Human serotransferrin: structure and function

Structural origins of the insulin-mimetic activity of bis(acetylacetonato)oxovanadium(IV)

We have investigated the interaction of bis(acetylacetonato)oxovanadium(IV) (VO(acac)(2)) with bovine serum albumin (BSA) by EPR and angle-selected electron nuclear double resonance, correlating results with assays of glucose uptake by 3T3-L1 adipocytes. EPR spectra of VO(acac)(2) showed no broadening in the presence of BSA; however, electron nuclear double resonance titrations of VO(acac)(2) in the presence of BSA were indicative of adduct formation of VO(acac)(2) with albumin of 1:1 stoichiometry. The influence of VO(acac)(2) on uptake of 2-deoxy-d-[1-(14)C]glucose by serum-starved 3T3-L1 adipocytes was measured in the presence and absence of BSA. Glucose uptake was stimulated 9-fold in the presence of 0.5 mm VO(acac)(2), 17-fold in the presence of 0.5 mm VO(acac)(2) plus 1 mm BSA, and 22-fold in the presence of 100 nm insulin. BSA had no influence on glucose uptake, on the action of insulin, or on glucose uptake in the presence of VOSO(4). The maximum insulin-mimetic effect of VO(acac)(2) was observed at VO(acac)(2):BSA ratios less than or equal to 1.0. Similar results were obtained also with bis(maltolato)oxovanadium(IV). These results suggest that the enhanced insulin-mimetic action of organic chelates of VO(2+) may be dependent on adduct formation with BSA and possibly other serum transport proteins.

Competitive binding of bismuth to transferrin and albumin in aqueous solution and in blood plasma

Several bismuth compounds are currently used as antiulcer drugs, but their mechanism of action is not well established. Proteins are thought to be target sites. In this work we establish that the competitive binding of Bi(3+) to the blood serum proteins albumin and transferrin, as isolated proteins and in blood plasma, can be monitored via observation of (1)H and (13)C NMR resonances of isotopically labeled [epsilon-(13)C]Met transferrin. We show that Met(132) in the I132M recombinant N-lobe transferrin mutant is a sensitive indicator of N-lobe metal binding. Bi(3+) binds to the specific Fe(3+) sites of transferrin and the observed shifts of Met resonances suggest that Bi(3+) induces similar conformational changes in the N-lobe of transferrin in aqueous solution and plasma. Bi(3+) binding to albumin is nonspecific and Cys(34) is not a major binding site, which is surprising because Bi(3+) has a high affinity for thiolate sulfur. This illustrates that the potential target sites for metals (in this case Bi(3+)) in proteins depend not only on their presence but also on their accessibility. Bi(3+) binds to transferrin in preference to albumin both in aqueous solution and in blood plasma.

Steric restrictions on the binding of large metal ions to serum transferrin

Apotransferrin in 0.1 M N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonic acid at 25 degrees C and pH 7.4 was titrated with acidic solutions of Lu3+, Tb3+, and Eu3+. Metal binding at the two specific metal-binding sites of transferrin was followed from changes in the difference UV spectra at 245 nm. The binding of Tb3+ was also followed from changes in the fluorescence emission spectrum at 549 nm. Apotransferrin was titrated with solutions containing varying ratios of the metal ion and the competitive chelating agent nitrilotriacetic acid, and metal-transferrin binding constants were calculated by nonlinear least-squares fits of the absorbance as a function of titrant added. The sequential carbonate-independent equilibrium constants for the binding of two metal ions are log KM1 = 11.08 and log KM2 = 7.93 for Lu3+, log KM1 = 11.20 and log KM2 = 7.61 for Tb3+, and log KM1 = 9.66 and log KM2 = 7.27 for Eu3+. Titrations of both C-terminal and N-terminal monoferric transferrins indicate that all of these metal ions bind more strongly to the C-terminal binding site. The trend in log K values as a function of the lanthanide ionic radius has been evaluated both by plots of log K versus the metal ion charge/radius ratio and by linear free-energy relationships in which binding constants for complexes of the larger lanthanides are plotted versus the binding constants for complexes with the smallest lanthanide, Lu3+. Both methods indicate that there is a sharp drop in the binding constants for the C-terminal binding site for metals larger than Tb3+. This decrease is attributed to a steric hindrance to the binding of the larger cations. The steric effect is not as strong for metal binding at the N-terminal site. As a result, the selectivity for binding to the C-terminal site, which is quite high for the smaller lanthanides, drops sharply on going from Tb3+ to Nd3+.

Binding of monovalent anions to human serum transferrin

Serum transferrin is the protein whose primary function is to bind iron and transport it through the blood. Apotransferrin has two specific metal-binding sites that bind a variety of metal ions in addition to the ferric ion. The distinguishing feature of the transferrins is that a "synergistic" bicarbonate anion is bound along with the metal ion to form a stable Fe(3+)-CO3-Tf ternary complex. Previous research has shown that apotransferrin will also bind divalent anions such as phosphate and sulfate. Difference UV spectroscopy has now been used to show that a series of monovalent anions bind weakly to apotransferrin. Equilibrium constants for the binding of chloride, perchlorate, bromide, fluoride and Hepes have been calculated. A reaction scheme for the binding of anions is proposed which predicts that the binding of the nonsynergistic anions to apotransferrin will interfere with metal binding by competing directly with the binding of the synergistic bicarbonate anion. Difference UV data are presented which demonstrate this type of competition between nonsynergistic anions and Tb3+. Competition from the nonsynergistic anions follows the order HPO4(2-) > SO4(2-) approximately F- > ClO4- approximately Cl- approximately Br-. Speciation calculations have been performed to determine the concentrations of anion-apotransferrin complexes in Hepes and Tris buffers and in human serum and to estimate the extent to which competition from anions in the buffer will interfere with metal-binding to apotransferrin.

Calorimetric studies of serum transferrin and ovotransferrin. Estimates of domain interactions, and study of the kinetic complexities of ferric ion binding

Human serum transferrin and hen ovotransferrin have been studied by differential scanning calorimetry (DSC), in an effort to quantitatively estimate the free energy of interaction of the N- and C-domains in each protein and to further understand their interaction with chelated ferric ions. In the case of serum transferrin, separate DSC transitions are observed for the two domains while only a single, coupled transition is seen for ovotransferrin. Although domain interactions are somewhat larger for ovotransferrin (-4100 cal/mol) than for serum transferrin (-3100 cal/mol), the major cause of separated transitions for serum transferrin is that the difference in intrinsic folding stability of the N- and C-domains is about 4-fold larger than for ovotransferrin. Chelated ferric ions bind strongly to each site in both proteins and produce changes in Tm by as much as 30 degrees C. When apparent binding constants are estimated from DSC results, these appear to be substantially larger than those estimated previously from equilibrium methods at low temperatures, where very long equilibrium times must be used because of slow ligand release. Although second DSC upscans on each protein show good "reversibility", downscans on serum transferrin revealed that liganded forms of the protein are in fact not in true equilibrium during upscanning, which causes Tm values during upscans to be higher than the true reversible Tm values. The likely reason for this kinetic control over unfolding is the slow release of bound ferric ions and those effects, for technical reasons, cannot be totally eliminated by lowering the scan rate.

Calorimetric studies of the binding of ferric ions to human serum transferrin

The binding of ferric ions, chelated with nitrilotriacetate, to human serum transferrin (hTF) has been studied using ultrasensitive titration calorimetry. Studies were done in both the presence and the absence of the synergistic bicarbonate anion. It was found that the C-site of hTF is capable of weakly binding bicarbonate (K of 250 M-1, delta H of -8 kcal) at the binding site even before ferric ion is added, although this does not happen to the same extent at the N-site. When preinsertion of the bicarbonate ion occurs, then ferric ion can subsequently bind very quickly to the C-site. Although the chelated ferric ion can bind weakly to the N-site in a fast reaction, the insertion of the bicarbonate ion occurs subsequently in a slow endothermic reaction. Binding of ferric ion to both sites is quickly reversible in the absence of bicarbonate but becomes kinetically controlled for long periods of time once bicarbonate has inserted into the metal-binding site due to the long time required for release of ferric ion. Estimates of the heats of binding to each site, apparent binding constants, and heat capacities of binding are made for different sets of solution conditions. Results from this study are compared to earlier results with ovotransferrin (Lin, L.-N., Mason, A. B., Woodworth, R. C., & Brandts, J. F. (1991) Biochemistry 30, 11660-11669), with major differences and some similarities noted.

Potential 67Ga radiopharmaceuticals for myocardial imaging: tris(1-aryl-3-hydroxy-2-methyl-4-pyridinonato)gallium(III) complexes

A series of highly lipophilic complexes of 1-aryl-3-hydroxy-2-methyl-4-pyridinones with gallium(III)-67 has been evaluated in vitro and in vivo as potential radiopharmaceuticals. The pyridinones have different substituents at the para-position of the phenyl ring: R = H, CH3, OCH3 and NO2. Biodistribution studies of 67Ga complexes have been carried out in rabbits, mice, rats and a dog. High heart uptake of the radionuclide has been shown in rabbits and the dog. The different biodistribution patterns in mice and rats indicate that there is a species difference in the biodistribution of these complexes. Rabbits and the dog show rapid heart uptake and blood clearance. The speciation of the Ga3+ ion in vivo is simulated in vitro with a simple blood plasma model based on the available thermodynamic data.

Characterization of the cooperative cross-linking of doxorubicin N-hydroxysuccinimide ester derivatives to water soluble proteins

Protein-anthracycline interactions have been examined by using reactive N-hydroxysuccinimide ester derivatives of doxorubicin. These compounds cross-link to lysine epsilon-amino groups with high efficiency and offer the possibility for structural studies of protein-anthracycline complex formation by using gel filtration, ultracentrifugation and spectrophotometric methods. The results are in accordance with association of anthracycline to the hydrophobic ligand binding cavities of serum albumin. The results for proteins not having hydrophobic domains (IgG, serum transferrin, lactotransferrin, ovotransferrin) suggest that complex formation is cooperative and involves two steps: initial self-association of anthracycline into aggregated structures and subsequent binding of protein at the aggregate surface. With serum transferrin, anthracycline self-association makes possible the assembly of stable nanometer-sized protein-anthracycline particles held together by non-covalent bonds. This reaction, which is highly reproducible and efficient, may have applications in the field of development of anthracycline carrier systems.

The determination of the pKa of histidine residues in proteins by Raman difference spectroscopy

Sensitive Raman difference spectroscopy was used to monitor the protonation and deprotonation of histidine residues in apo-transferrin. We have shown previously that the behavior of small molecules and/or small molecular groups bound to proteins or other large macromolecules can be studied by Raman difference spectroscopy (Yue, K.T. et al. (1989) J. Raman Spectrosc. 20, 541-545). Using this method, we have measured the Raman difference spectra of human transferrin at different pH values with respect to pH 8.9, titrating its various histidine residues. About 12 +/- 2 of the 19 residues were titrated. The pH difference spectrum of transferrin obtained is very similar to that of histidine in solution, but with clear differences in the 1200-1400 cm-1 region. A titration curve with pKa of 6.08 +/- 0.01 fit the data of histidine in solution and a value of 6.56 +/- 0.02 was found for the average value of the 12 histidine residues inside transferrin. The technique has enough sensitivity at present to monitor a single histidine residue in a 130 kDa molecule and to determine the titration curve of one residue in a 40 kDa protein.

Site-specific rate constants for iron removal from diferric transferrin by nitrilotris(methylenephosphonic acid) and pyrophosphate

The kinetics of iron removal from human serum diferric transferrin by nitrilotris(methylenephosphonic acid) (NTP) and pyrophosphate (PPi) have been studied in 0.1 M, pH 7.4, N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonate buffer at 25 degrees C using urea/polyacrylamide gel electrophoresis. The four microscopic rate constants required for a complete description of iron removal from the two transferrin metal-binding sites have been measured at 100 mM concentrations of NTP and PPi. There is very good agreement between the rate constants determined by electrophoresis in this study and the corresponding rate constants determined spectrophotometrically for monoferric transferrins that have been labeled at the empty binding site with substitutionally inert Co(III). The results validate the use of cobalt-labeled transferrins as models for kinetic studies on iron removal from diferric transferrin.

Site selectivity in the binding of inorganic anions to serum transferrin

Equilibrium constants for the sequential binding of two anions at the specific metal-binding sites of apotransferrin have been measured by difference ultraviolet spectroscopy in 0.1 M N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (Hepes) at pH 7.4 and 25 degrees C. Log K1 values for phosphate, phosphite, sulfate, and arsenate fall in the narrow range of 3.5-4.0, while the log K1 for bicarbonate is 2.73. No binding is observed for nitrate, perchlorate, or borate. A dinegative charge appears to be the most important criterion for anion binding. Equilibrium constants have also been measured for binding of anions to both forms of mono(ferric)transferrin. There appears to be a very small site selectivity (0.2 to 0.4 log units) for phosphate, arsenate, and phosphite that favors binding to the N-terminal site, but there is no detectable selectivity for binding of sulfate or bicarbonate. Comparison of the binding affinities and anion selectivity with literature data on anion-binding to protonated macrocyles and cryptates strongly supports the existence of specific anion-binding sites on the protein. Binding constants were also measured in 0.01 M Hepes. The anionic sulfonate group of the buffer appears to have a small effect on anion binding.

Covalent modification of serum transferrin with phospholipid and incorporation into liposomal membranes

A method is described for incorporation of water-soluble proteins into liposomal membranes using covalent protein-phospholipid conjugates in detergent solution. A disulfide derivative of phosphatidylethanolamine containing a reactive N-hydroxysuccinimide ester group is synthesized, and the derivative is reacted with serum transferrin in deoxycholate-containing buffer. Disulfide-linked transferrin-phosphatidylethanolamine conjugates containing up to 6 mol phospholipid/mol protein are prepared. The amphiphilic conjugates have solubility properties very similar to integral membrane proteins. The conjugates self-associate to form protein micelles of narrow size distribution (Stokes radii 6-7 nm), and in the presence of excess phospholipid (egg phosphatidylcholine), they readily incorporate into liposomal membranes upon removal of detergent. Stable incorporation into liposomes requires the introduction of two molecules of phosphatidylethanolamine into the transferrin. Using the disulfide linker to release transferrin from the liposomes, evidence is presented for a function of the phosphatidylethanolamine as an anchor-molecule into the liposomal lipid. Optimal conditions for preparation of homogeneous liposomes with diameters in the range 30-125 nm and with a varying content of transferrin are defined. The liposomes appear well suited for studies on liposome-cell membrane interactions.

Evidence of conformational changes in the non-equivalent binding sites of human serum transferrin

Samples of monoferric human serum transferrin have been prepared in which the iron occupies predominantly the N-site (sample A) and the C-site (sample B). 111In was then added in concentrations small enough to ensure that there was always an excess of specific binding sites. Because of the presence of apo-transferrin in both the samples, the occupancy by 111In in the two sites was only 75-78% C-site in sample A and only 61-65% N-site in sample B. Time differential PAC spectra showed a transition in the quadrupole frequency which took place at different temperatures, approximately 275 K in sample A and between 290 and 305 K in sample B. Debye and Arrhenius plots of the temperature dependence of the correlation time associated with molecular reorientation indicated an effective molecular volume about 50% larger than that of the hydrated diferric molecule determined by "biochemical" methods, and an activation energy for re-orientation of approximately 0.065 eV.

The spectroelectrochemical determination of the reduction potential of diferric serum transferrin

The first spectroelectrochemical measurement of the formal reduction potential of iron transferrin has been carried out using methyl viologen to mediate electron transfer to the protein. These calculations take into consideration the weak nature of the ferrous transferrin complex. A value of -0.52(8) V vs. the normal hydrogen electrode was obtained in 0.100 M tris(hydroxymethyl)aminomethane buffer at pH 7.4, 22 degrees C, and 2.0 M KCl. A high ionic strength was necessary to effect reduction, supporting the observation that ions play an important role in the reduction of iron in transferrin. Finally, a procedure for carrying out the reduction of methyl viologen at a gold electrode in a spectrophotometric cell is described.

Affinity labels for the anion-binding site in ovotransferrin

Bromopyruvate, a known alkylating agent, has previously been reported to function as an affinity label for the anion-binding site in the iron-binding protein ovotransferrin [Patch, M.G., & Carrano, C. J. (1982) Biochim. Biophys. Acta 700, 217-220]. However, the present results indicate that hydroxypyruvate also functions in an almost identical manner, which implies that alkylation of a susceptible nucleophile cannot be the mechanism responsible for the covalent attachment of the anion. Model complexes and amino acid analysis of labeled ovotransferrin suggest that initial Schiff base formation, followed by reduction of the imine bond between the affinity anion and a lysine within the locus of the anion-binding site, accounts for the irreversible labeling. As expected, the covalently attached anions render the iron in the ovotransferrin-iron-anion ternary complex much more resistant to loss at low pH. It is proposed that the covalently labeled protein be used to test the hypothesis that iron removal from transferrin occurs by protonation and loss of the anion in low-pH lysosomal vesicles.

The effects of salts and amino group modification on the iron binding domains of transferrin

The origins of the effects of salts on the properties of the iron binding sites of transferrin have been investigated. The chaotropically distinct salts NaCl and NaClO4 each induce characteristic changes in the EPR lineshapes of the N- and C-terminal Fe3+ binding domains, respectively. To a good approximation the perturbed EPR spectrum of diferric transferrin in the presence of salts is the sum of the EPR spectra of the N- and C-terminal monoferric proteins. Acetylation of amino groups causes spectral and kinetic changes in the protein similar to those induced by NaClO4. Thus, both acetylation and NaClO4 cause a loss of structure in the g' = 4.3 EPR signal of the N-terminal domain, and both retard iron removal from this domain. In contrast, iron removal from the C-terminal domain is accelerated by acetylation or the presence of NaClO4. These observations are ascribed to charge effects of lysine residues which are probably in the vicinity of the iron binding sites.

The study of iron mobilisation from transferrin using alpha-ketohydroxy heteroaromatic chelators

A group of heteroaromatic chelators with an alpha-ketohydroxy binding site have been tested for their ability to mobilise iron from transferrin in vitro. When these chelators were mixed with iron-saturated transferrin at physiological pH, biphasic reactions were observed. The alpha-ketohydroxy heteroaromatic chelators were found to cause substantial iron removal compared to other known chelators. These findings suggest that these chelators may have an important role in the study of iron metabolism and a possible clinical use in the treatment of transfusional iron overload in thalassaemia, and other diseases of iron imbalance.

Reduction potential of iron in transferrin

The reduction potential of Fe3+ in transferrin was measured spectrophotometrically by equilibration with methyl viologen in the presence of sodium dithionite. For an ionic strength near 0.1 M at 25 degrees C and pH 7.3 under 0.048 atm. CO2, half of the iron is reduced at a potential near -0.40 V (vs. standard hydrogen electrode). At least one disulfide bond of the protein is partially reduced at a potential of -0.44 V, as evidenced by reaction with [14C]iodoacetate.

The competitive equilibrium between aluminium and ferric ions for the binding sites of transferrin

Human transferrin is shown to bind 2 mol of aluminium per mol of protein using spectrophotometric titration. Competitive equilibrium between aluminium and ferric ions for transferrin binding sites is observed, and a value of 2.5 (+/- 0.4) X 10(15) M-1 is found for the apparent binding constant under physiological conditions.

Kinetics of the removal of ferric ion from transferrin by aminoalkylphosphonic acids

The kinetics of ion removal at 25 degrees C in 0.1 M Tris, pH 7.4 by a series of phosphonic acids have been evaluated. The initial rate of iron removal is first order in ferric-transferrin, but shows a hyperbolic dependence on the concentration of the phosphonate ligand. At high ligand concentrations the reaction is clearly biphasic, and the data are interpreted in terms of nonequivalent rate constants for iron removal from the two transferrin iron-binding sites. Rate constants for three phosphonic acid ligands are approximately 0.025 min-1 and approximately 0.007 min-1 for the faster and slower binding sites. The results are discussed in relation to the conformational change mechanism for iron removal from transferrin proposed by Coward et al. [21].

Cobalt(II) as an NMR probe for the investigation of the coordination sites of conalbumin

The bis and mono cobalt(II) derivatives of conalbumin in the presence of bicarbonate have been prepared. The 1H NMR spectra have been recorded at 60 MHz. Well-shaped isotropically shifted signals in the range -100 to +100ppm have been observed for both the mono and bis cobalt(II) derivatives; besides the intensity, all the isotropically shifted signals for the two derivatives are superimposable, indicating that the two sites are so similar as to be indistinguishable within the resolution of the technique. With the aid of T1 measurements, the signals have been assigned to the protons of two histidine and two tyrosinate ligands. The spectra are consistent with six-coordinated, high-spin cobalt(II) chromophores with two trans tyrosinate moieties at each site.

Electron-nuclear double resonance of copper complexes of human transferrin

Electron-nuclear double resonance (ENDOR) spectroscopy has been used to study ligand and copper hyperfine interactions in Cu(II) complexes of human transferrin. A nearly isotropic superhyperfine interaction of the Cu(II) spin with a single 14N nucleus was identified, and the principal values of its tensor were estimated. All principal values of the copper hyperfine tensor were also directly measured for the first time. Resonances from at least two exchangeable protons were observed, but their origin could not be ascertained. At physiological pH, and in the presence of bicarbonate, ENDOR spectra of the two metal-binding sites were virtually indistinguishable.

Comparative study of the iron-binding properties of human transferrins. II. Electron paramagnetic resonance of mixed metal complexes of human lactotransferrin

Human lactotransferrin is able to bind two vanadyl(IV) ions in specific metal-binding sites. The EPR signals of the two vanadyl bound ions, however, appear as one. This result suggests that the environments of the binding sites of human lactotransferrin are similar. The binding activity is promoted to pH 4 using carbonate or bicarbonate as synergistic anion. This unusual stability of the anion-binding site, which is destroyed below pH 6 for other transferrins, can explain in part the great stability of the metallic complexes of human lactotransferrin. However, the different sensitivities of the two metal-binding sites towards protonation permit the preparation of mixed vanadyl(IV), iron(III) complexes with VO2+ bound either on the N-terminal (acid-labile or B site) or on the C-terminal (acid-stable or A site) site. Analysis of the spectra of such mixed complexes shows the presence of a third nonspecific VO2+-binding site termed A'. The nonspecific A' site seems to be located on the outer surface of the protein close to the C-terminal site.

The primary structure of hen ovotransferrin

Peptide sequences obtained from hen ovotransferrin are compared with the complete amino acid sequence of the protein deduced from a cDNA sequence (Jeltsch and Chambon, preceding paper). Of the 705 positions of the whole protein 605 can be matched by the peptide sequences. Some possible discrepancies between the two methods are pointed out. The two halves of the chain show marked similarities in their sequences with 37% identical residues. The positions of the 15 disulphide bridges are shown; there are 6 homologous bridges in each half of the molecule and 3 extra bridges which occur only in the C-terminal half. The terminal residues of the half-molecule fragments obtained by limited proteolysis are identified. The two domains are joined by a 9-residue connecting peptide. Sequence variability has been found at 9 positions. The sequence of hen ovotransferrin is compared with the partial available for human transferrin. From this some tentative conclusions about the identities of the metal-binding residues and about the evolution of transferrin are reached.

An affinity label for the anion binding site in ovotransferrin. Implications for iron release to reticulocytes

Bromopyruvate has been found to be an affinity label for the anion binding site in ovotransferrin. Spectral and radioactive labeling studies indicate that the bromopyruvate first forms a reversible ternary complex with ovotransferrin and iron and then reacts to yield the covalently bound product. This derivative is partially resistant to iron loss by protonation and suggests that protonation and loss of anion is a requisite first step for iron release to reticulocytes.

Polynuclear iron compounds in human transferrin preparations

During commonly used saturation procedures of transferrin with iron compounds, both as ferri and ferrous, polynuclear iron compounds are easily formed, even when nitrilotriacetate (NTA) is used as a strong iron ligand. The presence of these nonspecific bound irons is demonstrated with Mossbauer spectroscopy and with electronic optical spectroscopy. But no evidence, however, has been found of two different iron binding sites. Because dialysis is not able to remove all polynuclear iron, an easy method with gel filtration has been developed that does remove the polynuclear iron. Some notes are made about the often used method, in transferrin biochemistry, of saturation determination, i.e. the quotient of the absorbances of 470 and 280 nm.