Ultrasonic absorption and relaxation spectra in aqueous bovine hemoglobin

Measurements of the frequency and p^H dependence of acoustic absorption at 0°C in aqueous solutions of freshly prepared bovine oxyhemoglobin are reported. The role of ionization and possible direct proton-transfer between proximal pairs in determining the characteristic times for the relaxation of the internal charge distribution is discussed. It is concluded that treatments which consider various classes of residues as ionizing independently will not give approximately correct relaxation spectra. A model which takes into account the coupling between the degrees of ionization of the various residues is found to give rough agreement with the observed acoustic absorption in the p^H range in which the native conformation is stable.     

UV resonance raman spectra of ligand binding intermediates of sol-gel encapsulated hemoglobin.

We report for the first time specific conformational changes for a homogeneous population of ligand-bound adult deoxy human hemoglobin A (HbA) generated by introducing CO into a sample of deoxy-HbA with the effector, inositol hexaphosphate, encapsulated in a porous sol-gel. The preparation of ligand-bound deoxy-HbA results from the speed of ligand diffusion relative to globin conformational dynamics within the sol-gel (1). The ultraviolet resonance Raman (UVRR) difference spectra obtained reveal that E helix motion is initiated upon ligand binding, as signaled by the appearance of an alpha14beta15 Trp W3 band difference at 1559 cm(-1). The subsequent appearance of Tyr (Y8a and Y9a) and W3 (1549 cm(-1)) UVRR difference bands suggest conformational shifts for the penultimate Tyralpha140 on the F helix, the "switch" region Tyralpha42, and the "hinge" region Trpbeta37. The UVRR results expose a sequence of conformational steps leading up to the ligation-induced T to R quaternary structure transition as opposed to a single, concerted switch. More generally, this report demonstrates that sol-gel encapsulation of proteins can be used to study a sequence of specific conformational events triggered by substrate binding because the traditional limitation of substrate diffusion times is overcome.     

Covalent binding of glutathione to hemoglobin. II. Functional consequences and structural changes reflected in NMR spectra

Binding of glutathione by disulfide linkage to Cys-beta 93 of hemoglobin tetramers within sickle cells increases the oxygen affinity and significantly inhibits sickling at low partial oxygen pressure (Garel, M-C., Domenget, C., Caburi-Martin, J., Prehu, C., Galacteros, F., and Beuzard, Y. (1986) J. Biol. Chem. 261, 14704-14709). This article reports a characterization of the oxygen-binding properties of glutathionyl hemoglobin (G-Hb) in solution in the presence or absence of allosteric effectors. The studies reveal a nearly 6-fold increase in oxygen affinity compared to native HbA and a Hill coefficient at half-saturation (n50) of 1.50 compared to n50 of approximately 2.9 for HbA. The oxygen Bohr effect measured in the alkaline pH range is reduced by 38%. Addition of 2,3-diphosphoglycerate decreases the oxygen affinity of G-Hb and HbA to a similar extent and increases the Bohr effect, indicating that the binding sites for organic phosphates are not perturbed in G-Hb. The rate of autooxidation of G-HbO2 is slower than of HbAO2. Oxidation by ferricyanide of G-HbCO is also reduced and is biphasic, demonstrating a heterogeneous susceptibility of the hemes in G-Hb. Flash photolysis experiments indicate that the tetramer-dimer dissociation constant is 1 order of magnitude greater for G-HbCO than for HbACO. High resolution NMR spectra at 400 MHz show that in G-Hb: the tertiary structure of the beta heme pocket is significantly perturbed, particularly in the F helix and the EF corner; the formation of the salt bridge between His-beta 146 and Asp-beta 94, a feature of the deoxy state, is precluded; and a deoxy interchain (alpha 1 beta 2) contact between Asp beta 2 99 and Tyr alpha 1 42 is appreciably destabilized. The NMR data provide a structural basis for interpreting the high oxygen affinity, reduced cooperativity, and diminished polymerization of G-HbS.     

Time-resolved emission spectra of hemoglobin on the picosecond time scale

We used front-face illumination to examine the steady-state and time-resolved emission from the intrinsic tryptophan emission of human hemoglobin (Hb). Experimental conditions were identified which eliminated all contributions of scattered light. The sensitivity obtained using front-face optics was adequate to allow measurement of the wavelength-dependent frequency response of the emission to 2 GHz. The intensity decays displayed pico- and nanosecond components in the emission at all wavelengths from 315 to 380 nm. The contribution of the picosecond component decreased from 72 to 37% over this range of wavelengths. Frequency-domain measurements were used to calculate the time-resolved emission spectra and decay-associated emission spectra. These spectra indicate that the picosecond components of the emission display maxima near 320 nm, whereas the nanosecond components are centered at longer wavelengths near 335 nm. The nanosecond components appear to be due to residual impurities which remain even in highly purified samples of Hb. However, we cannot eliminate the possibility that some of these components are due to Hb itself.     

Near-infrared spectra of Scapharca homodimeric hemoglobin: characterization of the deoxy and photodissociated derivatives.

The near-infrared charge transfer band at 760 nm (band III) has been investigated in deoxy and photodissociated dimeric Scapharca hemoglobin. At 300 K, the 10-ns spectrum of the carbonmonoxy derivative photoproduct is shifted by about 6 nm toward longer wavelengths with respect to the deoxy spectrum, both in buffer and in glycerol/buffer solutions. Moreover, the band III peak occurs at about the same wavelength at 300 K and at 10 K for the 10-ns photodissociated derivative, whereas in the deoxy derivative large changes in peak position and linewidth are observed as a function of temperature. These findings suggest that in dimeric Scapharca hemoglobin the photoproduct has not relaxed after 10 ns. The complete time dependence of the relaxation process has been studied both in buffer and in glycerol/buffer solutions at room temperature. The relaxation from the photoproduct to the deoxy species occurs on a microsecond time scale, in line with recent optical absorption and resonance Raman measurements.     

Time dependence of near-infrared spectra of photodissociated hemoglobin and myoglobin

The near-infrared charge-transfer transitions at approximately 760 nm in photodissociated hemoglobin and myoglobin display very different time dependences. In photodissociated myoglobin at room temperature the transition has fully relaxed to its deoxymyoglobin value by 10 ns. In photodissociated hemoglobin, the transition is shifted by 6 nm to longer wavelengths at 10 ns. It relaxes about halfway back to the deoxyhemoglobin value by about 100 ns but subsequently changes very slowly out to about 100 microseconds when the signal intensity becomes too small to follow any further. The intensity of this transition, present in only five-coordinate hemes, is found to follow the same time dependence as the wavelength change. Consequently, there appears to be a correlation between a structural property of the heme (as inferred from the wavelength of the charge-transfer transition) and a functional property (the CO recombination) of the protein (as inferred from the intensity of the transition). Possible origins for this correlation are considered.     

Gelation of sickle hemoglobin. III. Nitrosyl hemoglobin.

Sickle cell nitrosyl hemoglobin was examined for gelation by an ultracentrifugal method previously described (Briehl &; Ewert, 1973) and by birefringence. In the presence of inositol hexaphosphate gelation which exhibited the endothermic temperature dependence seen in gels of deoxyhemoglobin S was observed by both techniques. In the absence of inositol hexaphosphate no gelation was observed, nor did nitrosyl hemoglobin A exhibit gelation. On the assumption that gelation is dependent on the deoxy or T (low ligand affinity) as opposed to the oxy or R (high ligand affinity) quaternary structure this supports the conclusion that nitrosyl hemoglobin S in inositol hexaphosphate assumes the T structure, in contrast to the other liganded ferrohemoglobin derivatives oxy and carbon monoxide hemoglobin. Assuming further that the quaternary structures and isomerizations are the same in hemoglobins A and S it can also be concluded that nitrosyl hemoglobin A in inositol hexaphosphate assumes the T state. Since no gelation was seen in stripped nitrosyl hemoglobin S, inositol hexaphosphate serves to effect an R to T switch in this derivative. Thus R-T isomerization in nitrosyl hemoglobin occurs without change in ligand binding at the sixth position of the heme group confirming the conclusion of Salhany (1974) and Salhany et al. (1974).Lowering of the pH toward 6 favors gelation of NO hemoglobin S as it does of deoxy and aquomethemoglobin S (Briehl &; Ewert, 1973,1974), consistent with a favoring of the T structure due to strengthening of the interchain salt bridges and the binding of inositol hexaphosphate and/or changes in site-to-site interactions on which gelation depends.     

The effect of inositol hexaphosphate on the absorption spectra of alpha and beta chains in nitrosyl hemoglobin.

The spectral changes of nitrosyl hemoglobin on addition of inositol hexaphosphate were studied in hybrid-heme hemoglobins. The results showed that the decrease in absorption in the Soret region was mainly due to a spectral change in alpha chains, and that the tension on heme in the quaternary T structure was much stronger in alpha than in beta chains.     

Secondary ion mass spectra of tryptic peptides of human hemoglobin chains

Secondary ion mass spectra of tryptic peptides of human globin alpha-, beta-, gamma and delta-chains were studied. Almost all mass peaks of protonated molecular ions of tryptic peptides were observed and they were very stable and abundant. The present results show the possibilities for quantitative analysis of two gamma-globin species: A gamma and G gamma chains, and for structural analysis of unknown abnormal hemoglobins.     

pH-dependent Soret difference spectra of the deoxy and carbonmonoxy forms of human hemoglobin and its derivatives.

The transition from deoxy to oxystructure of hemoglobin A (Hb) is accompanied by the breaking of the salt bridges formed by C-terminal residues in deoxy-Hb. This, in turn, changes the state of the heme. The switch between these different allosteric forms can be followed by changes in the optical absorbance spectra (Perutz, M. F., Ladner, J. E., Simon, S. R., and Ho, C. (1974), Biochemistry 13, 2163). Using difference spectroscopy in the soret region, pH-dependent spectral changes of Hb and its derivatives (carbamylated at both the alpha-NH2 groups, alpha2cbeta2c; N-ethylsuccinimide hemoglobin, NES-Hb) in their deoxy and carbonmonoxy forms were measured. From these measurements, the pK values of histidine-146beta and valine-1alpha in deoxy-Hb were determined to be 8.6 +/- 0.2 and 7.7 +/- 0.1, respectively. In carbonmonoxy-Hb a pK value of 6.3 +/- 0.1 was found.     

The hemoglobins of Artemia salina. V. Genetic variation in hemoglobin 1, hemoglobin 2, and hemoglobin 3

Electrophoretic mobilities of three hemoglobins (Hb1, Hb2, and Hb3) were studied in 15 populations of brine shrimps. Genetic segregation data support the model that Hb2 contains n -polypeptides and n -polypeptides; Hb1 contains 2n -polypeptides. Hb3 contains neither - nor -polypeptides. There is no evidence of linkage of and loci with each other or with the locus (or loci) which governs Hb3 or with the nonhomologous portion of the sex chromosomes. Hemoglobins of different populations may be hybridized in vitro by incubation at high temperature. Reversible dissociation to subunits which contain only one ( or ) polypeptide occurs at 40 C (for Hb1) and at 50 C (for Hb2).Supported by Grant HD-11445 from the National Institutes of Health.     

Mouse hemoglobin during gestation. Absence of fetal hemoglobin

A "fetal hemoglobin' has been reported to exist during mouse gestation, Investigations using CMC chromatography, starch gel electrophoresis or isoelectric focusing have shown a hemoglobin band from fetal tissues, and blood was obtained which was different from the adult hemoglobin and designated a "fetal hemoglobin'. In the current study isoelectric focusing was used to study the hemoglobins existing in the tissues and blood during fetal and neonatal development and the results suggest there is no "fetal hemoglobin' present during gestation. It appears that the hemoglobin designated as "fetal' in our laboratory was a methemoglobin formed by an incomplete reaction of KCN with the hemoglobin. The additional hemoglobin bands which were obtained from fetal liver or neonatal spleen tissues appeared to be a modified adult hemoglobin.