Anesthetic-ion channel interactions: the effect of lidocaine on the stability and transport properties of the membrane-spanning domain of band 3

A hybrid approach to advancing quantitative prediction of tissue distribution of basic drugs in human

A general toxicity of basic drugs is related to phospholipidosis in tissues. Therefore, it is essential to predict the tissue distribution of basic drugs to facilitate an initial estimate of that toxicity. The objective of the present study was to further assess the original prediction method that consisted of using the binding to red blood cells measured in vitro for the unbound drug (RBCu) as a surrogate for tissue distribution, by correlating it to unbound tissue:plasma partition coefficients (Kpu) of several tissues, and finally to predict volume of distribution at steady-state (V(ss)) in humans under in vivo conditions. This correlation method demonstrated inaccurate predictions of V(ss) for particular basic drugs that did not follow the original correlation principle. Therefore, the novelty of this study is to provide clarity on the actual hypotheses to identify i) the impact of pharmacological mode of action on the generic correlation of RBCu-Kpu, ii) additional mechanisms of tissue distribution for the outlier drugs, iii) molecular features and properties that differentiate compounds as outliers in the original correlation analysis in order to facilitate its applicability domain alongside the properties already used so far, and finally iv) to present a novel and refined correlation method that is superior to what has been previously published for the prediction of human V(ss) of basic drugs. Applying a refined correlation method after identifying outliers would facilitate the prediction of more accurate distribution parameters as key inputs used in physiologically based pharmacokinetic (PBPK) and phospholipidosis models.

Forces and factors that contribute to the structural stability of membrane proteins

While a considerable amount of literature deals with the structural energetics of water-soluble proteins, relatively little is known about the forces that determine the stability of membrane proteins. Similarly, only a few membrane protein structures are known at atomic resolution, although new structures have recently been described. In this article, we review the current knowledge about the structural features of membrane proteins. We then proceed to summarize the existing literature regarding the thermal stability of bacteriorhodopsin, cytochrome-c oxidase, the band 3 protein, Photosystem II and porins. We conclude that a fundamental difference between soluble and membrane proteins is the high thermal stability of intrabilayer secondary structure elements in membrane proteins. This property manifests itself as incomplete unfolding, and is reflected in the observed low enthalpies of denaturation of most membrane proteins. By contrast, the extramembranous parts of membrane proteins may behave much like soluble proteins. A brief general account of thermodynamics factors that contribute to the stability of water soluble and membrane proteins is presented.

Forces and factors that contribute to the structural stability of membrane proteins

While a considerable amount of literature deals with the structural energetics of water-soluble proteins, relatively little is known about the forces that determine the stability of membrane proteins. Similarly, only a few membrane protein structures are known at atomic resolution, although new structures have recently been described. In this article, we review the current knowledge about the structural features of membrane proteins. We then proceed to summarize the existing literature regarding the thermal stability of bacteriorhodopsin, cytochrome-c oxidase, the band 3 protein, Photosystem II and porins. We conclude that a fundamental difference between soluble and membrane proteins is the high thermal stability of intrabilayer secondary structure elements in membrane proteins. This property manifests itself as incomplete unfolding, and is reflected in the observed low enthalpies of denaturation of most membrane proteins. By contrast, the extramembranous parts of membrane proteins may behave much like soluble proteins. A brief general account of thermodynamics factors that contribute to the stability of water soluble and membrane proteins is presented.

The reversibility of absorption promoter interaction with red blood cell membranes studied with differential scanning calorimetry

Absorption promoters, or adjuvants, are used to enhance the gastrointestinal absorption of poorly absorbed drugs such as macromolecules. In the present work, adjuvant-membrane interactions have been studied by differential scanning calorimetry (DSC) using red blood cell (RBC) membranes as model membrane. These interactions caused temperature shifts, amplitude changes, and broadening of the RBC transitions. Because more than one transition may be simultaneously affected by a given adjuvant, complex overlappings occur. Gaussian modeling and nonlinear regression analysis, therefore, were used to resolve these transitions. A correlation, which may serve as an indicator of adjuvant potency, was found between adjuvant concentration and induced transition temperature shifts. Further, these shifts recovered to baseline after successive washings with buffer (for most adjuvants). Sodium lauryl sulfate induced transition alterations, however, never recovered. Thus the DSC might be useful in monitoring reversible adjuvant-membrane interactions.

Interaction of amphiphiles with integral membrane proteins. I. Structural destabilization of the anion transport protein of the erythrocyte membrane by fatty acids, fatty alcohols, and fatty amines

The effect of model amphiphiles on the structural stability of the anion exchange protein (band 3) of the human erythrocyte membrane was studied by differential scanning calorimetry. The concentration of membranes, as well as the concentration, head group, alkyl chain length, degree of unsaturation, and double bond configuration of a variety of alkane derivatives were all varied in a systematic way. The depression of the denaturation temperature of band 3 per unit membrane concentration of the amphiphile was then determined in order to quantitate the potency of each drug. Saturated fatty acids of chain length C8 to C24 displayed a monotonic decrease in potency up to C20, followed by a dramatic diminution in potency at C22 and C24. Unsaturation caused only minor increases in the abilities of fatty acids to perturb the anion exchanger, and surprisingly, there was neither a trend for the number of double bonds nor a significant cis-trans distinction. Arachidonic acid, as an exception, was much more effective than any other amphiphile in destabilizing band 3. Fatty acids were about three times more potent than fatty amines and fatty alcohols; however, the enhanced partitioning of the latter into the membrane compensated at certain membrane/buffer ratios for its reduced intrinsic potency. A quantitative model interpretation of the data is presented in an accompanying paper.

Interaction of amphiphiles with integral membrane proteins. II. A simple, minimal model for the nonspecific interaction of amphiphiles with the anion exchanger of the erythrocyte membrane

In a previous paper we have reported on the structural perturbation of the erythrocyte membrane anion exchanger by a regular series of model amphiphiles, as shown by differential scanning calorimetry (Gruber, H.J. and Low, P.S., Biochim. Biophys. Acta, preceding article). Now the data are interpreted by a model in which the effects of amphiphile structure upon buffer-membrane partitioning are well separated from the dependence of the intrinsic potencies of membrane-bound amphiphiles upon amphiphile structure. The buffer-membrane partitioning situation was demonstrated to regularly change between extremes within a series of homologous amphiphiles, i.e. from a negligible to a predominant fraction of total amphiphile in the sample residing in the membrane. Based upon this demonstration a large number of reports on the chain length dependence of apparent potency could be reinterpreted in terms of chain length profiles of intrinsic potency, allowing for a comparison of the responses of various membrane proteins to homologous series of amphiphiles. The response patterns for chain length variation could be divided into three distinct classes: the intrinsic potency (i) can be independent of chain length over a very wide range of length, (ii) it can be rather independent up to a critical length where a sudden cut-off in potency occurs, or (iii) it can drop monotonically over a wide range of chain length. The intrinsic potency values of saturated fatty acids in destabilizing the anion exchanger were interpreted by very simple assumptions: only direct interactions between amphiphiles and target proteins and a simple amphiphile partition equilibrium between a pool of equivalent low affinity sites on the protein and the bulk lipid matrix. The observed monotonic decay of the intrinsic potency of saturated fatty acids with increasing chain length from C8 to C20 was translated into a constant increment of free energy by which each additional CH2 favors the transfer away from sites on the protein towards the bulk lipid matrix. Arguments were presented suggesting that the direct interaction between amphiphiles and target protein is completely nonspecific for alkyl chain length while the residual specificity for shorter over longer amphiphiles is due to the higher tendency of longer chains to preferentially bind in the bulk lipid matrix. Thus a completely new role of the lipid as a competitor, rather than a mediator, was postulated.

Activity of the anion exchange protein (band 3) of human erythrocytes as affected by hydroxychloroaromatic chemicals

The membranous segment of the anion transport protein (band 3) of the human erythrocyte membrane has been shown [T.L. Miller and R.J. Smith, Archs Biochem. Biophys. 250, 128 (1986)] to be destabilized by relatively low concentrations of many hydroxychloroaromatic compounds (HO-Cl chi-Ar), including hydroxychlorodiphenyl ethers (HO-Cl chi-DPE), major contaminants of technical grade pentachlorophenol (PCP). In the present study, HO-Cl chi-DPE also caused a concentration-dependent inhibition of the rate of sulfate exchange mediated by band 3 in human erythrocytes. The most active compound studied, 2-HO-Cl9-DPE, was about nine times more potent in inhibiting sulfate exchange than 2-HO-2',4,4'-Cl3-DPE, the least active compound studied. The potency of HO-Cl chi-DPE as inhibitors of anion exchange generally increased with the degree of chlorination. The concentration-dependent decreases in the sulfate exchange rate elicited by 2-HO-Cl9-DPE and 2-HO-2',4,4'-Cl3-DPE paralleled the effects of these compounds on the stability of band 3.

Thermotropic properties of human erythrocyte membrane proteins as affected by hydroxychloroaromatic compounds

The thermal stability of the anion transport protein (band 3) and other proteins of the human erythrocyte membrane, as influenced by hydroxychloroaromatic (HO-Cl2-Ar) compounds, was studied by differential scanning calorimetry. Various hydroxychlorodiphenyl ethers (HO-Clx-DPEs) and hexachlorophene, but not pentachlorophenol, caused a marked decrease in the thermal stability of band 3. Most of the other calorimetric transitions of the erythrocyte membrane were only slightly affected. The activity of HO-Clx-DPEs toward lowering the transition temperature of band 3 generally increased with the degree of chlorination, and was somewhat dependent on the position of hydroxyl substitution. At higher concentrations of HO-Clx-DPEs, there was a decrease in the enthalpy change and a broadening of the endothermic transition of band 3. The order of effectiveness of these compounds, as determined from band 3 denaturation temperatures, was similar to the order of potency previously observed for hemolysis of human erythrocytes.

Charge-independent effects of drugs on erythrocyte morphology

The effects of chlorpromazine, tetracaine, indomethacin, barbitone and benzyl alcohol on human erythrocyte shape have been examined. Cationic and anionic drugs produced stomatocytes and echinocytes respectively as expected for cells in isotonic saline. Particular attention has been directed here to some features of drug induced morphology change which are independent of the charge of the drug. It was found that (i) the direction (increase or decrease) of the extent of morphological change as temperature was increased from 20 to 37 degrees, (ii) the exposure time for maximum shape change (0-2 min), and (iii) the time course of cell morphology (0-30 min) were different for similarly charged drugs. The influence of low concentrations of the drugs on the thermal fragmentation patterns of the cells has been determined. A single index has been derived which allows comparison of the morphological effects of cationic and anionic drugs. It was concluded that, while the type (stomatocyte or echinocyte) of shape change observed was dependent on the charge of the drug, cell morphology at drug concentrations high enough to produce marked shape change at 37 degrees was strongly influenced by charge independent drug-specific effects.

Identification and partial characterization of the xanthine oxidase transitions of the milk fat globule membrane

Differential scanning calorimetry of bovine milk fat globule membranes (MFGM) yields five to eight transitions, depending on the conditions employed during isolation and assay of the membranes. Transitions A, B, and C were shown in a previous publication to derive from lipid melting, while transition D was found to stem from the unfolding of a structural protein termed butyrophilin [K. C. Appell, T. W. Kennan, and P. S. Low (1982) Biochim. Biophys. Acta 690, 243-250]. In this report we present evidence that the E1, E2, and F endotherms derive from the major MFGM protein, xanthine oxidase. Support for this contention derives from (i) thermal gel analysis; (ii) thermal inactivation analysis; (iii) comparison of the calorimetric properties of endotherms I, II, and III of purified xanthine oxidase with transitions E1, E2, and F of MFGM; (iv) comparison of the properties of a peculiar exotherm in scans of both the purified enzyme and MFGM; and (v) examination of the effects of specific ligands, reducing agents, and pH on both the xanthine oxidase and MFGM transition. The existence of three independent endotherms (I, II, and III) in purified xanthine oxidase demonstrates that the enzyme is composed of multiple independent domains. The interconversion of transitions I (E1) and II (E2) with a change in the redox conditions of the medium implies that these two transitions may be manifestations of the interconvertible dehydrogenase and oxidase forms of the enzyme, respectively. The relative independence of the I/II transitions from transition III further shows that only slight interaction between the major domains of xanthine oxidase exists.

Multiple effects of short-chain alcohols on binding to rat heart muscarinic receptors

Short-chain alcohols inhibited the equilibrium binding of agonists and antagonists to rat heart muscarinic receptors. Methanol, ethanol, propan-2-ol and propan-1-ol, when used at low concentrations, behaved as pseudo-competitive antagonists. Their rank order of potency paralleled their relative partition coefficients, suggesting that this inhibition was simply due to the interaction of the alcohols with a hydrophobic part of the receptor or with membrane lipids. The four alcohols increased the dissociation rate constant of [3H]oxotremorine M from the high-affinity agonist receptors and decreased the stability of this receptor state. These effects might reflect increased membrane fluidity and/or decreased hydrophobic interactions (see below). By contrast, the effects of alcohols on the association and dissociation rates of N-[3H]- methscopolamine (an antagonist) were not correlated to their relative octanol/water partition coefficient (a measure of their affinity for biophases ). Alcohols, at the relatively high concentrations necessary for increased membrane 'fluidity', are known to affect the relative stability of various protein conformations. We believe that the effects of alcohols on antagonist binding to rat heart muscarinic receptors reflected changes in the activation energy of association and dissociation reactions, the inhibition of equilibrium binding being mainly due to decreased 'hydrophobic interactions'.

Kinetics of acetylcholine-activated cation channel blockade by the calcium antagonist D-600 in Aplysia neurons

The effects of the calcium channel blocker D-600 on the cation channels activated by acetylcholine (ACh) was studied in voltage-clamped Aplysia neurons by voltage-jump relaxation analysis. D-600 blocked the steady-state ACh current in a highly voltage-dependent manner, the degree of antagonism increasing with membrane hyperpolarization. In the presence of D-600 the current relaxations following hyperpolarizing command steps became biphasic. The time constants of ACh-induced current relaxations (tau f), which approximate the mean channel lifetime, were reduced in a voltage-dependent manner, the degree of reduction of tau f increasing with increasing membrane potential. In addition to the acceleration of tau f, a slow, inverse kinetic component (tau s) of the relaxation appeared in the presence of D-600. The rate of this inverse kinetic component was accelerated either by increasing the agonist or antagonist dose or by increasing the membrane potential. These results suggest that D-600 acts to antagonize the acetylcholine response through a blockade of the open state of the transmitter-activated cation channel. Possible kinetic schemes for this interaction are discussed.