SummaryThe entry of a water molecule into the distal heme pocket of pentacoordinate heme proteins such as myoglobin and the α,β chains of hemoglobin can be detected by time-resolved spectroscopy in the heme visible bands after photolysis of the CO complex. Reviewing the evidence from spectrokinetic studies of Mb variants, we find that this optical method measures the occupancy of non(heme)coordinated water in the distal pocket, n w , with high fidelity. This evidence further suggests that perturbation of the kinetic barrier presented by distal pocket water is often the dominant mechanism by which active site mutations affect the bimolecular rate constant for CO binding. Water entry into the heme pockets of isolated hemoglobin subunits was detected by optical methods. Internal hydration is higher in the native α chains than in the β chains, in agreement with previous crystallographic results for the subunits within Hb tetramers. The kinetic parameters obtained from modeling of the water entry and ligand rebinding in Mb mutants and native Hb chains are consistent with an inverse dependence of the bimolecular association rate constant on the water occupancy factor. This correlation suggests that water and ligand mutually exclude one another from the distal pockets of both types of hemoglobin chains and myoglobin..
Raman spectroscopy is a form of vibrational spectroscopy based on inelastic scattering of light. In resonance Raman spectroscopy, the wavelength of the incident light falls within an absorption band of a chromophore, and this overlap of excitation and absorption energy greatly enhances the Raman scattering efficiency of the absorbing species. The ability to probe vibrational spectra of select chromophores within a complex mixture of molecules makes resonance Raman spectroscopy an excellent tool for studies of biomolecules. In this Current Topic, we discuss the type of molecular insights obtained from steady-state and time-resolved resonance Raman studies of a prototypical photoactive protein, rhodopsin. We also review recent efforts in ultraviolet resonance Raman investigations of soluble and membrane-associated biomolecules, including integral membrane proteins and antimicrobial peptides. These examples illustrate that resonance Raman is a sensitive, selective, and practical method for studying the structures of biological molecules, and the molecular bonding, geometry, and environments of protein cofactors, the backbone, and side chains.
The protein, azurin, has enabled the study of the tryptophan radical. Upon UV excitation of tyrosine-deficient apoazurin and in the presence of a Co(III) electron acceptor, the neutral radical (W48•) is formed. The lifetime of W48• in apoazurin is 41 s, which is shorter than the lifetime of several hours in Zn-substituted azurin. Molecular dynamics simulations revealed enhanced fluctuations of apoazurin which likely destabilize W48•. The photophysics of W48 was investigated to probe the precursor state for ET. The phosphorescence intensity was eliminated in the presence of an electron acceptor while the fluorescence was unchanged; this quenching of the phosphorescence is attributed to ET. The kinetics associated with W48• were examined with a model that incorporates intersystem crossing, ET, deprotonation, and decay of the cation radical. The estimated rate constants for ET (6 × 10 6 s –1 ) and deprotonation (3 × 10 5 s –1 ) are in agreement with a photoinduced mechanism where W48• is derived from the triplet state. The triplet as the precursor state for ET was supported by photolysis of apoazurin with 280 nm in the absence and presence of triplet-absorbing 405 nm light. Absorption bands from the neutral radical were observed only in the presence of blue light.
Applications of fluorescence spectroscopy to biomolecules, with focus on membrane proteins, are discussed in this article. A broad range of molecular insights can be gained with this simple technique because the emission properties of a chromophore are typically sensitive to the environment. The intensities and maximum wavelengths of steady‐state fluorescence spectra are used to elucidate the thermodynamics of membrane protein folding, monitor the extent of solvent exposure of chromophores, determine the depths of insertion into synthetic bilayers, probe the degree of rotational freedom in solvent‐exposed and buried regions, and measure the evolution of distances between donor and acceptor moieties. We also address some of the challenges associated with fluorescence measurements of integral membrane proteins. An important goal is to provide a practical guide for laboratory measurements as well as examples of analyses related to membrane protein structure and dynamics.
The folding reaction of a β-barrel membrane protein, Outer Membrane Protein A (OmpA), is probed with Förster resonance energy transfer (FRET) experiments. Four mutants of OmpA were generated in which the donor fluorophore, tryptophan, and acceptor molecule, 1,5-IAEDANS, are placed in various locations on the protein to report the evolution of distances across the bilayer and across the protein pore during a folding event. Analysis of the FRET efficiencies reveals three timescales for tertiary structure changes associated with insertion and folding into a synthetic bilayer. A narrow pore forms during the initial stage of insertion, followed by bilayer traversal. Finally, a long-time component is attributed to equilibration and relaxation, and may involve global changes such as pore expansion and strand extension. These results augment the existing models that describe concerted insertion and folding events, and highlight the ability of FRET to provide insight into the complex mechanisms of membrane protein folding.
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