Absorption and resonance Raman spectra using Soret excitation of alkaline metmyoglobin (metMb), methemoglobin (metHb), and horseradish peroxidase (HRP) were obtained at room and low temperature. At 298 K both metMb and metHb exhibit two isotope-sensitive bands assigned to high- and low-spin nu(Fe-OH) stretching modes, respectively, which are correlated with the spin-state population. The low-spin stretch occurs 60 cm-1 to higher energy than the corresponding high-spin vibration. When the temperature is lowered, only the low-spin species is observed. HRP exhibits at both 298 and 20 K only the low-spin nu(Fe-OH) stretching mode, which occurs 50 cm-1 to lower energy than the corresponding modes observed in the globins. This is explained in the context of a strong hydrogen bond between the hydroxyl ligand and the distal His42 and/or Arg38. Lowering temperature causes in all of the examined proteins a strengthening of the Fe-OH bond and a contraction of the core of about 0.01 A, as determined by the upshifting of the low-spin nu(Fe-OH) stretching mode and the core size marker bands. Both effects are ascribed to an increase of the packing forces.
The complexes of horse myoglobin (Mb) with the anionic surfactant sodium dodecyl sulfate (SDS), and with the cationic surfactants cetyltrimethylammonium chloride (CTAC) and decyltrimethylammonium bromide (DeTAB), have been studied by a combination of surface tension measurements and optical spectroscopy, including heme absorption and aromatic amino acid fluorescence. SDS interacts in a monomeric form with Mb, which suggests the existence of a specific binding site for SDS, and induces the formation of a hexacoordinated Mb heme, possibly involving the distal histidine. Fluorescence spectra display an increase of tryptophan emission. Both effects point to an increased protein flexibility. SDS micelles induce both the appearance of two more heme species, one of which has the features of free heme, and protein unfolding. Mb/CTAC complexes display a very different behavior. CTAC monomers have no effect on the absorption spectra, and only a slight effect on the fluorescence spectra, whereas the formation of CTAC aggregates on the protein strongly affects both absorption and fluorescence. Mb/DeTAB complexes behave in a very similar way as Mb/CTAC complexes. The surface activity of the different Mb/surfactant complexes, as well as the interactions between the surfactants and Mb, are discussed on the basis of their structural properties.
The nonsymbiotic hemoglobins, AHb1 and AHb2, have recently been isolated from Arabidopsis thaliana. Using steady-state and time-resolved spectroscopic methods, we show that Fe2+ AHb1 contains a mixture of penta- and hexacoordinated heme, while Fe2+ AHb2 is fully hexacoordinated. In the CO complexes, polar interactions and H-bonds with the ligand are stronger for AHb1 than for AHb2. The ligand binding kinetics are substantially different, reflecting the distribution between the penta- and hexacoordinated species, and indicate that protein dynamics and ligand migration pathways are very specific for each of the two proteins. In particular, a very small, non-exponential geminate rebinding observed in AHb1 suggests that the distal heme cavity is connected with the exterior by a relatively open channel. The large, temperature-dependent geminate rebinding observed for AHb2 implies a major role of protein dynamics in the ligand migration from the distal cavity to the solvent. The structures of AHb1 and AHb2, modeled on the basis of the homologous rice hemoglobin, exhibit a different cavity system that is fully compatible with the observed ligand binding kinetics. Overall, these kinetic and structural data are consistent with the putative NO-dioxygenase activity previously attributed to AHb1, whereas the role of AHb2 remains elusive.
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