ATPase that had been labeled with the phosphorescent probe erythrosin-isothiocyanate (ErITC). Anisotropy decays were fit to a function that consisted of three exponential decays plus a constant background, as well as to a function describing explicitly the uniaxial rotation of proteins in a membrane. In the absence of TG, the anisotropy was best-fit by a model representing the rotation of three populations, corresponding to different-sized oligomeric species in the membrane. The addition of stoichiometric amounts of TG to the Ca-ATPase promptly decreased the overall apparent rate of decay, indicating decreased rotational mobility. A detailed analysis showed that the principal change was not in the rates of rotation but rather in the population distribution of the Ca-ATPase molecules among the different-sized oligomers. TG decreased the proportion of small oligomers and increased the proportion of large ones. Preincubation of the ErITC-SR in 1 mM Ca2+, which stabilizes the E1 conformation relative to E2, was found to protect partially against the changes in the TPA associated with the presence of the inhibitor. These results are consistent with the hypothesis that TG inhibits the Ca-ATPase by stabilizing it in an E2-like conformation, which promotes the formation of larger aggregates of the enzyme. When combined with the effects of other inhibitors on the Ca-ATPase, these results support a general model for the coupling of enzyme conformation and self-association in this system.

Hexanol and lidocaine affect the oligomeric state of the Ca-ATPase of sarcoplasmic reticulum

Hexanol at 7 degrees C stimulates the activity of the Ca-ATPase of sarcoplasmic reticulum (SR). Time-resolved phosphorescence spectroscopy studies of SR whose Ca-ATPase is covalently labeled with erythrosin isothiocyanate (ERITC) indicate that at 7 degrees C hexanol (1) cause a concentration-dependent increase in the rate of decay of phosphorescence anisotropy, (2) causes larger oligomers of Ca-ATPase to dissociate into smaller oligomers, and (3) increases the rotational mobility of Ca-ATPase in all its oligomeric states. Electron paramagnetic resonance (EPR) spectroscopy of spin-labeled stearic acid (SASL) in SR suggests that at 7 degrees C hexanol diminishes the fraction of SR lipids in the boundary lipid domain and disorders and fluidizes both the boundary lipid and the unrestricted lipid domain. In protein-free liposomes of extracted SR lipids hexanol increases fluidity and decreases order to a greater extent near the center of the lipid bilayer than near the polar head groups. At 25 degrees C hexanol has biphasic effects on Ca-ATPase activity: at 10 and 20 mM hexanol increases activity, but at 30 mM and especially at 40 mM there is inhibition of Ca-ATPase activity. The influence of hexanol at 25 degrees C on the oligomeric state of Ca-ATPase is also biphasic. At 10 and 20 mM, hexanol promotes the dissociation of larger oligomers into smaller ones, whereas at higher concentrations, 30 and 40 mM, hexanol causes larger oligomers to be formed from smaller ones. Lidocaine at 25 degrees C inhibits Ca-ATPase activity and causes dramatic slowing of the decay of phosphorescence anisotropy of ERITC-labeled SR by causing the formation of larger oligomers of Ca-ATPase from smaller ones. In protein-free liposomes of SR lipids at 25 degrees C, lidocaine disorders and fluidizes the acyl chains near the center of the bilayer (as did hexanol), but has opposite effects near the polar head groups. The opposite effects of hexanol and lidocaine on the oligomeric state of the SR Ca-ATPase provide a new molecular explanation for the opposite effects of hexanol and lidocaine on the activity of the Ca-ATPase. We conclude that the biphasic effects of hexanol on the activity of Ca-ATPase can be accounted for by biphasic effects of hexanol on the oligomeric state of the Ca-ATPase. This study supports the view that anesthetics can alter interactions between membrane proteins.

Identification of heterotrimeric and low molecular weight GTP-binding proteins in rabbit skeletal muscle longitudinal sarcoplasmic reticulum

Direct photoaffinity labeling of proteins of longitudinal sarcoplasmic reticulum (LSR) of rabbit skeletal muscle with [32P]GTP revealed GTP-binding proteins of about 52, 45 and 30 kDa. ADP-ribosylation with [32P]NAD in the presence of cholera toxin (CTX) or pertussis toxin (PTX) indicates the existence of a CTX substrate (about 45 kDa); no PTX substrates were observed. Western blots of LSR probed with RM/1, an antiserum against a decapeptide from the C-terminus of Gs alpha, showed an immunoreactive band at about 45 kDa. [32P]GTP overlays of Western blots of LSR showed a heavily-labeled protein of about 29 kDa and one or more additional slightly smaller proteins that were more weakly labeled. When LSR was subjected to mild trypsin hydrolysis, the Western blot overlay revealed three bands at about 23, 25 and 29 kDa. Western blots of LSR proteins showed no significant immunoreactivity with the anti-(pan)-ras monoclonal antibodies 142-24E05 and Ras 11. ADP-ribosylation of LSR with [32P]NAD in the presence of C3 exoenzyme of Clostridium botulinum yielded a labeled band at about 23 kDa. Our results indicate the presence in rabbit LSR of a Gs alpha, the absence of Gi and G(o), and the presence of several low molecular weight GTP-binding proteins, distinct from p21 ras, one of which belongs to the rho or rac family.

Influence of the 53 kDa glycoprotein on the cooperativity of the Ca(2+)-ATPase of the sarcoplasmic reticulum

Previous results from this laboratory suggest that the 53 kDa glycoprotein (GP-53) of rabbit skeletal muscle sarcoplasmic reticulum membrane (SR) may influence coupling between Ca2+ transport and ATP hydrolysis by the Ca(2+)-ATPase. Here we report evidence that GP-53 may influence the cooperative behavior of the Ca(2+)-ATPase. The ATPase activity of the Ca(2+)-ATPase displays negative cooperative dependence (Hill coefficient n less than 1) on [MgATP] and has positive cooperative dependence (n greater than 1) on [Ca2+]free. We have determined the degree of cooperativity for native SR vesicles, SR preincubated with antiserum against GP-53 or preimmune serum, and SR partially extracted with KCl-cholate. Our results show that SR preincubated with preimmune serum or SR treated with cholate in 50 mM KCl (yielding membranes rich in GP-53) demonstrate a cooperative dependence of Ca(2+)-ATPase activity on both [ATP] and [Ca2+] similar to that of untreated SR. SR preincubated with anti-GP-53 antiserum (which causes an uncoupling of Ca2+ transport from ATP hydrolysis) or SR extracted with cholate in 1 M KCl (yielding membranes depleted of GP-53) displays decreased positive cooperative dependence on [Ca2+] and decreased negative cooperative dependence on [ATP]. The results are consistent with the interpretation that GP-53 may influence the cooperative behavior of the Ca(2+)-ATPase.

Antibodies against the 53 kDa glycoprotein inhibit the rotational dynamics of both the 53 kDa glycoprotein and the Ca(2+)-ATPase in the sarcoplasmic reticulum membrane

The purpose of this study is to better define the relationship of the 53 kDa glycoprotein (GP-53) of the sarcoplasmic reticulum (SR) to other SR proteins. Towards that end the effects of antibodies against GP-53 on the rotational dynamics of maleimide spin-labeled proteins of SR of rabbit skeletal muscle were investigated. The labeling protocol used in this study provided 1.6 +/- 0.3 moles spin label incorporated per 10(5) g SR protein. Labeling specificity studies indicated that nearly 70% of the label bound specifically to the Ca(2+)-ATPase, with the remainder bound to GP-53. Using saturation-transfer electron paramagnetic resonance (ST-EPR), it was determined that the rotational mobility (i.e., the rate of rotation) of the spin-labeled SR proteins decreased greater than 5-fold upon preincubation of MSL-SR with an antiserum against the GP-53, while preincubation of MSL-SR with preimmune serum had no effect. Preincubation of MSL-SR with a monoclonal antibody against the GP-53 produced a 4-fold decrease in the rotational mobility of the MSL-SR proteins compared to control measurements. Further, these effects showed a marked calcium dependence: the decrease in the rotational mobility of the MSL-SR proteins preincubated with anti-GP-53 antibodies in 500 microM Ca2+ was 3-6-fold greater than that of MSL-SR preincubated with antibodies in 5 mM EGTA. While MSL was bound to both Ca(2+)-ATPase and GP-53, model calculations indicated that the decreases observed in the rotational mobility of the MSL-SR proteins caused by the anti-GP-53 monoclonal antibodies were too large to be accounted for by effects on GP-53 alone. The calculations suggest that the rotational rate of Ca(2+)-ATPase was also diminished by anti-GP-53 monoclonal antibodies, indicating an interaction between GP-53 and Ca(2+)-ATPase in the SR membrane.

Calcium transport by sarcoplasmic reticulum of skeletal muscle is inhibited by antibodies against the 53-kilodalton glycoprotein of the sarcoplasmic reticulum membrane

The effects of an antiserum against the 53-kDa glycoprotein (GP-53) of the sarcoplasmic reticulum (SR) and of monoclonal antibodies against GP-53 on Ca2+ transport and ATP hydrolysis by SR of rabbit skeletal muscle have been investigated. Preincubation of SR with an antiserum against GP-53 resulted in decreased ATP-driven Ca2+ transport by the SR but had no effect on Ca2+-stimulated ATP hydrolysis. Preincubation of SR with preimmune serum had no significant effect on either Ca2+ transport or Ca2+-ATPase activity. The effect of anti-GP-53 serum was time and concentration dependent. Preincubation of SR with two monoclonal antibodies against GP-53 had no effect on Ca2+ transport or on Ca2+-stimulated ATP hydrolysis. However, preincubation of SR with either monoclonal antibody against GP-53 together with a monoclonal antibody against the Ca2+-ATPase (at levels which had little effect alone) resulted in markedly decreased rates of Ca2+ uptake and ATP hydrolysis. Preincubation of SR with anti-GP-53-serum or with monoclonal antibodies, under the same conditions that inhibited Ca2+ uptake, did not increase the passive permeability of the SR membrane to Ca2+, did not decrease the permeability of the SR to oxalate, and did not cause significant proteolysis of the Ca2+-ATPase. Our results are consistent with the interpretation that GP-53 may modulate the function of the Ca2+-ATPase of the SR membrane.

Use of a membrane-bound fluorophore to characterize diffusion boundary layers around human erythrocytes

A novel method is used to demonstrate the presence of diffusion boundary layers around erythrocytes following rapid mixing in a stopped-flow spectrophotometer and to estimate the apparent dimensions of the diffusion boundary layers. Pink erythrocyte ghosts labeled on their external surfaces with tetramethyl rhodamine isothiocyanate (TRITC) were mixed in a stopped-flow apparatus with 50 mM NaI in Ringer's solutions. I- is an effective collisional quencher of TRITC fluorescence. TRITC fluorescence after flow stopped decreased monoexponentially with time. The concentration of I- at the cell surface as a function of time was estimated from the dependence of TRITC fluorescence on I- concentration in steady-state experiments. The kinetics of the increase in I- concentration at the cell surface was fit to two diffusional models: a planar erythrocyte ghost bounded by planar diffusion boundary layer and a spherical erythrocyte surrounded by a spherical shell diffusion boundary layer. The planar model best fits the experimental data with a diffusion boundary layer 4.68 microns thick. Using the spherical model the experimental data is best fit by a 6.9 microns diffusion boundary layer.

Coupling of Ca2+ transport to ATP hydrolysis by the Ca2+-ATPase of sarcoplasmic reticulum: potential role of the 53-kilodalton glycoprotein

An essential feature of the function of the Ca2+-ATPase of sarcoplasmic reticulum (SR) is the close coupling between the hydrolysis of ATP and the active transport of Ca2+. The purpose of this study is to investigate the role of other components of the SR membrane in regulating the coupling of Ca2+-ATPase in SR isolated from rabbit skeletal muscle, reconstituted SR, and purified Ca2+-ATPase/phospholipid complexes. Our results suggest that (1) it is possible to systematically alter the degree of coupling obtained in reconstituted SR preparations by varying the [KC1] present during cholate solubilization, (2) the variation in coupling is not due to differences in the permeability of the reconstituted SR vesicles to Ca2+, and (3) vesicles reconstituted with purified Ca2+-ATPase are extensively uncoupled under our experimental conditions regardless of the lipid/protein ratio or phospholipid composition. In reconstituted SR preparations prepared by varying the [KC1] present during cholate treatment, we find a direct correlation between the relative degree of coupling between ATP hydrolysis and Ca2+ transport and the level of the 53-kilodalton (53-kDa) glycoprotein of the SR membrane. These results suggest that the 53-kDa glycoprotein may be involved in regulating the coupling between ATP hydrolysis and Ca2+ transport in the SR.

Asymmetric transport of a fluorescent glucose analogue by human erythrocytes

A fluorescent glucose analogue, 6-deoxy-N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-aminoglucose (NBDG), was synthesized and its interactions with the hexose transport system of the human red blood cell were investigated. NBDG entry is inhibited by increasing concentrations of D-glucose (Ki = 2 mM). However, NBDG exit is unaffected by D-glucose in red blood cells. Cytochalasin B was found to inhibit both NBDG entry and exit. NBDG accumulates in the red blood cell above the theoretical equilibrium concentration. Accumulation of NBDG is temperature-sensitive and is due to the binding of NBDG to some intracellular substance. The binding of NBDG to purified hemoglobin suggests that accumulation of NBDG by erythrocytes is due to the intracellular binding of NBDG to hemoglobin. NBDG does not accumulate in pink erythrocyte ghosts, while its rate of uptake is still inhibited by D-glucose and cytochalasin B. Although there was no apparent D-glucose inhibition of NBDG exit by intact red blood cells, D-glucose was able to inhibit NBDG exit by pink erythrocyte ghosts. The differing properties of NBDG influx and efflux support the interpretation that the hexose transport system of the human red blood cell appears asymmetric although it may be intrinsically symmetric.

Perturbation of egg phosphatidylcholine and dipalmitoylphosphatidylcholine multilamellar vesicles by n-alkanols. A fluorescent probe study

The perturbing effects of n-alkanols (pentanol, decanol and tetradecanol) in egg phosphatidylcholine and dipalmitoylphosphatidylcholine multilamellar vesicles were studied with five fluorescent probes, 1-(4'-trimethylaminophenyl)-6-phenylhexa-1,3,5-triene (TMA-DPH), 1,6-diphenyl-1,3,5-hexatriene, and 2-, 7-, and 12-(9-anthroxyloxy)stearic acid (2-, 7-, and 12-AS). These probes localize at various depths in the membrane, enabling study of the membrane-order gradient. Phase-modulation fluorescence spectroscopy was used to measure steady-state anisotropies, excited-state lifetimes and differential polarized lifetimes from which the limiting hindered anisotropies (r infinity) and the logarithm of the rotational rate (log R) were calculated. The probes that localize at about the same depth in the membrane (TMA-DPH and 2-AS, diphenylhexatriene and 12-AS) generally, but not always, showed similar changes in r infinity and log R with added alkanols. However, the absolute values of r infinity and log R were usually different. The inconsistencies are attributed to differences in the probes' sizes, structures, photophysical properties and perturbing abilities. The perturbation of membranes by alkanols is chain-length-dependent. Pentanol disorders the membrane at all depths but is more effective in the membrane center than nearer to the polar headgroups of the phospholipids, tetradecanol can be accommodated into the membrane without effect or with increased order and the effects of decanol are intermediate between pentanol and tetradecanol. Our results with alkanols indicate that: a single perturber can have different effects on membrane order at different depths in the bilayer; the perturbation is observed at and distant from the perturbers' location in the membrane, and the bilayer center is more susceptible to perturbation by alkanols than the region of the bilayer near the phospholipid headgroups.

Regulation of glycolysis in rat aorta

Certain factors that might contribute to the regulation of the rate of glycolysis by rat aorta were investigated. Rat aortic rings were incubated with [14C]glucose, and the release of [14C]lactate was determined. There was good agreement between the lactate production estimated by enzymatic assay and by [14C]lactate release, suggesting that almost all the lactate produced under our experimental conditions was derived from exogenous glucose. When the glucose concentration in the medium was 10 mM or higher, the rate of glucose transport did not limit the rate of lactate production. In most cases studies were done both aerobically and anaerobically. In Hanks' Balanced Salt Solution the aerobic rate of lactate production was 18% of the anaerobic rate. We tested the effects on glycolysis of agents that alter ATP generation by mitochondria or ATP splitting by Na+-K+-ATPase or the mitochondrial ATPase. Under aerobic conditions, ouabain (5 mM) caused a 54% decrease in lactate production, and gramicidin (5 micrograms/ml) caused a 45% increase. Under anaerobic conditions, neither ouabain nor gramicidin affected lactate production. Aerobically dinitrophenol (25 microM) and carboxyatractyloside (0.5 mM) caused substantial increases in lactate production, 72 and 98% respectively. Under anaerobic conditions the effects of dinitrophenol and carboxyatractyloside were much smaller, with dinitrophenol causing a 15% increase and carboxyatractyloside a 12% decrease in lactate production. Increasing the concentration of phosphate in the incubation medium caused marked increases in lactate production. Both aerobically and anaerobically, shifting from 1.3 to 50 mM phosphate in the incubation medium caused a 3.5-fold increase in lactate production.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of cholesterol on acyl chain dynamics in multilamellar vesicles of various phosphatidylcholines

Phase modulation fluorescence spectroscopy was used to investigate the influence of cholesterol (0 to 50 mol%) on acyl chain dynamics in multilamellar vesicles of phosphatidylcholine. Four different phosphatidylcholines (DPPC, DOPC, POPC, and egg PC) and six different fluorescent probes (diphenylhexatriene and five anthroyloxy fatty acids) were employed. We found that: (1) Increased cholesterol content had only slight effects on fluorescence lifetimes of the six probes. (2) Increased cholesterol content increased the steady-state fluorescence anisotropy (r) of all the probes except 16-anthroyloxy palmitate (16-AP) in each of the four phosphatidylcholines. (3) Added cholesterol tended to limit the extent of probe rotation (as reflected by r infinity, the infinite-time anisotropy) to a much greater extent than it altered the rate of probe rotation. (4) The tendency for cholesterol to order the structure of the bilayer was greatest in the proximal half of the acyl chains and diminished toward the center of the bilayer. (5) In some phosphatidylcholines the rotations rates of probes located near the bilayer center (diphenylhexatriene and 16-AP) were apparently increased by increasing levels of cholesterol. (6) In several respects dipalmitoylphosphatidylcholine (DPPC) vesicles responded differently to increased cholesterol than vesicles of the other three phosphatidylcholines. (7) A single second-order equation described the relationship between r infinity and r for the five anthroyloxy fatty acid probes in the four different phosphatidylcholines over a wide range of cholesterol content. The data for diphenylhexatriene in the different phosphatidylcholines could not be fit by a single equation.

Effect of diffusion boundary layers on the initial uptake of O2 by red cells. Theory versus experiment

We have applied theories of mass transfer, in laminar and turbulent flow, to red cells in the stopped-flow apparatus in order to estimate the effect of extracellular diffusion boundary layers on the initial rate of O2 uptake. We compared the theoretical predictions with the results of our previous stopped-flow experiments with suspensions of red cells to which bovine serum albumin (BSA) had been added to decrease O2 solubility and diffusivity (Huxley and Kutchai, 1981). Models of red cells in laminar flow (Friedlander, 1957, 1961; Harriott, 1962) predict a significant retardation of the rate of O2 entry into red cells by diffusion boundary layers. Mixing in the stopped-flow apparatus occurs by convective and turbulent mechanisms in addition to simple molecular diffusion. The more complex theory of mass transfer to particles in turbulent flow (Levich, 1962) shows, because the red cells are highly entrained in the flow, that mixing is not complete on the time scale of initial O2 uptake. The O2 permeability of the diffusion boundary layer, predicted by both laminar and turbulent flow theories, approximates the experimentally obtained value. The theories of mass transfer to particles in laminar flow predict the dependence of the rate of O2 uptake on red cell size observed by other investigators. This suggests that these experimental results may be primarily due to the effect of diffusion boundary layers. Our studies are consistent with the interpretation that red cells in rapid mixing devices may be mixed incompletely with the suspending fluid; thus O2 transfer is limited by molecular diffusion in the immediate vicinity of the erythrocyte. We conclude that the rates of respiratory gas exchange by red cells in flowing systems may be partly limited by diffusion boundary layers.

Determination of fluorescence polarization of membrane probes in intact erythrocytes. Possible scattering artifacts

The anisotropy of the fluorescence of diphenylhexatriene has been reported to be less in the membranes of intact erythrocytes than in erythrocyte ghost membranes or in membranes prepared from erythrocyte lipids. Evidence is presented that this may be an artifact due to the intense light scattering by the intact erythrocytes.

The effect of the red cell membrane and a diffusion boundary layer on the rate of oxygen uptake by human erythrocytes

1. This paper deals with the contributions of the red cell membrane and an external diffusion boundary layer (;unstirred layer') to the resistance to O(2) entry into the red cell. Bovine serum albumin (BSA) was added to the extracellular fluid to enhance the effect of the diffusion boundary layer by diminishing both the solubility and the diffusivity of O(2). The rate of O(2) uptake by human red cells at various extracellular BSA concentrations was determined with a stopped-flow rapid-reaction apparatus.2. The initial rate of O(2) uptake by the red cells was directly proportional to the diffusion coefficient of O(2) in the extracellular fluid.3. If the diffusion boundary layer and the plasma membrane are considered as resistors in series, we estimate that 82-100% of the total resistance to O(2) entering the cell is due to the diffusion boundary layer. Our best estimate is that 95% of the resistance resides in the diffusion boundary layer.4. Our best estimate of the O(2) permeability of the red cell membrane is 3.15 x 10(-6) m-mole/(cm(2) sec mmHg). With this permeability the membrane would account for only 5% of the total resistance to O(2) entering the cell. Partly because the membrane O(2) diffusion resistance is a small fraction of the total resistance our estimate of the membrane resistance has a large standard deviation. Taking our estimate of the membrane resistance plus and minus its standard deviation we find that the membrane may account for 0-18% of the total resistance to O(2) entering the cell.5. The effective thickness of the diffusion boundary layer immediately after mixing is about 1.93 mum according to our analysis.

Monitoring volume changes in red cell ghosts by means of a trapped fluorescent probe

A method is described for monitoring changes in the volume of red cell ghosts by means of a fluorescent probe trapped inside them.. The fluorophore, 8-hydroxy-1,3,6-pyrenetrisulfonate, is partially quenched by the residual hemoglobin in the ghosts. When the ghosts swell, the hemoglobin concentration is reduced, the quenching is somewhat relieved and the fluorescence output increases. Opposite changes occur when the ghosts shrink. Fluorescence intensity is linearly related to ghost volume for both swelling and shrinking, but there is a larger change in fluorescence for shrinking from the isotonic volume than for an equivalent swelling. This method has been used to follow the swelling phase of dye-loaded ghosts suspended in a solution of a penetrating nonelectrolyte in isotonic saline.

Effects of anesthetic alcohols on membrane transport processes in human erythrocytes

1. Anesthetic alcohols (pentanol, hexanol and heptanol) were found to increase the fluidity of red cell membrane lipids as monitored by the fluorescence depolarization of diphenylhexatriene. The relative potency of the alcohols was found to be parallel to their relative membrane/water partition coefficients. 2. Hexanol had biphasic effect on erythritol uptake by simple diffusion by red cells. At concentrations less than 9 mM, there was an approximately linear increase in erythritol permeability with increasing alcohol concentration. 3. The facilitated transport of uridine was markedly inhibited by hexanol. Hexanol at 6 mM produced a 65% inhibition of uridine (4 mM) uptake. Hexanol decreased both the apparent Km and V values for the equilibrium exchange of uridine. 4. The facilitated transport of galactose was only slightly inhibited by hexanol. 5. Hexanol was without effect on the passive and active fluxes of Na+ and K+ in red cells with altered cation contents. Cells that were slightly depleted of K+ and cells that were highly K+ -depleted were both insensitive to hexanol.

Erythrocyte water permeability. The effects of anesthetic alcohols and alterations in the level of membrane cholesterol

1. Treatment of human erythrocytes with anesthetic n-alkanols (pentanol, hexanol and hepatanol) results in a decrease in the osmotic water permeability of the red cell membrane. 2. The alcohol-induced changes in osmotic water permeability are proportional to the alcohol concentration and roughly parallel diphenylhexatriene that are induced by the alcohols. 3. Enrichment of the red cell membrane in cholesterol also results in a decrease in the osmotic water permeability. 4. Moderate depletion (9% or 40%) of membrane cholesterol is without effect on the osmotic water permeability, even though this treatment results in a significant increase in the rotational mobility of diphenylhexatriene in the membrane lipids.

Effects of n-alkanols on the membrane fluidity of chick embryo heart microsomes

The n-alkanols from butanol through octanol are membrane perturbing agents that fluidize the microsomal membranes of 20-day-old chick embryo hearts as measured by the fluorescence depolarization of 1,6-diphenylhexatriene. In terms of the aqueous concentrations of n-alkanols the fluidizing effect increases with increasing number of carbons per n-alkanol. In terms of the membrane concentrations of n-alkanols the fluidizing effect is roughly equivalent for all the n-alkanols studied.

Mediated transport and metabolism of lactate in rat aorta

1. Under appropriate conditions L- and D-lactate enter the cells of rat aorta and are metabolized. Oxidation of lactate to CO2 occurs under aerobic conditions. 2. L- and D-lactate are taken up into the cells when oxygen, glucose, or both oxygen and glucose are present in the incubation medium. Both L- and D-lactate are excluded from the cells when neither oxygen nor glucose is present. 3. D,L-Glyceraldehyde prevents the uptake of L-lactate. The effect is apparently not due to the inhibition of glucose metabolism by L-glyceraldehyde. 4. L-lactate (20 mM) markedly inhibits the uptake of 5 mM D-lactate, but 20 mM D-lactate fails to inhibit the uptake of 5 mM L-lactate. 5. Raising the pH of the incubation medium markedly depresses the uptake of L-lactate. 6. The results provide evidence that L- and D-lactate enter the cells of rat aorta by a mediated transport system.

Developmental changes in plasma membrane fluidity in chick embryo heart

1. Decreases in the rate of transport of sugars (facilitated transport), amino acids (active transport), and urea (simple diffusion) occur in chick embryo heart during development. This work considers the possibility that changes in the plasma membrane fluidity during development contribute to the observed changes in transport activities. 2. Technics were developed for subcellar fractionation of chick embryos and adult chickens. 3. The depolarization of the fluorescence of 1,6-diphenylhexatriene was used to estimate the fluidity of the lipid portion of plasma membrane enriched fractions of hearts from chick embryos at various stages of development and from adult hearts. 4. There is a pattern of decreasing membrane viscosity as development proceeds. Between 5-6 days and 10 days of embryonic life a 20% decrease in viscosity of the plasma membrane-enriched fraction occurs. Between 10 and 20 days of embryonic life there is no significant change in viscosity. Between 20 days of development (1 day before hatching) and adulthood there is a further 55% decrease in plasma membrane viscosity. 5. It is proposed that the changes in membrane fluidity observed may contribute to developmental changes in membrane transport activities, but other factors must also be involved.

Uptake of sorbitol by chick embryo heart cells at various stages of development

Sorbitol enters chick embryo heart cells from five days of development on. The rate of sorbitol entry becomes slower as development proceeds and the data suggest this is principally due to an increase in the apparent Km of transport, the Vmax remaining relatively constant. The uptake of sorbitol displays saturation kinetics and is believed on this ground to be carrier-mediated. Sorbitol does not appear to be actively transported since it is not concentrated against a gradient and its uptake is not inhibited by iodoacetate or 2, 4-dinitrophenol. Sorbitol does not appear to be taken up via the glucose transport system since uptake is not stimulated by insulin or inhibited by glucose or phloretin.

Role of the red cell membrane in oxygen uptake

The rate at which red blood cells take up O2 or CO as measured in a rapid reaction apparatus is considerably less than predicted from solution of the equations for diffusion and chemical reaction in a layer of hemoglobin solution about the same thickness as the red cell. Nicolson and Roughton (1951) showed that this discrepancy could be accounted for by postulating that the red cell membrane is an important barrier to gas uptake. Sinha (1969) measured the rate of O2 uptake by single red cells located near a gas-plasma interface. The equations for diffusion and chemical reaction of O2 in a membraneless layer of hemoglobin solution for conditions that correspond to Sinha's experiments are solved. The calculated time course of O2 uptake fits the experimental data sufficiently well to suggest that the resistance of the red cell membrane to O2 diffusion is not an important limiting factor. Also analyzed in this way is the data of Carlson and Comroe (1958). The author finds that calculations predict a faster rate of CO uptake by biconcave disc shaped red cells than was observed experimentally, but that calculations for sphered red cells agree well enough with experimental data that membrane CO permeability may not be primary in limiting CO uptake by spherocytes.

Nonequilibrium facilitated oxygen transport in hemoglobin solution

We have used the quasi-linearization method to obtain numerical solutions to the equations which describe steady-state diffusion of oxygen through layers of hemoglobin solution. The numerical solutions show how the facilitated flux of oxygen depends upon the layer thickness, reaction-rate coefficients, and other parameters of the system. The results indicate that steady-state oxygen diffusion in layers of hemoglobin solution, similar to those studied by Scholander, should be adequately described by the models which assume chemical equilibrium exists throughout the layer, but for layers of concentrated hemoglobin solution about the thickness of a human erythrocyte, the facilitation of oxygen diffusion should be much less than the equilibrium models predict.

Steady-state, hemoglobin-facilitated O2 transport in human erythrocytes

We measured the rate of oxygen transport through thin (165 micro) films of packed erythrocytes (Hb concentration = 30 g/100 ml). Under optimal conditions steady-state O(2) diffusion was nearly three times that found when the hemoglobin was prevented from acting as a carrier molecule by carbon monoxide binding or high oxygen back pressure. After each experiment we measured hemolysis and found that it averaged less than 1%. Hemolysis could not account for the facilitation, thus proving that facilitated transport of O(2) by hemoglobin can occur in red blood cells. The rate of facilitated transport was identical for Hb solutions of equal concentration to the cells. We interpret this to mean that under the conditions of our experiments the red cell membrane offers no detectable diffusion resistance to O(2) and that the mobility of Hb in intact red cells is the same as in concentrated Hb solution.