Temperature-induced changes of spin-labelled radioactive lipids in isolated guinea pig liver microsomal membranes before and in mitochondrial membranes after their translocation.

Lipids of isolated guinea pig liver microsomal membranes were labelled biosynthetically with isomeric doxyl stearic acid and temperature-induced changes of these membranes were studied by electron spin resonance. A noticeable discontinuity was detected at 10--12 degree C with 12- or 16-doxyl stearic acid containing membrane lipids which was attributed to the spin-labelled lipid--microsomal membrane protein interactions since no such discontinuity was detected in liposomes prepared from total lipid extracts of microsomal membranes. When microsomal membranes containing radioactive isomeric spin-labelled lipids were incubated with unlabelled mitochondria, reisolated mitochondrial membranes contained translocated radioactive isomeric spin-labelled lipids. Temperature-induced changes in these membranes showed no discontinuity with either isomeric doxyl stearic acid derivative, establishing a difference in the environment of translocated lipids in the membrane donor compared with that in the membrane acceptor. Microsomal membranes recovered from translocation experiments showed the same behaviour as the original membranes and exhibited the same discontinuity at 10--12 degree C, establishing that the translocation incubation itself did not alter the spin-labelled lipid interaction within these membranes. Studies of the loss of paramagnetism of spin-labelled lipids in microsomal membranes before and in mitochondrial membranes after their translocation showed a significant difference and suggested that both the outer and the inner mitochondrial membranes might have been involved.     

Enzymatic degradation and partial biosynthetic reconstitution of microsomal and mitochondrial membranes.

Guinea pig liver microsomal and mitochondrial membranes were degraded with phospholipase C and D followed by partial biosynthetic reconstitution. Activities of phosphatidylinositol synthetase in microsomal membranes and NADPH-cytochrome c reductase were almost completely lost after phospholipase C and D treatment; almost complete restoration of the original activity was achieved after biosynthesis of phosphatidylcholine in degraded microsomes, but was not reparable after biosynthesis of cytidinediphosphodiglycerides (CDP-diglycerides). The mitochondrial biosynthesis of polyglycerophosphatides was completely retained after degradation of these membranes with phospholipase C, but after similar treatment with phospholipase D, only about one-quarter of the original activity remained, the relative composition of polyglycerophosphatides being significantly different. The activity of NADPH-cytochrome c reductase of microsomes represented about 76% of the original activity after phospholipase C treatment, but only approximately 1% after treatment with phospholipase D. Although this activity could not be restored with CDP-diglyceride synthesis, it was restored to about 75% of the original activity after the biosynthesis of phosphatidylcholine in these fragments. These and additional experimental findings are discussed in terms of the relation between structural organization of lipids and proteins and enzymatic activities of membrane-bound phospholipid-synthesizing enzymes in microsomal and mitochondrial membranes isolated from guinea pig liver.     

Cytosol protein-independent translocation of isomeric spin-labelled radioactive lipids from isolated guinea pig liver microsomal to mitochondrial membranes

Intermembranous translocation of membrane-bound radioactive lipids covalently labelled with 5-, 12, and 16-doxyl stearic acid was studied. Guinea pig liver microsomal membranes containing known amounts of isomeric spin-labelled radioactive phosphatidic acid, phosphatidylcholine, and diglycerides were incubated with unlabelled mitochondria; reisolated mitochondria contained around 28-31% of microsomal labelled lipids above the microsomal contamination. The effect of adding crude or 'pH 5.1' 105 000 X g cytosol supernatant on the amount and composition of translocated labelled lipids was studied. While the translocation of labelled phosphatidylcholine was slightly stimulated by the addition of these cytosol supernatants, no significant increase of the amount of translocated labelled phosphatidic acic and diglycerides was observed by this addition. In view of these results, a probable mechanism for the cytosol protein-independent translocation of lipids between biological membranes is proposed.     

Mitochondrial importation of lipids and liponucleotides from microsomes independent of and facilitated by purified cytosol proteins

The mitochondrial importation of microsomal lipids and liponucleotides in the presence and in the absence of partially purified cytosol protein(s) isolated from guinea pig liver was studied by the aid of isomeric (5-, 12-, and 16-(N-oxyl-4',4'-dimethyloxazolidine)stearoyl) spin-labelled radioactive phosphatide acid, phosphatidylcholine, neutral lipids, and CDP-diglycerides. Using a conventional procedure for the protein purification, cytosol protein(s) was purified approximately 1000-fold in respect to its ability to catalyze the translocation of isomeric spin-labelled lipids and liponucleotides from the microsomal to mitochondrial membranes. The highest activity of this protein was exhibited with biosynthesized spin-labelled lipids and liponucleotides bound to the microsomal membranes as substrates and the lowest, with the synthetic liponucleotides and derived lipids bound to the microsomal membranes. The partially purified protein was active in catalyzing the mitochondrial import of phospholipids from microsomes after heat treatment up to 90 degrees C. In addition to the cytosol protein catalyzing mechanism of mitochondrial import of lipids and liponucleotides from microsomal membranes, another cytosol protein independent mechanism of the mitochondrial importation of the same lipids and liponucleotides was also demonstrated in an agreement with our previous reports on the existence of cytosol protein independent intermembranous translocation of phospholipids. These experimental findings are discussed in terms of possible physiological significance and reaction mechanisms involved in the mitochondrial import of lipids and liponucleotides from the microsomal membranes of guinea pig liver.     

Selective enzymatic radioactive and spin labelling of phospholipids in biological membranes: application to study of temperature-induced changes of microsomal phosphatidylinositols and mitochondrial polyglycerophosphatides.

A new method for the covalent radioactive and spin labelling of lipids within isolated biological membranes has been described in detail and applied to studies of temperature-induced changes of microsomal and mitochondrial membranes. The method is based on the enzymatic use of radioactive substrates carrying covalently bound doxyl derivatives of stearic acid in the biosynthesis of phospholipids in isolated membranes. Radioactive-and spin-labelled lipids bound to the microsomal and mitochondrial membranes were then used as internal probes in monitoring temperature-induced changes of these membranes. Since the analysis of isolated radioactive-and spin-labelled lipids revealed the exact composition of membrane-bound labelled lipids, specific temperature-induced changes were correlated with specific lipids of examined membranes. Phosphatidylinositol of microsomal membranes and polyglycerophosphatides (phosphatidyl-glycerol and cardiolipin) of mitochondrial and inner mitochondrial membranes were found to be involved in the apparent formation of lipid clusters at around 20-30 degrees C. Cardiolipin was found to be involved in the fluidization of inner mitochondrial membranes. These findings are discussed in view of the present state of knowledge of the organization of lipids in biological membranes.     

Glucagon-stimulated adenylate cyclase detects a selective perturbation of the inner half of the liver plasma-membrane bilayer achieved by the local anaesthetic prilocaine.

Prilocaine can increase the fluidity of rat liver plasma membranes, as indicated by a fatty acid spin-probe. This led to the activation of the membrane-bound fluoride-stimulated adenylate cyclase activity, but not the Lubrol-solubilized activity, suggesting that increased lipid fluidity can activate the enzyme. With increasing prilocaine concentrations above 10 mM, the membrane-bound fluoride-stimulated activity was progressively inhibited, even though bilayer fluidity continued to increase and the activity of the solubilized enzyme remained unaffected. Glucagon-stimulated adenylate cyclase was progressively inhibited by increasing prilocaine concentrations. Prilocaine (10 mM) had no effect on the lipid phase separation occurring at 28 degrees C and attributed to those lipids in the external half of the bilayer, as indicated by Arrhenius plots of both glucagon-stimulated adenylate cyclase activity and the order parameter of a fatty acid spin-probe. However, 10 mM-prilocaine induced a lipid phase separation at around 11 degrees C that was attributed to the lipids of the internal (cytosol-facing) half of the bilayer. It is suggested that prilocaine (10 mM) can selectively perturb the inner half of the bilayer of rat liver plasma membranes owing to its preferential interaction with the acidic phospholipids residing there.     

Quick-freeze differential scanning calorimetry and saturation transfer electron spin resonance: novel techniques for assessing phase transitions in biological membranes

Quick-freeze differential scanning calorimetry (QF-DSC) and saturation transfer-electron spin resonance (ST-ESR) spectroscopy were used to study lipid gel-phase transitions in mature green tomato fruit microsomal membranes. ST-ESR of 12-doxyl methyl stearate labelled membranes proved to be reproducible and provided increased sensitivity to temperature-induced structural changes, allowing the detection of several transitions in isolated membranes (6 degrees C, 21 degrees C, 28 degrees C). QF-DSC led to the assessment of lipid gel phase transitions in isolated microsomal membranes and microsomal membrane lipids by enhancing the transition. A phase transition enthalpy of 114 J/g and an onset temperature of 29.8 degrees C were obtained for whole membranes while with isolated lipids values of 370 J/g and 19.9 degrees C were found.     

Biosynthetic incorporation of cis-parinaric acid into radioactive sn-3-phosphatidic acid

Isolated guinea pig liver microsomal membranes catalyzed the incorporation of naturally occurring cis-parinaric acid into sn-3-[U-14C]glycerophosphate. This resulted in the formation of sn-3-[14C](parinaroyl)phosphatidic acid, which was isolated by Chelex-100 and DEAE-cellulose column chromatography and further purified by Sephadex-G 25. The sn-3-[14C](parinaroyl)phosphatidic acid thus obtained exhibited absorption and fluorescence spectra substantially different from the cis-parinaric acid. Distribution of the incorporated cis-parinaric acid between the hydroxyl groups of biosynthesized sn-3-[14C]phosphatidic acid was determined by degradation with Crotalus adamanteus venom. This established that the major portion of the incorporated cis-parinaric acid esterified the secondary hydroxyl group in the sn-3-[14C]phosphatidic acid, while the primary hydroxyl group was esterified to a significantly lesser degree. The similarity between the biochemical incorporation of isomeric doxyl stearic acids into lipids of biological membranes and that of cis-parinaric acid into sn-3-phosphatidic acid described in this communication are discussed in relation to the possible use of these probes in studies of intact biological membranes.     

Investigation of secondary and tertiary structural changes of cytochrome c in complexes with anionic lipids using amide hydrogen exchange measurements: an FTIR study.

The structure of cytochrome c bound to anionic lipid membranes composed of dimyristoyl, dipalmitoyl, or dioleoyl phosphatidylglycerols, or of bovine heart cardiolipin, has been investigated by Fourier transform infrared spectroscopy. Only small changes in secondary structure, as registered by the amide I band of cytochrome c, were observed upon binding at temperatures below that of denaturation of the protein, and these were not coupled to the thermotropic phase transitions of the lipid. The denaturation temperature of the protein decreased by approximately 25-30 degrees upon binding, in a progression which correlated with that of the lipid phase transition temperatures, being approximately 7 degrees lower for complexes with dioleoyl than with dipalmitoyl phosphatidylglycerol. Large changes in the amide proton exchange characteristics, as monitored by the spectral shifts in the amide I band of the protein in D2O, were observed on binding cytochrome c to the lipid membranes. For the slowly exchanging population, the amide deuteration rates of the free protein were nearly independent of temperature, whereas those of the bound protein increased by up to two orders of magnitude over the temperature range from 10 to 40 degrees C. In addition, the extent of exchange differed between the bound and unbound protein. A structural transition in the bound protein was detected as a discontinuous step in Arrhenius plots of the deuterium exchange rates which occurred at a temperature in the region of 22 to 29 degrees C, depending on the lipid, far below that of denaturation. The temperature of this transition was determined by the physical state of the lipid, being 7 degrees lower for the lipids in the fluid state than for those in the gel state, and, for complexes with dimyristoyl phosphatidylglycerol, occurred at an intermediate temperature, being controlled by the lipid chain-melting transition at 27-28 degrees C. These results provide evidence for a coupling of the tertiary structure of the membrane-bound protein with the physical state of the membrane lipids.     

Effects of growth at different temperatures on the physical state of lipids in native microsomal membranes from Tetrahymena

Fluorescence measurements of the probe 1,6-diphenyl-1,3,5-hexatriene in native Tetrahymena pyriformis microsomal membranes revealed characteristic "break points" in curves of polarization vs. temperature. In the 5--35 degree C range, membranes from cells grown at 39 degrees C exhibited two break points, one at 11.6 +/- 0.6 degrees C and another at 23.1 +/- 1.6 degrees C. Membranes from 15 degrees C grown cells also showed two break points, one at 8.0 +/- 1.7 degrees C and another at 17.7 +/- 1.7 degrees C. Complementary measurements of turbidity (absorbance at 360 nm) vs. temperature revealed break points at approximately the same temperatures as observed with the fluorescent probe, thus strengthening the likelihood that the break points signify the onset or termination of lipid phase separations or some other significant structural alteration of lipids. In general, break points measured in the native membrane samples occurred at slightly lower temperatures than did break points in lipids extracted from comparable membranes. This suggests two possible types of protein--lipid interaction. First, there may be a selective withdrawal of relatively highly saturated phospholipid molecular species from the bulk lipid phase and into protein annulus regions. Alternatively, the configuration of the hydrophobic core of certain key membrane proteins may be such that nonspecific interactions with the lipids stabilize the liquid-crystalline phase.     

Liver ischemia increases the molecular order of microsomal membranes by increasing the cholesterol-to-phospholipid ratio

An accelerated degradation of phospholipid is the likely basis of irreversible cell injury in ischemia, and the membranes of the endoplasmic reticulum of the liver are a convenient system with which to study the effect of such a disturbance on the structure and function of cellular membranes. In the present report, electron spin resonance spectroscopy has been used to evaluate changes in the molecular ordering of microsomal membrane phospholipids in the attempt to relate the loss of lipid to alterations in membrane structure. The order parameter, S, was calculated from spectra reflecting the anisotropic motion of 12-doxyl stearic acid incorporated into normal and 3-h ischemic microsomal membranes. Over the temperature range 4-40 degrees C, the molecular order (S) of ischemic membranes was increased by 8-10%. This increase was reproduced in the ordering of the phospholipids in liposomes prepared from total lipid extracts of the same membranes. In contrast, after removal of the neutral lipids, liposomes prepared from phospholipids of ischemic and control membranes had the same molecular order. There were no differences in the phospholipid species of control and ischemic membranes or in the fatty acid composition of the phospholipids. In the neutral lipid fraction of ischemic membranes, however, triglycerides and cholesterol were increased compared to control preparations. There were no free fatty acids. The total cholesterol content of the liver was unchanged after 3 h of ischemia. The cholesterol-to-phospholipid ratio of ischemic membranes, however, was increased by 22% from 0.258 to 0.315 as a consequence of the loss of phospholipid. Addition of cholesterol to the control total lipid extracts to give a cholesterol-to-phospholipid ratio the same as in ischemic membranes resulted in liposomes with order parameters similar to those of liposomes prepared from ischemic total lipids. It is concluded that the degradation of the phospholipids of the microsomal membrane results in a relative increase in the cholesterol-to-phospholipid ratio. This is accompanied, in turn, by an increased molecular order of the residual membrane phospholipids.     

Characterization of nuclear membranes and endoplasmic reticulum isolated from plant tissue

Nuclei, nuclear membranes and rough endoplasmic reticulum (rER) were isolated from onion root tips and stems. Structural preservation and purity of the fractions was determined by electron microscopic and biochemical methods. Gross compositional data (protein, phospholipid, nonpolar lipids, sterols, RNA, DNA), phospholipid and fatty acid patterns, enzyme activities (ATPases, ADPase, IDPase, glucose-6-phosphatase, 5'-nucleotidase, acid phosphatase, and NADH- and NADPH-cytochrome C reductases), and cytochrome contents were determined. A stable, high salt-resistant attachment of some DNA with the nuclear membrane was observed as well as the association of some RNA with high salt-treated nuclear and rER membranes. The phospholipid pattern was identical for both nuclear and rER membranes and showed a predominance of lecithin (about 60%) and phosphatidyl ethanolamine (20-24%). Special care was necessary to minimize lipid degradation by phospholipases during isolations. Nonpolar lipids, mostly sterols and triglycerides, accounted for 35-45% of the membrane lipids. Sterol contents were relatively high in both membrane fractions (molar ratios of sterols to phospholipids ranged from 0.12 to 0.43). Sitosterol accounted for about 80% of the total sterols. Palmitic, oleic, and linoleic acids were the most prevalent acids in membrane-bound lipids as well as in storage lipids and occurred in similar proportions in phospholipids, triglycerides and free fatty acids of the membrane. About 80% of the fatty acids in membrane phospholipids and triglycerides were unsaturated. A cytochrome of the b5 type was characterized in these membranes, but P-450-like cytochromes could not be detected. Both NADH and NADPH-cytochrome c reductases were found in nuclear and rER membranes and appeared to be enriched in rER membranes. Among the phosphatases, Mg2+-ATPase and, to lesser extents, ADPase, IDPase and acid phosphatase activities occurred in the fractions, but significant amounts of monovalent ion-stimulated ATPase, 5'-nucleotidase and glucose-6-phosphatase activities did not. The results obtained emphasize that the close biochemical similarities noted between rER and nuclear membranes of animal cells extend to these fractions from plant cells.     

Phospholipids and structural modification of tissues and cell membranes for adaptation in high altitude mountains

The nature of the impact of physical factors of high altitudes (3200 m) on the lipids of tissues and membranes of animals was researched. It was established that the adaptation process in Wistar rats was followed by peroxide degradation and subsequent modification of the phospholipids' structure of tissues and microsomal membranes. Adaptive phospholipids reconstruction takes place in microsomal membranes in the tissues of the lungs, brain, liver and skeletal muscles. Together with this, the amount of phosphatidylinositol and phosphatidic acid accumulates, indicating that the hydrolysis of phosphatidylinositol-4, 5 biphosphate to diacylglycerol and secondary messenger--inositol triphosphate, occurs. A decrease in temperature adaptation (+10 degrees C) leads to a more noticeable shift in peroxide oxidation of lipids, phospholipid structure in the tissues and membranes rather than adaptation in thermoneutral conditions (+30 degrees C). Modification of lipid composition of tissues and cell membranes in the highlands obviously increases the adaptive capabilities of cells of the whole body: physical performance and resistance to hypoxia increases in animals.     

Mechanism of release of integral proteins from rat liver microsomal membranes

The release of three integral enzymatic activities (NADH- and NADPH-cytochrome c reductase and 5'-nucleotidase) and total protein from washed rat liver microsomal membranes, upon simple incubation at 37 degrees C in aqueous media, was investigated. Release does not depend on contaminating proteases and is enhanced by alkaline pH. Total protein and enzyme release is consistent with a loss of phospholipids which are not recovered in the soluble phase. Following incubation at pH 9.0 large amounts of free fatty acids were recovered in the soluble phase, accounting for a ratio of 1/1 (w/w) with released protein. This evidence, together with the data available about densities (1.07-1.08 g/ml) and molecular weights (1 700 000-700 000) of the released enzymes, suggests that they are solubilized from microsomal membranes in the form of mixed micelles mostly formed by free fatty acids and integral proteins, probably owing to the activity of endogenous phospholipases on membrane lipids. Release of total protein and enzymatic activities is decreased by Ca2+, whose possible role in the phenomenon is discussed.     

On the interaction of a lipophilic drug with different sites of rat-liver microsomes. Equilibrium studies with a substituted pleuromutilin.

The binding of the diterpenoid drug 14-deoxy-14-[(2'-diethylamino-ethyl)-mercaptoacetoxy]-dihydromutilin hydrogen fumarate in the cell of rat liver is mainly to the microsomal fraction. Besides specific binding to cytochrome P-450, where the enzymic degradation of the drug occurs, we observed a very high number of identical sites (site A) with an affinity of approximately 4.2 x 10(3) M(-1) (25 degrees C, PH 7.4). Model investigations demonstrate that these interactions occur almost exclusively with the microsomal phospholipid moiety. Their capacity for the drug was determinated to be of the order of 0.2 mol/mol phospholipid. The specific interaction of the pleuromutilin derivative with cytochrome P-450 gives rise to different spectral changes of the protein. At low concentrations where weak cooperativity of the overall binding to microsomes (sites B) was found, the formation of a type I complex was observed. At increasing concentrations of the drug this interaction vanishes and a spectral change of a different type (modified type II) arises. The affinity for this complex is identical with that of the phospholipid binding sites. The interaction of the drug with the phospholipid moiety might give rise to dual effects. Firstly the very near neighbourhood of a multitude of relatively weak binding sites will facilitate a transport of the drug along the microsomal membranes. Secondly, the loading of the membranes with the drug at high concentrations might influence the binding to cytochrome P-450 so that a qualitatively different interaction takes place.     

Proteolysis of human reticulocyte membrane proteins: Evidence for a physiological role of the acid endopeptidases

Endogenous membrane proteins, labeled by incubating human reticulocytes with l-[¹⁴C]leucine, are degraded at pH 7.3 by membrane-bound acid proteinases. Solubilized membrane proteins are also degraded at neutral pH by the purified membrane acid proteinases. Exogenous proteins are not degraded by intact membranes and therefore association with the membrane seems to be an essential requirement for protein degradation in the physiological pH range. These findings provide evidence for a physiological function of the enzymes previously characterized as acid proteinases.     

Factors affecting steroid and prostaglandin secretion by reproductive tissues of cycling and pregnant sows in vitro

Mitochondrial, microsomal and pellicular membranes were isolated from Tetrahymena cells grown at 39 degrees C or 15 degrees C, and phospholipids, in turn, were separated from total lipids extracted from these membranes. The effect of growth temperature on their solid-to-fluid phase transition temperature was examined by wide-angle X-ray diffraction. The transition temperatures of phospholipids from mitochondria, microsomes and pellicles were 21, 19 and 26 degrees C for cells grown at 39 degrees C and -8, -3 and 6 degrees C for cells grown at 15 degrees C, respectively. All phospholipids were found in a completely fluid state at these growth temperatures. From a comparison between the phospholipids and total lipids from pellicles of cells grown at 39 degrees C, a triterpenoid alcohol, tetrahymanol, caused the transition temperature to increase. The alignment of tetrahymanol in membranes was examined with pellicle'a total lipid oriented in a sample holder.     

Interactions between beta-lactam antibiotics and isolated membranes of Streptococcus faecalis ATCC 9790.

The DD-carboxypeptidase-exchange membrane-bound enzyme in Streptococcus faecalis ATCC 9790 reacts with beta-lactam antibiotics to form complexes with rather long half-lives. Depending upon the antibiotic, the second-order rate constants for complex formation range from 0.75-560 M-1 S-1 (at 37 degrees C and in water) and the first-order rate constants for complex breakdown range from 1.3 to 26 x 10(-5) s-1 (at 37 degrees C and in 5 mM phosphate buffer pH 7.5). There are about 30 pmol of DD-carboxypeptidase-exchange enzyme per mg of membrane protein. The degradation products arising from benzylpenicillin are phenylacetylglycine and probably N-formyl-D-penicillamine. Isolated membranes also contain other penicillin binding sites (about 70 pmol/mg membrane protein). That part of benzylpenicillin which reacts with at least some of these latter sites is slowly degraded into penicilloic acid. Normal functioning of the DD-carboxypeptidase-exchange membrane-bound enzyme is important, if not essential, for cell growth. With the beta-lactam antibiotics tested inhibition of cell growth is mainly related to the rates of formation of the inactive enzyme-antibiotic complexes. The relationship, however, is not a direct one probably due to the competitive effect exerted by the other penicillin binding sites.     

Effect of the state of the lipid phase of the membrane on the effectiveness of photochemical modification of erythrocyte acetylcholinesterase

Modification of the lipid phase structure of the erythrocyte membrane by phospholipases A2, C and D as well as the partial depletion of cholesterol was shown to be accompanied by the change of the acetylcholinesterase (AChE) UV-sensitivity. The ability of UV-light to change the catalytic properties (Km) of the membrane-bound AChE not observed for free AChE (constant value of Km) and known as the phenomenon of photochemical allotopy, is retained in the cholesterol depleted membranes and disappears after an enzymatic treatment of the membranes by phospholipases. The possible non-photochemical influence of the membrane lipid phase in response to UV-damage of membrane-bound AChE is discussed.     

The relation between lipid mobility and the specific hormone binding of thyroid membranes.

1. The specific binding of thyroid-stimulating hormone to isolated human thyroid membranes was examined under a variety of conditions. 2. In phosphate-saline buffer (in the presence of 0.14 M-NaCl) on increasing the temperature the binding of the hormone is increased, the plots of bound/free hormone against temperature showing a distinct break around 30 degrees C. 3. Detailed analysis showed that the increased binding is associated with an increase in the number of binding sites. 4. The motional characteristics of three membrane-bound fluorescent probes, 2-(9-anthroyl)palmitic acid, 12-(9-anthryl)stearic acid and N-1-naphthyl-N-phenylamine, were also examined as a function of temperature by measuring both fluorescence polarizations and lifetimes. 5. The results indicated that the 'fluidity' of membrane lipids also increased with temperature. The temperature-dependence of this property also shows a change at about 30 degrees C. 6. Bivalent cations decreased both membrane fluidity and hormone binding. 7. Similar correlations were found between the binding of adrenocorticotrophic hormone and the fluidity of the plasma membranes obtained from adrenal-cortical cells, with the discontinuity occurring in this case at 23 degrees C. 8. The possibility of lipid mobility being important in controlling hormone-receptor function is discussed.