Cytochrome P-450scc-substrate interactions. Role of the 3 beta- and side chain hydroxyls in binding to oxidized and reduced forms of the enzyme

The steroid binding specificity of cytochrome P-450scc has been investigated for different oxidation/reduction and ligand-binding states of the enzyme (oxidized, reduced, oxygen-bound, and carbon monoxide-bound forms). The oxygen of the 3 beta-hydroxyl of cholesterol is important for the initial enzyme-substrate interaction. Significant binding requires the correct stereochemistry and appears to be controlled by the electron density on the 3 beta-oxygen. Interactions at this position (located at least 13 A from the heme iron) can modulate the heme midpoint potential. The binding site in this region contains a cleft which can accommodate up to two carbons joined in an ether linkage to the 3 beta-oxygen. The steroid intermediates of side chain cleavage (22R-hydroxycholesterol and 20 alpha,22R-dihydroxycholesterol) bind more tightly to the ferric enzyme than does cholesterol and utilize specific interactions of these side chain hydroxyls with a grouping(s) on the polypeptide chain (i.e. not with the heme iron). The interaction requires the correct stereochemistry; a 22S-hydroxyl cannot be readily accommodated in the binding site. The specificity of the interaction for hydroxyls at the 22R- versus the 20 alpha-position is altered upon reduction of the enzyme, indicating a reduction-induced conformational change in the active site. The specific interference of binding of 22R-hydroxy steroids by heme-bound carbon monoxide (but not oxygen), together with the known bond angles and distances for Fe-C-O and Fe-O-O, allows localization of the 22R-hydroxyl group on a line perpendicular to the heme plane, between 2 and 3 A from the iron.     

Cell binding, uptake and cytosolic partition of HIV anti-gag phosphodiester oligonucleotides 3'-linked to cholesterol derivatives in macrophages

The purpose of this study is to evaluate the cell interactions of a new class of compounds composed of phosphodiester oligonucleotides linked to the cholesterol group at position 3, 7, or 22 of the steroid structure. The resulting conjugates were assessed for their capacity to bind, penetrate and partition in the cytoplasmic compartment of murine macrophages. The results showed that lipophilic conjugates bind to cells much faster (t(1/2) < or = 10 min) than do underivatized oligomers. Oligomers tethered to the cholesterol at positions 3 and 7 (PO-GEM-3-Chol and PO-GEM-7-Chol) interacted more efficiently with cell membranes and were better internalized than oligomers attached to the cholesterol moiety at position 22 (PO-GEM-22-Chol). The cytosolic fraction of internalized oligomers was studied by a digitonin-based membrane permeabilization method. The recovered fraction of oligomers that can freely diffuse from the cytosol was comparable for GEM-91, a phosphorothioate congener, and for PO-GEM-7-Chol (50-60% of the internalized oligomers), while that of PO-GEM-3-Chol was less (30% of the internalized oligomers) indicating a higher membrane affinity of the latter derivative as compared to the other investigated compounds. Membrane binding and cell internalization correlated well with the hydrophobicity of the conjugates as characterized by their partition coefficients in a water-octanol system. Due to their capacity of rapid binding and cytosolic partition in cells, cholesterol-derivatized oligonucleotides at position 3 or 7 of the steroid molecule appeared as good candidates for systemic delivery of anti-HIV antisense compounds.     

Steroid hormone biosynthesis by a sesterterpene pathway in the rat and rabbit testis

Rat and rabbit testis preparations were incubated with [4-14C]cholesterol and 23,24-dinor-[7 alpha-3H]5-cholen-3 beta-ol, the latter being a proposed intermediate in the sesterterpene pathway for steroid biosynthesis. Steroids were isolated, purified by thin-layer chromatography and crystallised to constant specific activity. It was found that rat and rabbit testis can utilise 23,24-dinor-5-cholen-3 beta-ol to produce testosterone. The tritium/carbon-14 ratios in the testosterone and androstenedione isolated indicated that these tissues differentiated between the two substrates. This finding is supported by the observation that, on stimulation with HCG, the tritium/carbon-14 ratios in the testosterone isolated were increased compared to the controls. The results of further experiments implied that, while the biosynthesis of testosterone from cholesterol occurred in the rat testis mitochondrial fraction, its biosynthesis from 23,24-dinor-5-cholen-3 beta-ol occurred in the microsomal fraction.     

Electronic and stereochemical characterizations of intermediates in the photolysis of ferric cytochrome P450scc nitrosyl complexes. Effects of cholesterol and its analogues on ligand binding structures.

Low temperature photolysis of nitric oxide from the nitrosyl complexes of ferric cytochrome P450scc was examined by EPR spectroscopy to elucidate the stereochemical interaction between heme-bound ligand and side-chain of cholesterol or its hydroxylated analogues at the substrate-binding site. The photoproducts of the NO complexes trapped at 5 K exhibited new EPR absorptions providing information on the steric crowding of the distal heme moiety. Without substrate, the photoproduct exhibited a broad EPR absorption at g-8 due to magnetic dipole-dipole interaction between the photo-dissociated NO (S = 1/2) and the ferric iron (S = 5/2). This indicates that the photo-dissociated NO can move far away from the heme iron in the less restricted distal heme moiety of the substrate-free cytochrome P450scc. In the presence of substrates, such as cholesterol, 20(S)-hydroxycholesterol, 22(S)-hydroxycholesterol, 22(R)-hydroxycholesterol, and 25-hydroxycholesterol, the EPR spectra of the photoproducts exhibited many variations having broad g-8 absorptions and/or the widespread signals together with zero-field absorption. Among the steroid complexes used, 20(S)-hydroxycholesterol complex exhibited a conspicuously widespread EPR signal with a distinct zero-field absorption due to a spin-coupled interaction between the ferric iron (S = 5/2) and the photolyzed NO (S = 1/2). These results indicate that the 20(S)-hydroxycholesterol complex has restricted substrate-binding structure and that the hydroxylation of the cholesterol side-chain at the 22R position is necessary to proceed the side-chain cleavage reaction properly in cytochrome P450scc.     

The enzyme activity of bovine adrenocortical cytochrome P-450 producing pregnenolone from cholesterol: Kinetic and electrophoretic studies on the reactivity of hydroxycholesterol intermediates

Electrofocusing of a highly-purified preparation of bovine adrenocortical cytochrome P-450(scc) showed a single peak of enzyme activity at pH 6.8, when either cholesterol, [20S]-20-hydroxycholesterol, [22R]-22-hydroxycholesterol or [20R, 22R]-20, 22-dihydroxycholesterol was used as the substrate for the side chain cleavage reaction. The formation of pregnenolone from these hydroxycholesterols was inhibited by [20R, 22S]-20, 22-epoxycholesterol similarly in a competitive manner and the Ki value for the epoxide was found to be 12–15 μM for all these substrates. When one of the above mentioned substrates was incubated in a concentration sufficient for maximal reaction velocity, the addition of another hydroxycholesterol did not result in further increase of pregnenolone production. These results support the assumption that a single species of enzyme catalyzes all the three steps of the reaction, i.e., 20-hydroxylation, 22-hydroxylation and cleavage of carbon chain between carbon-20 and carbon-22.     

Active site-directed inhibitors of cytochrome P-450scc. Structural and mechanistic implications of a side chain-substituted series of amino-steroids

A series of analogues of cholesterol, each having a shortened side chain and a primary amine group, were prepared and tested for their effects on bovine adrenocortical cholesterol side chain cleavage cytochrome P-450 (P-450scc). A previous study had shown that one derivative, 22-amino-23,24-bisnor-5-cholen-3 beta-ol, is a potent competitive inhibitor of the enzyme and forms a complex in which the steroid ring binds to the cholesterol site and the side chain amine forms a bond with the heme iron (Sheets, J. J., and Vickery, L. E. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 5773-5777). In the studies reported here, the 23-amine derivative, 23-amino-24-nor-5-cholen-3 beta-ol, was found to be an equally potent inhibitor and to be competitive with respect to cholesterol (Ki = 38 nM). Binding of the 23-amine to P-450scc also caused formation of a low spin complex with an absorption maximum at 422 nm, indicative of a nitrogen-donor ligand. Other derivatives in which the side chain amine was linked closer to the steroid, 17 beta-amino-5-androsten-3 beta-ol and (20 R + S)-20-amino-5-pregnen-3 beta-ol, were found to be only very weak inhibitors (I50 greater than 100 microM) and did not produce the 422 nm spectral form when bound. Derivatives in which the amine was attached a greater distance from the steroid ring, 24-amino-5-cholen-3 beta-ol and 25-amino-26,27-bisnor-5-cholesten-3 beta-ol, caused a progressive decrease in inhibitory potency and a failure to produce the 422 nm form on binding. The dependence of the type of interaction of these amino-steroids with P-450scc upon the amine position establishes that the steroid binding site and the heme catalytic site of the enzyme are fixed within a specific distance of one another. The heme appears to be located sufficiently close to the position that the side chain of cholesterol would occupy to allow for direct attack of an iron-bound oxidant to occur during hydroxylation and side chain cleavage.     

Cytochrome P-450 of adrenal mitochondria. Spin states as detected by difference spectroscopy.

Adrenal mitochondrial cytochrome P-450 which functions in cholesterol side chain cleavage (P-450scc) exhibited type I (lambdamax 385, lambdamin 420 nm) and inverse type I (lambdamin 385, lambdamax 420 nm) difference spectra with several steroids. The magnitude and type of response were dependent on the particular steroid and on the extent to which cholesterol was bound to the cytochrome in the intact mitochondrion. the inverse type I difference spectrum induced by 3beta-hydroxy-pregn-5-ene-20-one (pregnenolone) was dependent on the proportion of high spin cholesterol-cytochrome P-450scc complexes. With rat adrenal mitochondria cholest-5-ene-3beta, 20alpha-diol (20alpha-hydroxycholesterol) invariably induced a smaller inverse type I response and, under conditions where cytochrome P-450scc was nearly free of cholesterol, even produced a small type I response. Two distinct steroid binding sites on cytochrome P-450scc were detected by, respectively, the slow type I response to cholest-5-ene-3beta, 25-diol (25-hydroxycholesterol) and the rapid type I response to a subsequent addition of cholest-5-ene-3beta, 20alpha, 22 R-triol (20alpha, 22R-dihydroxycholesterol). The relative proportions of the spectral responses to these steroids were dependent on the previous extent of adrenal activation by adrenocorticotropic hormone (ACTH), because this stimulatory process altered the combination of mitochondrial cholesterol with cytochrome P-450scc. It is proposed that the two steroid binding sites on cytochrome P-450scc interact with steroids in the following way: site I binds cholesterol, 25-hydroxycholesterol, and 20alpha, 22R-dihydroxycholesterol with formation of a partially high spin cytochrome; site II binds both pregnenolone and 20alpha-OH cholesterol resulting in a low spin cytochrome. Interactions between sites I and II are not competitive, and occupancy of site II ensures a low spin state irrespective of the occupancy of site I. A second mode of interaction by 20alpha, 22R-dihydroxycholesterol stabilizes a high spin cytochrome and is competitive with site II binding by 20alpha-hydroxycholesterol or pregnenolone. Formation of a maximally high spin cytochrome follows occupancy by 20alpha, 22R-dihydroxycholesterol at both sites.     

Pregnenolone synthesis from cholesterol and hydroxycholesterols by mitochondria from ovaries following the stimulation of immature rats with pregnant mare's serum gonadotropin and human choriogonadotropin

The rate of pregnenolone synthesis by cytochrome P-450scc was measured in mitochondria isolated from ovaries of immature rats treated with pregnant mare's serum gonadotropin and human choriogonadotropin. Using cholesterol, 25-hydroxycholesterol, 20 alpha-hydroxycholesterol, (22R)-22-hydroxycholesterol and (22R)-20 alpha,22-dihydroxycholesterol as substrates, we have determined that the first hydroxylation of cholesterol, in the 22R position, is rate limiting in pregnenolone synthesis. It proceeds at only 22% of the rate of either of the subsequent two hydroxylations. 25-Hydroxycholesterol proved to be a suitable substrate for determining the maximum rate of pregnenolone synthesis by cytochrome P-450scc in isolated mitochondria. The maximum rate was 13 mol steroid.min-1.mol cytochrome P-450scc-1 and did not change after the follicles in the immature ovary had been stimulated to mature and luteinize with gonadotropin. Using endogenous cholesterol in isolated mitochondria as substrate, the time course of pregnenolone synthesis was the same during the follicular phase as in the luteal stage of gonadotropin-induced development. We conclude that during the artificial induced development of follicles in the immature ovary, the major cause of the increase in the rate of pregnenolone synthesis is the increase in the cytochrome P-450scc content of the mitochondria, rather than changes in the catalytic activity of cytochrome P-450scc or the cholesterol availability to the cytochrome.     

The importance of the phospholipid bilayer and the length of the cholesterol molecule in membrane structure.

The properties of mixtures of phosphatidylcholine and analogues of cholesterol bearing side chains of varying lengths were examined by a variety of methods. The incorporation of the analogues into sonicated liposomes and their effect on the rate of osmotic shrinking of multilamellar liposomes were determined. The ordering of a steroid spin label was studied in an oriented multibilayer system and the effect of the analogues on the phase transition of dipalmitoyl phosphatidylcholine monitored using the spin label TEMPO (2,2,6,6-tetramethylpiperidine-N-oxyl). Mixtures of analogues and phospholipid were also studied in monolayers. In all the bilayer systems studied cholesterol caused the greatest 'rigidifying' effect, the analogues with shorter or longer side chains being less effective. However, in the monolayer experiments the length of the sterol molecule was found to be much less critical. It is suggested that cholesterol is anchored in position in a phospholipid bilayer by virtue of the molecule being the precise length required to maximise interactions between neighbouring molecules without disturbing the bilayer structure.     

Metabolic conversion of six steroid hormones by human plasma high-density lipoprotein

Sixteen different steroid hormones were individually tested in equilibrium dialysis against plasma high-density, low-density and very-low-density lipoproteins (HDL, LDL, VLDL) under physiological conditions. Six steroid hormones (androstenediol (AEDOL), estradiol (E2), dehydroepiandrosterone (DHEA), dihydrotestosterone (DHT), pregnenolone (P5), and progesterone (P4)) demonstrated metabolic interaction with HDL, particularly HDL3. In four cases (AEDOL-HDL, E2-HDL, DHEA-HDL and P5-HDL) the interaction products were more lipophilic, while in the other two cases (DHT-HDL, P4-HDL) they were hydrophilic compared to the original steroid hormone substrates. The lipophilic products appeared to be long-chain fatty acid steroid hormone esters at the C-3 position of the steroid hormone. This was confirmed, in preparative incubations, for the two strongest steroid hormone reactants (DHEA and P5) by gas chromatography-mass spectroscopy (GC-MS). Naturally occurring DHEA and P5 esters were identified in normal fresh human plasma by GC-MS, and their fatty acid compositions were similar to that of native HDL3 cholesterol esters. It was deduced that lecithin-cholesterol acyl transferase enzyme was responsible for the lipophilic type conversion activity with P5 greater than DHEA greater than AEDOL greater than E2. For DHT and P4, which exhibit a fundamentally different (hydrophilic) type of metabolic conversion, a totally different form of HDL-associated metabolic activity is indicated. These newly discovered steroid hormone-lipoprotein interactions may be important for steroid hormone processing in plasma and/or steroid hormone delivery to cells.     

Optimum interaction of sterol side chains with phosphatidylcholine.

The specificity of the interaction between the cholesterol side chain and egg phosphatidylcholine was precisely defined by examining the effect of three new analogues of cholesterol with modified side chains on the ordering of two steroid spin labels in liposomes. The complete side chain of cholesterol was shown to be required for maximum ordering. Sterols with side chains shorter or longer than cholesterol caused significantly less ordering.     

Optimum interaction of sterol side chains with phosphatidylcholine

The specificity of the interaction between the cholesterol side chain and egg phosphatidylcholine was precisely defined by examining the effect of three new analogues of cholesterol with modified side chains on the ordering of two steroid spin labels in liposomes. The complete side chain of cholesterol was shown to be required for maximum ordering. Sterols with side chains shorter or longer than cholesterol caused significantly less ordering.     

Configurations of fatty acyl chains in egg phosphatidylcholine-cholesterol mixed bilayers

Based on the structural properties of cholesterol and egg phosphatidylcholine, and on the assumption that the van der Waals' type attactive interaction between the steroid nucleus and the fatty acyl chains provides a stabilizing force for the cholesterol-egg phosphatidylcholine complex, some specific orientation and configurations of the fatty acyl chains around the steroid nucleus in the interacting system are proposed in terms of an optimal packing. The proposed model suggests that the saturated chains are largely facing the flattened (α) surface of the steroid nucleus of cholesterol, while the unsaturated chains can interact with both the α and β surfaces of the steroid nucleus. It is also suggested that the angular methyl groups on the β surface of the steroid nucleus lock the unsaturated fatty acyl chain in a relatively immobile configuration. Experimental evidence which provides support for the proposed stereochemical model is presented.     

Effects of cholesterol analogues and inhibitors on the heme moiety of cytochrome P-450scc: a resonance Raman study

Interactions of cholesterol analogues and inhibitors with the heme moiety of cytochrome P-450scc were examined by resonance Raman spectroscopy. The Raman spectra of ferric cytochrome P-450scc complexed with inhibitors such as cyanide, phenyl isocyanide, aminoglutethimide, and metyrapone were characteristic of low-spin state and were very similar. However, the effect of exchange of the sixth ligand from the oxygen atom (ferric low-spin state) to the nitrogen atom upon aminoglutethimide and metyrapone binding was seen as down-frequency shifts of the v3 band from 1503 to 1501 and 1502 cm-1, respectively, while cyanide and phenyl isocyanide binding caused an up-frequency shift of the v3 band to 1505 cm-1. The effects of cholesterol analogues [22(R)-hydroxycholesterol, 22(S)-hydroxycholesterol, 22-ketocholesterol, 20(S)-hydroxycholesterol, and 25-hydroxycholesterol] on a Fe2+-CO stretching frequency of cytochrome P-450scc in ferrous CO form were examined. The 22(R)-hydroxycholesterol complex could not give a clear Fe2+-CO stretching Raman band due to a strong photodissociability. 22(S)-Hydroxycholesterol and 25-hydroxycholesterol complexes gave the Raman bands at 487 and 483 cm-1, respectively, whereas 20(S)-hydroxycholesterol and 22-ketocholesterol complexes gave Fe2+-CO stretching frequencies (478 cm-1) almost identical with that without substrate (477 cm-1). These findings suggest the existence of the following physiologically important natures of the cytochrome P-450scc active site: (1) there is a strong steric interaction between heme-bound carbon monoxide and the 22(R)-hydroxyl group or the 22(R)-hydrogen of the steroid side chain and (2) the hydroxylation at the 20S position may cause a conformational change of the side-chain group relative to the heme.     

Cholesterol, hydroxycholesterols, and bile acids

Although a variety of oxidation products of cholesterol occur in vitro, enzyme-catalyzed oxidations can occur at only 5 sites on the cholesterol molecule: C7alpha, C22R, C24S, C25, and C27. The genes coding for the synthesis of these enzymes were cloned, the tissue expressions of the mRNAs were identified, and the enzymes were characterized. The biologic properties of the hydroxycholesterol molecules that are initially generated and their metabolites are under study. Downregulation of cholesterol synthesis via the SREBP/SCAP regulatory pathway is common to the initial hydroxycholesterols, but more variations exist with respect to these intermediates functioning as ligands for the nuclear receptor LXRalpha. Because this receptor regulates the expression of cholesterol 7alpha-hydroxylase and ABC transporter proteins, hydroxycholesterols and their intermediate steroid metabolites modulate a number of biologic processes. Metabolism of 22S-hydroxycholesterol to steroid hormones differs from that of the other hydroxycholesterols which form mostly steroid acidic products, otherwise known as bile acids. In vivo estimates of their production rates in intact humans indicate that 24S and 25-hydroxycholesterol account for no more than 7% of total bile acid production per day. Current evidence indicates that cholesterol 7alpha-hydroxycholesterol generated in the liver is the major source of bile acids in older adults. It is also known that the cholesterol 27-hydroxylation pathway is the only one expressed in fetal and neonatal life. Precisely when the proportions contributed by these two metabolic pathways to bile acid synthesis begin to shift and the role of the cholesterol 27-hydroxylase pathway in reverse cholesterol transport mandate further study.     

Discriminatory inhibition of adrenocortical 17 alpha-hydroxylase activity by inhibitors of cholesterol side chain cleavage cytochrome P-450

Two inhibitors of the cholesterol side chain cleavage reaction were tested for their ability to inhibit bovine adrenocortical 17 alpha-hydroxylase and 21-hydroxylase activities. One inhibitor, 22-amino-23,24-bisnor-5-cholen-3 beta-ol (22-ABC), was found to be a potent inhibitor of 17 alpha-hydroxylation of either progesterone or pregnenolone but was inactive on 21-hydroxylase activity. 22-ABC was found to be a competitive inhibitor of 17 alpha-hydroxylase (cytochrome P-45017 alpha) activity, having an apparent inhibitor constant of 29 nM when using pregnenolone as the substrate. Spectral binding studies showed that 22-ABC produces a type II difference spectrum when added to a bovine adrenocortical microsomal preparation, due presumably to a coordination of its amine nitrogen atom to the heme-iron of cytochrome P-45017 alpha. The second cholesterol side chain cleavage inhibitor tested, (20R)-20-phenyl-5-pregnene-3 beta,20-diol (20-PPD), was found not to inhibit either the 21- or 17 alpha-hydroxylase activities. It is proposed that the phenyl group projecting from C-20 of 20-PPD prevents this steroid from binding to cytochrome P-45017 alpha. The discriminatory interaction of these two steroids with adrenocortical cytochromes P-450 provides some insight with respect to possible structural features of the active-site regions of these enzymes.     

Site-specific mutagenesis of an essential histidine residue in pancreatic cholesterol esterase

The histidine residue essential for the catalytic activity of pancreatic cholesterol esterase (carboxylester lipase) has been identified in this study using sequence comparison and site-specific mutagenesis techniques. In the first approach, comparison of the primary structure of rat pancreatic cholesterol esterase with that of acetylcholinesterase and cholinesterase revealed two conserved histidine residues located at positions 420 and 435. The sequence in the region around histidine 420 is quite different between the three enzymes. However, histidine 435 is located in a 22-amino acid domain that is 47% homologous with other serine esterases. Based on this sequence homology, it was hypothesized that histidine 435 is the histidine residue essential for catalytic activity of cholesterol esterase. The role of His435 in the catalytic activity of pancreatic cholesterol esterase was then studied by the site-specific mutagenesis technique. Substitution of the histidine in position 435 with glutamine, arginine, alanine, serine, or aspartic acid abolished the ability of cholesterol esterase to hydrolyze p-nitrophenyl butyrate and cholesterol [14C]oleate. In contrast, mutagenesis of the histidine residue at position 420 to glutamine had no effect on cholesterol esterase enzyme activity. The results of this study strongly suggested that histidine 435 may be a component of the catalytic triad of pancreatic cholesterol esterase.     

Relationship of steroidal structure to ethylene production by etiolated mung bean segments

Several brassinosteroid (BR) analogues, cholesterol and aldosterone were evaluated for their effectiveness alone and in combination with indole-3-acetic acid (IAA) in stimulating ethylene production by etiolated mung bean ( Vigna radiata L. Rwilcz cv. Berken) hypocotyl segments. Changing the conformation of the two hydroxyl groups on C-22 and C-23 positions from α to β did not greatly reduce the efficiency of these compounds to stimulate ethylene production alone or in combination with IAA. There was little difference in activity observed when the conformation of the methyl group in the C-24 position was changed from α to β. However, when hydroxyls were deleted from the side chain in the C-22 and C-23 positions, the compound was rendered inactive alone or in combination with IAA. The compound was also inactivated by removing the 7-oxa function on the B-ring and by substituting an ethyl group for the methyl group in the C-24 position. Both aldosterone and cholesterol were ineffective in promoting ethylene production. This study shows that very stringent structural features are required for a steroid to have BR-like activity and to act synergistically with auxin in the promotion of ethylene synthesis.     

The Interaction between Steroid Hormones and Lipid Monolayers on Water

The interaction of progesterone, testosterone, androsterone, and etiocholanolone with insoluble lipid films (cholesterol and saturated hydrocarbons containing either alcohol, ester, acetamide, phosphate, amine, or carboxyl groups) was studied. In addition to surface pressure and surface potential measurements of the surface films, radioactive tracers were used to measure the concentration of adsorbed steroid in the lipid films. In general, steroids form mixed films with the insoluble lipid films. Compression of the insoluble lipid films to their most condensed state leads to complete ejection of adsorbed steroid from the surface in all cases except with the amine, for which a small amount of steroid is still retained in the surface. Interactions between the steroids and insoluble lipids are primarily due to van der Waals or dispersion forces; there were no significant contributions from dipole-dipole interactions (except possibly with the amine). Specific interactions between cholesterol and the soluble steroids were not observed. Evidence suggests that low steroid concentrations influence structure of lipid films by altering the hydration layer in the surface film. In contrast to a specific site of action, it is proposed that steroid hormones initiate structural changes in a variety of biological sites; this model of steroid action is consistent with the ubiquity of many steroid hormones.     

The importance of the phospholipid bilayer and the length of the cholesterol molecule in membrane structure

The properties of mixtures of phosphatidylcholine and analogues of cholesterol bearing side chains of varying lengths were examined by a variety of methods. The incorporation of the analogues into sonicated liposomes and their effect on the rate of osmotic shrinking of multilamellar liposomes were determined. The ordering of a steroid spin label was studied in an oriented multibilayer system and the effect of the analogues on the phase transition of dipalmitoyl phosphatidylcholine monitored using the spin label TEMPO ($\text{2,2,6,6-}\text{tetramethylpiperidine}\text{-N-}\text{oxyl}$). Mixtures of analogues and phospholipid were also studied in monolayers.In all the bilayer systems studied cholesterol caused the greatest ‘rigidifying’ effect, the analogues with shorter or longer side chains being less effective. However, in the monolayer experiments the length of the sterol molecule was found to be much less critical. It is suggested that cholesterol is anchored in position in a phospholipid bilayer by virtue of the molecule being the precise length required to maximise interactions between neighbouring molecules without disturbing the bilayer structure.