H+ titrations were conducted on the separated haemoglobin components of eel Anguilla anguilla in both the oxygenated and deoxygenated states. In anodic haemoglobin, the addition of GTP, and to a lesser extent Cl, increased the magnitude of the Haldane effect and shifted its maximum value into the in vivo pH range. Of the 22 histidine residues in the anodic component, only approximately seven were titratable, presumably the β-chain residues at positions 41, 97, 109 and 146 (helical positions C7, FG4, G11 and HC3, respectively).

In cathodic haemoglobin, a small negative Haldane effect was observed at pH values between 6.8 and 8.5 which disappeared in the presence of GTP (molar ratio 3:1 GTP:haemoglobin tetramer). GTP had virtually no effect on the buffer value at fixed oxygenation status, and the lowest buffer value was observed at in vivo pH values. No titratable histidine residues were observed in the cathodic component, indicating that all 14 histidines in this component are buried.

We conclude that the anodic component, which constitutes two-thirds of the haemoglobin in the eel, plays the predominant role in CO2 transport and pH homeostasis in vivo.

Haemoglobin heterogeneity within individuals is a common occurrence in the blood of teleost fishes. In 77 genera of teleost fish sampled in the Amazon, only 8 % of the species possessed a single haemoglobin component, and on average four electrophoretic components were observed per species (Fyhn et al. 1979). The functional implications of haemoglobin multiplicity in fish have been extensively studied. Apart from having anodic components with normal Bohr and Root effects, many teleosts have cathodic components, which have high O2 affinities, small, often reversed, Bohr effects and no Root effects; the cathodic components may therefore safeguard O2 uptake under hypoxic and acidotic conditions (Weber, 1990). In contrast, little is known about the role that different components play in hydrogen ion buffering and in the transport and excretion of CO2.

In general, there is an inverse relationship between the magnitude of the Haldane effect and the buffer value of the haemoglobins found in vertebrates. Teleost fishes such as eel, tench, carp and to a lesser extent rainbow trout are characterised by large Haldane effects and a low haemoglobin buffer value at fixed oxygenation status, the reverse being observed in elasmobranchs (Jensen, 1989). The two possible combinations permit equally viable but quite different strategies in terms of CO2 transport and excretion (Jensen, 1991).

The eel (Anguilla anguilla) possesses only two haemoglobin components, one anodic and one cathodic (Pelster and Weber, 1990). It is not known whether the inverse relationship between the magnitude of the Haldane effect and the haemoglobin buffer value observed in whole blood exists within individual haemoglobin components in species exhibiting haemoglobin heterogeneity. This was examined by conducting H+ titrations (which permit simultaneous assessments of the Haldane effect and buffer value) on isolated and purified haemoglobin components of eel. The molecular bases for the titration characteristics were interpreted in relation to the amino acid sequences that have recently been obtained for both haemoglobin components of eel (Fago et al. 1995, 1997). Specifically, the number of titratable histidine residues and their specific locations within the protein moeity were determined in both components.

As in other teleosts, red cell ATP and GTP (NTP) concentrations in eels decrease during exposure to hypoxia, increasing haemoglobin O2-affinity; GTP is the more potent cofactor (Weber et al. 1976). The presence of GTP at a molar GTP:haemoglobin tetramer (Hb4) ratio of 2:1, as found in vivo (Weber et al. 1976), dramatically increases the magnitude of the Haldane effect in the anodic haemoglobin component (Breepoel, 1981b). Titrations were also conducted in the presence of GTP at a GTP:Hb4 ratio of 3:1 (which represents saturating conditions; Breepoel et al. 1981b) to shed light on the relative roles of the individual components in CO2 transport and excretion in vivo.

Animal acquisition and care

European eels (Anguilla anguilla) were purchased from a local fish farm and maintained in the Zoophysiology Department at Aarhus University in running fresh water at 15 °C. Fish were fed twice a week to satiation and kept for 2 months prior to blood sampling. Blood was drawn from the caudal vein into heparinized syringes. Blood samples from several individuals were pooled and kept on ice.

Preparation of haemoglobin solutions

Red cells were washed three times with 5 vols of cold 0.9 % NaCl and lysed with 3 vols of ice-cold 0.05 mol l−1 Tris buffer (pH 7.6). Cell debris was removed by centrifugation at 14 000 revs min−1 for 10 min. All remaining procedures were conducted at 4 °C. The haemoglobin solution was repeatedly dialysed against 20 mmol l−1 Tris buffer (pH 8.04) over an 18 h period. Haemoglobin components were separated by ion-exchange chromatography on a Sephacel DEAE column (2 cm×20 cm) and eluted with a linearly increasing (0–0.3 mol l−1) NaCl gradient in 20 mmol l−1 Tris buffer (pH 8.04). The eluted fractions were collected in 1 ml samples for absorption measurements at 540 nm and for chloride concentration measurements using a Radiometer CMT1 chloride titrator. The elution yielded two main components, one positively charged (cathodic) and the other negatively charged (anodic). Haemoglobin fractions within each component were pooled as indicated in Fig. 1. Each component was dialysed against three changes of distilled water over the following 12 h and then passed repeatedly through a mixed-bed resin (Amberlite IRN-150L monobed mixed resin) to remove ions, checked by conductivity measurements. The concentrated stripped haemoglobin components were separated into 1 ml samples that were frozen at −80 °C until titrations were conducted.

Fig. 1.

Separation of the cathodic and anodic haemoglobin components of eel blood by anion-exchange chromatography. Circles, optical density measured at 540 nm; triangles, Cl concentration. The box at the base of each peak indicates the fractions pooled in each component.

Fig. 1.

Separation of the cathodic and anodic haemoglobin components of eel blood by anion-exchange chromatography. Circles, optical density measured at 540 nm; triangles, Cl concentration. The box at the base of each peak indicates the fractions pooled in each component.

Titrations

In each experiment, the concentrated stripped haemoglobin sample was thawed and diluted to a final concentration of 50 μmol l−1 Hb4. Haemoglobin concentration was measured after conversion to cyanomethaemoglobin using a millimolar extinction coefficient of 11 at 540 nm. The haemoglobin solution was then equilibrated with either pure oxygen or pure nitrogen (>99.9965 %) for 2 h in a titration vessel thermostatted at 15 °C. Titrations were conducted starting at the isoionic point of the haemoglobin solution by the automated addition of 10 μl of freshly prepared and carbonate-free 0.01 mol l−1NaOH (assayed with potassium hydrogen phthalate) or 0.01 mol l−1 HCl (assayed with NaOH) using a Radiometer Titralab automated titration system with data acquisition. The pH of the haemoglobin solution was measured using a Radiometer combined pH electrode (GK 2321C) connected to the Radiometer Titralab and recorded 5 min after the addition of titrant, by which time the pH had stabilised. Each complete titration curve for the anodic component consisted of four separate titrations; addition of HCl or NaOH from isoionic pH in samples equilibrated with O2 or N2. For the cathodic component, only HCl was added from the isoionic point in O2 and N2 because of its high isoionic pH.

Titrations were conducted in triplicate (yielding virtually identical results) for the anodic and cathodic components under four different conditions: concentrated stripped haemoglobin diluted with (i) distilled water (stripped); (ii) distilled water with GTP (guanosine 5′-triphosphate sodium salt) at a molar ratio of 3:1 relative to the tetrameric haemoglobin (GTP:Hb4); (iii) KCl to a final concentration of 0.1 mol l−1; and (iv) KCl to a final concentration of 0.1 mol l−1 KCl and GTP at a GTP:Hb4 molar ratio of 3:1. Titrations were also conducted on GTP solutions alone. The buffer value of the GTP/solvent solution was subtracted from that of the haemoglobin components as described in the text. Prior to the titrations, methaemoglobin levels were measured according to the method of Benesch et al. (1973), and samples were discarded if values greater than 5 % were measured.

The haemolysates resolved into two well-defined peaks during ion-exchange chromatography and consisted of approximately 32 % cathodic and 68 % anodic haemoglobin (Fig. 1).

Titration of the anodic component

The titration curves for the anodic haemoglobin component are shown in Fig. 2, in which ZH (the net charge of the protein) is plotted as a function of pH in the presence of 0.1 mol l−1 KCl in the absence (Fig. 2A) and in the presence (Fig. 2B) of GTP. The traces are drawn to the same scale with zero net proton charge as the reference point (Tanford, 1962). The fixed acid Haldane effect (ΔZH; the number of protons released per Hb4 oxygenated at constant pH) can be calculated from the distance between the oxygenated and deoxygenated curves at constant pH. ΔZH is illustrated in Fig. 3 for stripped haemoglobin and for haemoglobin in 0.1 mol l−1 KCl in the absence and presence of saturating levels of GTP (3:1 molar ratio of GTP:Hb4). The maximum fixed acid Haldane effect (referred to simply as the Haldane effect from this point onwards, unless otherwise indicated) increased from 2.1 at pH 6.3 in stripped haemoglobin to 2.9 at pH 6.9 in 0.1 mol l−1 KCl (see Fig. 3). The presence of GTP further elevated ΔZH to a maximum value of 4.6 at pH 7.3. The trace for the Haldane effect in the presence of GTP without KCl was not included in this figure because it was identical to that of GTP with KCl. At low and high pH values (pH<5.3 and pH>8.1 for stripped haemoglobin, pH<5.9 and pH>7.9 for haemoglobin + KCl, and pH<6.4 and pH>8.2 for haemoglobin + KCl + GTP), a small negative Haldane effect was observed.

Fig. 2.

Titration curves for ZH (net H+ charge) as a function of pH for the anodic eel haemoglobin in (A) 0.1 mol l−1 KCl and (B) 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1). Open symbols, oxygenated haemoglobin; filled symbols, deoxygenated haemoglobin; temperature, 15 °C.

Fig. 2.

Titration curves for ZH (net H+ charge) as a function of pH for the anodic eel haemoglobin in (A) 0.1 mol l−1 KCl and (B) 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1). Open symbols, oxygenated haemoglobin; filled symbols, deoxygenated haemoglobin; temperature, 15 °C.

Fig. 3.

The fixed acid Haldane effect (ΔZH; the number of protons released per Hb4 oxygenated at constant pH) as a function of pH in the eel anodic component for stripped haemoglobin (dotted line), for haemoglobin in 0.1 mol l−1 KCl (broken line) and for haemoglobin in 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1; solid line). ΔZH was calculated from the vertical distance between titration curves for oxygenated and deoxygenated haemoglobins at intervals of 0.1 pH unit. Each curve represents the mean of three complete titrations with the S.E.M. indicated by the vertical bars every 0.5 pH unit. Values for haemoglobin with GTP in the absence of KCl are identical to those for haemoglobin in 0.1 mol l−1 KCl with GTP (solid line) and have been omitted for clarity.

Fig. 3.

The fixed acid Haldane effect (ΔZH; the number of protons released per Hb4 oxygenated at constant pH) as a function of pH in the eel anodic component for stripped haemoglobin (dotted line), for haemoglobin in 0.1 mol l−1 KCl (broken line) and for haemoglobin in 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1; solid line). ΔZH was calculated from the vertical distance between titration curves for oxygenated and deoxygenated haemoglobins at intervals of 0.1 pH unit. Each curve represents the mean of three complete titrations with the S.E.M. indicated by the vertical bars every 0.5 pH unit. Values for haemoglobin with GTP in the absence of KCl are identical to those for haemoglobin in 0.1 mol l−1 KCl with GTP (solid line) and have been omitted for clarity.

The area between the ΔZH curves and ΔZH=0 (Fig. 3) was measured to determine the Bohr group recruitment during the addition of Cl and GTP. Compared with stripped haemoglobin, the addition of Cl increased the area by 5 %, and further addition of GTP increased it by 26 %. Thus, both Cl and GTP increased the magnitude of the alkaline Haldane effect, increased the pH at which the maximum Haldane effect was observed and reduced the pH range over which the Haldane effect was observed.

Titration of the cathodic component

Titration curves for cathodic haemoglobin in 0.1 mol l−1 KCl in the absence and presence of GTP are shown in Fig. 4. In the absence of GTP, a negative Haldane effect is seen above pH 6.8 (deoxygenated haemoglobin is more acidic than oxygenated haemoglobin at constant ZH), while below pH 6.8 the Haldane effect is positive but small. Fig. 5 illustrates the magnitude of the Haldane effect over the pH range 5.3–8.5 for the different conditions. At all pH values measured, KCl slightly increased ΔZH (or reduced the magnitude of the negative Haldane effect), while GTP virtually eliminated any Haldane effect.

Fig. 4.

Titration curves for ZH as a function of pH for the cathodic eel haemoglobin in (A) 0.1 mol l−1 KCl and (B) 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1). See legend to Fig. 2 for further details.

Fig. 4.

Titration curves for ZH as a function of pH for the cathodic eel haemoglobin in (A) 0.1 mol l−1 KCl and (B) 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1). See legend to Fig. 2 for further details.

Fig. 5.

The fixed acid Haldane effect (ΔZH; the number of protons released per Hb4 oxygenated at constant pH) as a function of pH in the eel cathodic component for stripped haemoglobin (dotted line), for haemoglobin in 0.1 mol l−1 KCl (broken line) and for haemoglobin in 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1; solid line). See legend to Fig. 3 for further details.

Fig. 5.

The fixed acid Haldane effect (ΔZH; the number of protons released per Hb4 oxygenated at constant pH) as a function of pH in the eel cathodic component for stripped haemoglobin (dotted line), for haemoglobin in 0.1 mol l−1 KCl (broken line) and for haemoglobin in 0.1 mol l−1 KCl plus GTP (GTP:Hb4 molar ratio of 3:1; solid line). See legend to Fig. 3 for further details.

Buffer value of the anodic component

The buffer values of the anodic haemoglobin at constant oxygenation status (mol H+ mol−1 tetramer pH unit−1) were derived from the slope between adjacent points on the titration curve relating ZH to pH (Fig. 6A). In the presence of KCl, the buffer value in the pH range 5.5–9 showed maxima at pH 6.2 in oxygenated haemoglobin and at pH 7.3 in deoxygenated haemoglobin. The additional presence of GTP increased the maximum haemoglobin buffer value and shifted this maximum to a higher pH, the shift being greater in oxygenated (to pH 6.9) than in deoxygenated (to pH 7.7) conditions.

Fig. 6.

Buffer value (−dZH/dpH; mol H+ mol−1 Hb4 pH unit−1) as a function of pH in (A) anodic haemoglobin and (B) cathodic haemoglobin in 0.1 mol l−1 KCl in the presence (squares) and absence (circles) of GTP at a GTP:Hb4 molar ratio of 3:1 for oxygenated (upper panels) and deoxygenated (lower panels) conditions. The buffer value of GTP alone was subtracted from respective traces.

Fig. 6.

Buffer value (−dZH/dpH; mol H+ mol−1 Hb4 pH unit−1) as a function of pH in (A) anodic haemoglobin and (B) cathodic haemoglobin in 0.1 mol l−1 KCl in the presence (squares) and absence (circles) of GTP at a GTP:Hb4 molar ratio of 3:1 for oxygenated (upper panels) and deoxygenated (lower panels) conditions. The buffer value of GTP alone was subtracted from respective traces.

When the data for the anodic haemoglobin are expressed as the inverse of the buffer value compared with ZH (differential titration), two well-resolved peaks are obtained, particularly in the deoxygenated condition (Fig. 7A). The distance between these two sharp peaks indicates the number of titratable groups that exist in the neutral pH range (de Bruin and van Os, 1968; Janssen et al. 1970, 1972). This value was 9 for the anodic haemoglobin (Fig. 7A).

Fig. 7.

Differential titration curve (−dpH/dZH, the inverse of buffer value, versus ZH) of (A) deoxygenated and (B) oxygenated anodic haemoglobin of eel in 0.1 mol l−1 KCl and (C) deoxygenated and (D) oxygenated cathodic haemoglobin of eel in 0.1 mol l−1 KCl. The horizontal distance between inflection points indicates the number of titratable groups within the neutral pH range (see Discussion for further explanation).

Fig. 7.

Differential titration curve (−dpH/dZH, the inverse of buffer value, versus ZH) of (A) deoxygenated and (B) oxygenated anodic haemoglobin of eel in 0.1 mol l−1 KCl and (C) deoxygenated and (D) oxygenated cathodic haemoglobin of eel in 0.1 mol l−1 KCl. The horizontal distance between inflection points indicates the number of titratable groups within the neutral pH range (see Discussion for further explanation).

Buffer value of the cathodic component

In contrast with the buffer value for the anodic component, that of the cathodic component at constant oxygenation status (Fig. 6B) showed no peak in the measured pH range and a minimum buffer value near pH 7.5 in both the oxygenated and deoxygenated haemoglobins. In addition, only a small increase in the haemoglobin buffer value was induced by GTP in the pH range between 6 and 7.5. Also, the differential titration revealed only one well-resolved peak in contrast with the two observed in anodic haemoglobin (Fig. 7C,D), indicating that there are no titratable groups within the neutral pH range in the cathodic haemoglobin component. Titrations were conducted beyond the pH values reported in Fig. 7; however, no second peak was found (data not shown).

The haemoglobin system in eel A. anguilla consists of one-third cathodic and two-thirds anodic component (Fig. 1; Pelster and Weber, 1990; Fago et al. 1995). The H+ titrations of these components reveal pronounced differences that correlate well with molecular data and indicate distinctive roles in buffering. While the anodic component possessed a large Haldane effect and a low buffer value, the cathodic component exhibited a low Haldane effect and low buffer value. These data indicate that the H+ equilibria of the anodic haemoglobin component are the more important for H+ buffering and CO2 transport.

Haldane effect

Anodic component

The Haldane effect (which is thermodynamically equivalent to the Bohr effect; Wyman, 1964) arises from changes in the pK of specific ionizable groups that are linked to haemoglobin oxygenation (Imai, 1982). In mammalian haemoglobin, the Bohr effect is divided into two regions over the pH range between 5 and 10. Whereas an increase in proton concentration decreases the oxygen affinity (alkaline Bohr effect) in the alkaline pH range, it increases the oxygen affinity below pH 6.5 as a result of an uptake of protons during oxygenation (acid Bohr effect). While the alkaline Bohr effect was large in anodic eel haemoglobin relative to that in human haemoglobin, the acid Bohr effect was not observed in the stripped component because of the presence of a Root effect (Pelster and Weber, 1990), which represents a drastic reduction in haemoglobin O2-affinity at low pH. In the presence of GTP, however, the titrations reveal a slight acid Bohr effect below pH 6.4 (Fig. 3).

In human haemoglobin, proton binding to His β146(HC3) (the histidine residue occurring at the 146th position of the β-subunit and at helical position HC3), which forms a salt bridge with Asp β94(FG1), accounts for approximately 50 % of the Bohr effect (Perutz et al. 1969; Kilmartin and Wootton, 1970; Shih et al. 1984). Although His β146(HC3) is conserved in eel anodic haemoglobin, Asp β94(FG1) is replaced by Glu (Fago et al. 1997), which may still form a salt bridge with His β146(HC3) and contribute substantially to the Bohr effect (Chien and Mayo, 1980b). In carp haemoglobin, removal of His β146(HC3) reduces the magnitude of the Bohr effect by half (Parkhurst et al. 1983). The magnitude of the Haldane effect is determined by the number of Bohr groups and their pK shifts, so that additional groups must be involved or the same groups must contribute more in anodic eel haemoglobin to account for the much larger Haldane effect compared with that of human haemoglobin (Imai, 1982). Additional groups that may be involved are discussed by Fago et al. (1997).

The presence of 0.1 mol l−1 Cl slightly increased the Haldane effect and the pH at which the maximum value was observed in the anodic component. In human haemoglobin, α1Val accounts for approximately 25 % of the alkaline Bohr effect in the presence of Cl. As in other fish haemoglobins (Farmer, 1979), the N-terminal residues of the α-chains are acetylated in A. anguilla and in the American eel A. rostrata (Fago et al. 1997; Gillen and Riggs, 1973) and are therefore unavailable to contribute to the Bohr effect. Another group that has been proposed to contribute to the Cl-induced Bohr effect in vertebrate haemoglobins is Lys β82(EF6) (Perutz et al. 1980), which is conserved in both the anodic and cathodic eel components (Fago et al. 1995, 1997). GTP similarly increased both the Haldane effect and the pH at which it was maximal. The absence of cumulative effects of GTP and Cl (Fig. 3, data for haemoglobin in the presence of GTP are identical in the presence and absence of KCl; results not shown) suggests overlapping binding sites for the two effectors (e.g. at Lys β82). Apart from this residue, organic phosphates bind to fish haemoglobin at the N-terminal amino group Val(NA1), at Glu(NA2) and at Arg(H21) of the β-chains (Gronenborn et al. 1984; Weber and Wells, 1989). All these residues are conserved in anodic eel haemoglobin (Fago et al. 1997), explaining the large influence of GTP on the Haldane effect.

Cathodic component

In the absence of organic phosphates, oxygenation of the cathodic haemoglobin at pH values above 6.8 is associated with an uptake of protons, causing a reversed acid Bohr effect. The absence of the normal alkaline Bohr effect correlates with the replacement of His β146(HC3) with Phe (Fago et al. 1995). In human haemoglobin, the removal of this histidine inhibits the expression of the normal alkaline Bohr effect and permits expression of a reversed Bohr effect, which suggests that the Bohr groups exhibit a higher affinity for protons in the oxygenated than in the deoxygenated state. The possible molecular mechanisms underlying the reversed Bohr effect are discussed elsewhere (Fago et al. 1995).

The most likely groups to contribute to the reverse Bohr effect are the N-terminal amino groups of the β-chains and the imidazole groups of histidines, all of which possess pKa values in the pH range at which the reverse Bohr effect is observed. The five histidine residues in the α-chains are unlikely to contribute because they are not titratable (Fig. 7C,D) and they occur in many fish haemoglobins that do not exhibit a reverse Bohr effect (Fago et al. 1995).

The presence of Cl slightly increased the Haldane effect (decreased the negative Haldane effect) at all pH values. This effect is probably due to the presence of Lys β82(EF6), which may contribute to the Cl-dependent Bohr effect in human haemoglobin and is conserved in cathodic haemoglobin. Although Cl strongly decreases the oxygen affinity of cathodic eel haemoglobin (Weber et al. 1976), Breepoel et al. (1981a) found no Cl effect at concentrations greater than 0.1 mol l−1. GTP in the presence or absence of Cl (results for the latter not shown) virtually eliminates the negative Bohr effect at pH values above 7, as has been observed previously (Weber et al. 1976; Fago et al. 1995; Feuerlein and Weber, 1996).

Buffer value

Eel haemolysates exhibit a lower buffer value than human haemolysates (Breepoel et al. 1980), and titrations reveal a low buffer value for both the anodic and cathodic haemoglobin components (Fig. 6). The buffer value of haemoglobin at fixed oxygenation status is determined by the nature of the groups that exchange protons with the solvent. The groups titrated can be roughly divided into three classes, each distinguished from the others by an inflection point in a titration curve (de Bruin and van Os, 1968; Janssen et al. 1970, 1972): (a) the carboxyl groups of aspartic and glutamic acids, which are titrated below pH 5.5, (b) the imidazole groups of histidine and the N-terminal amino groups, which are titrated between pH 5.5 and 9 (neutral pH range), and (c) the groups titrated at pH values above 9. However, the pK values vary depending on the nature of adjacent groups (Paetzel and Dalbey, 1997). The low buffer value in the neutral pH range in teleost fish haemoglobins compared with that in most other vertebrate haemoglobins is correlated with the low total histidine content of the haemoglobin (Jensen, 1989). In eel, the anodic component contains 22 (Fago et al. 1997) and the cathodic component contains 14 (Fago et al. 1995) histidine residues (Table 1), values much lower than those found in human haemoglobin A (38 residues, Braunitzer et al. 1961).

Table 1.

Histidine residues in the α-and β-chains of the anodic and cathodic eel haemoglobins

Histidine residues in the α-and β-chains of the anodic and cathodic eel haemoglobins
Histidine residues in the α-and β-chains of the anodic and cathodic eel haemoglobins

Not all the histidine residues in the tetramer are available for proton binding since some are buried within the protein moiety. In the anodic component, there appear to be nine titratable groups in the neutral pH range (Fig. 7), as is also observed in carp (Jensen, 1989). Excluding the N-terminal amino groups of the α-chains that are acetylated and those of the β-subunits that are available for titration, this leaves seven titratable histidines per tetramer from a total of 22 histidines (Table 1). Of the 22 histidines in the anodic component, eight (per tetramer) consist of the proximal and distal histidines which ligate with the iron atom of the haem groups and are thus unavailable for proton binding, leaving 14 histidine residues. Thus, of the seven titratable histidine residues per tetramer (Fig. 7), there are 14 that could potentially be titrated in the neutral pH range in the anodic component.

The single maximum in the differential titration curve of the cathodic component (Fig. 7C,D) indicates that there are no titratable groups in the neutral pH range for this component (Breepoel et al. 1981a); thus, none of the 14 histidine residues in this component (Fago et al. 1995) is titratable. It may be possible to determine which histidines in the anodic component are titratable if it can be assumed that the titratabilities of histidine residues found at the same location in the two components are equivalent. On this basis, the histidines at β41(C7), β97(FG4), β109(G11) and β146(HC3) in the anodic component, i.e. eight per tetramer, would be available for titration (Table 1). Together with the two β-chain N-terminal residues, this indicates the presence of 10 titratable groups, which agrees closely with the value of nine groups as determined in Fig. 7.

The addition of GTP to the anodic component increased the maximal buffer value observed and the pH at which it was manifested (Fig. 6). The implied increase in apparent pK of haemoglobin in both the oxygenated and deoxygenated condition indicates that GTP binds to both forms. Although the affinity for organic phosphates is generally much higher for deoxygenated than for oxygenated haemoglobin (Garby et al. 1969), there is evidence for GTP binding to oxygenated haemoglobin in tench (Weber et al. 1987) and for IHP binding to oxygenated haemoglobin in carp (Chien and Mayo, 1980a,b). The raised pK in the presence of GTP increased the pH at which the Haldane effect was observed (Fig. 3). The reduced difference between pK values for oxygenated and deoxygenated haemoglobin resulted in the narrower pH range over which the Haldane effect was observed (Fig. 3).

In conclusion, in the titrations conducted in the present study, GTP was present at a 3:1 molar excess compared with haemoglobin tetramers, which is not much greater than that measured in vivo (2:1 GTP:Hb4; Weber et al. 1976). These data provide insight into the roles of the two components in vivo. A dominant aspect with respect to CO2 transport and pH homeostasis of the blood is that the Haldane effect is very large in the anodic component but virtually absent from the cathodic component. Although both haemoglobins have low buffer capacities relative to those of air-breathing vertebrates, that of the anodic component is always equal to or greater than that of the cathodic component, which is probably due to the specific histidine residues at β41(C7), β97(FG4), β109(G11) and β146(HC3). Thus, the inverse relationship between the magnitude of the Haldane effect and the buffer value observed in the whole blood haemolysates from various vertebrates (Jensen, 1989) does not extend to the individual components in eel. Since the cathodic component constitutes only approximately one-third of the total haemoglobin, it will make only a minor contribution to the buffer value of the blood.

Haemoglobin multiplicity in fish is thought to permit a division of labour between the various haemoglobin components with respect to O2 transport (Weber, 1990). This also appears to apply to CO2 transport and pH homeostasis, which in the eel is accomplished predominantly by the anodic component.

We thank Angela Fago and Hans Malte for valuable discussions and criticisms and the two anonymous referees for their suggestions. Support from the Danish Natural Science Research Council is acknowledged, and C.J.B. was supported by an NSERC postdoctoral fellowship.

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