Jacques Gallay

Relation between membrane phospholipid composition, fluidity and function in mitochondria of rat brown adipose tissue. Effect of thermal adaptation and essential fatty acid deficiency.

Male weanling rats were maintained either at 28 degrees C (thermoneutrality) or at 5 degrees C (cold adaptation). During 9 weeks they were fed either a 2% hydrogenated coconut oil diet deficient in essential fatty acids or a diet containing 2% sunflower oil. The respective incidences of cold adaptation and of EFA deficiency on lipid composition of mitochondrial membranes from brown adipose tissue (BAT) were investigated. Using 1,6 diphenylhexatriene (DPH) as a probe, the parameters of membrane fluidity were estimated by steady-state fluorescence polarization measurements (rs) and by time-resolved fluorescence anisotropy decay (order parameter S). Cold acclimation induced a decrease of phosphatidylcholine to phosphatidylethanolamine (PC/PE ratio), an increase of the total fatty acid unsaturation index (T.U.). EFA deficiency had the same effect as cold on the PC/PE ratio, but decreased T.U. Cold adaptation induced a larger decrease of S than of rs, whereas EFA deficiency only increased rs and did not modify S. In liposomes prepared from mitochondrial lipids, rs values were smaller than in whole mitochondria. Both in cold-adapted and in EFA-deficient rats the variations of rs were correlated with lipid unsaturation. Comparison between BAT thermogenic activity, assessed by GDP binding and proportions of PE and PC showed a high correlation suggesting a change in the membrane occurring with the increase of mitochondrial activity that could be related to phospholipid composition rather than to membrane fluidity.

Alcohol abuse increases the lipid structural order in human erythrocyte membranes: A steady-state and time-resolved anisotropy study

The effect of ethanol abuse on the lipid ordering of the human erythrocyte membranes was studied by steady-state and time-resolved fluorescence anisotropy measurements of DPH and its polar analogue TMA-DPH, which probe different membrane regions. Steady-state anisotropy values with DPH as a probe were slightly but significantly increased (+3%) in erythrocyte membranes from alcoholic patients. A resistance to the ethanol fluidizing effect was evidenced in these membranes with DPH and TMA-DPH. No difference in the probe lifetimes was detected between the control and the alcoholic subjects. In the alcoholic patients as compared to the healthy controls, the residual anisotropy for DPH was significantly increased (+7%) corresponding to an increase in the orientational order parameter of 4%; a decrease of the apparent correlation time value was also observed. Nevertheless, no differences between the two erythrocyte populations were observed with TMA-DPH.

Origin of laurdan sensitivity to the vesicle-to-micelle transition of phospholipid-octylglucoside system: a time-resolved fluorescence study.

The fluorescent probe laurdan has been shown to be sensitive to the vesicle-to-micelle transition of phosphatidylcholine/octylglucoside (M. Paternostre, O. Meyer, C. Grabielle-Madelmont, S. Lesieur, and, Biophys. J. 69:2476-2488). On the other hand, a study on the photophysics of laurdan in organic solvents has shown that the complex de-excitation pathway of the probe can be described by two successive processes, i.e., an intramolecular charge transfer followed by dielectric relaxation of the solvent if polar. These two excited-state reactions lead to three emitting states, i.e., a locally excited state, a charge transfer state, and a solvent relaxed state (M. Viard, J. Gallay, M. Vincent, B. Robert and, Biophys. J. 73:2221-2234). Experiments have been performed using time-resolved fluorescence on the probe inserted in amphiphile aggregates (mixed liposomes, mixed micelles) different in detergent-to-lipid ratios. The results have been compared with those obtained for laurdan inserted in dipalmitoyl phosphatidylcholine liposomes in the gel and in the fluid lamellar phase. Except for laurdan in dipalmitoyl phosphatidylcholine liposomes in the gel lamellar phase, the red part of the emission spectra originates from the de-excitation of the relaxed excited state of laurdan, indicating that indeed the dielectric relaxation process is an important phenomena in the ground-state return pathway of this probe. On the other hand, the maximization entropy method (MEM) analysis of the fluorescence decay recorded in the blue part of the emission spectra indicates that the dielectric relaxation is not the only reaction occurring to the excited state of laurdan. Moreover, the analysis of the fluorescence decays of laurdan inserted in gel lamellar dipalmitoylphosphatidylcholine (DPPC) liposomes indicates excited-state reactions, although dielectric relaxation is impossible. These results are in agreement with the de-excitation pathway determined from laurdan behavior in organic solvent even if, in most of the aggregates studied in this work, the major phenomenon is the dielectric relaxation of the solvent. All along the vesicle-to-micelle transition, we have observed that the lifetime of the relaxed excited state of laurdan continuously decreases probably due to a dynamic quenching process by water molecules. On the other hand, the time constant of the dielectric relaxation process remains almost unchanged in the lamellar part of the transition but abruptly decreases as soon as the first mixed micelle is formed. This decrease is continuous all over the rest of the transition even if it is more pronounced in the mixed liposomes and mixed micelles coexistence. The increase of the octylglucoside-to-lipid ratio of the mixed micelles via the change of the size and the shape of the aggregates may facilitate the penetration and the mobility of water molecules. Therefore, during the vesicle-to-micelle transition, laurdan probes the evolution of both the amphiphile packing in the aggregates and the increase of the interface polarity. This study finally shows that the detergent-to-lipid ratio of the mixed micelles is an important parameter to control to limit the penetration and the mobility of water within the amphiphile aggregates and that laurdan is a nice tool to monitor this phenomenon.

Tryptophan Octyl Ester in Detergent Micelles of Dodecylmaltoside: Fluorescence Properties and Quenching by Brominated Detergent Analogs

The fluorescence properties of tryptophan octyl ester (TOE), a hydrophobic model of Trp in proteins, were investigated in various mixed micelles of dodecylmaltoside (DM) and 7,8-dibromododecyl beta-maltoside (BrDM) or 10,11-dibromoundecanoyl beta-maltoside (BrUM). This study focuses on the mechanism via which these brominated detergents quench the fluorescence of TOE in a micellar system. The experiments were performed at a pH at which TOE is uncharged and almost completely bound to detergent micelles. TOE binding was monitored by its enhanced fluorescence in pure DM micelles or its quenched fluorescence in pure BrUM or BrDM micelles. In DM/BrUM and DM/BrDM mixed micelles, the fluorescence intensity of TOE decreased, as a nonlinear function of the molar fraction of brominated detergent, to almost zero in pure brominated detergent. The indole moiety of TOE is therefore highly accessible to the bromine atoms located on the detergent alkyl chain because quenching by bromines occurs by direct contact with the fluorophore. TOE is simultaneously poorly accessible to iodide (I(-)), a water-soluble collisional quencher. TOE time-resolved fluorescence intensity decay is heterogeneous in pure DM micelles, with four lifetimes (from 0.2 to 4.4 ns) at the maximum emission wavelength. Such heterogeneity may arise from dipolar relaxation processes in a motionally restricted medium, as suggested by the time-dependent (nanoseconds) red shift (11 nm) of the TOE emission spectrum, and from the existence of various TOE conformations. Time-resolved quenching experiments for TOE in mixed micelles showed that the excited-state lifetime values decreased only slightly with increases in the proportion of BrDM or BrUM. In contrast, the relative amplitude of the component with the longest lifetime decreased significantly relative to that of the short-lived species. This is consistent with a mainly static mechanism for the quenching of TOE by brominated detergents. Molecular modeling of TOE (in vacuum and in water) suggested that the indole ring was stabilized by folding back upon the octyl chain, forming a hairpin conformation. Within micelles, the presence of such folded conformations, making it possible for the entire molecule to be located in the hydrophobic part of the micelle, is consistent with the results of fluorescence quenching experiments. TOE rotational correlation time values, in the nanosecond range, were consistent with a hindered rotation of the indole moiety and a rotation of the complete TOE molecule in the pure DM or mixed detergent micelles. These results, obtained with a simple micellar model system, provide a basis for the interpretation of fluorescence quenching by brominated detergents in more complex systems such as protein- or peptide-detergent complexes.

Single-spanning membrane protein insertion in membrane mimetic systems: role and localization of aromatic residues

Membrane protein insertion in the lipid bilayer is determining for their activity and is governed by various factors such as specific sequence motifs or key amino-acids. A detailed fluorescence study of such factors is exemplified with PMP1, a small (38 residues) single-membrane span protein that regulates the plasma membrane H+-ATPase in yeast and specifically interacts with phosphatidylserines. Such interactions may stabilize raft domains that have been shown to contain H+-ATPase. Previous NMR studies of various fragments have focused on the critical role of interfacial residues in the PMP1 structure and intermolecular interactions. The C-terminal domain contains a terminal Phe (F38), a single Trp (W28) and a single Tyr (Y25) that may act together to anchor the protein in the membrane. In order to describe the location and dynamics of W28 and the influence of Y25 on protein insertion within membrane, we carried out a detailed steady-state and time-resolved fluorescence study of the synthetic G13-F38 fragment and its Tyr-less mutant, Y25L in various membrane mimetic systems. Detergent micelles are conveniently used for this purpose. We used dodecylphosphocholine (DPC) in order to compare with and complement previous NMR results. In addition, dodecylmaltoside (DM) was used so that we could apply our recently described new quenching method by two brominated analogs of DM (de Foresta et al. 2002, Eur. Biophys. J. 31:185–97). In both systems, and in the presence and absence of Y25, W28 was shown to be located below but close to the polar headgroup region, as shown by its maximum emission wavelengths (λmax), curves for the quenching of Trp by the brominated analogs of DM and bimolecular constants for quenching (kq) by acrylamide. Results were interpreted by comparison with calibration data obtained with fluorescent model peptides. Time-resolved anisotropy measurements were consistent with PMP1 fragment immobilization within peptide-detergent complexes. We tentatively assigned the two major Trp lifetimes to the Trp (χ1=60° and 180°) rotamers, based on the recent lifetime–rotamer correlation proposed for model cyclic peptides (Pan and Barkley 2004, Biophys J 86:3828–35). We also analyzed the role of the hydrophobic anchor, by comparing the micelle binding of fragments of various lengths including the synthesized full-length protein and detected peculiar differences for protein interaction with the polar headgroups of DM or DPC.

A S‐adenosylmethionine methyltransferase‐like domain within the essential, Fe‐S‐containing yeast protein Dre2

Yeast Dre2 is an essential Fe‐S cluster‐containing protein that has been implicated in cytosolic Fe‐S protein biogenesis and in cell death regulation in response to oxidative stress. Its absence in yeast can be complemented by the human homologous antiapoptotic protein cytokine‐induced apoptosis inhibitor 1 (also known as anamorsin), suggesting at least one common function. Using complementary techniques, we have investigated the biochemical and biophysical properties of Dre2. We show that it contains an N‐terminal domain whose structure in solution consists of a stable well‐structured monomer with an overall typical S‐adenosylmethionine methyltransferase fold lacking two α‐helices and a β‐strand. The highly conserved C‐terminus of Dre2, containing two Fe‐S clusters, influences the flexibility of the N‐terminal domain. We discuss the hypotheses that the activity of the N‐terminal domain could be modulated by the redox activity of Fe‐S clusters containing the C‐terminus domain inu2003vivo.

Structural and dynamic properties of juxta-membrane segments of caveolin-1 and caveolin-2 at the membrane interface

Caveolins (cav1–3) are essential membrane proteins found in caveolae. The caveolin scaffolding domain of cav-1 includes a short sequence containing a CRAC motif (V94TKYWFYR101) at its C-terminal end. To investigate the role of this motif in the caveolin–membrane interaction at the atomic level, we performed a detailed structural and dynamics characterization of a cav-1(V94-L102) nonapeptide encompassing this motif and including the first residue of cav-1 hydrophobic domain (L102), in dodecylmaltoside (DM) or dodecylphosphocholine (DPC) micelles, as membrane mimics. Cav-1(V94-L102) partitioned better in DPC and in DM/anionic lipid micelles than in DM micelles, as shown by fluorescence titration and CD. NMR data revealed that this peptide folded as an amphipathic helix located in the polar head group region of DPC micelles. The two tyrosine side-chains, flanked by arginine and lysine residues, are situated on one face of this helix, whereas the phenylalanine and tryptophan side-chains are located on the opposite face. Fluorescence studies showed significant Trp subnanosecond rotations, the presence of several rotamers, and a heterogeneous location within the water/micelle interface. NMR studies of the shorter cav-1(V94-R101) peptide and of the homologous sequence of cav-2(I79SKYVMYKF87) allowed the description of the effect of L102 and of the amino acid variations occurring in cav-2 on the structure and localization in DPC micelles. Based on the topological model of caveolins, our results suggest that the cav-1 and cav-2 nonapeptides studied form interfacial α-helix membrane anchors in which the K/RhhhYK/Rh motif, also found in cav-3, may play a significant role.

The polar headgroup of the detergent governs the accessibility to water of tryptophan octyl ester in host micelles

Many attempts have been made to rationalize the use of detergents for membrane protein studies [J. Biol. Chem. 264 (1989) 4907]. The barrier properties of the detergent headgroup may be one parameter critically involved in protein protection. In this paper, we analyzed these properties using a model system, by comparing the accessibility of tryptophan octyl ester (TOE) to water-soluble collisional quenchers (iodide and acrylamide) in three detergent micelles. The detergents used differed only in the chemical nature of their polar headgroups, zwitterionic for dodecylphosphocholine (DPC) and nonionic for octa(ethylene glycol) dodecyl monoether (C(12)E(8)) and dodecylmaltoside (DM). In all cases, in phosphate buffer at pH 7.5, the binding of 5 microM TOE was complete in the presence of a slight excess of detergent micelles over TOE molecules, resulting in a significant blue shift and greater intensity of TOE fluorescence emission. The resulting quantum yield of bound TOE was between 0.08 (in DPC) and 0.12 (in DM) with an emission maximum (lambda(max)) of approximately 335 nm whatever the detergent micelle. Time-resolved fluorescence intensity decays of TOE at lambda(max) were heterogeneous in all micelles (3-4 lifetime populations), with mean lifetimes of 1.7 ns in DPC, and 2 ns in both C(12)E(8) and DM. TOE fluorescence quenching by iodide, in detergent micelles, yielded linear Stern-Volmer plots characteristic of a dynamic quenching process. The accessibility of TOE to this ion was the greatest with C(12)E(8), followed by DPC and finally DM (Stern-Volmer quenching constants K(sv) of 2 to 5.5 M(-1)). In contrast, the accessibility of TOE to acrylamide was greatest with DPC, followed by C(12)E(8) and finally DM (K(sv)=2.7-7.1 M(-1)). TOE also presents less rotational mobility in DM than in the other two detergents, as shown from anisotropy decay measurements. These results, together with previous TOE quenching measurements with brominated detergents [Biophys. J. 77 (1999) 3071] provide reference data for analyzing Trp characteristics in peptide (and more indirectly protein)-detergent complexes. The main finding of this study was that TOE was less accessible (to soluble quenchers) in DM than in DPC and C(12)E(8), the cohesion of DM headgroup region being suggested to play a role in the ability of this detergent to protect function and stability of solubilized membrane proteins.

TIME RESOLVED FLUORESCENCE PROPERTIES OF PHENYLALANINE IN DIFFERENT ENVIRONMENTS. COMPARISON WITH MOLECULAR DYNAMICS SIMULATION

Time resolved fluorescence of the phenylalanine residue (Phe) alone and included in the transmembrane domain (TMD) sequences of the epidermal growth factor receptor (EGFR) and ErbB-2 was studied using the synchrotron radiation source of light, and compared to molecular dynamics (MD) simulations. The fluorescence intensity decay is strongly sensitive to the environment. A mono-exponential decay was obtained for Phe amino acid alone in two different solvents and for Phe included in EGFR transmembrane sequence, with fluorescence lifetime values varying from 1.7 ns (EGFR) to 7.4 ns (Phe dissolved in water). In ErbB-2 transmembrane sequence three lifetimes were detected. The relative amplitude of the shortest one (0.14 ns) is smaller than 10%, whereas the others (0.6 and 2.2 ns) are almost equally represented. They have been attributed to different rotamers exchanging slowly. This interpretation is supported by MD simulations which evidence transitions in time series of the chi 1 dihedral angle of Phe observed in the case of ErbB-2. The anisotropy decays are similar for both peptides and indicate the presence of a correlation time in the nanosecond range (1-4 ns) and the probable existence of a very fast one (< 0.05 ns). Autocorrelation functions computed from MD simulations corroborate these results.

Molecular radiative transport. III. Experimental intensity decays

A critical experimental test of a previously developed theory of molecular radiative transport is described. It is concluded that the theory gives an accurate description of the effect of radiative transport on fluorescence observables. The numerical coefficients of the fluorescence decay are computed from a Monte Carlo integration procedure that mimics the photon trajectories inside a realistic sample cell, and is carried out only using known molecular and geometrical parameters. The predicted parameters are confronted with the experimental observables accessible in a typical single-photon timing experiment, rhodamine 101 in ethanol being the system studied. The theoretical predictions quantitatively describe the effects of concentration and excitation and emission wavelengths experimentally observed in optical dense nondiffusing media for the two most common geometric arrangements: front-face and right-angle detection. It is shown that radiative transport leads to spatially heterogeneous fluorescence ki...