Chemicobiological interactions and the use of partition coefficients in their correlation

Drug Disposition in Subjects with Obesity: The Research Work of Darrell R. Abernethy

In 1979, the late Dr. Darrell R. Abernethy and colleagues began a series of clinical studies aimed at understanding the pertinent determinants of drug distribution, elimination, and clearance in obesity, and how those variables are interconnected. The studies confirmed that volume of distribution (Vd) and clearance are the principal independent biological variables, which conjointly determine elimination half-life as a dependent variable. For drugs distributed by passive diffusion, their pharmacokinetic Vd - after correcting for plasma protein binding - was increased in obesity, depending in part on the physicochemical lipophilicity of the individual drugs, and the quantitative extent of obesity in overweight individuals. Across all studies, the ratio of mean clearance in obese divided by control groups had an overall median value of 1.21 (range: 0.75 to 3.11), indicating a small and variable effect of obesity on clearance, without clear directionality. Since drug clearance was not clearly related to lipophilicity or degree of obesity, the prolonged half-life of lipophilic drugs in obese patients was largely explained by the increased Vd. Dr. Abernethy further identified delayed attainment of steady-state after initiation of multiple-dose treatment, and delayed washout after termination of dosage, as potential clinical consequences of the extended half-life in obese persons. These consequences for specific drugs have been recently emphasized in contemporary studies of chronic dosage in subjects with obesity. Without data identifying an obesity-related change in clearance for a specific drug, maintenance doses (in milligrams) should be based on ideal weight rather than adjusted upward based on total weight. This article is protected by copyright. All rights reserved.

Substrate recognition of the membrane-associated sialidase NEU3 requires a hydrophobic aglycone

The human neuraminidases (NEU) consist of a family of four isoforms (NEU1-NEU4). Members of this enzyme family are proposed to have important roles in health and disease through regulation of the composition of cellular sialosides. The NEU3 isoform is a membrane-associated enzyme that cleaves glycolipid substrates. However, few reports have examined the substrate specificity of the enzyme for non-natural substrates. We report here a series of 11 synthetic trisaccharides that feature modifications of the aglycone or the Neu5Ac residue of an octyl β-sialyllactoside. The time course of substrate cleavage by NEU3 was monitored using an electrospray ionization mass spectrometry assay to obtain relative rates (k(rel)). We observed that NEU3 substrate activity was directly dependent upon the hydrophobicity of the aglycone but had no apparent requirement for features of the ceramide headgroup. We also observed that trisaccharides with incorporated azide groups in the Neu5Ac residue at either C9 or the N5-Ac position were substrates, and in the case of the N5-azidoacetyl derivative, the activity was superior to that of GM3. However, the incorporation of larger aryl groups was tolerated only at C9, but not at N5-Ac. We propose a two-site model for enzyme recognition, requiring interaction at both the Neu5Ac residue and the hydrophobic aglycone.

Effect of membrane perturbing treatments on the membrane-bound peptidases ofStreptococcus cremorisHP

The effects of solubilization, treatment with organic solvents and storage under alkaline conditions on membrane-associated peptidases of intact cells ofStreptococcus cremorisHP were studied. Differences in the response of the peptidase activities towards these membrane perturbing treatments were observed. Pyrrolidonecarboxylylpeptidase (PCP) and an endopeptidase (P50) showed 50% irreversible inhibition at the same concentration of each solvent tested. An amino- and proline iminopeptidase activity and the endopeptidase P37were in this respect much more sensitive to the action of the solvents. Within a homologous series of n-alkanols irreversible inhibition of PCP showed a dependence on the hydrophobicity of the solvent molecules. Only P37activity was increased considerably upon solubilization of the enzyme. Similar levels of activation were found upon treatment of cells with 3% (v/v) n-butanol at 25 °C or storage at 30 °C at an alkaline pH. Optimal activity of P50during n-butanol treatment was at 25 °C using a concentration of 5% (v/v), but no activation was observed upon solubilization. The results are discussed in terms of enzyme–lipid interaction and accessibility of the enzymes in situ. It is concluded that the enzymes apparently occupy different positions within the membrane although they may together constitute a functional peptide-hydrolysing unit.

Physicochemical and Biological Data for the Development of Predictive Organophosphorus Pesticide QSARs and PBPK/PD Models for Human Risk Assessment

A search of the scientific literature was carried out for physiochemical and biological data [i.e., IC50, LD50, Kp (cm/h) for percutaneous absorption, skin/water and tissue/blood partition coefficients, inhibition ki values, and metabolic parameters such as Vmax and Km] on 31 organophosphorus pesticides (OPs) to support the development of predictive quantitative structure-activity relationship (QSAR) and physiologically based pharmacokinetic and pharmacodynamic (PBPK/PD) models for human risk assessment. Except for work on parathion, chlorpyrifos, and isofenphos, very few modeling data were found on the 31 OPs of interest. The available percutaneous absorption, partition coefficients and metabolic parameters were insufficient in number to develop predictive QSAR models. Metabolic kinetic parameters (Vmax, Km) varied according to enzyme source and the manner in which the enzymes were characterized. The metabolic activity of microsomes should be based on the kinetic activity of purified or cDNA-expressed cytochrome P450s (CYPs) and the specific content of each active CYP in tissue microsomes. Similar requirements are needed to assess the activity of tissue A- and B-esterases metabolizing OPs. A limited amount of acetylcholinesterase (AChE), butyrylcholinesterase (BChE), and carboxylesterase (CaE) inhibition and recovery data were found in the literature on the 31 OPs. A program is needed to require the development of physicochemical and biological data to support risk assessment methodologies involving QSAR and PBPK/PD models.

Rokitamycin: bacterial resistance to a 16-membered ring macrolide differs from that to 14- and 15-membered ring macrolides

Rokitamycin is the latest semi-synthetic 16-membered ring macrolide introduced into clinical practice. It is characterized by greater hydrophobicity, better bacterial uptake and a slower release, more cohesive ribosomal binding, and a longer post-antibiotic-effect (PAE) than can be observed with other available 14-, 15- and 16-membered ring macrolides. Rokitamycin exerts its activity on strains that harbor inducible erm genes or the efflux gene, mef(A). It has also been reported to be more active in vitro than other 16-membered ring macrolides. However, these recognized features are not fully exploited yet because current automated test procedures used in many microbiological laboratories determine susceptibility only to erythromycin or clarithromycin. Resistance to 16-membered ring macrolides cannot be predicted solely on the basis of known resistance to erythromycin or clarithromycin as revealed by an automated susceptibility assay. At least equally important is the knowledge of the bacterial resistance phenotype. This is underlined by the existence of Gram-positive coccal strains resistant to erythromycin and other 14-,15-membered ring macrolides but susceptible to 16-membered ring macrolides. Since the local prevalence of erythromycin phenotypes is generally unknown but might determine the outcome of treatment, the procedure for identifying the phenotypes in erythromycin-resistant strains (which can be easily and cheaply performed using the two- or three-disk assay) should become routine, at least in the countries in which 16-membered ring macrolides are used. This approach should help to optimize the use of macrolides, improve our knowledge of the local prevalence of phenotypes resistant to erythromycin, and offer the possibility of treating infections caused by certain types of erythromycin-resistant pathogens.

Anesthetic activity of monoketones in mice: relationship to hydrophobicity and in vivo effects on Na+/K+ -ATPase activity and membrane fluidity

The in vivo anesthetic activity of monoketones in mice was examined in relation to their hydrophobicity and to the in vivo effects on Na+/K+ -adenosine triphosphatase (Na+/K+ -ATPase) activity and membrane fluidity. Anesthetic potency (AD50) of monoketones was determined; AD50 implys the dose required to anesthetize 50% of the animals from the treated group. The n-octanol/water partition coefficient (P) was used as an index of hydrophobicity. Membrane fluidity was determined by using 1,6-diphenyl-1,3,5-hexatriene (DPH) or 1-(4-trimethylammoniumphenyl)-6-phenyl-1,3,5-hexatriene (TMA-DPH as fluorescence probes. Log (1/AD50) was the parabolic function of log P, log ((1/AD50) = -0.167(log P)2 + 0.698 log P - 1.365, and the log P that corresponds to the minimum AD50 was estimated to be 2.09. Brain synaptosomes were prepared from mice that were considered anesthetized with each of the 4 monoketones (1.5-fold AD50), methyl n-propyl, methyl n-amyl, methyl 3-methylhexyl and methyl n-octyl ketone. The Na+/K+ -ATPase activity was inhibited by methyl n-propyl ketone alone, membrane DPH fluidity was decreased by each of the 4 monoketones, and membrane TMA-DPH fluidity was decreased by methyl n-propylketone alone. These results suggest an involvement of the decreased DPH fluidity in monoketone-induced anesthesia.

The expanding role of quantitative structure-activity relationships (QSAR) in toxicology

Quantitative structure-activity relationships (QSAR) have found wide use in correlating the bioactivity of all kinds of organic compounds with all kinds of biological entities. So many QSAR have been published that it is time for a new phase of study, that of comparative QSAR. From our current database of about 6000 QSAR illustrative examples are discussed.

In vitro influences of alcohols on mouse synaptosomes, and structure-activity relationships

Little information is available on the structure-central nervous system membrane toxicity relationship of alcohols. The purpose of the present study was to study in vitro influence of alcohols (n = 20) on the activity of the toxic indicator Na+/K(+)-adenosine triphosphatase (Na+/K(+)-ATPase) and acetylcholinesterase (AchE), and membrane fluidity in mouse brain synaptosomes, in terms of the structure-activity relationship. The potency of inhibition for the enzymes (IC50) and the potency of increasing membrane fluidity (IC12.5) were determined experimentally, and n-octanol/water partition coefficient (P) and the steric constant Taft Es are cited from the literature. Regression analysis revealed that log 1/IC50 for Na+/K(+)-ATPase is a function of log P and Taft Es. The situation was true for AchE activity. The results indicate that the hydrophobicity expressed as log P and the steric effect of the alcohols play an important role in inhibiting both enzyme activities. A linear relationship between log 1/IC12.5 for membrane fluidity and log P is shown, indicating a significant effect of the alcohols on membrane fluidity. Based on these results, it is suggested that the alcohols inhibit the Na+/K(+)-ATPase and AchE activity through a direct action on the enzymes and/or through changing the membrane fluidity.

Comparative QSAR in toxicology: examples from teratology and cancer chemotherapy of aniline mustards

During the past 30 years, thousands of quantitative structure-activity relationships (QSAR) have been published for all sorts of chemicals acting on many forms of life or parts thereof (DNA, enzymes, organelles, etc.). Very little effort has been made to show the relationship among these equations. In this report, we discuss two examples, the toxicity of phenols to rats and the effect of aniline mustards on a variety of living systems, where the electronic effects in the QSAR can be correlated to QSAR from physical organic chemistry. This enables one to make better mechanistic deductions about the biological structure-activity relationships. From this, it is concluded that radicals formed from the phenols cause birth defects.

Physical-chemical-activity relationship of organic solvents: effects on Na(+)-K(+)-ATPase activity and membrane fluidity in mouse synaptosomes

Physical-chemical-activity relationship of aromatic hydrocarbons (n = 10) and alkyl acetates (n = 16) with respect to their in vitro effects on synaptosomal membranes was studied. Na(+)-K(+)-adenosine triphosphatase (Na(+)-K(+)-ATPase) activity and membrane fluidity, which was determined using the fluorescence probe 1,6-diphenyl-1,3,5-hexatriene, were used as potential indicators of neuronal cell toxicity. The potency of inhibition for the enzyme (IC50), the potency of increasing membrane fluidity (IC12.5), and n-octanol/water partition coefficient (P) were all determined experimentally for 26 solvents. Correlation analyses were made on aromatic hydrocarbons and on alkyl acetates. There were linear relationships between log P and pIC50 (log1/IC50) values, and between log P and pIC12.5 (log1/IC12.5) values, indicating that the hydrophobicity of the solvents determines their toxic ability to affect membrane environment; the more hydrophobic the solvents are, the more toxic they are. A direct linear relationship between Na(+)-K(+)-ATPase activity pIC50 and membrane fluidity pIC12.5 values was also shown. This predictive correlation suggests a similar mechanism of membrane surface interaction govering both processes that are common to the test solvents. The present results confirm the importance of the lipid environment of neuronal membranes in maintaining the normal function of membrane-bound protein.

Modelling of chemical reactions catalysed by membrane-bound enzymes. Determination and significance of the kinetic constants

A model of multiphasic systems, based on the assumption of zero-order partition of substrates and products into the membranes, is applied to reversible mono-substrate and bi-substrate reactions catalysed by membrane-bound enzymes. Apart from replacement of single-phase kinetic constants by apparent kinetic constants, the derived kinetic expressions are formally identical with those for corresponding single-phase systems. The model confers to the apparent kinetic constants an experimentally verifiable meaning. For full characterization of membrane-kinetic systems, experiments at various concentrations of enzyme-embedding phospholipid are required. Extrapolation to zero phospholipid concentration of each Km app then yields the corresponding true kinetic constant characteristic of the membrane-bound enzyme and also provides a technique for determination of the membrane-partition constants. The procedure implies that the phospholipid content should be assayed for full characterization of membrane-bound enzymes. If, for practical reasons, the assays have to be limited to a single enzyme concentration, correction of the apparent kinetic constants is still possible provided the phospholipid concentration and the partition constants of the reactants are known. The model has permitted prediction of a number of previous observations reflecting the multiphasic nature of the systems. The assumptions, underlying the model, and their implications are examined as well as some commonly used experimental designs for determination of the type of enzymic site.

Macrolide accumulation by Bacteroides fragilis ATCC 25285

The accumulation of macrolide antibiotics in Bacteroides fragilis ATCC 25285 was increased in the order erythromycin, josamycin, and rokitamycin, depending on hydrophobicity. The half-times of efflux were also prolonged in the same order. Furthermore, MICs of the antibiotics were correlated with the extent of hydrophobicity. These findings suggest that the macrolide antibiotics are accumulated in B. fragilis by means of their hydrophobic properties, and the efficient accumulation of the drugs may explain the susceptibility of this gram-negative bacterium to macrolides.

Toward a quantitative comparative toxicology of organic compounds

Correlation equations between logP (P = octanol water partition coefficient) and the biological activity of alcohols has been derived for 101 examples on all sorts of systems, from simple proteins to whole animals. This provides an overview of the toxic nature of hydrophobic compounds which can be used as a basis for comparison of more complex chemicals. About 100 examples of the hydrophobic effects of chemicals, other than alcohols, to various living systems or their parts are presented for comparison. It is clear that hydrophobic xenobiotics are toxic to almost every form of life, including humans (or parts there of).

Hydrophobicity and central nervous system agents: on the principle of minimal hydrophobicity in drug design

The problem of getting drugs across the so-called blood-brain barrier (BBB) has long been under extensive investigation; however, the other side of the problem, that of keeping drugs out of the central nervous system (CNS), has not been studied so intently. As we strive to make more and more refined drugs with fewer side effects, the problem of keeping drugs out of the CNS has possibly become more important than getting them in. The role of lipophilicity has long been recognized as being important in CNS penetration by chemicals, but we believe that not enough attention has been devoted to just exactly what is meant when it is said that "a lipophilic drug is needed for CNS penetration." How lipophilic? Can hydrophilic properties keep drugs out of the CNS? How hydrophilic should they be? There are other reasons for making drugs hydrophilic. Hydrophobic drugs, other factors being equal, are more inhibitory of biochemical systems than hydrophilic congeners. Evidence is beginning to show that cytochrome P450 is induced in direct proportion to hydrophobicity by a variety of compounds, and cytochrome P450 may produce modifications in lipophilic molecules in the body. Hydrophobic drugs are more slowly eliminated. This report discusses these problems in terms of the octanol-water (log P) hydrophobic scale. The principle is proposed that, without convincing evidence to the contrary, drugs should be made as hydrophilic as possible without loss of efficacy. Antihistamines are discussed in terms of what kind of hydrophobic-hydrophilic balance is best to avoid CNS-related problems.

Anesthetics produce differential actions on the discharge activity of a single neuron

The effects of 26 anesthetic agents were studied on the rhythmical discharge activity of a single isolated neuron (crayfish stretch receptor). Many of these agents produced concentration-dependent biphasic responses (excitation and depression), and some also induced altered discharge patterns (burst activity). The dominant effect of a few of the anesthetics was excitation (e.g. alphaxolone); depression (e.g. decanol); or burst activity (e.g. benzocaine). A correlation was found to exist between equieffective concentrations in the perfusate and membrane/buffer partition coefficients; however, this general phenomenon does not provide an explanation for the biphasic or differential responses. These results demonstrate that selective interactions occur at the level of the single neuron, and suggest the existence of recognition sites in neuronal membranes which can discriminate structural differences of anesthetics.

Serum-catalyzed hydrolysis of metronidazole amino acid esters

Glycine (Gly), alanine (Ala), valine (Val), leucine (Leu), isoleucine (Ile), phenylalanine (Phe), and lysine (Lys) esters of metronidazole were synthesized using dicyclohexylcarbodiimide (DCC) coupling or a mixed-anhydride route, using tert-butyloxycarbonyl (tert-Boc) amino acids. Human serum-catalyzed hydrolysis of these esters at 37 degrees C give half-lives varying from 4.5 min for the Phe ester to 96 h for the Ile ester. Also determined was the pH-rate profile for hydrolysis in aqueous buffers at 25 degrees C. A linear relationship was observed between the logarithmic value of the hydrolysis rate constant in serum and that of the OH- -catalyzed hydrolysis of cationic esters. This finding may indicate that the esters studied are "equally" poor substrates for binding to the enzymes in serum and, thus, the difference observed in the serum-catalyzed hydrolysis rate is solely derived from the chemical lability of an ester bond. Interestingly, the extent of chemical activation observed in the buffer system appears to be amplified in the serum-catalyzed hydrolysis.

The inhibition of alcohol dehydrogenase in vitro and in isolated hepatocytes by 4-substituted pyrazoles

As a means of comparing the functional properties of an enzyme in dilute solution in vitro with those for the same enzyme acting in its normal cellular environment, a study was conducted with 4-substituted pyrazoles as inhibitors of rat liver alcohol dehydrogenase in vitro and ethanol oxidation in isolated rat hepatocytes. Inhibitor constants (Ki's) for the same set of pyrazole derivatives were also determined for human liver alcohol dehydrogenase. The best-fitting equations were derived to relate the Ki's to the chemical nature of substituents. These quantitative structure-activity relationships show that pyrazoles with stronger electron-withdrawing substituents are weaker inhibitors both for the enzyme in vitro and, to an equal extent, for ethanol oxidation by intact cells. Inhibitor effectiveness is also dependent on substituent hydrophobicity, but, while increasing hydrophobicity makes stronger inhibitors of the enzyme in vitro, it can diminish the effectiveness in vivo by decreasing permeability through the cell membrane. A structure-activity analysis of published Ki's for pyrazoles acting against human pi-ADH indicates that its active site differs from those in other alcohol dehydrogenases.

Microsomal dechlorination of chloroethanes: structure-reactivity relationships

1. The dechlorination rates of six haloethanes were investigated in vitro, using liver microsomes derived from rats treated with Aroclor 1254. 2. The compounds studied were 1,1-dichloroethane, 1,2-dichloroethane, 1,1,1-trichloroethane, 1,1,2,2-tetrachloroethane, 1,1,1-trifluoro-2-chloroethane and hexachloroethane. 3. Dechlorination kinetics (Km and Vmax) were measured at various substrate concentrations. 4. Electron densities in the molecules for which dechlorination data are available were calculated by the MINDO/3 method. 5. A previously reported correlation between electronic parameters and dechlorination rate was not confirmed, but rather a separate relationship between these parameters for each of three structural classes (RCH2Cl, RCHCl2 and RCCl3) was observed. 6. On the basis of these observations, possible reaction mechanisms and their toxicological implications are discussed.

Differential perturbation of erythrocyte membrane function by structurally related polycyclic aromatic hydrocarbons

Examination of the interaction of a number of structurally related polycyclic aromatic hydrocarbons with the erythrocyte plasma membrane indicated that the presence and position of methyl groups on the lipophilic hydrocarbon nucleus determined whether the compound acted as an inhibitor of membrane function. 7,12-Dimethylbenz(a)anthracene, a potent carcinogen, acted as a noncompetitive inhibitor of membrane acetylcholinesterase. The inhibition depended on the anion composition of the buffer at the time of exposure of the cells to inhibitor, i.e., it was only manifest in the presence of an anion gradient. The temperature dependence of the intact cell enzyme in the presence of inhibitor was influenced by the temperature at which the compound was added prior to assay and may involve the perturbation of tightly associated lipids. Glucose exchange across the membrane was inhibited by the same compounds which inhibit acetylcholinesterase. The temperature dependence of the exchange was not grossly altered by the presence of 7,12-dimethylbenz(a)anthracene. The observed inhibition of two membrane functions by the polycyclic aromatic hydrocarbons does not correlate simply with their theoretical octanol/water partition coefficients, water solubilities, or ability to confer membrane stabilization against osmotic hemolysis. This demonstration of differential inhibition by compounds having the same overall hydrophobicity was unexpected and suggests a more complex mode of interaction with the cell membrane.

Nitrosamine carcinogenicity: a quantitative Hansch-Taft structure-activity relationship

Statistically significant correlations have been demonstrated between carcinogenic activity, water-hexane partition coefficients and electronic factors for an extensive series of N-nitroso compounds. Electronic factors were expressed by the Taft sigma* values of substituents on the carbon atoms alpha to the N-nitroso group. Such correlations indicate that transport of the carcinogen to its active site has an important effect on its potency. The correlations also implicate reactivity at the alpha-carbon in the determination of carcinogenic activity and point out various structural types which do not follow the general rule.

Liposolubility as an aspect of nitrosamine carcinogenicity: quantitative correlations and qualitative observations

Carcinogenicity data for a number of nitrosamines have been examined for possible structure-activity correlations with liposolubility by the method of Hansch. Correlations were found in two cases which support a previous mechanistic suggestion and which also suggest a possible difference between the action of nitrosopiperidines and dinitrosopiperazines in inducing olfactory carcinomas. No correlations were found for non-cyclic nitrosamines.

Observations on the accessibility of acceptor substrates to the active centre of UDP-glucuronosyltransferase in vitro

The partition coefficients between octanol and pH 7.4 buffer for eleven substrates of UDP-glucuronosyltransferase (EC 2.4.1.17) have been determined. They range between 1.1 and 690 in the order p-aminophenol less than phenol less than (o-aminobenzoic acid = o-aminophenol = p-aminobenzoic acid) less than p-nitrophenol less than 4-methylumbelliferone less than mercaptobenzothiazole less than harmol less than phenolphthalein less than 1-naphthol. The effect of Triton X-100, used as a model membrane pertubant, on the enzyme activity of UDP-glucuronosyltransferase in rat liver homogenates towards these substrates was determined and compared with the partition coefficients. Enzyme activities towards p-aminophenol and phenol were decreased by Triton X-100, the enzyme activities towards other acceptor substrates were enhanced maximally with 0.025% (w/v) Triton. "Native" enzyme activity (except for amino containing compounds) and activation could be related to partition coefficient of the substrate. An increase in lipid solubility resulted in reduced enzyme activity in untreated homogenates and greater activation. These results suggest UDP-glucuronosyltransferase lies behind a partially lipid-impenetrable abrrier and it is suggested that this barrier is broken up by membrane perturbants to permit free access of the more lipid-soluble substrates. In addition, the formation in vitro of a glucuronide from mercaptobenzothiazole was demonstrated.

The chemistry and conformational and biological analysis of vitamin D3, its metabolites and analogues

The chemical properties, stereochemical relationships and solution conformation, as assessed in part by proton NMR spectroscopy, for vitamin D3, its major metabolites [including 1alpha,25-(OH)2D3, its hormonally active form] and a number of A-ring and side chain analogues are evaluated and discussed in relation to their biological activity. In particular the relative ability of many of these seco-steroids to compete both with 25-OHD3 for its chick serum binding protein and 1alpha,25-(OH)2-D3 for its chick intestinal cytosol-chromatin receptor system was quantitated, in vitro. Further, the relative effectiveness of all these metabolites and analogues to mediate in vivo intestinal calcium absorption and bone calcium mobilization was determined. Collectively these chemical and biological studies constitute a "systems analysis" of the various steroid structural parameters both required and tolerated by the multi-stepped endocrine system associated with the biological actions of vitamin D.

Permeability characteristics of the adipocyte cell membrane and partitioning characteristics of the adipocyte triglyceride core

The unidirectional rates of passive permeation of a homologous series of saturated fatty acids and bile acids into rat epididymal adipocytes were measured to determine the permeability characteristics of this mammalian cell membrane. For fatty acids containing 5 to 12 carbon atoms the logarithm of the permeability coefficient was a linear function of the number of carbons in the fatty acid chain: fatty acids with less than five carbon atoms showed anomalously high permeabilities. Using the data for the fatty acids with 5 to 12 carbon atoms, the incremental free energy of transfer (delta delta F w leads to l) of the -CH2 moiety from the aqueous environment into the fat cell was calculated to equal -547 cal mole-1. The delta delta F w leads to l of the -OH moiety calculated from data using bile acids as the probe molecules was +1,225 cal mole-1. After rupturing the fat cells by freeze-thawing, partition ratios also were measured between bubber and the lipid phase of the adipocyte core using both the fatty acid series and a series of terminal diols as probe molecules. Using these partition ratios delta delta F w leads to l for the -CH2 and -OH substituent groups was calculated to equal -830 and +2,070 cal mole-1, respectively. On the basis of these studies, two conclusions were drawn. First, like many epithelial surfaces and the erythrocyte membrane, the fat cell membrane exhibits anomalously high permeabilities to small molecular weight, polar compounds. Since this behavior in the adipocyte, as in the erythrocyte, cannot be attributed to structures such as tight junctions, it must be explained on the basis of some physico-chemical feature of the cell membrane itself. Secondly, the values of the delta delta F w leads to l indicate that the adipocyte membrane is less polar than the intestinal and gallbladder membranes but more polar than the membranes of Nitella and the erythrocyte.