Gerry A. Smith

The effect of bilayer thickness on the activity of (Na+ + K+)-ATPase

The activities of purified (Na+ + K+)-ATPase supported by a series of phosphatidylcholines with monounsaturated (cis-9) fatty acyl chains (di(n : 1) phosphatidylcholine) varying in length from n = 12 to n = 23 were determined by the lipid titration technique. The ATPase activity at 20 degrees C decreased from 2.9 to 0.1 mumol/min per mg protein as n was decreased from 16 to 12 and decreased from 2.9 to 1.0 mumol/min per mg protein as n was increased from 20 to 23. In further experiments, the di(n : 1) phosphatidylcholine-ATPase complexes were treated with increasing proportions of n-decane, which has been shown previously to increase the thickness of black lipid membranes. n-Decane caused a large increase (greater than 20-fold) in activity of the short-chain complexes (n = 12,13); for n = 14--18, the ATPase activity first increased and subsequently decreased as the proportion of decane was increased, and for n = 20 or 23 decane caused a progressive decrease in activity with increasing concentration. These effects confirm qualitatively that a major factor determining the activity in each bilayer is its thickness. This behaviour closely parallels that of the (Ca2+ + Mg2+)-ATPase of sarcoplasmic reticulum [1] and suggests that a major class of trans-membrane transport proteins may have a similar dependence on bilayer thickness.

The lipid environment of the glucagon receptor regulates adenylate cyclase activity

1. The lipids composition of rat liver plasma membranes was substantially altered by introducing synthetic phosphatidylcholines into the membrane by the techniques of lipid substitution or lipid fusion. 40-60% of the total lipid pool in the modified membranes consisted of a synthetic phosphatidylcholine. 2. Lipid substitution, using cholate to equilibrate the lipid pools, resulted in the irreversible loss of a major part of the adenylate cyclase activity stimulated by F-, GMP-P(NH)P or glucagon. However, fusion with presonicated vesicles of the synethic phosphatidylcholines causes only small losses in adenylate cyclase activity stimulated by the same ligands. 3. The linear form of the Arrhenius plots of adenylate cyclase activity stimulated by F- or GMP-(NH)P was unaltered in all of the membrane preparations modified by substitution or fusion, with very similar activation energies to those observed with the native membrane. The activity of the enzyme therefore appears to be very insensitive to its lipid environment when stimulated by F- or gmp-p(nh)p. 4. in contrast, the break at 28.5 degrees C in the Arrhenius plot of adenylate cyclase activity stimulated by glucagon in the native membrane, was shifted upwards by dipalmitoyl phosphatidylcholine, downwards by dimyristoyl phosphatidylcholine, and was abolished by dioleoyl phosphatidylcholine. Very similar shifts in the break point were observed for stimulation by glucagon or des-His-glucagon in combination with F- or GMP-P(NH)P. The break temperatures and activation energies for adenylate cyclase activity were the same in complexes prepared with a phosphatidylcholine by fusion or substitution. 5. The breaks in the Arrhenius plots of adenylate cyclase activity are attributed to lipid phase separations which are shifted in the modified membranes according to the transition temperature of the synthetic phosphatidylcholine. Coupling the receptor to the enzyme by glucagon or des-His-glucagon renders the enzyme sensitive to the lipid environment of the receptor. Spin-label experiments support this interpretation and suggest that the lipid phase separation at 28.5 degrees C in the native membrane may only occur in one half of the bilayer.

The glucagon receptor of rat liver plasma membrane can couple to adenylate cyclase without activating it.

1. Activation of adenylate cyclase in rat liver plasma membranes by fluoride or GMP-P (NH)P yielded linear Arrheniun plots. Activation by glucagon alone, or in combination with either fluoride or GMP-P(NH)P resulted in biphasic Arrhenius plots with a well-defined break at 28.5 +/- 1 degrees C. 2. The competitive glucagon antagonist, des-His-glucagon did not activate the adenylate cyclase but produced biphasic Arrhenius plots in combination with fluoride or GMP-P(NH)P. The break temperatures and activation energies were very similar to those observed with glucagon alone, or in combination with either fluoride or GMP-P(NH)P. 3. It is concluded that although des-His-glucagon is a potent antagonist of glucagon, it nevertheless causes a structural coupling between the receptor and the catalytic unit.

Exchange of partners in glucagon receptor-adenylate cyclase complexes. Physical evidence for the independent, mobile receptor model

Abstract The apparent target sizes of the glucagon receptor and the catalytic unit of adenylate cyclase in rat liver plasma membranes have been measured by the technique of radiation inactivation in an electron beam. When irradiated in the uncoupled state, the apparent target size for the catalytic unit assayed by fluoride-stimulated activity was 160 000, and for the receptor assayed by specific 125 I-labelled glucagon binding was 217 000. The corresponding target size estimated from glucagon-stimulated activity after irradiation in the uncoupled state was 389 000. When the complexes were irradiated in the coupled state in the presence of glucagon, the apparent target sizes from 125 I-labelled glucagon binding, and fluoride- or glucagon-stimulated activities had similar values of 310 000, 380 000 and 421 000, respectively. However, if the complexes were allowed to uncouple by removing glucagon after irradiation and activity was then assayed after readdition of glucagon, the apparent target size from the glucagon-stimulated activity increases from 421 000 to 811 000. The pattern of apparent target sizes obtained under these different conditions has been tested against the pattern predicted for simple models of the coupling mechanism. The only simple model that is consistent with the pattern of target sizes requires the receptors and catalytic units to be present in approximately equal numbers. On binding glucagon, the receptor forms a locking interaction with the catalytic units, so that the complex and its components are inactivated as a single target with an apparent size of about 380 000 ( ± 15% ). After the removal and readdition of glucagon to complexes that were irradiated in the coupled state, the new population of complexes must contain hybrids of active and inactive partners obtained by exchange between active and inactivated complexes, to account for the doubling in apparent target size to 811 000 for glucagon-stimulated activity. This hybridization of catalytic units and receptors is the essential feature of the model that distinguishes it from others in which permanently associated complexes of the two components are activated by lateral dimersation on binding glucagon. Simple models of this type are shown to be physically improbable. It is emphasized that the models described are based only on the relationships between the apparent target sizes of components that are defined by their functions, and the apparent target sizes do not necessarily relate solely to the components that can be defined structurally as the receptor or catalytic unit.

Free cytosolic Ca2+ measurements with fluorine labelled indicators using 19FNMR

Characterisation by 19F NMR of fluorine-labelled indicators of cytosolic free Ca2+ concentration (by 5FBAPTA) and pH (by Fquene) is described, together with the techniques used to load the cell suspensions with the indicators for NMR spectroscopy. Useful features of the 19F NMR indicators include direct identification of the intracellular cation bound to the indicators, internal calibration of [Ca]i and pHi from the spectra, and simultaneous measurements of two or more indicators in the same cell suspension. Perturbations of cellular functions by 5FBAPTA and quin 2 are very similar, but vary widely in different cell systems. The [Ca]i and pHi responses of normal and transformed cells to mitogens and growth factors in serum are compared with data from similar experiments using fluorescence indicators. The only major discrepancy in [Ca]i measurements using the two independent assays was observed in Ehrlich ascites tumour cells. These cells have a high intracellular Zn2+ content which substantially quenches the quin 2 fluorescence, but does not affect [Ca]i measurements by 5FBAPTA. The Zn2+ present in the cells is detected as a separate response in the 5FBAPTA spectrum. The time course of the Ca signal in 2H3 cells stimulated by antigen to release histamine by exocytosis has been defined using 5FBAPTA and quin 2. Extension of the 19F NMR technique to [Ca] i and pHi measurements in perfused organs is illustrated in rat heart and responses to pharmacological agents are demonstrated. Developments in prospect to improve sensitivity and to measure [Na]i with a new family of indicators are outlined.

Some mitogens cause rapid increases in free calcium in fibroblasts

Quiescent 3T3 fibroblasts grown on microcarrier beads and loaded with the [Ca2+] indicator quin2 had a cytosolic free Ca2+ concentration ([Ca2+]i) of 154 ± 11 nM (SE; n = 32). Stimulation with the mitogens vasopressin, epidermal growth factor (EGF) or prostaglandin F2α (PGF2α) caused a very rapid increase in [Ca2+]i to a maximum of 200–500 nM after 60–90 s. [Ca2+]i declined thereafter to a level above that in quiescent cells which was maintained for at least 15 min. In contrast no immediate effects on [Ca2+]i were detected after the addition of the mitogens insulin or 12‐O‐tetradecanoylphorbol 13‐acetate (TPA). These studies indicate that early changes in [Ca2+]i may be involved in the action on fibroblasts of some, but not all, mitogens.

Bilayer thickness and enzymatic activity in the mitochondrial cytochrome c oxidase and ATPase complex

Lipid-protein interactions are of great importance for the correct function and location of membrane-bound enzymes [ 1,2]. Nevertheless very little is known about the structure and folding of the polypeptide chains directly involved in the interaction with lipids. So far a low-resolution picture of polypeptide arrangement in the membrane has been obtained only for bacteriorhodopsin [3]. Few of the many integral membrane proteins, which have been isolated in pure form, have been sequenced. Most of these sequences show uninterrupted stretches of uncharged amino acids ,Z 18 residues long [4]. Hydrophobic photolabelling with photoreactive lipids has been used to identify which of these segments are in contact with lipids and hence to define the protein surface of the hydrophobic sector [5-71. A defined bilayer thickness is required for optimal activity of the sarcoplasmic reticulum Ca2+-ATPase and the (Na+, K+)-ATPase [8,9]. This investigation was based on the use of a homologous series of unsaturated phosphatidylcholines of different fatty acid chain length, which form bilayers of varying thickness [8]. Thus some information on the vertical dimension of the hydrophobic sector and on the forces involved in the

The exogenous lipid requirement for histamine release from rat peritoneal mast cells stimulated by concanavalin A

Mast cells contain storage granules which fuse with the plasma membrane and release their contents from the cell when stimulated in vivo by an antigen to which the animal has been sensitised [ 1,2]. This process is responsible for the anaphylactic response, and the main component of the storage granules is histamine. The mechanism of stimulation involves the crosslinking of the IgE molecules bound to F, receptors on the cell surface [3]. Dimerisation of the receptors appears to generate a sufficient signal, since stimulation by dimeric IgE is as effective as polymeric forms of the antibody [4]. The stimulation of the cells in vitro occurs with a wide range of agents which interact with the plasma membrane, including the plant lectin concanavalin A (con A) [5,6]. Con A appears to act by the same mechanism as antigen in that it crosslinks IgE molecules bound to the cell surface by multivalent interaction with carbohydrate residues on the IgE molecules [7]. A peculiarity of the rat peritoneal mast cell system in vitro is that stimulation by antigen [8], anti-&E antibody [9], con A [6] and anti F, receptor antibody [lo] is strongly and specifically potentiated by the lipid phosphatidyl serine (PS). Here we report further examination of the lipid involvement in the stimulation of mast cells by con A. We show that the lyso-PS analogue is at least 1 03-fold more potent than PS; that it probably acts by binding directly to the cells, and that <3 X 1 O6 molecules/cell of bound lyso-PS are required for maximal co-stimulation with con A. Although the entry of Ca*+ into the cells has been strongly implicated in the mechanism of stimulation [ 1 11, lyso-PS appears to have little or no action as a Ca2+ ionophore by itself or in combination with the Ca2+ ionophore A23 187 which stimulates mast cells in the presence of external Ca*+ [ 121.

The phospholipid headgroup specificity of an ATP-dependent calcium pump.

We have replaced the lipid associated with a purified calcium transport protein with a series of defined synthetic dioleoyl phospholipids in order to determine the effect of phospholipid headgroup structure on the ATPase activity of the protein. At 37 degrees C the zwitterionic phospholipids (dioleoyl phosphatidylcholine and dioleoyl phosphatidylethanolamine) support the highest activity, while a phospholipid with two negative charges (dioleoyl phosphatidic acid) supports an activity which is at least twenty times lower. Dioleoyl phospholipids with a single net negative charge support at intermediate ATPase activity which is not affected by the precise chemical structure of the phospholipid headgroup. The protocol used to determine the phospholipid headgroup specificity of calcium transport protein is novel because it establishes the composition of the lipid in contact with the protein without the need to isolate defined lipid-protein complexes. This allows the lipid specificity to be determined using only very small quantities of test lipids. We also determined the ability of the same phospholipids to support calcium accumulation in reconstituted membranes. Two requirements had to be met. The phospholipid had to support the ATPase activity of the pump protein and it had to form sealed vesicles as determined by electron microscopy. Since a number of phospholipids met those requirements it is clear that in vitro the lipid specificity of the calcium-accumulating system is rather broad.

Intracellular ph and free calcium changes in single cells using quene 1 and quin 2 probes and fluorescence microscopy.

Photometric fluorescence microscopy has been used to measure intracellular pH (pHi) and free calcium concentrations ([Ca]i) in individual mouse thymocytes and 2H3 rat basophil leukaemic cells containing indicators for pH (quene 1) or calcium (quin 2). The pHi and [Ca]i measurements in individual 2H3 cells and mouse thymocytes and their responses to various stimuli were consistent with the corresponding data obtained from suspensions of these cells measured in a spectrofluorimeter. Photometric fluorescence microscopy of these indicators in individual cells provides a sensitive and fast method of following pHi and [Ca]i responses in individual cells.