Equilibrium studies of lecithin-cholesterol interactions. II. Phase relations in surface films: analysis of the "condensing" effect of cholesterol

From measurements of the equilibrium spreading pressure pie for dispersions of lecithin--dimyristoyl (DML) or dioleoyl (DOL)--and cholesterol (CHOL) in water, we have deduced the phase relations in both the aqueous dispersions and the equilibrium surface films. At 29.5 degrees C, when the mole fraction of cholesterol in the dispersion chi(CHOL) is 0 chi(CHOL) less than chi(CHOL) less than 0.33, pie is constant and equal to the value for pure lecithin (DOL or DML). The phase rule predicts than two bulk lipid phases coexist; these are pure lecithin and lecithin:cholesterol 2:1 complex. The equilibrium surface film contants only lecithin and therefore lecithin and 2:1 complex are immiscible in surface films. When 0.33 less than chi/CHOL) less than 1.0, pie is also contant with a value intermediate between that for pure lecithin and cholesterol. In this range of lipid composition two bulk lipid phases also coexist: lecithin:cholesterol 2:1 complex and pure cholesterol. However, the equilibrium surface film contains only the 2:1 complex and, therefore, 2:1 complex is also immiscible with cholesterol in surface films. When pi less than pie, as in the case of spread films, we deduce that two surface phases may coexist; the composition of the phases will depend on chi(CHOL). When 0 less than chi(CHOL) less than 0.33, both lecithin and 2:1 complex coexist, and when 0.33 less than chi(CHOL) less than 1.0, 2:1 complex and cholesterol coexist. The "condensing" effect of cholesterol in lecithin surface films is reexamined. The effect is attributed to formation of the lecithin:cholesterol 2:1 complex and nonequilibrium conditions in the two-phase surface film.     

Stoichiometry of receptor-Gs-adenylate cyclase interactions.

Little is known about the relative stoichiometry of guanine nucleotide-binding (G) proteins relative to the effector systems to which they link. We addressed this question for the stimulatory G protein (Gs) linked to adenylate cyclase. Forskolin stimulates the catalytic subunit of adenylate cyclase (C), but it has a higher efficacy and potency when C also interacts with the G protein Gs. Accordingly, we measured high-affinity [3H]forskolin binding to intact cells to assay alpha s-C complexes. No high-affinity specific binding occurred with unstimulated cells. The beta-adrenergic agonist isoproterenol promoted the binding of [3H]forskolin to about 3000 sites per cell, suggesting that each receptor on average activates at least several Gs molecules. Activating Gs directly with cholera toxin maximally promoted [3H]forskolin binding to a similar number of sites, suggesting that this is the maximal number of alpha s-C complexes formed per cell. We conclude that each cell likely contains only a few thousand functional copies of C, and that the availability of C (rather than Gs, which exists in more than 100,000 copies per cell) is likely to be limiting for agonist stimulation of adenylate cyclase activity.     

Bimolecular systems: I. Linear systems of complexes

A vast number of biologically important processes are based upon bimolecular systems. In these systems intermediate complexes are formed. Bimolecular systems in which no complex-complex interactions occur are called linear systems of complexes. A definition and some characteristic properties of these systems are given here. There may exist a contradiction of Onsager's principle of detailed balancing in these systems; however, no principal differences are found between the steady state behavior of an open system and that of a closed system. It is shown that the steady state behavior of a linear system of complexes of arbitrary complexity has some similarities with the steady state behavior of a simple bimolecular system, e.g., Michaelis-Menten enzymatic reaction. Multiplicity of action of the substances participating in biomolecular processes may produce some qualitative differences in the steady state behavior of the system.     

Equilibrium studies of cytidine for chloride substitution in palladium complexes

Equilibrium constants for substitution of Cl^? by cytidine in PdCl^42? and Pd(en)Cl² in aqueous solution were determined. Equilibrium constants for substitution of Cl^? by pyridine in Pd(en)Cl₂ were also measured. For unit ionic strength at 25°C, log K values for the successive substitutions of two chlorides are: PdCl₄^2? -cytidine, log K₁ = 4.49, log K₂ = 3.45; Pd(en)Cl₂-cytidine, log K₁ = 3.32, log K₂ = 2.56; Pd(en)Cl₂-pyridine, log K₁ = 4.31, log K₂ = 3.15. Comparison of equilibrium constants indicates that intramolecular hydrogen bonding and steric interactions of the exocyclic substituents ortho to the binding site of cytidine do not contribute significantly to the stability of the palladium-nucleoside complexes. Coordination equilibria, of deprotonated cytidine occur in alkaline solutions of PdCl₄^2? and the ligand.     

Drug-metal interactions: spectroscopic studies of copper hydantoin complexes.

The preparation and spectral properties of copper(II) complexes of two hydantoins are reported. Complexes of the general formula Cu(hyd)2(py)2, where hyd = phenytoin or nirvanol; and py = pyridine were prepared and characterized by infrared and ESR. Spectral data show that the copper atom is bound to the nitrogen atom of the hydantoin anion and to the nitrogen atom of the pyridine molecule to form 2:2:1 hydantoin:pyridine:copper complexes. The ESR data indicate that both complexes have tetragonal symmetry (g11 greater than g perpendicular greater than g e) with the unpaired electron in the d x2-y2 orbital.     

Interaction of chloride with yeast aminopeptidase I. Equilibrium binding studies

The effect of chloride on metal binding by yeast aminopeptidase I, as well as the binding of chloride to various enzyme forms were studied by means of a micro-centrifugation technique using radioactive 36Cl- as a ligand. Chloride did not significantly alter the binding of activating Zn2+, or binding of Co2+ to the essential metal sites. Both the native Zn2+ enzyme and Co2+-substituted aminopeptidase I bind stoichiometric amounts of C1- (1 Cl-/subunit) with apparent dissociation constants of 0.1-0.2 mM. Additional Cl- was bound at higher concentrations. In contrast to the metal-containing enzyme forms the apoenzyme did not express the high-affinity chloride binding site.     

Subunit interactions of lobster hemocyanin. I. Ultracentrifuge studies

Subunit interactions in the hemocyanin of New England lobster, Homarus americanus, were investigated by means of the ultracentrifuge, using sedimentation velocity and Archibald molecular weight methods. It was verified that a 17S species dimerizes rapidly and reversibly to form a 25S species in the pH range 9.4–9.7 in the presence of calcium ion. From the Ca²⁺ and pH dependence of the equilibrium constant for this process, the absorption of approximately five calcium ions and three protons accompany the formation of one molecule of the 25S species. The sedimentation velocity patterns were also found to shift in favor of the 17S species with the imposition of excess hydrostatic pressure.     

Equilibrium partition studies of the myofibrillar interactions of glycolytic enzymes

The interactions of several glycolytic enzymes with muscle myofibrils in imidazole-chloride buffer (pH 6.8, I 0.158) have been investigated by equilibrium partition studies. Results for aldolase, glyceraldehyde-3-phosphate dehydrogenase, lactate dehydrogenase, and phosphofructokinase are interpreted in terms of a myofibrillar capacity of 76 nmol/g protein and a single intrinsic association constant for each tetravalent enzyme with matrix sites. The existence of separate myofibrillar sites for aldolase and glyceraldehyde-3-phosphate dehydrogenase is established by demonstrating independence of the binding of each enzyme upon the presence of the other. Although this investigation provides further physicochemical support for myofibrillar adsorption of glycolytic enzymes in the cellular environment, its findings are incompatible with the proposition (B. I. Kurganov, N. P. Sugrobova, and L. S. Mil'man (1985) J. Theor. Biol. 116, 509-526) that the phenomenon reflects the formation of a specific multienzyme complex attached to the myofibril.     

Stoichiometry of protein complexes in plant photosynthetic membranes

Hetero-oligomeric membrane protein complexes form the electron transport chain (ETC) of oxygenic photosynthesis. The ETC complexes undertake the light-driven vectorial electron and proton transport reactions, which generate energy-rich ATP and electron-rich NADPH molecules for carbon fixation. The rate of photosynthetic electron transport depends on the availability of photons and the relative abundance of electron transport complexes. The relative abundance of the two photosystems, critical for the quantum efficiency of photosynthesis in changing light quality conditions, has been determined successfully by optical methods. Due to the lack of spectroscopic signatures, however, relatively little is known about the stoichiometry of other non-photosystem complexes in plant photosynthetic membrane. Here we determine the ratios of all major thylakoid-bound ETC complexes in Arabidopsis by a label-free quantitative mass spectrometry technique. The calculated stoichiometries are consistent with known subunit composition of complexes and current estimates of photosystem and cytochrome b₆f concentrations. The implications of these stoichiometries for photosynthetic light harvesting and the partitioning of electrons between the linear and cyclic electron transport pathways of photosynthesis are discussed.     

Equilibrium centrifugation studies of hepatitis C virus: evidence for circulating immune complexes.

The buoyant density of hepatitis C virus (HCV), with high in vivo infectivity (strain H) or low in vivo infectivity (strain F), was determined by sucrose gradient equilibrium centrifugation. Viral RNA of strain H was detected in fractions with densities of < or = 1.09 g/ml (principally approximately 1.06 g/ml), while that of strain F was found in fractions with densities of approximately 1.06 and approximately 1.17 g/ml. The observed difference was confirmed by differential flotation centrifugation; in NaCl solution with a density of 1.063 g/ml, most of the HCV RNA of strain H was detected in the top fraction, while that of strain F appeared in the bottom. The same relationship between buoyant density and infectivity was observed in flotation centrifugation experiments with other HCV strains. In immunoprecipitation experiments with anti-human immunoglobulin, HCV (as measured by HCV RNA) was precipitated from the samples with low infectivity and high density but not from those with high infectivity and low density. Examination of serial sera from a chimpanzee infected with HCV revealed parallel changes in the buoyant density and immunoprecipitability of HCV-associated RNA during the course of infection. These data suggest that HCV is bound to anti-HCV antibodies as antigen-antibody complexes in chronic hepatitis C.     

Properties of phosphatidylethanolamine-containing phospholipid-apolipoprotein complexes modified by lecithin-cholesterol acyltransferase

The effect of the inclusion of phosphatidylethanolamine (PE), a phospholipid with unusual packing properties, on the substrate properties of protein-lipid complexes toward lecithin-cholesterol acyltransferase (LCAT) has been studied. Recombinant particles of apolipoprotein A-I with dimyristoylphosphatidylcholine (DMPC), dilauroylphosphatidylethanolamine (DLPE) and cholesterol were prepared at a molar ratio of 1:140:14 (A-I/DMPC/cholesterol) or 1:70:70:14 (A-I/DMPC/DLPE/cholesterol); the efficiency of cholesterol incorporation into complexes containing phosphatidylethanolamine was found to be very pH-dependent, with enhanced cholesterol incorporation at elevated pH values. By incubating the complexes with either purified human LCAT or the d greater than 1.21 g/ml fraction of rat serum as a source of LCAT activity, it was found that a high degree of cholesterol esterification could be achieved with either complex; however, the DLPE-containing complex possessed a much smaller Stokes' diameter than the DMPC-only particle despite compositional similarities between these complexes. With respect to particle diameter the DLPE-containing particles behaved more like complexes prepared with egg yolk lecithin than did complexes prepared with DMPC alone. When human LDL was added to the incubations to provide a source of additional cholesterol, the products were markedly different. Concomitant with an increased cholesteryl ester core was an increase in the protein stoichiometry in both types of particles, from 2 to 3 or 4 apo A-I per particle. The proportion of DLPE to DMPC in the products was reduced from 1:1 to 0.3:1, reflecting a preferential hydrolysis of PE by LCAT, and the Stokes' diameters of the DMPC-only and the DLPE-containing complexes were closely similar. We conclude that the presence of elevated proportions of certain phospholipid species may significantly alter both the physical properties of the particles and their substrate properties with regard to reactions with enzymes of lipid metabolism.     

Fluorescence studies of possible protein-protein interactions in model lipoprotein complexes

Summary The structure of model lipoprotein complexes, extracted from an aqueous phase into isooctane, has been investigated using a fluorescence technique. The technique is based on the transfer of excitation energy from one protein (or DNS-labelled protein) to a second protein containing a fluorescence quencher, such as a haem group. The results obtained with model complexes in isooctane are consistent with a structure comprised of an inner protein core, and an outer layer of phospholipids.     

Stoichiometry of P1 plasmid partition complexes

The P1 plasmid prophage is faithfully partitioned by a high affinity nucleoprotein complex assembled at the centromere-like parS site. This partition complex is composed of P1 ParB and Escherichia coli integration host factor (IHF), bound specifically to parS. We have investigated the assembly of ParB at parS and its stoichiometry of binding. Measured by gel mobility shift assays, ParB and IHF bind tightly to parS and form a specific complex, called I + B1. We observed that as ParB concentration was increased, a second, larger complex (I + B2) formed, followed by the formation of larger complexes, indicating that additional ParB molecules joined the initial complex. Shift Western blotting experiments indicated that the I + B2 complex contained twice as much ParB as the I + B1 complex. Using mixtures of ParB and a larger polyhistidine-tagged version of ParB (His-ParB) in DNA binding assays, we determined that the initial I + B1 complex contains one dimer of ParB. Therefore, one dimer of ParB binds to its recognition sequences that span an IHF-directed bend in parS. Once this complex forms, a second dimer can join the complex, but this assembly requires much higher ParB concentrations.     

Magnesium-induced self-association of calf brain tubulin. I. Stoichiometry.

The self-association of calf brain tubulin at pH 7.0 in the presence of magnesium ions has been examined by velocity sedimentation. The schlieren patterns were analyzed by methods described by Gilbert and by Cox. The observed process is best described in terms of a rapidly reversible progressive self-association of the tubulin dimer with identical chain elongation equilibrium constants, k, terminated by a ring-closing step, at degree of polymerization n = 26 +/- 2, with k26 greater than k. The end product of the polymerization reaction has a sedimentation coefficient s20,w0 k2 +/- 2 S. It is hydrodynamically equivalent to a closed ring structure observed in the electron microscope at identical conditions.