Fluorescent probe studies of normal, persistently infected, rous sarcoma virus-transformed, and trypsinized rat cells

The fluorescent probes pyrene, pyrene butyric acid and N-phenyl 1-naphthylamine were used to study membranes of normal cells, RSV-transformed cells, cells treated with a proteolytic enzyme, and cells persistently infected with lymphocytic choriomeningitis virus. The lifetimes of excited pyrene and pyrene butyric acid showed only minor changes when these probes were in normal, transformed, trypsinized or persistently infected cells. However, pyrene, but not pyrene butyric acid, lifetimes are shorter in cell membranes than in homogeneous solvents. The quenching of excited pyrene in cells by quencher molecules was slower than corresponding reactions in homogeneous solutions indicating that the probe was screened from the quenchers by the membrane. However, quenching reactions with the pyrene butyric acid probe were similar in cells and homogeneous solvents. This indicates that pyrene and pyrene butyric acid reside in different lipid regions of the membrane. Transformed and trypsinized cells showed increased membrane fluidity compared to normal and persistently infected cells. Membrane fluidity was determined from the excimer/monomer fluorescence ratios of pyrene, and by the polarization of N-phenyl 1-naphthylamine fluorescence. Several techniques distinguished between normal and transformed or trypsinized cells; however, the only parameter unique to viral transformation was a blue shift of the fluorescence maxima of N-phenyl 1-naphthylamine. This shift reflected a less polar environment for N-phenyl 1-naphthylamine in virus-transformed cells.     

Effect of cholinergic ligands and local anesthetics on acetylcholine receptor enriched membrane preparations from Torpedo californica electroplax.

Pyrene was introduced in acetylcholine receptor (AcChR)-rich membrane preparations of Torpedo californica electroplax. The lifetime of the singlet excited state of pyrene was used to probe the properties of the hydrocarbon regions of the lipid bilayer as well as the possible perturbing effects of cholinomimetic agents on this region. After excitation with a single 15-ns pulse with a Q-switched ruby laser, the lifetime of the pyrene singlet excited state in the membranes was 200 ns. In desensitized membranes the pyrene fluorescence lifetimes remained unchanged when the cholinergic ligands carbamylcholine, d-tubocurarine, decamethonium, and hexamethonium, as well as α-bungarotoxin, were present. By contrast, the lifetime was shortened when local anesthetics were present. In sensitized membranes no changes in the pyrene lifetimes were detected when the membranes were converted from their resting state to a carbamylcholine-induced “desensitized state.” Water-soluble fluorescence quenchers affected the lifetime of pyrene in membranes. The second order rate constants for the pyrene-quencher interaction were used to detect changes in fluidity and/or membrane lipid accessibility to quenchers induced by ligands or anesthetics. No changes were detected in the quenching constants of nitromethane or Tl⁺ in the presence of cholinergic agents (with the exception of d-tubocurarine); on the other hand, a marked decrease in Tl⁺ accessibility was induced by the anesthetics procaine and tetracaine. Fluorescene dynamics measurements indicate that the hydrocarbon core of the bulk lipid in electroplax is not significantly affected by binding cholinergic ligands to membranebound AcChR. However, the hydrophobic region of the membrane is perturbed by both local anesthetics and one cholinergic ligand, d-tubocurarine. Pyrene was also incorporated into lipid vesicles prepared from T. californica electroplax lipids. The fluorescence lifetimes and quenching values of these lifetimes yielded results similar to those obtained with both sensitized and “desensitized” membrane preparations. The d-tubocurarine effect on the Tl⁺ quenching of the pyrene probe is ascribed to direct interaction of d-tubocurarine with the lipids. These findings favor a mechanism in which perturbation of the hydrophobic (lipid) environment of the AcChR in membranes by local anesthetics and even d-tubocurarine may influence the receptor conversion: sensitized state ? desensitized state.     

The study of rous sarcoma virus-transformed baby hamster kidney cells using fluorescent probes

The fluorescent probes pyrene, pyrene butyric acid and $\text{N-}\text{phenyl}$ 1-naphthylamine have been used to investigate the changes that accompany in vitro transformation of a baby hamster kidney cell line using Rous sarcoma virus. The fluorescent probes which reside in the membrane were used to compare the changes in microviscosity and polarity of the membranes of normal cells with two transformed cell lines. The spectrofluorimetric data indicate that following transformation the probe $\text{N-}\text{phenyl}$ 1-naphthylamine resides in a more polar environment. However, using the probe pyrene, the yield of excimer indicates decreased mobility of this probe in the membrane of transformed cells. The data also indicate differences between the two transformed cell lines. Laser photolysis was used to study the lifetime of the pyrne probes and the quenching of the pyrene fluorescence in the membrane by several different quenching molecules. The data indicate differences between the three cell lines and suggest that transformation decreases movement within the membrane.     

The study of rous sarcoma virus-transformed baby hamster kidney cells using fluorescent probes.

The fluorescent probes pyrene, pyrene butyric acid and N-phenyl 1-naphthylamine have been used to investigate the changes that accompany in vitro transformation of a baby hamster kidney cell line using Rous sarcoma virus. The fluorescent probes which reside in the membrane were used to compare the changes in microviscosity and polarity of the membranes of normal cells with two transformed cell lines. The spectrofluorimetric data indicate that following transformation the probe N-phenyl 1-naphthylamine resides in a more polar environment. However, using the probe pyrene, the yield of excimer indicates decreased mobility of this probe in the membrane of transformed cells. The data also indicate differences between the two transformed cell lines. Laser photolysis was used to study the lifetime of the pyrene probes and the quenching of the pyrene fluorescence in the membrane by several different quenching molecules. The data indicate differences between the three cell lines and suggest that transformation decreases movement within the membrane.     

Monitoring the location profile of fluorophores in phosphatidylcholine bilayers by the use or paramagnetic quenching.

Spin probes differing in the position of their paramagnetic centre are used to quench the fluorescence of pyrene derivatives and chlorophylls incorporated into dimyristoyl phosphatidylcholine membranes. Pyrene butyric acid and pyrene decanoic acid with known orientation relative to the membrane surface are investigated. The quenching efficiency of fatty acid spin probes is dependent on the position of the nitroxide radical group in the fatty acid chain. Using this short range interaction we developed a spectroscopic method to chlorophyll-containing vesicles, we were able to characterize the orientation of the porphyrin ring within the membrane. Moreover, the chlorophyll fluorescence is also quenched by a water-soluble spin label. Therefore the porphyrin ring appears to be orientated in the polar head group region of the lipid layer, but not to be protruding out into the water phase. This conclusion is confirmed by the use of pyrene derivatives. Fluorescence quenching by a water-soluble spin label within the lipid matrix is observed even in the rigid state of the membrane. Fluorescence lifetime measurements suggest the existence of two different quenching mechanisms: (1) a static quenching occurring below the lipid phase transition temperature, and (2) an additional dynamic quenching taking place in the fluid state of the lipid bilayer.     

Monitoring the location profile of fluorophores in phosphatidylcholine bilayers by the use of paramagnetic quenching

Spin probes differing in the position of their paramagnetic centre are used to quench the fluorescence of pyrene derivatives and chlorophylls incorporated into dimyristoyl phosphatidylcholine membranes. Pyrene butyric acid and pyrene decanoic acid with known orientation relative to the membrane surface are investigated. The quenching efficiency of fatty acid spin probes is dependent on the position of the nitroxide radical group in the fatty acid chain. Using this short fange interaction we developed a spectroscopic method to characterize the molecular arrangement within the lipid membrane. Applied to chlorophyll-containing vesicles, we were able to characterize the orientation of the porphyrin ring within the membrane. Moreover, the chlorophyll fluorescence is also quenched by a water-soluble spin label. Therefore the porphyrin ring appears to be orientated in the polar head group region of the lipid layer, but not to be protruding out into the water phase.This conclusion is confirmed by the use of pyrene derivatives. Fluorescence quenching by a water-soluble spin label within the lipid matrix is observed even in the rigid state of the membrane. Fluorescence lifetime measurements suggest the existence of two different quenching mechanisms: (1) a static quenching occurring below the lipid phase transition temperature, and (2) an additional dynamic quenching taking place in the fluid state of the lipid bilayer.     

Fluorescence studies on the interaction of myoglobin with mitochondria

To determine the nature and characteristic parameters of the myoglobin-mitochondrion interaction during oxymyoglobin (MbO₂) deoxygenation in the cell, we studied the quenching of the intrinsic mitochondrial flavin and tryptophan fluorescence by different liganded myoglobins in the pH range of 6–8, as well as the quenching of the fluorescence of the membrane probes 1,8-ANS and merocyanine 540 (M 540) embedded into the mitochondrial membrane. Physiologically active MbO₂ and oxidized metmyoglobin (metMb), which are unable to bind oxygen, were used as the quenchers. The absence of quenching of flavin and tryptophan fluorescence implies that myoglobin does not form quenching complexes with either electron transport chain proteins of the inner mitochondrial membrane or with outer membrane proteins. We found, however, that MbO₂ and metMb effectively quench 1,8-ANS and M 540 fluorescence in the pH range of 6–8. Characteristic parameters of 1,8-ANS and M 540 fluorescence quenching by the myoglobins (extent of quenching and quencher binding constant, K _m) are very similar, indicating that both probes are localized in phospholipid sites of the mitochondrial membrane, and myoglobin is complexed with these sites. The dependence of K _m on ionic strength proves the important role of coulombic interactions in the formation of the quenching complex. Since the overall charge of myoglobin is shown not to influence the K _m values, the ionic strength dependence must be due to local electrostatic interactions in which polar groups of some part of the myoglobin molecule participate. The most likely candidates to interact with anionic groups of mitochondrial phospholipids are invariant lysine and arginine residues in the environment of the myoglobin heme cavity, which do not change their ionization state in the pH range investigated.     

Bromoacyl Analogues of Phosphatidylcholine with Intramolecular Fluorescence Quenching and Their Use as Substrates for Continuous Monitoring of Phospholipase A2 Activity

Two new derivatives of phosphatidylcholine with intramolecular fluorescence quenching were obtained by substituting residues of pyrene butyric and bromine-containing fatty acids for acyl chains. The two compounds can be used for quantitative evaluation of the catalytic activity of pancreatic phospholipase A₂ in kinetic mode.     

Oxygen diffusion-concentration in erythrocyte plasma membranes studied by the fluorescence quenching of anionic and cationic pyrene derivatives

Fluorescence quenching by oxygen of cationic [pyrene-(CH₂) _n N(CH₃) ₃ ⁺ ;n=1, 4, and 11] and anionic [pyrene-(CH₂) _n CO ₂ ^– ,n=3, 8, 11, and 15] probes was investigated in erythrocyte plasma membranes (leaky) in order to assess the ability of oxygen molecules to interact with solutes located at different positions in the membrane. The pseudounimolecular quenching rate constants measured increase, both for cationic and anionic probes, whenn increases. These results are interpreted in terms of an increased oxygen solubility toward the center of the membrane interior, and imply that lateral diffusion contributes more than transverse diffusion to total oxygen mobility. For all of the probes considered, quenching rates increase whenn-alkanols are added. The effect observed increases whenn decreases and when the size of then-alkanol alkyl chain increases. Arrhenius-type plots for the quenching rate constants show noticeable downward curvatures. Average (0–40°C) activation energies are 6 kcal/mol.Abbreviations EPM erythrocyte plasma membrane - PMTMA (1-pyrenyl)methyltrimethyl-ammonium - PBTMA 4-(1-pyrenyl)butyltrimethylammonium - PUTMA 11-(1-pyrenyl)-undecyltrimethylammonium - PB 4-(1-pyrenyl)butanoate - PN 9-(1-pyrenyl)nonanoate - PD 12-(1-pyrenyl)dodecanoate - PHD 16-(1-pyrenyl)hexadecnoate     

Use of fluorescence probes 1-aniline-8-naphthalene sulfonate and pyrene for studying the localisation of proteins in inner membranes from wheat etioplasts

The fluorescence probes 1-aniline-8-naphthalene sulfonate (ANS) and pyrene were applied for characterisation of the light-induced changes in etioplast inner membranes (EPIMs) from 7 d-old dark-grown wheat seedlings (Triticum aestivum L. cv. Pobeda). The major aim was to obtain information about the localisation of membrane proteins in the EPIMs, using probes situated in different regions of the membranes. The quenching of tryptophan fluorescence showed tha the main parts of proteins were accessible to the pyrene buried in the lipid bilayer which suggests that most of the proteins also enter the lipid bilayer. The substantial quenching of the tryptophan fluorescence by the surface-situated ANS demonstrated that a part of the tryptophan residues was probably localised close to the membrane surface. The registered changes after irradiation could be explained by the presence of large aggregates of NADPH-protochlorophyllide oxidoreductase (POR), protochlorophyllide (PChlide) and NADPH in membranes that start to disconnect and redistribute along the prothylakoids. This revised version was published online in August 2006 with corrections to the Cover Date.     

A two‐component Kdo hydrolase in the inner membrane of Francisella novicida

Lipid A coats the outer surface of the outer membrane of Gram‐negative bacteria. In Francisella tularensis subspecies novicida lipid A is present either as the covalently attached anchor of lipopolysaccharide (LPS) or as free lipid A. The lipid A moiety of Francisella LPS is linked to the core domain by a single 2‐keto‐3‐deoxy‐D‐manno‐octulosonic acid (Kdo) residue. F. novicida KdtA is bi‐functional, but F. novicida contains a membrane‐bound Kdo hydrolase that removes the outer Kdo unit. The hydrolase consists of two proteins (KdoH1 and KdoH2), which are expressed from adjacent, co‐transcribed genes. KdoH1 (related to sialidases) has a single predicted N‐terminal transmembrane segment. KdoH2 contains 7 putative transmembrane sequences. Neither protein alone catalyses Kdo cleavage when expressed in E. coli. Activity requires simultaneous expression of both proteins or mixing of membranes from strains expressing the individual proteins under in vitro assay conditions in the presence of non‐ionic detergent. In E. coli expressing KdoH1 and KdoH2, hydrolase activity is localized in the inner membrane. WBB06, a heptose‐deficient E. coli mutant that makes Kdo₂‐lipid A as its sole LPS, accumulates Kdo‐lipid A when expressing the both hydrolase components, and 1‐dephospho‐Kdo‐lipid A when expressing both the hydrolase and the Francisella lipid A 1‐phosphatase (LpxE).     

Interaction of fluorescence quenchers with the n-(9-anthroyloxy) fatty acid membrane probes

The fluorescence quenching of the $\text{n-(9-}\text{anthroyloxy}\text{)}$ (AO) fatty acid probes has been investigated in aqueous dispersions, vesicles of egg phosphatidylcholine and vesicles formed from red cell ghosts. Negatively charged (KI), neutral (acrylamide) and positively charged (CuSO₄) quenchers were used to monitor the location of the probes. The fluorescence of the probes, with the exception of the shortest chain (11-(9-anthroyloxy)undecanoic acid) is not quenched by acrylamide when associated with vesicles. This indicates that in association with vesicles, the 9-anthroyloxy moiety of the long chain probes is buried within the hydrocarbon region and thus well shielded from the aqueous phase. Measurements with KI indicate that the probes are present in the membrane at depths corresponding to the position of the 9-anthroyloxy moiety on the fatty acid, and that the quencher itself forms a concentration gradient within the membrane. Very little or no CuSO₄ quenching was observed for $\text{n-}\text{(9-anthroyloxy)stearic}$ acid probes $\text{(n-}\text{AS)with}\text{n > 2}$, suggesting that in these vesicles Cu²⁺ does not significantly penetrate the bilayer.     

Biosynthetic incorporation of fluorescent carbazolylundecanoic acid into membrane phospholipids of LM cells and determination of quenching constants and partition coefficients of hydrophobic quenchers

A fluorescence quenching method was developed for determining partition coefficients and diffusional rates of small molecules in cell membranes. This method involves quenching the fluorescence of carbazole-labeled membranes by hydrophobic molecules that partition into membranes. Cell membrane phospholipids of mouse LM cells in tissue culture were biosynthetically labeled with the carbazole moiety by supplementing the growth media with 11-(9-carbazolyl)undecanoic acid. Plasma membranes, microsomes, and mitochondria were isolated free of nonmembranous neutral lipids, and the incorporation of the fluorescent probe was characterized. Quenching studies of the carbazole moiety by a series of N-substituted picolinium perchlorate salts showed that the carbazole moiety was located in the hydrophobic interior of the membrane bilayer. The carbazole fluorescence also was quenched by the hydrophobic quenchers lindane, methoxychlor, and 1,1-dichloro-2,2-bis(rho-chlorophenyl)ethylene, indicating that these compounds partitioned into the membrane. Stern-Volmer quenching constants determined by fluorescence lifetime and intensity measurements were identical, as expected for dynamic quenching. The effects of different lipid compositions on quenching constants and partition coefficients were determined by comparing different membrane fractions. These parameters also were measured in membranes from cells in which the phospholipid composition was altered by substituting ethanolamine for choline in the growth medium. Changes in the lipid composition produced changes in the bimolecular quenching constants. For example, bimolecular quenching constants for 1,1-dichloro-2,2-bis(rho-chlorophenyl)ethylene were higher in mitochondrial membranes than in plasma membranes and microsomes. They were also higher in dispersions made from membrane phospholipids as compared with intact membranes or total lipid dispersion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetics of partly diffusion-controlled reactions

Spectrofluorimetric methods allowing an estimation of the “microviscosity” (or the microfluidity) of synthetic and natural membranes may be used if the emisive phenomenon is dependent upon the cohesion of its local environment. Of the different methods that may be proposed, the study of the reactions between electronically excited molecules A^*, which emit fluorescence, and B quenchers embedded in membranes, the rate constant of which is partly controlled by diffusion, are expected to inform about the values of diffusion coefficients of quenchers and therefore the “microviscosity” of the environment. Information may be improved when the product of the reaction between A^* and B is itself emissive (excimers, exciplexes). We propose here that a kinetic model may apply this type of reaction when a process of static quenching occurs. The use of this kinetic model in studies carried out in this area should lead to a more accurate determination of the diffusion coefficients of A^* and B and therefore of the “microviscosity.”     

Correlations between fatty acid distribution in phospholipids and the temperature dependence of membrane physical state

Cytoplasmic membranes of an unsaturated fatty acid auxotroph of Escherichia coli have been studied using spin labeled hydrocarbon probes. These studies reveal that the membrane lipids undergo changes of state at critical temperatures which reflect the physical properties of the fatty acid supplement supplied to the cells during growth. The critical temperatures observed in spin labeled membranes correlate with characteristic temperatures in membrane functions. Lipid analysis reveals that fatty acid composition and distribution in membrane phospholipids are primary determinants of the temperatures at which changes of state are observed in membrane lipids. Fatty acid composition and distribution can also produce unique interactions between certain spin label probes and their lipid environment.     

Release of outer membrane fragments from normally growing Escherichia coli

A complex containing lipopolysaccharides, phospholipids and proteins is released into the culture medium by Escherichia coli during normal growth. It can be separated from the medium by gelfiltration on Sephadex G-200 or by centrifugation. Electron microscopy revealed that this material is released as vesicles and membrane fragments. To determine the origin of these fragments, they were compared to outer and cytoplasmic membranes with respect to keto-deoxyoctulosonic acid, phospholipid, and protein content, phospholipid composition, fatty acid composition, protein distribution on sodium dodecyl sulfate-polyacrylamide gels, buoyant density, and content of several membrane marker enzymes. The results of this comparison indicate that the membrane fragments found in the culture supernatant of normally growing Escherichia coli consist of practically unmodified outer membrane. Possible mechanisms as to the cause of the release of outer membrane fragments, and its relationship to cell-division, are discussed.     

Membrane-bound acid pyrophosphatase from Sulfolobus tokodaii, a thermoacidophilic archaeon: heterologous expression of the gene and characterization of the product

Membranes of Sulfolobus tokodaii, a thermoacidophilic archaeon that grows optimally at pH 2–3, 75–80°C, show the ability to hydrolyze PPi with an optimum pH of 2–3. This acid PPase is proposed to be a dolicholpyrophosphatase that participates in glycoprotein biosynthesis. In the present study, the archaeal membranes hydrolyzed isopentenylpyrophosphate and geranylpyrophosphate, compounds related to dolicholpyrophosphate, at pH 3. However, the dolicholpyrophosphate-binding antibiotic bacitracin failed to inhibit the acid PPase. To investigate further the function and structure of the acid PPase, the gene was cloned and heterologously expressed in Escherichia coli. The membranes from recombinant E. coli showed PPase activity with similar pH and temperature dependence, substrate specificity, and kinetic parameters to those reported for Sulfolobus membranes. The acid PPase was solubilized and purified to electrophoretic homogeneity from the recombinant E. coli. The purified enzyme showed similar K _m values for PPi, ATP, and ADP to the membrane-bound enzyme. Lipids from the Sulfolobus membranes enhanced the activity to about threefold. Studies involving deletion mutants indicated that basic amino acids in the N-terminal (Arg2 and Lys3), as well as the residues (4th–69th) possibly twice-spanning the membrane, are essential for integration of the enzyme into membranes.     

Characterization of and lipopolysaccharide binding to the E. coli LptC protein dimer

Lipopolysaccharide (LPS, endotoxin) is the major component of the outer leaflet of the outer membrane of Gram‐negative bacteria such as Escherichia coli and Salmonella typhimurium. LPS is a large lipid containing several acyl chains as its hydrophobic base and numerous sugars as its hydrophilic core and O‐antigen domains, and is an essential element of the organisms' natural defenses in adverse environmental conditions. LptC is one of seven members of the lipopolysaccharide transport (Lpt) protein family that functions to transport LPS from the inner membrane (IM) to the outer leaflet of the outer membrane of the bacterium. LptC is anchored to the IM and associated with the IM LptFGB₂ complex. It is hypothesized that LPS binds to LptC at the IM, transfers to LptA to cross the periplasm, and is inserted by LptDE into the outer leaflet of the outer membrane. The studies described here comprehensively characterize and quantitate the binding of LPS to LptC. Site‐directed spin labeling electron paramagnetic resonance spectroscopy was utilized to characterize the LptC dimer in solution and monitor spin label mobility changes at 10 sites across the protein upon addition of exogenous LPS. The results indicate that soluble LptC forms concentration‐independent N‐terminal dimers in solution, LptA binding does not change the conformation of the LptC dimer nor appreciably disrupt the LptC dimer in vitro, and LPS binding affects the entire LptC protein, with the center and C‐terminal regions showing a greater affinity for LPS than the N‐terminal domain, which has similar dissociation constants to LptA.     

Serum and Egg Antibody Responses in Chickens to Escherichia coli

The effects of Freund’s adjuvants on antibody production in chickens against E. coli whole cells were examined. The levels of anti-E. coli IgG antibodies in serum were higher when Freund’s complete (FCA) or incomplete adjuvant (FIA) was administered than that without adjuvant. Production of antibodies recognizing E. coli cells and their lipopolysaccharide was enhanced by FIA, while both FIA and FCA enhanced production of antibodies recognizing outer membrane components. In contrast, serum IgM antibody levels were higher when no adjuvant was used. Anti-E. coli IgG antibodies in serum were efficiently transferred to egg yolk, giving antibody activity in egg yolk similar to that in serum. However, anti-E. coli IgM antibodies were not detected in the egg, suggesting that egg (white) IgM was not influenced by antigenic stimulation of the humoral immune system. Antimicrobial activity of the egg yolk IgG was highest when the bacteria antigen was injected with FIA.     

Dynamic quenchers in fluorescently labeled membranes. Theory for quenching in a three-phase system.

The theory for quenching of fluorescently labeled membranes by dynamic quenchers is described for a three-phase system: a fluorescently labeled membrane, a nonlabeled membrane, and an aqueous phase. Two different experimental protocols are possible to determine quenching parameters. Using the first protocol, partition coefficients and bimolecular quenching constants were determined for a hydrophobic quencher in carbazole-labeled membranes in the presence of an unlabeled reference membrane. These parameters determined for 1,1-dichloro-2,2-bis(p-chlorophenyl)ethylene (DDE) using this three-phase analysis were in good agreement with values determined by a two-phase analysis without the reference lipid. Hence, the theory was verified. In the second protocol, the quencher partition coefficient was determined for unlabeled membranes in the presence of a carbazole-labeled reference membrane. Partition coefficients for DDE determined by this method were the same as partition coefficients determined for carbazole-labeled membranes using the two-phase analysis. The greater ease in determining partition coefficients and bimolecular quenching constants by the three-phase analysis and, in particular, the ability to determine the partition coefficient in unlabeled membranes make the three-phase analysis especially useful. This method was used to study the effect varying the membrane lipid composition has on the partition coefficient. The data indicate that partition coefficients of DDE in fluid membranes are not dramatically dependent upon polar head group composition, fatty acid composition, or cholesterol content. However, partitioning into gel-phase lipids is at least 100-fold less than fluid-phase lipids.