A study of the perturbation effects of the local anesthetic procaine on human erythrocyte and model membranes and of modifications of the sodium transport in toad skin

The interaction of the local anesthetic procaine with human erythrocytes, isolated unsealed human erythrocyte membranes (IUM), isolated toad skins, and molecular models is described. The latter consisted of phospholipid multilayers built-up of dimyristoylphosphatidylcholine (DMPC) and of dimyristoylphosphatidylethanolamine (DMPE), representatives of phospholipid classes located in the outer and inner monolayers of the human erythrocyte membrane, respectively. Optical and scanning electron microscopy of human erythrocytes revealed that procaine induced the formation of stomatocytes. Experiments performed on IUM at 37 degrees C by fluorescence spectroscopy showed that procaine interacted with the phospholipid bilayer polar groups but not with the hydrophobic acyl chains. X-ray diffraction indicated that procaine perturbed DMPC structure to a higher extent when compared with DMPE, its polar head region being more affected. Electrophysiological measurements disclosed a significant decrease in the potential difference (PD) and in the short-circuit current (Isc) after the application of procaine to isolated toad skin, reflecting inhibition of active ion transport.     

The penetration of local anesthetics into the red blood cell membrane as studied by fluorescence quenching.

The local anesthetics procaine and tetracaine were found to quench the fluorescence of the probes N-octadecyl naphthyl-2-amine 6-sulfonic acid and 12-(9-anthroyl)stearic acid in the presence of erythrocyte membranes. This quenching was shown to be due to the aromatic amine of the procaine and tetracaine molecules. Lidocaine, an active anesthetic that does not contain an aromatic amine in the same position as does procaine and tetracaine did not quench either of the fluorophores. The preferential quenching of the fluorescent probes by procaine and tetracaine indicated a greater accessibility of tetracaine than of procaine to the hydrocarbon region of the membrane and a greater accessibility of procaine than of tetracaine at the membrane's surface. The addition of calcium was found to reverse the quenching of 12-(9-anthroyl)stearic acid by tetracaine in the presence of red cell membranes.     

Inhibition of receptor-mediated uptake of a lysosomal enzyme into fibroblasts by chloroquine, procaine and ammonia

Cultured human skin fibroblasts take up α- -iduronidase by receptor-mediated pinocytosis. Certain lysosomotropic amines such as chloroquine, ammonia and procaine inhibit this process, without affecting the fluid endocytosis of dextran. In contrast to the competitive inhibition by mannose 6-phosphate, the inhibition by amines is non-competitive and is therefore presumed not to affect binding of the enzyme to receptors. The dose response curves are very steep, and equations that best fit the data use a power of inhibitor concentration (i² for procaine, i⁴ for chloroquine), indicating interaction of several amine molecules at the inhibitory site(s). The inhibition is reversed by removal of the amine from the medium and does not result from accelerated efflux of endocytosed enzyme. We suggest that the amines interfere with delivery of receptor-bound enzyme to lysosomes.     

Local anaesthetics and nodal polyanions in peripheral nerve

Synopsis Pantocaine, procaine, xylocaine and cocaine were found to interact with the polyanionic matrix surrounding the nodal axon membrane of peripheral myelinated nerve. Their affinity for nodal anionic sites was found to lie between that of mono- and divalent inorganic cations. The affinity was related to the polar character of local anaesthetic molecules. The possible significance of these interactions is discussed in terms of current theories regarding the action of local anaesthetics on nerve impulse conduction.     

山莨菪碱与膜相互作用的小角X射线衍射研究

应用小角X射线衍射和差示扫描量热法研究了中药提取物山莨菪碱与DPPC多层膜的相互作用.结果表明,山莨菪碱不仅能降低DPPC多层膜的相变温度,而且能使多层膜发生分相现象,根据衍射结果并采用推广傅里叶合成去卷积法计算了脂双分子层膜的电子密度剖面图.从中我们估计山莨菪碱分子可能分布于脂双分子层极性头部的内侧     

Local anesthetics. Effect of pH on use-dependent block of sodium channels in frog muscle.

Sodium currents were studied under voltage clamp in the presence of neutral, amine, and quaternary local anesthetic compounds. Use-dependent block was observed as a cumulative depression of INa seen with repetitive depolarizing test pulses applied at frequencies of 2-10s-1. With quaternary QX-314, the time constant of use dependence was long, and with neutral benzocaine, very short. With lidocaine and procaine, increasing external pH (pHo) changed the time constant from long to short, but alterations of internal pH have no effect. Inactivation in Na channels was measured by the influence of prepulses on peak INa during test pulses. Single-stimulus inactivation curves were shifted more with lidocaine at high pHo than at low pHo, but inactivation curves measured during pulse trains with any of the drugs and at any pHo were strongly shifted. All measurements show that the drug-receptor reaction was slow for amine drugs at low pHo, as for quaternary drugs at any pHo, and fast for amine drugs at high pHo, as for neutral drugs at any pHo. The major effect of low pHo on amine drugs was to reduce the concentration of drugs in the fiber and to protonate drug molecules on the receptor, thus trapping them in the blocking position for a longer time. Direct effects of pH on the receptor seemed minimal.     

ESR and monolayer study of the localization of coenzyme Q10 in artificial membranes

The data obtained from the ESR experiments show a complex, depth dependent effect of CoQ10 on the lipid molecules mobility in the bilayer. These effects depend both on its concentration and the temperature. CoQ10 disturbs not only the hydrophobic core of the membrane but also the region close to the hydrophilic headgroups of phospholipids. Both these effects could be explained by the fact that the high hydrophobicity of CoQ10 causes the molecules to position itself in the interior of the bilayer, but at the same time its water seeking headgroup is located close to the region of the polar headgrops of membrane lipids. The presence of CoQ10 in the hydrophobic core has further implications on the properties of membrane intrinsic domain. Results of monolayer experiments indicate that CoQ10 may form aggregates when mixed with PC molecules in the lipid hydrocarbon chain-length dependent manner. CoQ10 is not fully miscible with DMPC or DPPC but it is well miscible with the long-chain DSPC molecules. Our suggestion is that CoQ10 when present in long-chain phospholipid bilayer, interacts with saturated fatty acyl-chains and adapt the structure which allows such interactions: either parallel to the saturated acyl chains or "pseudo-ring" conformation resembling sterol structure.     

Impact of urea on water structure: a clue to its properties as a denaturant?

A new investigation of the structure of urea-water solutions at a mole ratio of 1 urea to 4 water molecules is described. Neutron diffraction is used in conjunction with isotope labelling on the water and urea hydrogen atoms and on the nitrogen atom of urea. The diffraction data are analysed using the empirical potential structure refinement procedure to yield a set of site-site radial distribution functions and spatial density functions that are consistent with the diffraction data. The results are discussed in relation to recent and past X-ray and neutron diffraction experiments and theoretical studies of this system. It is found that urea incorporates readily into water, forming pronounced hydrogen bonds with water at both the amine and carbonyl headgroups. In addition the urea also hydrogen bonds to itself, forming chains or clusters consisting of up to approximately 60 urea molecules in a cluster. There, is however, little or no evidence of urea segregating itself from water, in marked contrast to a recent study of the methanol-water system. This behaviour is discussed in the context of the great propensity of urea to effect protein denaturation.     

Lateral diffusion of gramicidin S, M-13 coat protein and glycophorin in bilayers of saturated phospholipids. Mean field and Monte Carlo studies

We have developed a general model that relates the lateral diffusion coefficient of one isolated large intrinsic molecule (mol. wt. greater than or approximately 1000) in a phosphatidylcholine bilayer to the static lipid hydrocarbon chain order. We have studied how protein lateral diffusion can depend upon protein-lipid interactions but have not investigated possible non-specific contributions from gel-state lattice defects. The model has been used in Monte Carlo simulations or in mean-field approximations to study the lateral diffusion coefficients of Gramicidin S, the M-13 coat protein and glycophorin in dimyristoyl- and dipalmitoylphosphatidylcholine (DMPC and DPPC) bilayers as functions of temperature. Our calculated lateral diffusion coefficients for Gramicidin S and the M-13 coat protein are in good agreement with what has been observed and suggest that Gramicidin S is in a dimeric form in DMPC bilayers. In the case of glycophorin we find that the 'ice breaker' effect can be understood as a consequence of perturbation of the lipid polar region around the protein. In order to understand this effect is necessary that the protein hydrophilic section perturb the polar regions of at least approx. 24 lipid molecules, in good agreement with the numbers of 29-30 measured using 31P-NMR. Because of lipid-lipid interactions this effect extends itself out to four or five lipid layers away from the protein so that the hydrocarbon chains of between approx. 74 and approx. 108 lipid molecules are more disordered in the gel phase, so contributing less to the transition enthalpy, in agreement with the numbers of 80-100 deduced from differential scanning calorimetry (DSC). An understanding of the abrupt change in the diffusion coefficient at a temperature below the main bilayer transition temperature requires an additional mechanism. We propose that this change may be a consequence of a 'coupling-uncoupling' transition involving the protein hydrophilic section and the lipid polar regions, which may be triggered by the lipid bilayer pretransition. Our calculation of the average number of gauche bonds per lipid chain as a function of temperature and distance away from an isolated polypeptide or integral protein shows the extent of statically disordered lipid around such molecules. The range of this disorder depends upon temperature, particularly near the main transition.     

Polar and hydrophobic effects on ester aminolysis in dimethyl sulfoxide

Aminolysis of various carboxyl-containing esters by several tetra-, tri-, and diamines was kinetically studied in dimethyl sulfoxide. Rates were measured in the presence or absence of added sulfuric acid with the amine concentration being much greater than the ester concentration. In some reactions, pseudo-first-order rate constants manifested saturation kinetic behavior with respect to the total amine concentration, indicating the formation of complexes between the amines and the esters. The complex formation was most efficient when the carboxyl group of the ester substrate was located at the meta position to the ester group. In addition, the complex formation was facilitated by hydrophobic amines. In order to explain the positional stereoselectivity and the hydrophobic effects observed in the kinetic study, a structure of the complex is proposed. In this structure of the complex, two nitrogen atoms of the amine are linked by an intramolecular hydrogen bond and then further interact with the two carbonyl oxygen atoms of the substrate. In addition, the hydrophobic interaction between the hydrophobic portion of the amine and the benzene ring of the substrate stabilizes the complex. Dimethyl sulfoxide accommodates both the polar and the hydrophobic interactions that are needed in the formation of the complex, mimicking the microenvironment of enzyme active sites.     

Distribution of small hydrophobic molecules in membranes. I. Artificial lipid membranes]

A hydrophobic uncharged fluorescent probe of 4-dimethylaminochalcone (DMC) interacted with synthetic phospholipid membranes. Comparison of absorption spectra and fluorescence of DMC in the membranes and organic solvents shows that in the membranes the DMC molecules are located not in the hydrocarbon layer but in the polar regions near the surface. The probe is distributed regularly along the surface forming no dimers and clusters. Polar groups which surround the probe in the membrane are less mobile than the molecules of organic solvents at the same temperature. The evaluation shows that the relaxation time of polar groups in the probe environment is longer than 0.15-10(-9) sec. The DMC molecules may be located in different sites of the membrane surface, which seem to differ from one another in the mobility of polar groups.     

X-ray diffraction evidence for the presence of discrete water layers on the surface of membranes

X-ray diffraction spacings in multilayered membranes obtained from frog sciatic nerves were found to increase in discrete steps of approx. 5 A during swelling. These observed jumps in the repeat period suggest that the lipid bilayers exist in distinct states of hydration, and perhaps the swelling occurs by step-wise addition of water layers between the polar head groups. Our analysis and statistical tests of this hypothesis are presented.     

Density functional and molecular dynamics simulations of local anesthetics in 0.9% NaCl solution

We have made density functional calculations and molecular dynamics (MD) simulations to investigate the structure and pharmacological action of local anesthetics: tetracaine, procaine and lidocaine. The MD simulations were made in a NPT ensemble, in a 0.9% NaCl solution, on both unprotonated and protonated forms of the molecules. The radial distribution function was used to study solvent effects in different regions of the molecules. Although all three anesthetics have different degrees of hydrophobicity, the amino-terminals were the mostly affected by the protonation yielding hydrophilic regions. The charged amino-esters present hydrophilicity on the ester as well as amine terminals. Cl^?  from the solvent solution forms hydrogen bonds via protonated hydrogen attached to nitrogen, yielding neutral molecules, which could, in principle, penetrate the membranes and loose Cl^?  to act in the protonated form. Density functional theory calculations indicated a change in the electrostatic potential and showed that Cl^?  weakly binds to the amine hydrogen, what suggests it is a favorable interaction and supports the existence of the hydrochloric forms of these local anesthetics.     

Isolation and characterisation of a photosystem II reaction centre lipoprotein complex

A photochemically active reaction centre complex has been isolated from photosystem II preparations of spinach chloroplasts by Triton X-100 solubilisation and sucrose gradient fractionation. Electrophoresis of the complex revealed 5 bands indicating polypeptides of apparent molecular masses of 47, 43, 33, 30 and 10 kDa. Lipid analyses showed that polar, as well as neutral, lipids are associated with the complex. For approx. 40 chlorophyll a molecules there were 3.4 plastoquinone-9, 3.3 pheophytin a, 2.9 β-carotene, 29.3 monogalactosyldiacylglycerol and 12.4 sulphoquinovosyldiacylglycerol molecules. These results suggest that this photosystem II reaction centre complex, which most likely represents a minimum photochemically active unit, is a lipoprotein complex. A striking feature of the associated polar lipids is their very low degree of unsaturation.     

Heterogeneity of the cold-insoluble globulin of human plasma (CIg), a circulating cell surface protein.

The cold-insoluble globulin of human plasma (CIg), a circulating cell surface protein, exists in multiple molecular forms. Most molecules are found as two chain (MR approximately 220 000 per chain) disulfide-bridged dimeric units but several minor components of smaller size have also been identified; based upon their migration rates in dodecyl sulfate gel electrophoretic experiments, the smaller molecules characterized in this study range in molecular size from 235 000 to 146 000. The component of molecular weight 235 000 apparently represents a two chain disulfide-bridged derivative of larger parent molecules (one chain of 220 000 plus a smaller remnant), whereas smaller CIg components appear to be single chain proteins. These observations plus electrophoretic analyses of samples of plasmic digests of CIg indicate that the interchain disulfide bridging in the two chain molecule is located in a segment within approx. 175 residues of the NH2- or COOH-terminus.     

Lateral diffusion of gramicidin S,M-13 coat protein and glycophorin in bilayers of saturated phospholipids: Mean field and Monte Carlo studies

We have developed a general model that relates the lateral diffusion coefficient of one isolated large intrinsic molecule (mol. wt. ?1000) in a phosphatidylcholine bilayer to the static lipid hydrocarbon chain order. We have studied how protein lateral diffusion can depend upon protein-lipid interactions but have not investigated possible non-specific contributions from gel-state lattice defects. The model has been used in Monte Carlo simulations or in mean-field approximations to study the lateral diffusion coefficients of Gramicidin S, the M-13 coat protein and glycophorin in dimyristoyl- and dipalmitoylphosphatidylcholine (DMPC and DPPC) bilayers as functions of temperature. Our calculated lateral diffusion coefficients for Gramicidin S and the M-13 coat protein are in good agreement with what has been observed and suggest that Gramicidin S is in a dimeric form in DMPC bilayers. In the case of glycophorin we find that the ‘ice breaker’ effect can be understood as a consequence of perturbation of the lipid polar region around the protein. In order to understand this effect is is necessary that the protein hydrophilic section perturb the polar regions of at least approx. 24 lipid molecules, in good agreement with the numbers of 29–30 measured using ³¹P-NMR. Because of lipid-lipid interactions this effect extends itself out to four or five lipid layers away from the protein so that the hydrocarbon chains of between approx. 74 and approx. 108 lipid molecules are more disordered in the gel phase, so contributing less to the transition enthalpy, in agreement with the numbers of 80–100 deduced from differential scanning calorimetry (DSC). An understanding of the abrupt change in the diffusion coefficient at a temperature below the main bilayer transition temperature requires an additional mechanism. We propose that this change may be a consequence of a ‘coupling-uncoupling’ transition involving the protein hydrophilic section and the lipid polar regions, which may be triggered by the lipid bilayer pretransition. Our calculation of the average number of gauche bonds per lipid chain as a function of temperature and distance away from an isolated polypeptide or integral protein shows the extent of statically disordered lipid around such molecules. The range of this disorder depends upon temperature, particularly near the main transition.     

Structural and dynamical studies of mixed chlorophyll/phosphatidylcholine bilayers via x-ray diffraction, absorption polarization spectroscopy and nuclear magnetic resonance.

The structure and dynamics of phosphatidylcholine bilayers containing chlorophyll were studied by X-ray diffraction and absorption polarization spectroscopy in the form of hydrated orientated multilayers below the thermal phase transition of the lipid chains and by nuclear magnetic resonance in the form of single-wall vesicles above the thermal transition. Our results show that (a) chlorophyll is incorporated into the phosphatidylcholine bilayers with its porphyrin ring located anisotropically in the polar headgroup layer of the membrane and with its phytol chain penetrating in a relatively extended form between the phosphatidylcholine fatty acid chains in the hydrocarbon core of the mixed bilayer membrane and (b) the intramolecular anisotropic rotational dynamics of the host phosphatidylcholine molecules are significantly perturbed upon chlorophyll incorporation into the bilayer at all levels of the phosphatidylcholine structure. These dynamics for the host phosphatidylcholine fatty acids chains are qualitatively different from that of the incorporated chlorophyll phytol chains on a 10(-9)-10(-10)s time scale in the ideally mixed two-component bilayer.     

Kinetic studies and molecular modelling attribute a crucial role in the specificity and stereoselectivity of penicillin acylase to the pair ArgA145-ArgB263.

Kinetic experiments with a substrate series of phenylacetyl-arylamides reveal that at least one polar group in the amine moiety is required for the proper orientation of the substrate in the large nucleophile-binding subsite of penicillin acylase of Escherichia coli. Quantum mechanical molecular modelling of enzyme-substrate interactions in the enzyme active site shows that in the case of substrates lacking local symmetry, the productive binding implies two nonsymmetrical arrangements with respect to the two positively charged guanidinium residues of ArgA145 and ArgB263. This indicates a crucial role of the specified arginine pair in the substrate- and stereoselectivity of penicillin acylase.     

Effects of lithium on the human erythrocyte membrane and molecular models

The mechanism whereby lithium carbonate controls manic episodes and possibly influences affective disorders is not yet known. There is evidence, however, that lithium alters sodium transport and may interfere with ion exchange mechanisms and nerve conduction. For these reasons it was thought of interest to study its perturbing effects upon membrane structures. The effects of lithium carbonate (Li+) on the human erythrocyte membrane and molecular models have been investigated. The molecular models consisted in bilayers of dimyristoylphosphatidylcholine (DMPC) and dimyristoylphosphatidylethanolamine (DMPE), representing classes of phospholipids located in the outer and inner monolayers of the erythrocyte membrane, respectively. This report presents the following evidence that Li+ interacts with cell membranes: a) X-ray diffraction indicated that Li+ induced structural perturbation of the polar head group and of the hydrophobic acyl regions of DMPC and DMPE; b) experiments performed on DMPC large unilamellar vesicles (LUV) by fluorescence spectroscopy also showed that Li+ interacted with the lipid polar groups and hydrophobic acyl chains, and c) in scanning electron microscopy (SEM) studies on intact human erythrocytes the formation of echinocytes was observed, effect that might be due to the insertion of Li+ in the outer monolayer of the red cell membrane.     

The molecular organization of bimolecular lipid membranes. A study of the low frequency Maxwell-Wagner impedance dispersion

Theoretical considerations show that the presence of the polar group regions in bimolecular lipid membranes will produce a small (2–3%) dispersion of the bimolecular lipid membrane capacitance at low frequencies (0.1–100 Hz).A dispersion in conductance will also result. Calculations are given of the resolution of phase angle and impendance amplitude required to detect this dispersion and a new measuring technique is described which can achieve this. From the experimental result presented for lecithin bimolecular lipid membranes a determination was made of the individual capacitances and conductances of both the hydrocarbon and polar groups regions. The polar group conductance was found to vary from 700 μΩ^?1 · cm^?2 (in 1 mM KCl) to 2000 μΩ^?1 · cm^?2 (in 1 M KCl).The polar group capacitances were found to be approx.30 μF · cm^?2 and not systematically dependent on the concentration of the external electrolyte.