Ligand binding properties of hemoglobin 3 of the trout, Salmo gairdneri. The occurrence of an acid Bohr effect in the absence of heme-heme interaction.

The four components of hemoglobin from the rainbow trout (Salmo gairdneri) have been isolated. The oxygen affinities of the first two components eluted from the DEAE-cellulose column have much smaller pH dependencies than the last two components. These components have very low O2 affinities at low pH. The effect of pH on the equilibrium and kinetics of ligand binding to the third fraction, the pH-dependent component present in greatest amounts, has been studied. Measurements of ligand binding equilibria demonstrate the presence of both an alkaline and an acid Bohr effect. In the region of the alkaline Bohr effect the value of n in the Hill equation is a function of ligand affinity. For CO binding n decreases as the pH is decreased until at pH 6, the minimum ligand affinity is reached. At this pH there is also a complete loss of cooperative ligand binding. Decreasing the pH further results in an increase of ligand affinity, but this acid Bohr effect is not associated with a reappearance of cooperativity. This suggests that Fraction 3 of S. gairdneri is frozen in the low affinity, deoxygenated conformation at low pH and that the quaternary structure does not change even when fully liganded. However, the properties of the low affinity conformation of this hemoglobin are pH-dependent.     

Ethylisocyanide equilibria of hemoglobins M Iwate, M Boston, M Hyde Park, M Saskatoon, and M Milwaukee-I in half-ferric and fully reduced states.

The ethylisocyanide equilibria of all the five known hemoglobins M, namely Hb M Iwate (alpha287 Tyrbeta2), Hb M Boston (alpha258 Tyrbeta2), Hb M Hyde Park (alpha2beta292 Tyr), Hb M Saskatoon (alpha2beta263 tyr), and Hb M Milwaukee-I (alpha2beta267 Glu), were studied both in the half-ferric and fully reduced heme states. In the half-ferric state, no heme-heme interaction was observed for Hb M Iwate, Hb M Boston, and Hb M Hyde Park, but Hb M Saskatoon and Hb M Milwaukee-I show small but definite heme-heme interaction with Hill's n of 1.3. The beta chain mutants, Hb M Hyde Park and Hb M Saskatoon, have almost normal affinity for ethylisocyanide and a normal Bohr effect, whereas the alpha chain mutants, Hb M Iwate and Hb M Boston, have abnormally low affinity and almost no Bohr effect. Hb M Milwaukee-I showed a large Bohr effect and low affinity. These results are consistent qualitatively with those on oxygen equilibria reported previously. In the fully reduced state, in which all four hemes were in the ferrous state and capable of binding ethylisocyanide distinct differences were found in the extent of heme-heme interaction. Namely, the n values for proximal histidine mutants, Hb M Iwate and Hb M Hyde Park, were 1.1 and 1.0, respectively, whereas the distal histidine mutants, Hb M Boston and Hb M Saskatoon, showed high n values of 2.4 and 1.6, respectively. Hb M Milwaukee-I also exhibited a high n value of 2.0 The ethylisocyanide affinity of the four histidine mutants was high compared with that of Hb A, while that for Hb M Milwaukee-I was almost normal. All five Hbs M had approximately normal magnitudes of Bohr effect. In the half-ferric state, the proximal and distal histidine mutants of the same chain showed similar affinity for ethylisocyanide and Bohr effect, rather different from those of the mutants of the opposite chain. These differences seem to be derived from the difference of abnormal bonding of ferric iron to tyrosine or glutamic acid. On the other hand, the reduction of iron, which abolished the abnormal bonding and made all of the chains capable of binding ligand, extinguished the differences of alpha and beta chains, and the effect of amino acid side chains close to iron on ligand binding properties became clear. Proximal histidine, which is considered to trigger the transition between the T and R states, seems to be essential to the heme-heme interaction.     

The oxygen transport system in three species of the boreal fish family Gadidae. Molecular phylogeny of hemoglobin

The Arctic and Antarctic marine faunas differ by age and isolation. Fishes of the two polar regions have undergone different regional histories that have driven the physiological diversities. Antarctic fish are highly stenothermal, in keeping with stable water temperatures, whereas Arctic fish, being exposed to seasonal temperature variations, exhibit higher physiological plasticity. This study reports the characterization of the oxygen transport system of three Arctic species of the family Gadidae, namely the Arctic cod Arctogadus glacialis, the polar cod Boreogadus saida, and the Atlantic cod Gadus morhua. Unlike Antarctic notothenioids, the blood displays high multiplicity, i.e. it has three hemoglobins, similar to many other acanthomorph teleosts. In the most abundant hemoglobin, oxygen binding is modulated by heterotropic effectors, with marked Bohr and Root effects. Remarkably, in two species (A. glacialis and B. saida), the Hill coefficient is very close to one in the whole pH range, indicating the apparent absence of cooperativity. The amino acid sequences have been used to gain insight into the evolution history of globins of polar fish. The results indicate that Arctic and Antarctic globins have different phylogenies and lead us to suggest that the selective pressure of environment stability allows the phylogenetic signal to be maintained in the Antarctic sequences, whereas environmental variability would tend to disrupt this signal in the Gadidae sequences.     

Oxygen binding and its allosteric control in hemoglobin of the primitive branchiopod crustacean Triops cancriformis

Branchiopod crustaceans are endowed with extracellular, high-molecular-mass hemoglobins (Hbs), the functional and allosteric properties of which have largely remained obscure. The Hb of the phylogenetically ancient Triops cancriformis (Notostraca) revealed moderate oxygen affinity, cooperativity and pH dependence (Bohr effect) coefficients: P(50) = 13.3 mmHg, n(50) = 2.3, and Phi = -0.18, at 20 degrees C and pH 7.44 in Tris buffer. The in vivo hemolymph pH was 7.52. Bivalent cations increased oxygen affinity, Mg(2+) exerting a greater effect than Ca(2+). Analysis of cooperative oxygen binding in terms of the nested Monod-Wyman-Changeux (MWC) model revealed an allosteric unit of four oxygen-binding sites and functional coupling of two to three allosteric units. The predicted 2 x 4 and 3 x 4 nested structures are in accord with stoichiometric models of the quarternary structure. The allosteric control mechanism of protons comprises a left shift of the upper asymptote of extended Hill plots which is ascribable to the displacement of the equilibrium between (at least) two high-affinity (relaxed) states, similar to that found in extracellular annelid and pulmonate molluscan Hbs. Remarkably, Mg(2+) ions increased oxygen affinity solely by displacing the equilibrium between the tense and relaxed conformations towards the relaxed states, which accords with the original MWC concept, but appears to be unique among Hbs. This effect is distinctly different from those of ionic effectors (bivalent cations, protons and organic phosphates) on annelid, pulmonate and vertebrate Hbs, which involve changes in the oxygen affinity of the tense and/or relaxed conformations.     

Co-binding studies on Hb M Iwate. Allostery of a T state haemoglobin.

The mutant haemoglobin Hb M Iwate alpha 2Mmet87His leads to Tyr beta 2, is characterized by a stable T structure and a low ligand affinity. Sigmoidal CO-binding isotherms of symmetrical shape with Hill coefficients of n = 1.4 at pH 6 to n = 1.9 at pH 10 and the differences in the mean affinity (PCO(1/2)) and the affinity of the first ligand-binding beta subunit (1/L1 greater than Pco(1/2)) are the evidence for the cooperativity. The comparison of the Bohr effects of the two valency hybrid states (alpha 2Mmet beta met beta deoxy alpha 2Mmet beta 2deoxy) in the absence of and in the presence of polyphosphates leads to an indirect proof of pH-dependent subunit-subunit interaction. Inositol hexaphosphate-binding suppresses cooperativity in the pH range 5.5-8 (n = 1). Above pH 8 hte cooperativity increases to a final value of n = 1.9 at pH greater than 10, which is identical to that of stripped Hb M Iwate. The CO binding to the first binding site exhibits a Bohr effect. Polyphosphate anions have no influence on the CO binding of the first binding site. The heterotropic effects are discussed as intrachain effects (Bohr effect of the first binding site) and interchain effects (Bohr effect of Pco(1/2); influence of polyphosphates).     

Influence of carbon monoxide on hemoglobin-oxygen binding.

The oxygen dissociation curve and Bohr effect were measured in normal whole blood as a function of carboxyhemoglobin concentration [HbCO]. pH was changed by varying CO2 concentration (CO2 Bohr effect) or by addition of isotonic NaOH or HCl at constant PCO2 (fixed acid Bohr effect). As [HbCO] varied through the range of 2, 25, 50, and 75%, P50 was 26.3, 18.0, 11.6, and 6.5 mmHg, respectively. CO2 Bohr effect was highest at low oxygen saturations. This effect did not change as [HbCO] was increased. However, as [HbCO] was increased from 2 to 75%, the fixed acid Bohr factor increased in magnitude from -0.20 to -0.80 at very low oxygen saturations. The effect of molecular CO2 binding (carbamino) on oxygen affinity was eliminated at high [HbCO]. These results are consistent with the initial binding of O2 or CO to the alpha-chain of hemoglobin. The results also suggest that heme-heme interaction is different for oxygen than for carbon monoxide.     

Hemoglobins of the tadpole of the bullfrog, Rana catesbeiana. Temperature dependence of oxygen binding and pH dependence of subunit dissociation.

The temperature dependence of the oxygen equilibrium of tadpole hemoglobin has been determined between 0 degrees and 32 degrees for the unfractionated but phosphate-free lysate and between 12 degrees and 32 degrees for each of the four isolated components between pH 6 and 10 in 0.05 M cacodylate, Tris, or glycine buffers containing 0.1 M NaCl and 1 mM EDTA. Under these conditions the Bohr effect (defined as deltalog p50/deltapH) of the unfractionated lysate is positive at low temperatures between pH 6 and 8.5 and is negative above pH 8.5 to 8.8 at any temperature. As the temperature rises the Bohr effect below pH 8.5 changes greatly. In the interval pH 7.0 to 7.5, the magnitude of the Bohr effect decreases from + 0.28 at 0 degrees to zero at about 24 degrees and becomes negative, as in mammalian hemoglobins, above this temperature. Measurements with the isolated components show that the temperature dependence of oxygen binding for Components I and II and for Components III and IV is very similar. For both sets of components the apparent overall enthalpy of oxygenation at pH 7.5 is about -16.4 kcal/mol and -12.6 kcal/mol at pH 9.5. The measured enthalpies include contributions from the active Bohr groups, the buffer ions themselves, the hemoglobin groups contributing buffering, and any pH-dependent, oxygenation-dependent binding of ions such as chloride by the hemoglobin. The apportioning of the total enthalpy among these various processes remains to be determined. Between pH 8 and 10.5 tadpole oxyhemoglobin undergoes a pH-dependent dissociation from tetramer to dimer. The pH dependence of the apparent tetramer-dimer dissociation constant indicates that at pH 9.5 the dissociation of each tetramer is accompanied by the release of approximately 2 protons. In this pH range the oxygen equilibrium measurements indicate that about 0.5 proton is released for each oxygen molecule bound. The results are consistent with the conclusion that one acid group per alphabeta dimer changes its pK from about 10 to 8 or below upon dissociation of the tetramer.     

Steric factors moderate conformational fluidity and contribute to the high proton sensitivity of Root effect hemoglobins

The structural basis of the extreme pH dependence of oxygen binding to Root effect Hbs is a long-standing puzzle in the field of protein chemistry. A previously unappreciated role of steric factors in the Root effect was revealed by a comparison of pH effects on oxygenation and oxidation processes in human Hb relative to Spot (Leiostomus xanthurus) and Carp (Cyprinodon carpio) Hbs. The Root effect confers five-fold increased pH sensitivity to oxygenation of Spot and Carp Hbs relative to Hb A(0) in the absence of anionic effectors, and even larger relative elevations of pH sensitivity of oxygenation in the presence of 0.2M phosphate. Remarkably, the Root effect was not evident in the oxidation of the Root effect Hbs. This finding rules out pH-dependent alterations in the thermodynamic properties of the heme iron, measured in the anaerobic oxidation reaction, as the basis of the Root effect. The alternative explanation supported by these results is that the elevated pH sensitivity of oxygenation of Root effect Hbs is attributable to globin-dependent steric effects that alter oxygen affinity by constraining conformational fluidity, but which have little influence on electron exchange via the heme edge. This elegant mode of allosteric control can regulate oxygen affinity within a given quaternary state, in addition to modifying the T-R equilibrium. Evolution of Hb sequences that result in proton-linked steric barriers to heme oxygenation could provide a general mechanism to account for the appearance of the Root effect in the structurally diverse Hbs of many species.     

Effects of temperature on hardhead minnow (Mylopharodon conocephalus) blood-oxygen equilibria

Habitat perturbations, including dam construction with consequent temperature changes and the introduction of non-native species to California’s mid- to low-elevation streams, have negatively influenced some native fish populations’ historic distribution and abundance. Populations of hardhead, Mylopharodon conocephalus (Cyprinidae), have experienced such population declines, but environmental temperature effects on this large (to 60 cm SL), native species are poorly documented. We measured temperature effects on in vitro blood-oxygen affinity and equilibrium curve shape, key dynamics of the species’ oxygen-transport system, derived from blood collected from wild-caught hardhead. Over an 11–30 °C temperature range, the half-saturation value (P₅₀, an inverse measure of affinity) increased with the temperature from 0.51 to 1.80 kPa for low-PCO₂ (“arterial”) treatments and from 2.02 to 2.92 kPa for high-PCO₂ (“venous”) treatments. The apparent heat of oxygenation (temperature effect) was higher at temperatures > (absolute value) 19 °C. Therefore, hardhead’s blood has a decreased ability to bind oxygen at its gills at temperatures ≥25 °C, compared to that at temperatures ≤19 °C. The hardhead’s Bohr factors (Ф), non-bicarbonate buffer values (β), nucleoside triphosphate (NTP) concentrations, blood oxygen capacities (CBO₂), and mildly sigmoid-shaped oxygen equilibrium curves showed no relationship with temperature. Overall, their blood-oxygen equilibria suggest that hardhead can tolerate moderate hypoxia and temperature variations in its environment and that they have some capacity for sustained, high-aerobic activity.     

Modulators of haemocyanin oxygen affinity in the hypoxia- and sulphide-tolerant Baltic isopod Saduria entomon (L.)

Dialysed haemocyanin from the isopod Saduria entomon had a considerably increased oxygen affinity (lower P50) and Bohr factor (-1.71) compared to native haemocyanin (Bohr factor -1.36) indicating that dialysis removes a small molecule size modulating factor decreasing the affinity of native haemolymph. Dialysed haemocyanin had a slightly lower co-operativity (2.42 +/- 0.3) than native haemocyanin (2.9 +/- 0.2). L-Lactate (10 mmol l(-1)) improved oxygen affinity by 1-1.5 torr while urate had no effect. Mg2+ affected affinity in a pH-dependent manner (Bohr-factor increased to -1.67) while Ca2+ had no effect on the Bohr factor but increased affinity with ca 1 torr. Thiosulphate changed the Bohr factor to -1.75 to -1.82, similar to dialysed blood. Co-operativity was in neither case affected. The haemocyanin characteristics of S. entomon are similar to those of crustaceans from hydrothermal vents. These characteristics are probably general for crustaceans that are more or less permanently exposed to sulphide.     

Ontogenetic changes in the critical swimming speed of Gadus morhua (Atlantic cod) and Myoxocephalus scorpius (shorthorn sculpin) larvae and the role of temperature

Most studies on behavioural contributions to dispersal and recruitment during early life history stages of fishes have focused on coral reef species. For cold ocean environments, high variation in seasonal temperature and development times suggest that parallel studies on active behaviour are needed for cold-water species. Thus, we examined the critical swimming speed (U_crit) of marine fish larvae from 2 contrasting species: Gadus morhua (Atlantic cod) and Myoxocephalus scorpius (shorthorn sculpin), a pelagic and bottom spawner respectively. Within-species comparisons showed that sculpin reared at 6 °C had lower initial U_crit values, but a faster U_crit increase through development compared with 3 °C conspecifics, ultimately resulting in faster critical swimming speeds at metamorphosis (10.5 vs. 9.1 cm·s^− 1). In contrast, although cod larvae reared at 10 °C were faster swimmers at first feeding than 6 °C fish, temperature differences were absent after the first week. These results show that temperature influences the trajectory of larval critical swimming speed development, but that the relationship is species-specific. Although 6 °C sculpin and cod of similar length had equivalent U_crit values, the smaller size of cod at hatch (5.3 vs. 10.8 mm for sculpin) resulted in much lower age-specific U_crit values for cod. These data have significant implications for how swimming activity of the two species might affect dispersal, particularly in the first few weeks post-hatch. Overall, our data suggest that temperature during larval development influences the swimming capacity of cold-water marine fishes, and has important ramifications for biophysical models of dispersal.     

The Root effect

Considering the presently available data it is clear that the Root effect represents an exaggerated alkaline Bohr effect which occurs in the absence of a normal acid Bohr effect and is associated with a loss of oxygen binding capacity at low pH. Undoubtedly at the molecular level the presence of a Ser residue at position F9(94) beta in these haemoglobin is of primary importance. No Root effect haemoglobin has yet been identified which lacks this substitution. On the other hand however many haemoglobins are known which possess this Ser residue and at the same time lack a Root effect. Other factors arising from interactions at other sites in the haemoglobin molecule are obviously sufficient to negate the otherwise stabilizing effect of this critical Ser residue. The loss of cooperativity of Root effect systems as the pH is lowered is readily explained as due to stabilization of the low affinity T state to such a degree that the switch to the high affinity R state is suppressed even in the fully liganded molecule. The observation of Hill coefficients of less than unity requires that within the T state chain heterogeneity exists such that the alpha and beta chain haems demonstrate significantly different affinities for ligand. The physiological role of Root effect haemoglobins is demonstrably not inevitably linked to the swim bladder but more probably arose from the need to oxygenate the poorly vascularized retina of many fishes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular basis of the Bohr effect in arthropod hemocyanin

Flash photolysis and K-edge x-ray absorption spectroscopy (XAS) were used to investigate the functional and structural effects of pH on the oxygen affinity of three homologous arthropod hemocyanins (Hcs). Flash photolysis measurements showed that the well-characterized pH dependence of oxygen affinity (Bohr effect) is attributable to changes in the oxygen binding rate constant, k(on), rather than changes in k(off). In parallel, coordination geometry of copper in Hc was evaluated as a function of pH by XAS. It was found that the geometry of copper in the oxygenated protein is unchanged at all pH values investigated, while significant changes were observed for the deoxygenated protein as a function of pH. The interpretation of these changes was based on previously described correlations between spectral lineshape and coordination geometry obtained for model compounds of known structure (Blackburn, N. J., Strange, R. W., Reedijk, J., Volbeda, A., Farooq, A., Karlin, K. D., and Zubieta, J. (1989) Inorg. Chem., 28, 1349-1357). A pH-dependent change in the geometry of cuprous copper in the active site of deoxyHc, from pseudotetrahedral toward trigonal was assigned from the observed intensity dependence of the 1s --> 4p(z) transition in x-ray absorption near edge structure (XANES) spectra. The structural alteration correlated well with increase in oxygen affinity at alkaline pH determined in flash photolysis experiments. These results suggest that the oxygen binding rate in deoxyHc depends on the coordination geometry of Cu(I) and suggest a structural origin for the Bohr effect in arthropod Hcs.     

The reversible binding of oxygen to sulfhemoglobin.

The O2 binding properties of sulfhemoglobin were studied. The oxygen tension required for half-saturation of sulfhemoglobin is more than 2 orders of magnitude higher than that for hemoglobin A. The binding of O2 exhibits an alkaline Bohr effect larger than that observed for hemoglobin, yet the Hill number is unity. From the Bohr titration curve, 0.68 proton is released during O2 binding at 0 degrees C. Sulfhemoglobin prepared from carboxypeptidase A-treated hemoglobin has an affinity for O2 which is about the same as that of sulfhemoglobin at the theoretical limit of the Bohr titration curve. Like its carboxypeptidase A-treated hemoglobin precursor, this sulfhemoglobin does not bind O2 cooperatively. Thus, sulfhemoglobin appears to be in a high affinity form at alkaline pH and a low affinity form at acid pH, similar to hemoglobin A. These results demonstrate that the magnitude of the Hill number is not always an indicator of the interaction between oxygen binding and other functions in a hemoglobin.     

The Bohr effect of the blood in rainbow trout (Salmo gairdnerii). A comparative study with human blood, using precise oxygen equilibrium curves and the Adair model

1. The Bohr effects of trout blood (which exhibits the Root effect) and of human blood were compared. Precise oxygen equilibria were measured with an automatic recording system, on normal trout red blood cell suspensions at pH 7.6 - 8.6, at 10 and 20 degrees C, and on normal human red blood cell suspensions at pH 6.8 - 8.0, at 37 degrees C. 2. The data were fitted to the Adair's stepwise oxygenation model which describes experimental curves with four constants ki (i = 1-4). 3. Adair's scheme successfully fits the equilibrium data for trout and human blood, in the range of conditions examined. 4. The R-state Bohr effect (d log k4/ d pH), is very large in trout blood, indicating a large pH dependence of the R structure, as opposed to human blood. 5. The T-state Bohr effect (d log k1/ d pH), and the overall Bohr effect (d log Pm/ d pH), are equivalent in trout and human blood. 6. The overall Bohr effect is essentially accounted for by the first and fourth oxygenation steps in trout blood and shows a significant effect of temperature. 7. The data attribute a major role to Hb4 in trout blood isotherms and confirm the importance of the C-termini of Beta chains in Bohr and Root effects.     

Allosteric regulation and temperature dependence of oxygen binding in human neuroglobin and cytoglobin. Molecular mechanisms and physiological significance

Two new globin proteins have recently been discovered in vertebrates, neuroglobin in neurons and cytoglobin in all tissues, both showing heme hexacoordination by the distal His(E7) in the absence of gaseous ligands. In analogy to hemoglobin and myoglobin, neuroglobin and cytoglobin are supposedly involved in O2 storage and delivery, although their physiological role remains to be solved. Here we report O2 equilibria of recombinant human neuroglobin (NGB) and cytoglobin (CYGB) measured under close to physiological conditions and at varying temperature and pH ranges. NGB shows both alkaline and acid Bohr effects (pH-dependent O2 affinity) and temperature-dependent enthalpy of oxygenation. O2 and CO binding equilibrium studies on neuroglobin mutants strongly suggest that the bound O2 is stabilized by interactions with His(E7) and that this residue functions as a major Bohr group in the presence of Lys(E10). As shown by the titration of free thiols with 4,4'-dithiodipyridine and by mass spectrometry, this mechanism of modulating O2 affinity is independent of formation of an internal disulfide bond under the experimental conditions used, which stabilize thiols in the reduced form. In CYGB, O2 binding is cooperative, consistent with its proposed dimeric structure. Similar to myoglobin but in contrast to NGB, O2 binding to CYGB is pH-independent and exothermic throughout the temperature range investigated. Our data support the hypothesis that CYGB may be involved in O2-requiring metabolic processes. In contrast, the lower O2 affinity in NGB does not appear compatible with a physiological role involving mitochondrial O2 supply at the low O2 tensions found within neurons.     

Thermal sensitivity of metabolic rates and swimming performance in two latitudinally separated populations of cod, <Emphasis Type="Italic">Gadus morhua</Emphasis> L.

Atlantic cod populations live in a wide thermal range and can differ genetically and physiologically. Thermal sensitivity of metabolic capacity and swimming performance may vary along a latitudinal gradient, to facilitate performance in distinct thermal environments. To evaluate this hypothesis, we compared the thermal sensitivity of performance in two cod stocks from the Northwest Atlantic that differ in their thermal experience: Gulf of St Lawrence (GSL) and Bay of Fundy (BF). We first compared the metabolic, physiological and swimming performance after short-term thermal change to that at the acclimation temperature (7°C) for one stock (GSL), before comparing the performance of the two stocks after short-term thermal change. For cod from GSL, standard metabolism (SMR) increased with temperature, while active metabolism (AMR, measured in the critical swimming tests), EMR (metabolic rate after an exhaustive chase protocol), aerobic scope (AS) and critical swimming speeds (U _crit and U _b–c) were lower at 3°C than 7 or 11°C. In contrast, anaerobic swimming (sprint and burst-coasts in U _crit test) was lower at 11 than 7 or 3°C. Factorial AS (AMR SMR⁻¹) decreased as temperature rose. Time to exhaustion (chase protocol) was not influenced by temperature. The two stocks differed little in the thermal sensitivities of metabolism or swimming. GSL cod had a higher SMR than BF cod despite similar AMR and AS. This led factorial AS to be significantly higher for the southern stock. Despite these metabolic differences, cod from the two stocks did not differ in their U _crit speeds. BF cod were better sprinters at both temperatures. Cod from GSL had a lower aerobic cost of swimming at intermediate speeds than those from BF, particularly at low temperature. Only the activity of cytochrome C oxidase (CCO) in white muscle differed between stocks. No enzymatic correlates were found for swimming capacities, but oxygen consumption was best correlated with CCO activity in the ventricle for both stocks. Overall, the stocks differed in their cost of maintenance, cost of transport and sprint capacity, while maintaining comparable thermal sensitivities.     

Carbon monoxide binding to Rhodospirillum molischianum ferrocytochrome c'

Reversible carbon monoxide binding has been used to examine the structural and functional properties of reduced Rhodospirillum molischianum cytochrome c'. The symmetrical dimer is found to bind CO in a noncooperative manner, indicating that the heme sites function independently and with identical carbon monoxide affinity. The enthalpy change of binding CO (aqueous) to R. molischianum ferrocytochrome c' is determined to be -11 kcal/mol of CO, which is comparable to the heat of CO binding to other heme proteins. A Bohr effect is observed (0.31 +/- 0.04 proton released per mole of CO bound at pH 8), and a basic group is involved which changes its pK from 8.3 to 7.8 upon ligation. The histidine axial ligand to the heme iron is suggested to be the source of the Bohr effect. Increased CO affinities were observed at high pH or at neutral pH in the presence of phosphate. These solvent-induced changes in CO affinity do not appear to be caused by changes in quaternary structure but rather are more likely brought about by localized changes in the vicinity of the solvent-exposed heme face.     

The hemoglobin system of the brown moray Gymnothorax unicolor: structure/function relationships.

The Gymnothorax unicolor hemoglobin system is characterized by two components, called cathodic and anodic on the basis of their isoelectric point, which were separated by ion-exchange chromatography. The oxygen-binding properties of the purified components were studied in the absence and presence of chloride and/or GTP or ATP in the pH range 6.5-8.0. Stripped cathodic hemoglobin showed a small reverse Bohr effect, high oxygen affinity, and low co-operativity; the addition of chloride only caused a small decrease in oxygen affinity. In the presence of GTP or ATP, the oxygen affinity was dramatically reduced, the co-operativity increased, and the reverse Bohr effect abolished. Stripped anodic hemoglobin is characterized by both low oxygen affinity and co-operativity, and displayed a normal Bohr effect; the addition of chloride increased co-operativity, whereas ATP and GTP significantly modulated oxygen affinity at acidic pH values, enhancing the Bohr effect and giving rise to the Root effect. The complete amino-acid sequences of the alpha and beta chains of both hemoglobins were established; the molecular basis of the functional properties of the hemoglobins is discussed in the light of the primary structure and compared with those of other fish hemoglobins.     

The effect of macromolecular polyanions on the functional properties of human hemoglobin.

The binding of dextran sulphate and heparin to human hemoglobin and their effect on the properties of gas transport have been investigated. Both dextran sulphate and heparin are strongly bound by oxy-hemoglobin as well as deoxyhemoglobin and the stoichiometry of the binding (polyanion/tetrameric hemoglobin) is less than unity; sedimentation analysis gives indication for the existence of octomers. The oxygen affinity of hemoglobin is decreased, to the same extent, by both dextran sulphate and heparin. This effect is pH-dependent. In addition the polyanions affect the position and the magnitude of the Bohr effect. In the presence of dextran sulphate the recombination of hemoglobin with carbon monoxide after flash photolysis is biphasic and the fraction of quickly reacting material increases with dilution of the protein.