Librational motion of an "immobilized" spin label: hemoglobin spin labeled by a maleimide derivative.

The spin label Tempo-maleimide, when "immobilized" in hemoglobin, is shown to exhibit motional fluctuation whose amplitude and/or frequency depend on temperature and solution conditions. These motional fluctuations are observable by several electron spin resonance techniques. For desalted hemoglobin the fluctuations are detectable at approximately -15 degrees C using saturation transfer techniques and at approximately +25 degrees C using line-width measurements of normal absorption spectra. In ammonium sulfate precipitated hemoglobin, however, motional fluctuations are not detectable by either technique up to at least 40 degrees C. The most probable mechanism for spin-label motion appears to be either fluctuations in protein conformation which affect the label binding site or conformational transitions of the nitroxide ring itself. These motional fluctuations are shown to introduce a librational character to the overall label motion during hemoglobin rotational diffusion, with the librational motion significantly affecting the use of spin-label spectral shapes to calculate hemoglobin rotational correlation times.     

Analysis of mobility of protein side chains by spin label technique

Five spin labeled derivatives of a neurotoxin from cobra venom were analyzed by the earlier suggested method. The procedure was adjusted to the complex motional behaviour of the label. Each protein derivative carried covalently bound spin label on different lysine residues. In two derivatives, at positions Lys44 and Lys46, the labels were strongly mobile, whereas for other three derivatives modified at Lys15, Lys25 and Lys26 the label was less mobile with respect to the protein molecule, which made possible determination of the rotational correlation time of the protein molecule (2.8±0.3 ns). The rotational correlation time was in good agreement with the calculated value for the rigid sphere of the corresponding molecular weight. On the basis of the estimate of the anisotropic motion degree, it was found from the order parameter S that the label mobility increases in the following series of lysine residues: Lys26, Lys25, Lys15, Lys46, and Lys44. From the analysis of positions of outer wide peaks in ESR spectra obtained by varying temperature and viscosity of the medium, we determined the parameters for computer simulation. The theoretical and experimental spectra were found to be in good agreement.Nomenclature rotational correlation time of the protein molecule - _l rotational correlation time of the spin label - 2A _Z , 2A the rigid limit distance between OWP and IWP, respectively, for ESR spectra of spin labeled proteins - 2, 2 the averaged limit distance between the OWP and IWP correspondingly mobile spin label to respect of protein moiety with; = - 2A',2A distance between OWP and IWP in the ESR spectra of spin labeled proteins for any T and media Abbreviations SL spin label - NT neurotoxin II from cobra venom - NT-SL-Lys44 neurotoxin spin labeled at Lys44 residue - OWP outer wide peaks in the immobilized ESR spectra - IWP inner wide peaks in the immobilized ESR spectra - WL the residual linewidth     

Characterization of sulphydryl groups of the mitochondrial phosphate translocator by a maleimide spin label

A maleimide spin label strongly inhibits the phosphate/H+ symporter of rat liver mitochondria. While inducing half-maximal inhibition of transport, the spin label reacts preferentially with the SH groups of the carrier, which are at least of two types. One type of SH group is localized close to the surface of the membrane and its environment does not significantly influence the mobility of the probe. The second type of SH group is buried in the membrane, is not accessible to ascorbate or chromium oxalate and its environment greatly restricts the motion of the probe.     

Lipid chain dynamics in stratum corneum studied by spin label electron paramagnetic resonance

The lipid chain motions in stratum corneum (SC) membranes have been studied through electron paramagnetic resonance (EPR) spectroscopy of stearic acid spin-labeled at the 5th, 12th and 16th carbon atom positions of the acyl chain. Lipids have been extracted from SC with a series of chloroform/methanol mixtures, in order to compare the molecular dynamics and the thermotropic behavior in intact SC, lipid-depleted SC (containing covalently bound lipids of the corneocyte envelope) and dispersion of extracted SC lipids. The segmental motion of 5- and 12-doxylstearic acid (5- and 12-DSA) and the rotational correlation time of 16-doxylstearic acid (16-DSA) showed that the envelope lipids are more rigid and the extracted lipids are more fluid than the lipids of the intact SC over the range of temperature measured. The lower fluidity observed for the corneocyte envelope, that may be caused mainly due to lipid-protein interactions, suggests a major contribution of this lipid domain to the barrier function of SC. Changes in the activation energy for reorientational diffusion of the 16-DSA spin label showed apparent phase transitions around 54 degrees C, for the three SC samples. Some lipid reorganization may occur in SC above 54 degrees C, in agreement with results reported from studies with several other techniques. This reorganization is sensitive to the presence of the extractable intercellular lipids, being different in the lipid-depleted sample as compared to native SC and lipid dispersion. The results contribute to the understanding of alkyl chain packing and mobility in the SC membranes, which are involved in the mechanisms that control the permeability of different compounds through skin, suggesting an important involvement of the envelope in the skin barrier.     

Stratum corneum hydration: phase transformations and mobility in stratum corneum, extracted lipids and isolated corneocytes

The outermost layer of skin, stratum corneum (SC), functions as the major barrier to diffusion. SC has the architecture of dead keratin filled cells embedded in a lipid matrix. This work presents a detailed study of the hydration process in extracted SC lipids, isolated corneocytes and intact SC. Using isothermal sorption microcalorimetry and relaxation and wideline (1)H NMR, we study these systems at varying degrees of hydration/relative humidities (RH) at 25 degrees C. The basic findings are (i) there is a substantial swelling both of SC lipids, the corneocytes and the intact SC at high RH. At low RHs corneocytes take up more water than SC lipids do, while at high RHs swelling of SC lipids is more pronounced than that of corneocytes. (ii) Lipids in a fluid state are present in both extracted SC lipids and in the intact SC. (iii) The fraction of fluid lipids is lower at 1.4% water content than at 15% but remains virtually constant as the water content is further increased. (iv) Three exothermic phase transitions are detected in the SC lipids at RH=91-94%, and we speculate that the lipid re-organization is responsible for the hydration-induced variations in SC permeability. (v) The hydration causes swelling in the corneocytes, while it does not affect the mobility of solid components (keratin filaments).     

Stratum corneum hydration: Phase transformations and mobility in stratum corneum, extracted lipids and isolated corneocytes

The outermost layer of skin, stratum corneum (SC), functions as the major barrier to diffusion. SC has the architecture of dead keratin filled cells embedded in a lipid matrix. This work presents a detailed study of the hydration process in extracted SC lipids, isolated corneocytes and intact SC. Using isothermal sorption microcalorimetry and relaxation and wideline ¹H NMR, we study these systems at varying degrees of hydration/relative humidities (RH) at 25 °C. The basic findings are (i) there is a substantial swelling both of SC lipids, the corneocytes and the intact SC at high RH. At low RHs corneocytes take up more water than SC lipids do, while at high RHs swelling of SC lipids is more pronounced than that of corneocytes. (ii) Lipids in a fluid state are present in both extracted SC lipids and in the intact SC. (iii) The fraction of fluid lipids is lower at 1.4% water content than at 15% but remains virtually constant as the water content is further increased. (iv) Three exothermic phase transitions are detected in the SC lipids at RH = 91-94%, and we speculate that the lipid re-organization is responsible for the hydration-induced variations in SC permeability. (v) The hydration causes swelling in the corneocytes, while it does not affect the mobility of solid components (keratin filaments).     

Studies of the mobility of maleimide spin labels within the erythrocyte membrane

We have confirmed a method yielding reproducible and reliable spectrometric parameters derived from spin-labeled erythrocyte ghosts using nitroxide derivatives of maleimide compounds. The disorder parameter, W/S, was shown to vary with changes in the structure of the label, the conditions utilized for labeling such as ionic strength and erythrocyte age and the presence of drugs such as alcohol and acetaminophen. The nitroxide spectrum was also found to change with increasing and decreasing temperature in an irreversible manner. These findings should permit increased reliance to be placed on the spin-labeling technique when used to monitor changes in membrane lipid or protein assembly.     

Characterization of protein spin labeling by maleimide: evidence for nitroxide reduction

A quantitative determination of maleimide spin label (MAL) binding in oxi and met hemoglobin (Hb) and bovine serum albumin are investigated using double integration to the ESR signal. This determination permitted the observation that a considerable fraction of MAL is reduced, losing its paramagnetism. Experiments using the same spin label with myoglobin and Hb with blocked-SH groups, where reduction was not observed, indicate the involvement of SH groups in the process. The 4-hydroxy-2,2,6,6-tetramethylpiperidino-1-oxyl spin label (which is not able to bind in the SH group) is reduced too, but the dependence on the molar ratio is different in comparison with the MAL case. In both cases the reduction percentage depends on the molar ratio spin label to protein and to the protein concentration. In order to obtain the total SH groups labeled (two in the Hb case) it is necessary to use an excessive amount of label (around 18:1) in the 0.5 mM Hb concentration.     

The contact sites of sickle hemoglobin as seen by spin probe-spin label techniques

The spin-labeled tryptophan (TrpSL) was used as a structural probe of hemoglobin (Hb) contact sites. The electron paramagnetic resonance spectral data indicated that the probe exhibits weak binding to Hb with a dissociation constant of 3.2 x 10(-5) and 4.0 mol bound per Hb tetramer. The spectrum suggested that the bound tryptophan was 'partially immobilized' with a correlation time reflecting the environment of the tryptophan binding site of 8.5 s. The topology of the contact sites was investigated by using a dual spin label methodology in which TrpSL and 2H-15N covalently bound to B 93 cysteine residue were used. The electron spin resonance spectral data suggested that the tryptophan binding sites were located within 8-10 A of the nitroxide free radical of spin-labeled Hb. The environment of the contact sites is discussed.     

Selective labeling of membrane protein sulfhydryl groups with methanethiosulfonate spin label

Electron paramagnetic resonance was used to characterize the first use of a thiol-specific spin label in membranes. Procedures for use of the spin-label, 1-oxyl-2,2,5,5-tetramethyl-Δ³-pyrroline-3-methyl (methanethiosulfonate MTS) covalently attached to membrane proteins in human erythrocyte membranes are reported. The major findings are: (1) MTS was found to be thiol-specific in membranes as it is for soluble proteins; (2) MTS labels ghost proteins in as few as 30 min at room temperature, providing a distinct advantage when sensitive or fragile membranes are to be used; (3) the distribution of the spin label suggests that the major cytoskeletal protein, spectrin, and the major transmembrane protein (Band 3) incorporate the highest percentage of spin label. This procedure expands the tools with which the researcher can investigate the physical state of membrane proteins and its alteration upon interaction of membrane perturbants or in pathological conditions.     

Translational diffusion of lipid monomers determined by spin label electron spin resonance

The collision rates between spin-labelled valeric acid in water, and between the corresponding mixed-chain, spin-labelled phosphatidylcholine in water-methanol mixtures, and also between spin-labelled phosphatidylcholine monomers and micelles in water have been determined from the spin-spin broadening of the electron spin resonance spectrum. In each case the second order rate constants are consistent with a diffusion-controlled process. For spin-labelled valeric acid in water the translational diffusion coefficient at 20°C is 3.4 · 10⁻⁶ cm² · s⁻¹, and for spin-labelled phosphatidylcholine varies between 2.3 · 10⁻⁶ and 3.8 · 10⁻⁶ cm² · s⁻¹ within the range 44 to 88 wt% methanol. The spin-labelled phosphatidylcholine monomer diffusion coefficient in water at 20°C is 2.4 · 10⁻⁶ cm² · s⁻¹, deduced from the monomer-micelle association rate, with an activation energy of 4.0 kcal · mol⁻¹. The much slower on-rates for association of lipid monomers with phospholipid bilayer vesicles reported in the literature, therefore indicate that incorporation into bilayers is not a diffusion-controlled process.