Long-lived metastable states and hysteresis in the binding of acetylcholine to Torpedo california acetylcholine receptor

Charge-voltage curves of Shaker potassium channel are not hysteretic at steady state

Charge-voltage curves of many voltage-gated ion channels exhibit hysteresis but such curves are also a direct measure of free energy of channel gating and, hence, should be path-independent. Here, we identify conditions to measure steady-state charge-voltage curves and show that these are curves are not hysteretic. Charged residues in transmembrane segments of voltage-gated ion channels (VGICs) sense and respond to changes in the electric field. The movement of these gating charges underpins voltage-dependent activation and is also a direct metric of the net free-energy of channel activation. However, for most voltage-gated ion channels, the charge-voltage (Q-V) curves appear to be dependent on initial conditions. For instance, Q-V curves of Shaker potassium channel obtained by hyperpolarizing from 0 mV is left-shifted compared to those obtained by depolarizing from a holding potential of -80 mV. This hysteresis in Q-V curves is a common feature of channels in the VGIC superfamily and raises profound questions about channel energetics because the net free-energy of channel gating is a state function and should be path independent. Due to technical limitations, conventional gating current protocols are limited to test pulse durations of <500 ms, which raises the possibility that the dependence of Q-V on initial conditions reflects a lack of equilibration. Others have suggested that the hysteresis is fundamental thermodynamic property of voltage-gated ion channels and reflects energy dissipation due to measurements under non-equilibrium conditions inherent to rapid voltage jumps (Villalba-Galea. 2017. Channels. https://doi.org/10.1080/19336950.2016.1243190). Using an improved gating current and voltage-clamp fluorometry protocols, we show that the gating hysteresis arising from different initial conditions in Shaker potassium channel is eliminated with ultra-long (18-25 s) test pulses. Our study identifies a modified gating current recording protocol to obtain steady-state Q-V curves of a voltage-gated ion channel. Above all, these findings demonstrate that the gating hysteresis in Shaker channel is a kinetic phenomenon rather than a true thermodynamic property of the channel and the charge-voltage curve is a true measure of the net-free energy of channel gating.

Digression on chemical electromagnetic field effects in membrane signal transduction--cooperativity paradigm of the acetylcholine receptor

There is ongoing public concern on potential hazards and risks of even small electromagnetic fields (EMFs) such as those emanating from electrical appliances. Evolution and persistence of life in the natural geofields and basic scientific experience in using technical EMFs (F) suggest that, in general, living matter is remarkably stable against external field perturbations within the technical safety limits of the EM field strengths. Besides the trivial primary effects of EMF on ionic charges and dipolar matter, it is explicitly elaborated that cellular biochemical reactivity and channel transport processes are field dependent. However, equilibrium (K) and rate (k) constants are only sensitive to F if the reaction moments deltaM are finite, as seen in the general van't Hoff relationship d ln K/dF = deltaM/RT. Indeed, it is the difference (deltaM) in the electric or magnetic moments (M), representing the difference in the field forces on the reaction partners, that determines the extent of the field-induced transitions, say from an inactive conformer of a macromolecule to an active one. If small EM fields, which locally can only cause small shifts in K and k, are to become effective for chemical reactivity, amplification is required. A widely encountered concept of chemical amplification is structural, and thus functional, cooperativity, realized in many biopolymers. The cooperation of n units of such a polymer yields a larger deltaM(n)= ndeltaM and exponentially increases the field sensitivity of the overall equilibrium constant K(n) = Kn. Using the acetylcholine receptor protein as an example for signal amplification by structural cooperativity, explicit proposals are specified for the presumed amplification of small local field effects on proteins of the classical signal transduction cascades. Electric membrane field amplification by interfacial polarization in external fields is discussed in the context of using electric field pulses to transiently permeabilize cells and tissue for the direct transfer of effector substances and genes in cancer and gene therapy.

Phosphatidylinositol 4-kinase of Torpedo californica electrocytes: physico-chemical characterization and regulation by calcium and vicinal molecules of phosphatidylinositol

A phosphatidylinositol 4-kinase (Ptdlns 4-kinase, M(r) approximately 95,000) from the membranes of the electric organ of Torpedo californica was purified to apparent homogeneity. The Michaelis constant for ATP (KM = 280 +/- 60 microM at 20 degrees C) and the inhibition constant for adenosine (Ki = 0.4 mM at 20 degrees C) qualify the electrocyte Ptdlns 4-kinase as a type III kinase. The Ptdlns 4-kinase phosphorylates preferentially exogenous Ptdlns, added in the form of mixed Ptdlns/Triton X-100 micelles, whereas endogenously bound Ptdlns in the membrane fragments of electrocytes is a very poor substrate. It is important that the enzyme and the substrate Ptdlns are situated in different lipid bilayers. The catalytic turnover constant for exogenous Ptdlns is k = 55.3 +/- 6 min-1 at 20 degrees C and the molar Triton X-100/Ptdlns ratio of 16:1. For the substrate Ptdlns in the 'micellar solvent' Triton X-100, steady state kinetics were analysed in terms of the mole fraction X = n(Ptdlns)/[n(Ptdlns) + n(Triton X)] yielding the characteristic Michaelis mole fraction XM = 0.019 +/- 0.005 at 20 degrees C. The activity of the enzyme was enhanced about 5-fold in the presence of Triton X-114, yielding k = 277 +/- 30 min-1 at 20 degrees C. Triton X-114 has a shorter head-group, indicating that the vicinity of the Ptdlns head group in the mixed micelles should not be screened by bulky neighbours. The inhibition of the enzyme activity by Ca2+ is highly cooperative yielding the Hill inhibition constant Ki = 0.47 +/- 0.1 mM and the Hill coefficient h = 3.6 +/- 0.5. The enthalpy of activation is 100 +/- 10 kJ/mol between 0 degree C and 20 degrees C. Although the Ptdlns 4-kinase can be affinity-chromatographically copurified with the nicotinic acetylcholine (AcCho) receptor, suggesting tight association between the two proteins. AcCho does not affect the activity of the Ptdlns 4-kinase in the presence of the AcCho receptor.

The initiation of the muscle action potential

The specific functional properties of the nicotinic acetylcholine receptors (AChR) and the particular oligomeric membrane organization of AChR are suggested to be the basis for the steep electrical depolarisation, required for the initiation of the postsynaptic action potentials causing muscle contraction and discharge of electric organs. The dimer (M(r) approximately 580,000) and the monomer (M(r) approximately 290,000) of the detergent-solubilized, affinity-purified AChR of Torpedo californica electrocytes exhibit different channel conductances and larger oligochannels. Patch clamp data of the dimer, reconstituted in large lipid vesicles, show that the dimer is a double-channel protein causing single-channel events of conductance G(D) = 84 +/- 6 pS at 0.11 M K+ and 0.1 mM Ca2+ at 293 K (20 degrees C). At the same ionic conditions the vesicle-reconstituted monomer, if prevented from aggregation, exhibits a channel conductance, G(M) = 42 +/- 3 pS, which is only half of that of the dimer. The dimer conductivity event thus reflects the synchronous switching of its two constituent monomeric parts. The K(+)-conductance of the reconstituted Torpedo dimer is the same, and shows the same inhibitory Ca(2+)-dependence, as that of the Torpedo AChR expressed in Xenopus laevis oocytes (Imoto et al., Nature, 324, 670-674, 1986). In terms of Ca(2+)-binding, reducing K(+)-transport, the equilibrium constant is KCa = 0.48 mM at 0.11 m K+, 20 degrees C; G0([Ca]-->0) = 98 +/- 6 pS and G infinity ([Ca]-->infinity) = 27 +/- 6 pS. The ratio G0/G infinity and an estimate of the lateral surface area of the channel vestibule yields about 16 negatively charged groups in an average distance of 1.8 nm. These negative charges cause an accumulation of K+ ions in the channel vestibule by a factor of about 4. Our results and the comparison with the oocyte data reveal that it is also the dimer which is the physiological opening-closing unit of the AChR in the oocyte membrane. The larger macrochannel events are multiples of the dimer or of the monomer conductances. The occurrence of such oligochannels from AChR protein oligomers could guarantee the steep electrical depolarisation necessary to generate the action potential by the Na(+)-channel system.

Fluorescence correlation spectrometry of the interaction kinetics of tetramethylrhodamin α-bungarotoxin with Torpedo californica acetylcholine receptor

Fluorescence correlation spectroscopy (FCS) is suited to determine low concentrations (10(-8) M) of slowly interacting molecules with different translational diffusion coefficients on the level of single molecule counting. This new technique was applied to characterize the interaction dynamics of tetramethylrhodamin labelled alpha-bungarotoxin (B( *)) with the detergent solubilized nicotinic acetylcholine receptor (AChR) of Torpedo californica electric organ. At pseudo-first-order conditions for AChR, the complex formation with B( *) is monophasic. The association rate coefficient of the monoliganded species AChR . B is k(ass)' = 3.8 . 10(3) s(-1) at 293 K (20 degrees C). The dissociation of bound B( *) from the monomer species AChR . B( *) . B (and AChR . B(2)( *)), initiated by adding an excess of nonlabelled alpha-bungarotoxin (B), is biphasic suggesting a three state cascade for the B-sites: R(alpha) --> R(alpha)' --> R(alpha)'' with the exchange dissociation constants: (k(diss)')(B) = 5.5(+/-1) . 10(-5) s(-1) and (k(diss)'')(B) = 3(+/-1) . 10(-6) s(-1) at 293 K. The data are consistent with dissociative intermediate steps of ligand exchange on two different interconvertible conformations of one binding site. The dissociation of bound B( *) by excess of the neurotransmitter acetylcholine (ACh) is biphasic. At [ACh] = 0.1 M both B( *) are released from the AChR . B(2)( *) species. The mechanism involves associative ternary intermediates (AChR . B( *)A, AChR . B( *)A(2) and AChR . B(2)( *)A(2)). The equilibrium constants (K(A)) and dissociation rate constants (k(-A)) for ACh in the ternary complex state R(alpha)' and R(alpha)'', respectively, are K(A)' = 1.1 . 10(-2) M and k(-A)' = 3 . 10(5) s(-1) and K(A)'' = 7.5 . 10(-2) M and k(-A)'' = 2 . 10(6) s(-1). It is of physiological importance that the FCS data indicate that the AChR monomer species (M(r) = 290 000), which normally at [ACh] 1 mM only binds one ACh molecule, does bind two ACh molecules at [ACh] 0.1 M.

Structural heterogeneity of membrane receptors and GTP-binding proteins and its functional consequences for signal transduction

Recent information obtained, mainly by recombinant cDNA technology, on structural heterogeneity of hormone and transmitter receptors, of GTP-binding proteins (G-proteins) and, especially, of G-protein-linked receptors is reviewed and the implications of structural heterogeneity for diversity of hormone and transmitter actions is discussed. For the future, three-dimensional structural analysis of membrane proteins participating in signal transmission and transduction pathways is needed in order to understand the molecular basis of allosteric regulatory mechanisms governing the interactions between these proteins including hysteretic properties and cell-cybernetic aspects.

Nonequivalence of alpha-bungarotoxin binding sites in the native nicotinic receptor molecule

In the native, membrane-bound form of the nicotinic acetylcholine receptor (M-AcChR) the two sites for the cholinergic antagonist alpha-bungarotoxin (alpha-BGT) have different binding properties. One site has high affinity, and the M-AcChR/alpha-BGT complexes thus formed dissociate very slowly, similar to the complexes formed with detergent-solubilized AcChR (S-AcChR). The second site has much lower affinity (KD approximately 59 +/- 35 nM) and forms quickly reversible complexes. The nondenaturing detergent Triton X-100 is known to solubilize the AcChR in a form unable, upon binding of cholinergic ligands, to open the ion channel and to become desensitized. Solubilization of the AcChR in Triton X-100 affects the binding properties of this second site and converts it to a high-affinity, slowly reversible site. Prolonged incubation of M-AcChR at 4 degrees C converts the low-affinity site to a high-affinity site similar to those observed in the presence of Triton X-100. Although the two sites have similar properties when the AcChR is solubilized in Triton X-100, their nonequivalence can be demonstrated by the effect on alpha-BGT binding of concanavalin A, which strongly reduces the association rate of one site only. The Bmax of alpha-BGT to either Triton-solubilized AcChR or M-AcChR is not affected by the presence of concanavalin A. Occupancy of the high-affinity, slowly reversible site in M-AcChR inhibits the Triton X-100 induced conversion to irreversibility of the second site. At difference with alpha-BGT, the long alpha-neurotoxin from Naja naja siamensis venom (alpha-NTX) binds with high affinity and in a very slowly reversible fashion to two sites in the M-AcChR (Conti-Tronconi & Raftery, 1986). We confirm here that Triton-solubilized AcChR or M-AcChR binds in a very slowly reversible fashion the same amount of alpha-NTX.(ABSTRACT TRUNCATED AT 250 WORDS)

Phosphorylation of phosphatidylinositol associated with the nicotinic acetylcholine receptor of Torpedo californica

When isolated, detergent solubilized and affinity chromatographically purified nicotinic acetylcholine receptor of Torpedo californica electric organ is incubated with [gamma-32P]ATP/Mg2+, phosphatidylinositol 4-phosphate (PIP) is formed from receptor associated phosphatidylinositol (PI). This receptor associated endogenous kinase activity is enhanced by orthovanadate and, remarkably, also by acetylcholine. Exogenously added PI-kinase only increases the phosphorylation rate if vanadate is present. PIP as the main phosphorylation product (up to 95%) remains bound to the beta-, gamma- and delta-subunits of the receptor and to the receptor associated v-protein. The alpha-subunits do not carry 32p phosphate; no phosphatidylinositol 4,5-bisphosphate formation has been observed. Concomitant to lipid phosphorylation tyrosine and serine residues are phosphorylated (5% of total incorporated 32P phosphate).