Glucose transport in thymocyte plasma-membrane vesicles

Calf-thymocyte membrane vesicles, prepared by hypotonic lysis and homogenization, were isolated by standard centrifugal techniques designed for enrichment of plasma membrane. At 20°C, these vesicles equilibrated with d-glucose and 3-O-methyl-d-glucose more rapidly than with l-glucose. About 25% of the equilibrium d-sugar space (6 μl/mg protein) was very slowly penetrated by l-glucose ( ). The time course of d-sugar accumulation in excess of l-glucose accumulation indicated that this space equilibrated with d-glucose and 3-O-methyl-d-glucose with half-times of approximately 0.2–0.4 min. The remainder of the equilibrium d-sugar space (about 75%) appeared equally accessible to both glucose isomers ( to 5 min). This was confirmed in studies of efflux from preloaded vesicles, where the d-glucose space fell with a short half-time (0.2 min) to the l-glucose space, after which the two isomers exited with the same half-time. Addition of sucrose to increase osmolarity reduced both spaces (specific and non-specific) in a manner which indicated that little if any of the vesicle sugar was bound. This was confirmed by the fact that equilibrium glucose space was independent of glucose concentration and by the fact that vesicles immediately lost their sugar when diluted with water at 0°C. These data indicate the presence of two vesicle types, discriminant and indiscriminant as regards transport of the glucose isomers. Entry of d-glucose into the discriminant (stereospecific) vesicles was temperature sensitive (Q₁₀ > 2), saturable (K_m 2 mM), and was inhibited by phloretin (K_i < 200 μM), N-ethylmaleimide (K_i < 10 mM) and cytochalasin B (K_i < 2 μM), suggesting that these vesicles contain the plasma-membrane glucose carrier. Entry of l- and d-glucose into the indiscriminant vesicles showed none of these properties. The equilibrium-exchange K_m and V were about five times the entry K_m and V, indicating the substrate loading greatly facilitates carrier translocation, at least in the outward direction.     

Kinetics of glucose transport in human erythrocytes: zero-trans efflux and infinite-trans efflux at 0°C

The kinetic features of glucose transport in human erythrocytes have been the subject of many studies, but no model is consistent with both the kinetic observations and the characteristics of the purified transporter. In order to reevaluate some of the kinetic features, initial rate measurements were performed at 0°C. The following kinetic parameters were obtained for fresh blood: zero-trans efflux K_m = 3.4 mM, V_max = 5.5 mM/min; infinite-trans efflux K_m = 8.7 mM, V_max = 28 mM/min. For outdated blood, somewhat different parameters were obtained: zero-trans efflux K_m = 2.7 mM, V_max = 2.4 mM/min; infinite-trans efflux K_m = 19 mM, V_max = 23 mM/min. The K_m values for fresh blood differ from the previously reported values of 16 mM and 3.4 mM for zero-trans and infinite-trans efflux, respectively (Baker, G.F. and Naftalin, R.J. (1979) Biochim. Biophys. Acta 550, 474–484). The use of 50 mM galactose rather than 100 mM glucose as the infinite-trans sugar produced no change in the infinite-trans efflux K_m values but somewhat lower V_max values. Simulations indicate that initial rates were closely approximated by the experimental conditions. The observed time courses of efflux are inconsistent with a model involving rate-limiting dissociation of glucose from hemoglobin (Naftalin, R.J., Smith, P.M. and Roselaar, S.E. (1985) Biochim. Biophys. Acta 820, 235–249). The results presented here support the adequacy of the carrier model to account for the kinetics.     

Spatial requirements for insulin-sensitive sugar transport in rat adipocytes

(1) Alkyl sugar inhibition of d-allose uptake into adipocytes has been used to explore the spatial requirements of the external sugar transport site in insulin-treated cells. α-methyl and β-methyl glucosides show low affinity indicating very little space around C-1. The high affinity of d-glucosamine (K_i = 9.05 ± 0.66 mM) is lost by N-acetylation. $\text{N-}\text{Acetyl-}\text{d}\text{-glucosamine}$ shows no detectable affinity, indicating that a bulky group at C-2 is not accepted. Similarly $\text{2,3-}\text{di}\text{-O-}\text{methyl-}\text{d}\text{-glucose}$ (K_i = 42.1 ± 7.5 mM) has lower affinity than $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ (K_i = 5.14 ± 0.32 mM) indicating very little space around C-2 but much more around C-3. A reduction in affinity does occur if a propyl group is introduced into the C-3 position. The K_i for $\text{3-O-}\text{propyl-}\text{d}\text{-glucose}$ is 11.26 ± 2.12 mM. $\text{6-O-}\text{Methyl-}\text{d}\text{-galactose}$ (K_i = 87.2 ± 17.9 mM) and $\text{6-O-}\text{propyl-}\text{d}\text{-glucose}$ (K_i = 78.07 ± 12.6 mM) show low affinity compared with d-galactose and d-glucose, indicating steric constraints around C-6. High affinity is restored in $\text{6-O-}\text{pentyl-}\text{d}\text{-galactose}$ (K_i = 4.66 ± 0.23 mM) possibly indicating a hydrophobic binding site around C-6). (2) In insulin treated cells $\text{4,6-O-}\text{ethylidene-}\text{d}\text{-glucose}$ (K_i = 6.11 ± 0.5 mM) and maltose (K_i = 23.5 ± 2.1 mM) are well accommodated by the site but trehalose shows no detectable inhibition. These results indicate that the site requires a specific orientation of the sugar as it approaches the transporter from the external solution. C-1 faces the inside while C-4 faces the external solution. (3) To determine the spatial and hydrogen bonding requirements for basal cells 40 μM $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ was used as the substrate. Poor hydrogen bonding analogues and analogues with sterically hindering alkyl groups showed similar K_i values to those determined for insulin-treated cells. These results indicate that insulin does not change the specificity of the adipocyte transport system.     

Sugar transport in Coprinus cinereus

Two transport systems for glucose were detected: a high affinity system with a K_m of 27 μM, and a low affinity system with a K_m of 3.3 mM. The high affinity system transported glucose, 2-deoxy-d-glucose (K_m = 26 μM), 3-O-methylglucose (K_m = 19 μM), d-glucosamine (K_m = 652 μM), d-fructose (K_m = 2.3 mM) and l-sorbose (K_m = 2.2 mM). All sugars were accumulated against concentration gradients. The high affinity system was strongly or completely inhibited by N-ethylmaleimide, quercetin, 2,4-dinitrophenol and sodium azide. The system had a distinct pH optimum (7.4) and optimum temperature (45°C). The low affinity system transported glucose, 2-deoxy-d-glucose (K_m = 7.5 mM), and 3-O-methylglucose (K_m = 1.5 mM). Accumulation again occurred against a concentration gradient. The low affinity system was inhibited by N-ethylmaleimide, quercetin and 2,4-dinitrophenol, but not by sodium azide. The rate of uptake by the low affinity system was constant over a wide temperature range (30–50°C) and was not much affected by pH; but as the pH of the medium was altered from 4.5 to 8.9 a co-ordinated increase in affinity for 2-deoxy-d-glucose (from 52.1 mM to 0.3 mM) and decrease in maximum velocity (by a factor of five) occurred. Both uptake systems were present in sporelings germinated in media containing sodium acetate as sole carbon source. Only the low affinity system could initially be demonstrated in glucose-grown tissue, although the high affinity system was restored by starvation in glucose-free medium. The half-time for restoration of high affinity activity was 3.5 min and the process was unaffected by cycloheximide. Addition of glucose to an acetate-grown culture inactivated the high affinity system with a half-life of 5–7.5 s. Addition of cycloheximide to an acetate-grown culture caused decay of the high affinity system with a half-life of 80 min. Regulation is thus thought to depend on modulation of protein activity rather than synthesis, and the kinetics of glucose, 2-deoxy-d-glucose and 3-O-methylglucose uptake would be consistent with there being a single carrier showing negative co-operativity.     

Allosteric Regulation of Potassium Uptake in Plant Roots

In uptake experiments from nutrient solutions containing 2.0 mM K⁺ labelled with ⁸⁶Rb⁺, the relationship between potassium uptake efficiency and internal potassium concentration of the roots, [K⁺]_i was found to be partly sigmoidal for intact plants of spring wheat (Triticum aestivum L.), glasshouse cucumber (Cucumis sativus L.), birch (Betula verrucosa Ehrh.), lingonberry (Vaccinium vitis-idaea L.), Scots pine (Pinus silvestris L.) and Norway spruce (Picea abies (L.) Karst.), The results were interpreted in terms of sigmoidal enzyme kinetics for allosteric regulation. Hill plots of the data gave straight lines at specific [K⁺]_i intervals for the species. The slopes of the lines are the Hill coefficient, which could be regarded as a measure of the minimal number of allosteric sites. The Hill coefficient varied between - 14.4 and - 15.9. When divided by four, these values are fairly consistent with those in the literature. It is suggested that four active uptake sites interact with four groups of allosteric sites, each group containing four such sites, or that one active uptake site interacts with all the allosteric sites. Thus the results are evidence that the mechanism regulating K⁺ uptake is basically similar for the investigated plants. It is the interval of [K⁺]_i mediating highly negatively cooperative allosteric regulation that differs among species. For some of the species, n decreased from about 15 and approached unity at high [K⁺]_i values. This may indicate that only few sites are still available, making cooperativity unimportant. Alternatively high vacuolar [K⁺]_i concentrations may give rise to an incorrect evaluation of data from Hill plots, since the cytoplasmic K⁺ content likely regulates the allosteric mechanism. Moreover, it is suggested that gene-controlled carrier synthesis is responsible for the varying maximum K⁺ uptake efficiency among species.     

Opposite effects of d-fructose on total versus cytosolic ATP/ADP ratio in pancreatic islet cells

d-fructose (10 mM) augments, in rat pancreatic islets, insulin release evoked by 10 mM d-glucose. Even in the absence of d-glucose, d-fructose (100 mM) displays a positive insulinotropic action. It was now examined whether the insulinotropic action of d-fructose could be attributed to an increase in the ATP content of islet cells. After 30-60 min incubation in the presence of d-glucose and/or d-fructose, the ATP and ADP content was measured by bioluminescence in either rat isolated pancreatic islets (total ATP and ADP) or the supernatant of dispersed rat pancreatic islet cells exposed for 30 s to digitonine (cytosolic ATP and ADP). d-fructose (10 and 100 mM) was found to cause a concentration-related decrease in the total ATP and ADP content and ATP/ADP ratio below the basal values found in islets deprived of exogenous nutrient. Moreover, in the presence of 10 mM d-glucose, which augmented both the total ATP content and ATP/ADP ratio above basal value, d-fructose (10 mM) also lowered these two parameters. The cytosolic ATP/ADP ratio, however, was increased in the presence of d-glucose and/or d-fructose. Under the present experimental conditions, a sigmoidal relationship was found between such a cytosolic ATP/ADP ratio and either ⁸⁶Rb net uptake by dispersed islet cells or insulin release from isolated islets. These data provide, to our knowledge, the first example of a dramatic dissociation between changes in total ATP content or ATP/ADP ratio and insulin release in pancreatic islets exposed to a nutrient secretagogue. Nevertheless, the cationic and insulinotropic actions of d-glucose and/or d-fructose were tightly related to the cytosolic ATP/ADP ratio.     

The biguanide inhibition of d-glucose transport in membrane vesicles from small intestinal brush borders

Biguanides inhibit d-glucose uptake in vesicles from small-intestinal brush border membranes. Evidence is presented that this inhibition is due to a reduced concentration of Na⁺ in the microenvironment of the carrier(s) for d-glucose. Biguanides do not inhibit the uptake of either d-fructose or l-glucose.     

Characterization and solubilization of the cytochalasin B binding component from human placental microsomes

Human placental microsomes exhibit uptake of d-[³H]glucose which is sensitive to inhibition by cytochalasin B (apparent K_i = 0.78 /gm M). Characterization of [³H]cytochalasin B binding to these membranes reveals a glucose-sensitive site, inhibited by d-glucose with an ED₅₀ = 40 mM. The glucose-sensitive cytochalasin B binding site is found to have a K_d = 0.15μM by analysis according to Scatchard. Solubilization with octylglucoside extracts 60–70% of the glucose-sensitive binding component. Equilibrium dialysis binding of [³H]cytochalasin B to the soluble protein displays a pattern of inhibition by d-glucose similar to that observed for intact membranes, and the measurement of an ED₅₀ = 37.5 mM d-glucose confirms the presence of the cytochalasin B binding component, putatively assigned as the glucose transporter. Further evidence is attained by photoaffinity labelling; ultraviolet-sensitive [³H]cytochalasin B incorporation into soluble protein (M_r range 42 000-68 000) is prevented by the presence of d-glucose. An identical photolabelling pattern is observed for incorporation of [³H]cytochalasin B into intact membrane protein, confirming the usefulness of this approach as a means of identifying the presence of the glucose transport protein under several conditions.     

Active chloride transport in rabbit thick ascending limb of Henle's loop and elasmobranch rectal gland: chloride fluxes in isolated plasma membranes

Summary To investigate directly whether a sodium-potassium-chloride cotransport system is operating in the mammalian thick ascending limb of Henle's loop (TALH) and in the elasmobranch rectal gland, plasma membrane vesicles were prepared from TALH cells isolated from rabbit kidney outer medulla and from rectal glands ofSqualus acanthias, and chloride uptake was measured by a rapid filtration technique. Chloride uptake into TALH vesicles in the presence of a 25 mM Na₂SO₄, 25 mM K₂SO₄ gradient reached 70% of equilibrium at 2.5 min. In the presence of both sodium and potassium, the 15 s chloride uptake was inhibited 35% by 1 mM bumetanide. When either sodium or potassium was removed from the incubation medium, chloride uptake decreased to the level observed in the presence of 1 mM bumetanide. 0.5 mM SITS had no effect on chloride uptake by the plasma membrane vesicles. This sodium and potassium dependent, bumetanide sensitive chloride uptake was also observed under tracer exchange conditions. Chloride uptake into rectal gland plasma membrane vesicles in the presence of a 50 mM Na₂SO₄, 50 mM K₂SO₄ gradient reached 80% of equilibrium at 2.5 min. 1 mM bumetanide inhibited the 15 s uptake of chloride by 34% and removal of either sodium or potassium from the incubation medium reduced chloride uptake to the level observed in the presence of bumetanide under both gradient and tracer exchange conditions. These studies provide additional support for the hypothesis that a sodium-potassium-chloride cotransport system is operating in these epithelia.Abbreviations SITS 4-acetamido-4-isothiocyanato-stilbene-2,2-disulfonic acid - TALH thick ascending limb of Henle's loop     

Evidence for non-uniform distribution of d-glucose within human red cells during net exit and counterflow

The kinetic parameters of net exit of d-glucose from human red blood cells have been measured after the cells were loaded to 18 mM, 75 mM and 120 mM at 2°C and 75 mM and 120 mM at 20°C. Reducing the temperature, or raising the loading concentration raises the apparent K_m for net exit. Deoxygenation also reduces the K_m for d-glucose exit from red blood cells loaded initially to 120 mM at 20°C from 32.9 ± 2.3 mM (13) with oxygenated blood to 20.5 ± 1.3 mM (17) (P<0.01). Deoxygenation increases the ratio V_max/K_m from 5.29 ± 0.26 min⁻¹ (13) for oxygenated blood to 7.13 ± 0.29 min⁻¹ (17) for deoxygenated blood (P < 0.001). The counterflow of d-glucose from solutions containing 1 mM ¹⁴C-labelled d-glucose was measured at 2°C and 20°C. Reduction in temperature, reduced the maximal level to which labelled d-glucose was accumulated and altered the course of equilibration of the specific activity of intracellular d-glucose from a single exponential to a more complex form. Raising the internal concentration from 18 mM to 90 mM at 2°C also alters the course of equilibration of labelled d-glucose within the cell to a complex form. The apparent asymmetry of the transport system may be estimated from the intracellular concentrations of labelled and unlabelled sugar at the turning point of the counterflow transient. The estimates of asymmetry obtained from this approach indicate that there is no significant asymmetry at 20°C and at 2°C asymmetry is between 3 and 6. This is at least 20-fold less than predicted from the kinetic parameter asymmetries for net exit and entry. None of the above results fit a kinetic scheme in which the asymmetry of the transport system is controlled by intrinsic differences in the kinetic parameters at the inner and outer membrane surface. These results are consistent with a model for sugar transport in which movement between sugar within bound and free intracellular compartments can become the rate-limiting step in controlling net movement into, or out of the cell.     

Monosaccharide transport systems in the yeast Rhodotorula glutinis

By using d-glucose, d-xylose, d-galactose and d-fructose in the strictly aerobic yeast Rhodotorula glutinis and by comparing the half-saturation constants with inhibition constants the yeast was shown to possess a single common system for d-xylose and d-galactose (K _m's and K _i's all between 0.5 and 1.1 mM) but another distinct transport system for d-fructose. The transport of d-glucose has a special position in that glucose blocks apparently allotopically all the other systems observed although it uses at least one of them for its own transport. The different character of d-glucose uptake is underlined by its relative independence of pH (its K _m is completely pH-insensitive) in contrast with all other sugars. At low concentrations, all sugars show mutual positive cooperativity in uptake, suggesting at least two transport sites plus possibly a modifier site on the carrier.     

Some kinetic properties of the β-d-glucosidase (cellobiase) in a commercial cellulase product from Penicillium funiculosum and its relevance in the hydrolysis of cellulose

Some kinetic parameters of the β-d-glucosidase (cellobiase, β-d-glucoside glucohydrolase, EC 3.2.1.21) component of Sturge Enzymes CP cellulase [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] from Penicillium funiculosum have been determined. The Michaelis constants (K_m) for 4-nitrophenyl β-d-glucopyranoside (4NPG) and cellobiose are 0.4 and 2.1 mM, respectively, at pH 4.0 and 50°C. d-Glucose is shown to be a competitive inhibitor with inhibitor constants (K_i) of 1.7 mM when 4NPG is the substrate and 1 mM when cellobiose is the substrate. Cellobiose, at high concentrations, exhibits a substrate inhibition effect on the enzyme. d-Glucono-1,5-lactone is shown to be a potent inhibitor (K_i = 8 μM; 4NPG as substrate) while d-fructose exhibits little inhibition. Cellulose hydrolysis progress curves using Avicel or Solka Floc as substrates and a range of commercial cellulase preparations show that CP cellulase gives the best performance, which can be attributed to the activity of the β-d-glucosidase in this preparation in maintaining the cellobiose at low concentrations during cellulose hydrolysis.     

Contrasting modes of action of d-glucose and 3-O-methyl-d-glucose as protectors of the rat pancreatic B-cell against alloxan

Both d-glucose and its nonmetabolized analog $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ are known to protect the pancreatic B-cell against the toxic action of alloxan, as if the protective action of hexoses were to involve a membrane-associated glucoreceptor site. In the present study, the protective actions of the two hexoses were found to differ from one another in several respects. Using the process of glucose-stimulated insulin release by rat pancreatic islets as an index of alloxan cytotoxicity, we observed that the protective action of d-glucose was suppressed by d-mannoheptulose and menadione, impaired by NH₄Cl, and little affected by aminooxyacetate. These findings and the fact that d-glucose failed to decrease [2-¹⁴C]alloxan uptake by the islets suggest that the protective action of d-glucose depends on an increase in the generation rate of reducing equivalents (NADH and NADPH). The latter view is supported by the observation that the protective action of a noncarbohydrate nutrient, 2-ketoisocaproate, was also abolished by menadione. Incidentally, the protective action of 2-ketoisocaproate was apparently a mitochondrial phenomenon, it not being suppressed by aminooxyacetate. In contrast to that of glucose, the protective action of $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ was unaffected by d-mannoheptulose, failed to be totally suppressed by menadione, and coincided with a decreased uptake of [2-¹⁴C]-alloxan by the islets. It is concluded that the protective action of d-glucose in linked to the metabolism of the sugar in islet cells, whereas that of $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ results from inhibition of alloxan uptake. This conclusion reinforces our opinion that the presence in the B-cell of an alleged stereospecific membrane glucoreceptor represents a mythical concept.     

Interactions between Na+-dependent uptake of d-glucose,phosphate and l-alanine in rat renal brush border membrane vesicles

d-Glucose decreases phosphate reabsorption in rat proximal tubule. It is also postulated that some amino acids interact with phosphate reabsorption. To investigate the mechanism of these interactions, phosphate, d-glucose and l-alanine transport kinetics were measured in brush border membrane vesicles isolated from superficial rat kidney cortex by the calcium precipitation technique. At pH 7.4, Na⁺-dependent phosphate transport was inhibited in the presence of either d-glucose (39 mM) or l-alanine (2.4 mM). In this model, with d-glucose or with l-alanine the $\text{V}$ value of the phosphate uptake was decreased, whereas the apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ for the phosphate uptake was not affected. However, some inhibition of phosphate transport was observed in the presence of l-glucose, d-alanine or d-glucose after phlorizin preincubation. A 30% Na⁺-dependent l-alanine (0.1 mM) transport inhibition was observed in the presence of 5 mM phosphate. d-Glucose (1 mM) was also inhibited by 20% when 5 mM phosphate was added to incubation medium. According to several authors, in our model, d-glucose decreased the l-alanine transport and vice versa. Moreover, when the membrane potential was abolished, a clear inhibition of d-glucose by l-alanine persisted. These multiple interactions could be explained by the accelerated dissipation of the Na⁺ gradient insofar as the rate of the Na⁺ uptake was increased with d-glucose, l-alanine or phosphate and since the absence of variations in membrane potential did not suppress these inhibitions.     

Pathways of D-fructose transport in Arthrobacter pyridinolis

Previous work indicated that Arthrobacter pyridinolis can transport d-fructose by either a phosphoenolpyruvate: d-fructose phosphotransferase system or by a respiration-coupled system. The respiration-coupled transport system for d-fructose, which is stimulated by the addition of l-malate, has been characterized in membrane vesicles from d-fructose-grown cells. Such vesicles carry out malate-dependent uptake of d-fructose but not of d-glucose or l-rhamnose, indicating that there is a sugar-specific component to the respiration-coupled transport system. A mutant which is deficient in the d-fructose-specific component was isolated. Vesicles from fructose-glutamate-grown cells of a phosphotransferase-negative strain (AP100) exhibited malate-dependent d-fructose uptake, while phosphoenolpyruvate-dependent uptake was reduced to a small fraction of that seen with vesicles from wild-type cells. Inhibitors of electron transport, carbonyl cyanide m-chlorophenyl hydrazone, 2,4-dinitrophenol and N-ethylmaleimide caused marked inhibition of malate-dependent d-fructose uptake while exerting little or no effect on phosphoenolpyru-vate-dependent transport of the sugar in vesicles from wild-type cells. Activity of a flavin adenine dinucleotide-linked l-malic dehydrogenase was detected in membrane vesicles as well as in whole cells.     

Role of connecting loop I in catalysis and allosteric regulation of human glucokinase

Glucokinase (GCK, hexokinase IV) is a monomeric enzyme with a single glucose binding site that displays steady‐state kinetic cooperativity, a functional characteristic that affords allosteric regulation of GCK activity. Structural evidence suggests that connecting loop I, comprised of residues 47–71, facilitates cooperativity by dictating the rate and scope of motions between the large and small domains of GCK. Here we investigate the impact of varying the length and amino acid sequence of connecting loop I upon GCK cooperativity. We find that sequential, single amino acid deletions from the C‐terminus of connecting loop I cause systematic decreases in cooperativity. Deleting up to two loop residues leaves the k_cat value unchanged; however, removing three or more residues reduces k_cat by 1000‐fold. In contrast, the glucose K_0.5 and K_D values are unaffected by shortening the connecting loop by up to six residues. Substituting alanine or glycine for proline‐66, which adopts a cis conformation in some GCK crystal structures, does not alter cooperativity, indicating that cis/trans isomerization of this loop residue does not govern slow conformational reorganizations linked to hysteresis. Replacing connecting loop I with the corresponding loop sequence from the catalytic domain of the noncooperative isozyme human hexokinase I (HK‐I) eliminates cooperativity without impacting the k_cat and glucose K_0.5 values. Our results indicate that catalytic turnover requires a minimal length of connecting loop I, whereas the loop has little impact upon the binding affinity of GCK for glucose. We propose a model in which the primary structure of connecting loop I affects cooperativity by influencing conformational dynamics, without altering the equilibrium distribution of GCK conformations.     

Analysis of teleost hemoglobin by Adair and Monod-Wyman-Changeux models

Summary The allosteric effects of the erythrocytic nucleoside triphosphates (NTP) and of proton concentrations were investigated by precise measurement of Hb–O₂ equilibria of tench hemoglobin (including extreme, high and low saturation ranges) and analysed in terms of the MWC two state model and the Adair four step oxygenation theory.At low concentrations (NTP/Hb ratio=1.0, and pH>7.3) ATP, GTP and protons decrease Hb–O₂ affinity by increasing the allosteric constantL and reducingK _T, the association constant¹ of the deoxy, tense state of the Hb, without significantly affecting that (K _R) of the oxy state, increasing the free energy of cooperativity (G). High concentrations of these effectors, however, also reduceK _R. The greater sensitivity of the half-saturation O₂ tension (P ₅₀) of the Hb to GTP than to ATP at the same concentration, correlates with greater effects of GTP on bothK _T andK _R. The pH and NTP dependence of the four Adair association constants and the calculated fractional populations of Hb molecules in different stages of oxygenation show that the autochthonous NTP effectors and protons stabilize the T structure and postpone the TR transition basic to cooperativity in fish Hb.The possible implications of the findings for aquatic respiration are discussed.Abbreviations ATP adenosine triphosphate - DPG 2,3-diphosphoglycerate (glycerate-2,3-bisphosphate) - GTP guanosine triphosphate - IHP inositol hexaphosphate - NTP nucleoside triphosphates In this paperK _T andK _R are defined as theassociation equilibrium constants instead of dissociation constants (as originally defined by Monod et al. 1965) to facilitate comparison with the Adair constants