Phosphatydylglycerol promotes bilayer insertion of salmon calcitonin.

Neutron diffraction from oriented multibilayers has been used to study the bilayer interaction of the amphipathic peptide salmon calcitonin. Penetration of calcitonin into bilayers composed of dioleoylphosphatidylcholine increases with the addition of 15% (mol) of the anionic phospholipid dioleoylphosphatidylglycerol. Neutron scattering profiles of water distribution in stacked bilayers show a continuous band of deuterons across each bilayer, consistent with the suggestion that the hormone forms transbilayer alpha-helixes under these conditions. These experiments add to the growing body of data on the role of phosphatidylglycerol in bilayer insertion of protein helices and suggests a possible evolutionary history for calcitonin.     

Helix tilt of the M2 transmembrane peptide from influenza A virus: an intrinsic property

Solid-state NMR has been used to study the influence of lipid bilayer hydrophobic thickness on the tilt of a peptide (M2-TMP) representing the transmembrane portion of the M2 protein from influenza A. Using anisotropic (15)N chemical shifts as orientational constraints, single-site isotopically labeled M2-TMPs were studied in hydrated dioleoylphosphatidylcholine (DOPC) and dimyristoylphosphatidylcholine (DMPC) lipid bilayers oriented between thin glass plates. These chemical shifts provide orientational information for the molecular frame with respect to the magnetic field in the laboratory frame. When modeled as a uniform ideal alpha-helix, M2-TMP has a tilt of 37(+/-3) degrees in DMPC and 33(+/-3) degrees in DOPC with respect to the bilayer normal in these lipid environments. The difference in helix tilt between the two environments appears to be small. This lack of a substantial change in tilt further suggests that significant interactions occur between the helices, as in an oligomeric state, to prevent a change in tilt in thicker lipid bilayers.     

Three-dimensional structure of the transmembrane domain of Vpu from HIV-1 in aligned phospholipid bicelles

The three-dimensional backbone structure of the transmembrane domain of Vpu from HIV-1 was determined by solid-state NMR spectroscopy in two magnetically-aligned phospholipid bilayer environments (bicelles) that differed in their hydrophobic thickness. Isotopically labeled samples of Vpu(2-30+), a 36-residue polypeptide containing residues 2-30 from the N-terminus of Vpu, were incorporated into large (q = 3.2 or 3.0) phospholipid bicelles composed of long-chain ether-linked lipids (14-O-PC or 16-O-PC) and short-chain lipids (6-O-PC). The protein-containing bicelles are aligned in the static magnetic field of the NMR spectrometer. Wheel-like patterns of resonances characteristic of tilted transmembrane helices were observed in two-dimensional (1)H/(15)N PISEMA spectra of uniformly (15)N-labeled Vpu(2-30+) obtained on bicelle samples with their bilayer normals aligned perpendicular or parallel to the direction of the magnetic field. The NMR experiments were performed at a (1)H resonance frequency of 900 MHz, and this resulted in improved data compared to lower-resonance frequencies. Analysis of the polarity-index slant-angle wheels and dipolar waves demonstrates the presence of a transmembrane alpha-helix spanning residues 8-25 in both 14-O-PC and 16-O-PC bicelles, which is consistent with results obtained previously in micelles by solution NMR and mechanically aligned lipid bilayers by solid-state NMR. The three-dimensional backbone structures were obtained by structural fitting to the orientation-dependent (15)N chemical shift and (1)H-(15)N dipolar coupling frequencies. Tilt angles of 30 degrees and 21 degrees are observed in 14-O-PC and 16-O-PC bicelles, respectively, which are consistent with the values previously determined for the same polypeptide in mechanically-aligned DMPC and DOPC bilayers. The difference in tilt angle in C14 and C16 bilayer environments is also consistent with previous results indicating that the transmembrane helix of Vpu responds to hydrophobic mismatch by changing its tilt angle. The kink found in the middle of the helix in the longer-chain C18 bilayers aligned on glass plates was not found in either of these shorter-chain (C14 or C16) bilayers.     

Identification of the hydrophobic thickness of a membrane protein using fluorescence spectroscopy: studies with the mechanosensitive channel MscL

The hydrophobic thickness of a membrane protein is an important parameter, defining how the protein sits within the hydrocarbon core of the lipid bilayer that surrounds it in a membrane. Here we show that Trp scanning mutagenesis combined with fluorescence spectroscopy can be used to define the hydrophobic thickness of a membrane protein. The mechanosensitive channel of large conductance (MscL) contains two transmembrane alpha-helices, of which the second (TM2) is lipid-exposed. The region of TM2 that spans the hydrocarbon core of the bilayer when MscL is reconstituted into bilayers of dioleoylphosphatidylcholine runs from Leu-69 to Leu-92, giving a hydrophobic thickness of ca. 25 A. The results obtained using Trp scanning mutagenesis were confirmed using Cys residues labeled with the N-methyl-amino-7-nitroben-2-oxa-1,3-diazole [NBD] group; both fluorescence emission maxima and fluorescence lifetimes for the NBD group are sensitive to solvent dielectric constant over the range (2-40) thought to span the lipid headgroup region of a lipid bilayer. Changing phospholipid fatty acyl chain lengths from C14 and C24 results in no significant change for the fluorescence of the interfacial residues, suggesting very efficient hydrophobic matching between the protein and the surrounding lipid bilayer.     

Anionic phospholipids are essential for alpha-helix formation of the signal peptide of prePhoE upon interaction with phospholipid vesicles.

The conformational consequences of the interaction of the PhoE signal peptide with bilayers of different types of phospholipids was investigated using circular dichroism. It was found that interaction of the signal peptide with anionic phospholipid vesicles of dioleoylphosphatidylglycerol and dioleoylphosphatidylserine results in induction of high amounts of alpha-helical structure of 70% and 57%, respectively. Upon addition of the signal peptide to cardiolipin vesicles, less but still significant alpha-helical structure was induced (29%). In contrast, no alpha-helix formation was observed upon the interaction of the signal peptide with zwitterionic dioleoylphosphatidylcholine vesicles. In bilayers of dioleoylphosphatidylcholine with dioleoylphosphatidylglycerol, it was shown that in the presence of 100 mM NaCl a minimum amount of 50% of negatively charged lipid was required for induction of the maximal percentage of alpha-helix, whereas in the absence of salt a minimum amount of 35% of negatively charged lipid was necessary. Induction of alpha-helix structure appeared to be correlated with functionality, since, in a less functional analogue of the PhoE signal peptide, the PhoE-[Asp-19,20] signal peptide, less alpha-helix was induced than in the wild-type PhoE signal peptide. It is proposed that the interaction with anionic phospholipids is essential for a functional conformation of the PhoE signal sequence during protein translocation.     

The role of tryptophan residues in an integral membrane protein: diacylglycerol kinase

Tryptophan residues are thought to play special roles in integral membrane proteins, anchoring transmembrane alpha-helices into the lipid bilayer. We have studied the effect of mutating the five Trp residues in the diacylglycerol kinase (DGK) of Escherichia coli to Leu residues. The fluorescence emission maxima for DGK and a variety of Trp mutants in bilayers of dioleoylphosphatidylcholine [di(C18:1)PC] are all centered at ca. 327 nm, suggesting that all five Trp residues are located close to the glycerol backbone region of the bilayer. This is also consistent with fluorescence quenching experiments, measuring the separation between the Trp residues and the bromine atoms in a bilayer of dibromostearoylphosphatidylcholine. Mutation of Trp residues in DGK was found to have significant effects on activity for DGK reconstituted into bilayers of di(C18:1)PC containing 30 mol % 1,2-dihexanoylglycerol (DHG). Of the mutants containing a single Trp residue, only that containing Trp-112 was found to give active protein. The presence of both Trp-25 and Trp-112 gave higher activity than Trp-112 alone. Trp-25 and Trp-112 are the most important Trp residues in DGK as far as activity is concerned. Effects of mutations on K(m) for DHG were generally greater than effects on v(max). The activity of wild-type and mutant DHGs reconstituted into bilayers of phosphatidylcholines was sensitive to the chain length of the phospholipid, with highest activities for chain lengths of C18 or C20 and lower activities in phosphatidylcholines with shorter or longer chains. Compared to wild-type DGK, the Trp mutants were less affected by long-chain phosphatidylcholines but more affected by short-chain phospholipids. In mutants lacking Trp-25, low activities in short-chain phospholipids followed from a decrease in v(max) compared to wild type, combined with an increase in K(m) value for DHG, as observed in the wild type. It is suggested that Trp-25 plays a role in maintaining the alignment of ATP and DHG at the active site. Fluorescence emission spectra for the Trp mutants do not change significantly with changing fatty acyl chain length from C14 to C24, showing efficient hydrophobic matching between DGK and the surrounding lipid bilayer. It is suggested that hydrophobic matching is achieved by tilting of the transmembrane alpha-helix or rotation of residues at the ends of the helices about the Calpha-Cbeta bond linking the residue to the helix backbone. As well as any structural effects, the presence of Trp residues in DGK has a clear effect on thermal stability.     

Sensitivity of single membrane-spanning alpha-helical peptides to hydrophobic mismatch with a lipid bilayer: effects on backbone structure, orientation, and extent of membrane incorporation

The extent of matching of membrane hydrophobic thickness with the hydrophobic length of transmembrane protein segments potentially constitutes a major director of membrane organization. Therefore, the extent of mismatch that can be compensated, and the types of membrane rearrangements that result, can provide valuable insight into membrane functionality. In the present study, a large family of synthetic peptides and lipids is used to investigate a range of mismatch situations. Peptide conformation, orientation, and extent of incorporation are assessed by infrared spectroscopy, tryptophan fluorescence, circular dichroism, and sucrose gradient centrifugation. It is shown that peptide backbone structure is not significantly affected by mismatch, even when the extent of mismatch is large. Instead, this study demonstrates that for tryptophan-flanked peptides the dominant response of a membrane to large mismatch is that the extent of incorporation is reduced, when the peptide is both too short and too long. With increasing mismatch, a smaller fraction of peptide is incorporated into the lipid bilayer, and a larger fraction is present in extramembranous aggregates. Relatively long peptides that remain incorporated in the bilayer have a small tilt angle with respect to the membrane normal. The observed effects depend on the nature of the flanking residues: long tryptophan-flanked peptides do not associate well with thin bilayers, while equisized lysine-flanked peptides associate completely, thus supporting the notion that tryptophan and lysine interact differently with membrane-water interfaces. The different properties that aromatic and charged flanking residues impart on transmembrane protein segments are discussed in relation to protein incorporation in biological systems.     

Structure, topology, and tilt of cell-signaling peptides containing nuclear localization sequences in membrane bilayers determined by solid-state NMR and molecular dynamics simulation studies

Cell-signaling peptides have been extensively used to transport functional molecules across the plasma membrane into living cells. These peptides consist of a hydrophobic sequence and a cationic nuclear localization sequence (NLS). It has been assumed that the hydrophobic region penetrates the hydrophobic lipid bilayer and delivers the NLS inside the cell. To better understand the transport mechanism of these peptides, in this study, we investigated the structure, orientation, tilt of the peptide relative to the bilayer normal, and the membrane interaction of two cell-signaling peptides, SA and SKP. Results from CD and solid-state NMR experiments combined with molecular dynamics simulations suggest that the hydrophobic region is helical and has a transmembrane orientation with the helical axis tilted away from the bilayer normal. The influence of the hydrophobic mismatch, between the hydrophobic length of the peptide and the hydrophobic thickness of the bilayer, on the tilt angle of the peptides was investigated using thicker POPC and thinner DMPC bilayers. NMR experiments showed that the hydrophobic domain of each peptide has a tilt angle of 15 +/- 3 degrees in POPC, whereas in DMPC, 25 +/- 3 degree and 30 +/- 3 degree tilts were observed for SA and SKP peptides, respectively. These results are in good agreement with molecular dynamics simulations, which predict a tilt angle of 13.3 degrees (SA in POPC), 16.4 degrees (SKP in POPC), 22.3 degrees (SA in DMPC), and 31.7 degrees (SKP in DMPC). These results and simulations on the hydrophobic fragment of SA or SKP suggest that the tilt of helices increases with a decrease in bilayer thickness without changing the phase, order, and structure of the lipid bilayers.     

A fluorescence method to define transmembrane alpha-helices in membrane proteins: studies with bacterial diacylglycerol kinase

Hydropathy plots have problems in identifying the sequences of transmembrane (TM) alpha-helices when they contain charged residues. Here we show that fluorescence spectroscopy can be used to define the ends of TM alpha-helices. Diacylglycerol kinase (DGK) from Escherichia coli contains three transmembrane (TM) alpha-helices per monomer. We have used fluorescence techniques to define the region of the putative first TM helix (TM1) that spans the hydrophobic core of the lipid bilayer surrounding DGK in reconstituted membranes. Single Cys mutants were introduced into TM1 and flanking sites, in a mutant of DGK lacking the two native Cys residues. Introduction of Cys residues into the region between residues 28 and 34 resulted in mutants with low activities, due to a combination of reduced affinities for ATP and diacylglycerol and a reduced maximum rate. Cross-linking experiments showed that the low-activity mutants were present largely in the normal, trimeric form after reconstitution. Fluorescence emission maxima for the Cys mutants labeled with N-((2-(iodoacetoxy)ethyl)-N-methyl)amino-7-nitrobenz-2-oxa-1,3-diazole (IANBD) reconstituted into bilayers of dioleoylphosphatidylcholine varied with position, suggesting that the region of TM1 spanning the hydrophobic core of the bilayer runs from Glu-28 on the cytoplasmic side to Asp-49 or Val-50 on the periplasmic side. This locates the charged/polar cluster 32RQE34 within the hydrophobic core of the bilayer. Fluorescence quenching experiments agree with this assignment for TM1, the results showing a periodicity consistent with distinct stripes of amino acid residues along the length of the helix, the stripes facing the lipid bilayer and facing the rest of the protein, respectively. The residues located close to the glycerol backbone region of the bilayer remained the same when the lipid fatty acyl chain length was changed in the range C14 to C22, showing that hydrophobic matching between the protein and the surrounding lipid bilayer is highly efficient.     

Self-association of transmembrane alpha-helices in model membranes: importance of helix orientation and role of hydrophobic mismatch

Interactions between transmembrane helices play a key role in almost all cellular processes involving membrane proteins. We have investigated helix-helix interactions in lipid bilayers with synthetic tryptophan-flanked peptides that mimic the membrane spanning parts of membrane proteins. The peptides were functionalized with pyrene to allow the self-association of the helices to be monitored by pyrene fluorescence and Trp-pyrene fluorescence resonance energy transfer (FRET). Specific labeling of peptides at either their N or C terminus has shown that helix-helix association occurs almost exclusively between antiparallel helices. Furthermore, computer modeling suggested that antiparallel association arises primarily from the electrostatic interactions between alpha-helix backbone atoms. We propose that such interactions may provide a force for the preferentially antiparallel association of helices in polytopic membrane proteins. Helix-helix association was also found to depend on the lipid environment. In bilayers of dioleoylphosphatidylcholine, in which the hydrophobic length of the peptides approximately matched the bilayer thickness, association between the helices was found to require peptide/lipid ratios exceeding 1/25. Self-association of the helices was promoted by either increasing or decreasing the bilayer thickness, and by adding cholesterol. These results indicate that helix-helix association in membrane proteins can be promoted by unfavorable protein-lipid interactions.     

Cytochrome c-lipid interactions studied by resonance Raman and 31P NMR spectroscopy. Correlation between the conformational changes of the protein and the lipid bilayer.

The interaction of cytochrome c with negatively charged lipids has been studied by resonance Raman spectroscopy of the protein heme group and 31P NMR of the phospholipid headgroups. The gel-to-fluid-phase transition of dimyristoylphosphatidylglycerol induces shifts in the conformational and coordination equilibria of the bound cytochrome c, as recorded by the resonance Raman spectra in the fingerprint and marker band regions. Conformational and coordination shifts of the bound cytochrome are also induced on admixture of dioleoylglycerol or dioleoylphosphatidylcholine with dioleoylphosphatidylglycerol. In the case of dioleoylglycerol, significant changes take place even at levels as low as 5 mol %. Binding of cytochrome c induces or increases the content of near isotropically diffusing lipid registered by the 31P NMR spectra of the different lipids studied. Admixture of dioleoylglycerol also increases the bilayer curvature of dioleoylphosphatidylglycerol, inducing an inverted hexagonal phase at 50 mol % concentration; the tendency to spontaneous curvature in the lipid appears to relax the conformational change detected in the protein.     

Peptide Nanopores and Lipid Bilayers: Interactions by Coarse-Grained Molecular-Dynamics Simulations

A set of 49 protein nanopore-lipid bilayer systems was explored by means of coarse-grained molecular-dynamics simulations to study the interactions between nanopores and the lipid bilayers in which they are embedded. The seven nanopore species investigated represent the two main structural classes of membrane proteins (α-helical and β-barrel), and the seven different bilayer systems range in thickness from ∼28 to ∼43 Å. The study focuses on the local effects of hydrophobic mismatch between the nanopore and the lipid bilayer. The effects of nanopore insertion on lipid bilayer thickness, the dependence between hydrophobic thickness and the observed nanopore tilt angle, and the local distribution of lipid types around a nanopore in mixed-lipid bilayers are all analyzed. Different behavior for nanopores of similar hydrophobic length but different geometry is observed. The local lipid bilayer perturbation caused by the inserted nanopores suggests possible mechanisms for both lipid bilayer-induced protein sorting and protein-induced lipid sorting. A correlation between smaller lipid bilayer thickness (larger hydrophobic mismatch) and larger nanopore tilt angle is observed and, in the case of larger hydrophobic mismatches, the simulated tilt angle distribution seems to broaden. Furthermore, both nanopore size and key residue types (e.g., tryptophan) seem to influence the level of protein tilt, emphasizing the reciprocal nature of nanopore-lipid bilayer interactions.     

Voltage-dependent behaviour of dolichyl phosphate-phosphatidylcholine bilayer lipid membranes

The current-voltage steady-state characteristics, cyclic voltammograms and capacitance-voltage steady-state relationships of bilayer lipid membranes made from dioleoylphosphatidylcholine or its mixtures with dolichyl-12 phosphate have been studied. Sustained fluctuations of the capacitance of dolichyl phosphate modified bilayers under applied voltage were observed. The results suggest that the dynamics of dolichyl phosphate molecules in membranes can be regulated by transmembrane electrical potential.     

FRET study of membrane proteins: simulation-based fitting for analysis of membrane protein embedment and association

A new formalism for the simultaneous determination of the membrane embedment and aggregation of membrane proteins is developed. This method is based on steady-state F?rster (or fluorescence) resonance energy transfer (FRET) experiments on site-directed fluorescence labeled proteins in combination with global data analysis utilizing simulation-based fitting. The simulation of FRET was validated by a comparison with a known analytical solution for energy transfer in idealized membrane systems. The applicability of the simulation-based fitting approach was verified on simulated FRET data and then applied to determine the structural properties of the well-known major coat protein from bacteriophage M13 reconstituted into unilamellar DOPC/DOPG (4:1 mol/mol) vesicles. For our purpose, the cysteine mutants Y24C, G38C, and T46C of this protein were produced and specifically labeled with the fluorescence label AEDANS. The energy transfer data from the natural tryptophan at position 26, which is used as a donor, to AEDANS were analyzed assuming a helix model for the transmembrane domain of the protein. As a result of the FRET data analysis, the topology and bilayer embedment of this domain were quantitatively characterized. The resulting tilt of the transmembrane helix of the protein is 18 +/- 2 degrees. The tryptophan is located at a distance of 8.5 +/- 0.5 A from the membrane center. No specific aggregation of the protein was found. The methodology developed here is not limited to M13 major coat protein and can be used in principle to study the bilayer embedment of any small protein with a single transmembrane domain.     

Tilt angles of transmembrane model peptides in oriented and non-oriented lipid bilayers as determined by 2H solid-state NMR

Solid-state NMR methods employing (2)H NMR and geometric analysis of labeled alanines (GALA) were used to study the structure and orientation of the transmembrane alpha-helical peptide acetyl-GWW(LA)(8)LWWA-amide (WALP23) in phosphatidylcholine (PC) bilayers of varying thickness. In all lipids the peptide was found to adopt a transmembrane alpha-helical conformation. A small tilt angle of 4.5 degrees was observed in di-18:1-PC, which has a hydrophobic bilayer thickness that approximately matches the hydrophobic length of the peptide. This tilt angle increased slightly but systematically with increasing positive mismatch to 8.2 degrees in di-C12:0-PC, the shortest lipid used. This small increase in tilt angle is insufficient to significantly change the effective hydrophobic length of the peptide and thereby to compensate for the increasing hydrophobic mismatch, suggesting that tilt of these peptides in a lipid bilayer is energetically unfavorable. The tilt and also the orientation around the peptide axis were found to be very similar to the values previously reported for a shorter WALP19 peptide (GWW(LA)(6)LWWA). As also observed in this previous study, the peptide rotates rapidly around the bilayer normal, but not around its helix axis. Here we show that these properties allow application of the GALA method not only to macroscopically aligned samples but also to randomly oriented samples, which has important practical advantages. A minimum of four labeled alanine residues in the hydrophobic transmembrane sequence was found to be required to obtain accurate tilt values using the GALA method.     

Structural dynamics and topology of phospholamban in oriented lipid bilayers using multidimensional solid-state NMR

Phospholamban (PLN), a single-pass membrane protein, regulates heart muscle contraction and relaxation by reversible inhibition of the sarco(endo)plasmic reticulum Ca-ATPase (SERCA). Studies in detergent micelles and oriented lipid bilayers have shown that in its monomeric form PLN adopts a dynamic L shape (bent or T state) that is in conformational equilibrium with a more dynamic R state. In this paper, we use solid-state NMR on both uniformly and selectively labeled PLN to refine our initial studies, describing the topology and dynamics of PLN in oriented lipid bilayers. Two-dimensional PISEMA (polarization inversion spin exchange at the magic angle) experiments carried out in DOPC/DOPE mixed lipid bilayers reveal a tilt angle of the transmembrane domain with respect to the static magnetic field, of 21 +/- 2 degrees and, at the same time, map the rotation angle of the transmembrane domain with respect to the bilayer. PISEMA spectra obtained with selectively labeled samples show that the cytoplasmic domain of PLN is helical and makes an angle of 93 +/- 6 degrees with respect to the bilayer normal. In addition, using samples tilted by 90 degrees , we find that the transmembrane domain of PLN undergoes fast long-axial rotational diffusion about the bilayer normal with the cytoplasmic domain undergoing this motion and other complex dynamics, scaling the values of chemical shift anisotropy. While this dynamic was anticipated by previous solution NMR relaxation studies in micelles, these measurements in the anisotropic lipid environment reveal new dynamic and conformational features encoded in the free protein that might be crucial for SERCA recognition and subsequent inhibition.     

Hydrophobic matching controls the tilt and stability of the dimeric platelet-derived growth factor receptor (PDGFR) β transmembrane segment

The platelet-derived growth factor receptor β is a member of the cell surface receptor tyrosine kinase family and dimerizes upon activation. We determined the structure of the transmembrane segment in dodecylphosphocholine micelles by liquid-state NMR and found that it forms a stable left-handed helical dimer. Solid-state NMR and oriented circular dichroism were used to measure the tilt angle of the helical segments in macroscopically aligned model membranes with different acyl chain lengths. Both methods showed that decreasing bilayer thickness (DEPC-POPC-DMPC) led to an increase in the helix tilt angle from 10° to 30° with respect to the bilayer normal. At the same time, reconstitution of the comparatively long hydrophobic segment became less effective, eventually resulting in complete protein aggregation in the short-chain lipid DLPC. Unrestrained molecular dynamics simulations of the dimer were carried out in explicit lipid bilayers (DEPC, POPC, DMPC, sphingomyelin), confirming the observed dependence of the helix tilt angle on bilayer thickness. Notably, molecular dynamics revealed that the left-handed dimer gets tilted en bloc, whereas conformational transitions to alternative (e.g. right-handed dimeric) states were not supported. The experimental data along with the simulation results demonstrate a pronounced interplay between the platelet-directed growth factor receptor β transmembrane segment and the bilayer thickness. The effect of hydrophobic mismatch might play a key role in the redistribution and activation of the receptor within different lipid microdomains of the plasma membrane in vivo.     

Detergent Properties Influence the Stability of the Glycophorin A Transmembrane Helix Dimer in Lysophosphatidylcholine Micelles

Detergents might affect membrane protein structures by promoting intramolecular interactions that are different from those found in native membrane bilayers, and fine-tuning detergent properties can be crucial for obtaining structural information of intact and functional transmembrane proteins. To systematically investigate the influence of the detergent concentration and acyl-chain length on the stability of a transmembrane protein structure, the stability of the human glycophorin A transmembrane helix dimer has been analyzed in lyso-phosphatidylcholine micelles of different acyl-chain length. While our results indicate that the transmembrane protein is destabilized in detergents with increasing chain-length, the diameter of the hydrophobic micelle core was found to be less crucial. Thus, hydrophobic mismatch appears to be less important in detergent micelles than in lipid bilayers and individual detergent molecules appear to be able to stretch within a micelle to match the hydrophobic thickness of the peptide. However, the stability of the GpA TM helix dimer linearly depends on the aggregation number of the lyso-PC detergents, indicating that not only is the chemistry of the detergent headgroup and acyl-chain region central for classifying a detergent as harsh or mild, but the detergent aggregation number might also be important.