Incorporation of 2-fluorohistidine in murine protein in vivo.

The tissue distribution and time course of incorporation into acid insoluble (bound) and acid soluble (free) fractions of [3H]2-fluorohistidine is compared to that of U[14C]Histidine in mouse tissues in vivo. The cycloheximide-sensitive incorporation of 2-FHis is between 9 and 17 percent of that of His. Unlike [14C]His a major fraction, approximately 90% at 72 hrs, of isotope derived from [3H]2-FHis remains in tissues for a prolonged period in an acid soluble form. The excretion of isotope derived from [14C]His (T1/2 = 5 hr) is more rapid than from [3H]2-FHis (T1/2 = 11.4 hrs). 2-FHis, at doses from 100 to 250 mg/kg produce a reversible inhibition of growth in mice.

Pumiliotoxin alkaloids: a new class of sodium channel agents.

Pumiliotoxin B (PTX-B) and a variety of congeneric alkaloids and synthetic analogs stimulated sodium flux and phosphoinositide breakdown in guinea pig cerebral cortical synaptoneurosomes. The effects of PTX-B and active congeners and analogs on sodium flux in synaptoneurosomes were potentiated markedly by scorpion venom (Leiurus quinquestriatus). In neuroblastoma cells, PTX-B and active congeners had no effect on sodium flux unless synergized by alpha-scorpion toxin or scorpion venom. Certain inactive congeners, lacking hydroxyl groups in the 6-alkylidene side chain, inhibited sodium flux elicited by PTX-B, scorpion venom, or the sodium channel activator batrachotoxin. Such inhibition appeared different from inhibition by local anesthetics, since pumiliotoxins, unlike local anesthetics, had little or no effect on binding of [3H]batrachotoxinin A benzoate to sodium channels. Thus, it appears likely that some "inactive" congeners bind to the PTX-B binding site, but do not activate sodium channels. In the absence of scorpion venom the stimulation of phosphoinositide breakdown in synaptoneurosomes was consonant with the stimulatory effects of these compounds on sodium flux through voltage-dependent sodium channels.

Voltage-dependent sodium channels in synaptoneurosomes: studies with 22Na+ influx and [3H]saxitoxin and [3H]batrachotoxinin-A 20-alpha-benzoate binding. Effects of proparacaine isothiocyanate.

22Na+ influx and binding of [3H]saxitoxin ([3H]STX) and [3H]batrachotoxin-A 20-alpha-benzoate ([3H]BTX-B) were studied in guinea pig cerebral synaptoneurosomes. STX and tetrodotoxin (TTX) completely blocked the stimulation of sodium influx induced by 1 microM BTX. The IC50 values for STX and TTX closely matched the Ki values for inhibition of [3H]STX binding, suggesting that the sites labelled by [3H]STX are associated with a population of BTX-sensitive channels. BTX induced a dose-dependent stimulation of sodium influx in synaptoneurosomes (EC50 280 nM). The potency of BTX for stimulation of sodium influx was increased (EC50 24 nM) in the presence of 0.6 microgram/ml scorpion venom without any change in maximal influx. In contrast, specific binding of [3H]BTX-B to synaptoneurosomes was minimal in the absence of scorpion venom, but it was increased several fold in the presence of 60 micrograms/ml scorpion venom. With proparacaine isothiocyanate (PROPRIT), an irreversible local anesthetic, the inhibition of [3H]BTX-B binding by PROPRIT did not occur in parallel with an inhibition of sodium influx induced by BTX. Preincubation of synaptoneurosomes with 10 microM PROPRIT for 10 min resulted in approximately 70% inhibition of [3H]BTX-B binding in the presence of scorpion venom. Such preincubation did not alter BTX-induced sodium uptake in synaptoneurosomes. Preincubations of synaptoneurosomes with 100 microM PROPRIT for 10 min completely inhibited [3H]BTX-B binding, and under these conditions BTX-induced sodium influx was reduced only by 50%. The results indicate that virtual elimination of binding sites labeled by [3H]BTX-B in the presence of scorpion venom by PROPRIT has little effect on sodium influx induced by BTX.(ABSTRACT TRUNCATED AT 250 WORDS)

Pumiliotoxin B binds to a site on the voltage-dependent sodium channel that is allosterically coupled to other binding sites.

Pumiliotoxin B (PTX-B), an alkaloid that has cardiotonic and myotonic activity, increases sodium influx in guinea pig cerebral cortical synaptoneurosomes. In the presence of scorpion venom (Leiurus) or purified alpha-scorpion toxin, the PTX-B-induced sodium influx is enhanced severalfold. PTX-B alone has no effect on sodium flux in N18 neuroblastoma cells but, in the presence of alpha-scorpion toxin, stimulation of sodium influx by PTX-B reaches levels comparable to that attained with the sodium channel activator veratridine. In neuroblastoma LV9 cells, a variant mutant that lacks sodium channels, neither veratridine nor PTX-B induces sodium fluxes in either the presence or absence of alpha-scorpion toxin. In synaptoneurosomes and in N18 cells, the sodium influx induced by the combination of PTX-B and alpha-scorpion toxin is inhibited by tetrodotoxin and local anesthetics. PTX-B does not interact with two of the known toxin sites on the sodium channel, as evidenced by a lack of effect on binding of [3H]saxitoxin or [3H]batrachotoxinin A benzoate to brain synaptoneurosomes. Synergistic effects on sodium influx with alpha-scorpion toxin, beta-scorpion toxin, and brevetoxin indicate that PTX-B does not interact directly with three other toxin sites on the sodium channel. Thus, PTX-B appears to activate sodium influx by interacting with yet another site on the voltage-dependent sodium channel, a site that is coupled allosterically to sites for alpha-scorpion toxin, beta-scorpion toxin, and brevetoxin.

Stimulation of phosphoinositide breakdown in brain synaptoneurosomes by agents that activate sodium influx: antagonism by tetrodotoxin, saxitoxin, and cadmium.

Agents that increase intracellular concentrations of Na+ stimulate phosphoinositide breakdown in guinea pig cerebral cortical synaptoneurosomes. When combined, these agents did not have additive effects on phosphoinositide breakdown but did have additive or greater than additive effects with carbamylcholine. Scorpion venom (Leiurus quinquestriatus) and pumiliotoxin B, which induce small increases in influx of 22Na+ in synaptoneurosomes, stimulate phosphoinositide breakdown by about 6- and 3-fold, respectively; both effects are inhibited by tetrodotoxin (TTX). Batrachotoxin (BTX) and veratridine, which cause a large increase in influx of 22Na+ through activation of voltage-dependent sodium channels, induce a 5- to 6-fold dose-dependent increase in phosphoinositide breakdown, which appears competitively inhibited by 5 microM TTX. BTX- and veratridine-elicited influx of 22Na+ into synaptoneurosomes is virtually completely blocked by 5 microM TTX. Agents that block voltage-dependent calcium channels, such as D-600, nifedipine, and Co2+, do not inhibit either influx of 22Na+ or stimulation of phosphoinositide breakdown elicited by scorpion venom, pumiliotoxin B, or BTX. Cadmium ions (200 microM), which are known to block TTX-resistant sodium channels, block phosphoinositide breakdown induced by agents that activate sodium influx through sodium channels. Cadmium blocks BTX-induced phosphoinositide breakdown with an IC50 value of 48 microM, while blocking BTX-induced 22Na+ influx in synaptoneurosomes with a 13-fold lower potency (IC50, 610 microM). In the presence of 0.5 microM TTX, the IC50 for Cd2+ inhibition of BTX-induced 22Na+ influx is now 430 microM. Neither TTX nor Cd2+ antagonize neurotransmitter- or monensin-induced phosphoinositide breakdown. It appears that BTX-induced phosphoinositide breakdown in guinea pig synaptoneurosomes is dependent primarily on activation of TTX-resistant, Cd2+-sensitive sodium channels that account for only a small fraction of the total sodium influx induced by BTX in synaptoneurosomes. However, cadmium also may in some way inhibit phosphoinositide breakdown elicited by sodium channel agents at a point subsequent to sodium influx.

Cardiotonic activities of pumiliotoxin B, pyrethroids and a phorbol ester and their relationships with phosphatidylinositol turnover.

The cardiotonic activities of pumiliotoxins, pyrethroids and sodium and calcium channel activators were assessed in vitro with spontaneously beating guinea pig atria. The ability of these compounds to stimulate phosphoinositide turnover was assessed in guinea pig cerebral cortical synaptoneurosomes. The activity of pumiliotoxins for both cardiotonic activity and phosphoinositide breakdown was strongly dependent on the structure and configuration of the side chain and there was a correlation between structure and activity in the two systems. Pyrethroids that had cardiotonic activity also induced phosphoinositide breakdown. Other sodium channel and calcium channel activators that induced phosphoinositide breakdown were also cardiotonic. It is suggested that phosphoinositide breakdown leading to inositol phosphates and diacylglycerols may represent a mechanism underlying the cardiotonic effects of certain agents. A phorbol ester, phorbol 12-myristate 13-acetate, that mimics the activation of protein kinase C elicited by diacylglycerols, had cardiotonic activity.

Effects of ring fluorination on the adrenergic properties of phenylephrine.

The adrenergic properties of 2-, 4- and 6-fluorophenylephrine (2-FPE, 4-FPE, 6-FPE) were compared to those of phenylephrine (PE). The order of affinities of these compounds for alpha 1-adrenoceptors as determined by displacement of [3H]prazosin and [3H]WB-4101 binding to brain membranes was the same as the order of potencies for eliciting two alpha 1-adrenergic metabolic responses in guinea-pig cerebral cortical synaptoneurosomes, namely the stimulation of phosphatidylinositol turnover and the potentiation of 2-chloroadenosine-induced accumulation of cyclic AMP. In all cases the order was 6-FPE greater than PE greater than 4-FPE greater than 2-FPE. The order of affinities for alpha 2-adrenoceptors as determined by displacement of binding of [3H]clonidine to brain membrane was 6-FPE greater than PE greater than or equal to 4-FPE = 2-FPE. In contrast, the order of potencies for inhibition of forskolin-stimulated adenylate cyclase activity in human platelet membranes via an alpha 2-adrenoceptor was 6-FPE approximately equal to PE greater than 4-FPE much greater than 2-FPE. The FPEs and PE were partial agonists compared to epinephrine in human platelets. The affinities of these compounds for beta-adrenoceptors as determined by displacement of binding of [3H]dihydroalprenolol to brain membranes are 2-FPE greater than PE greater than or equal to 4-FPE much greater than 6-FPE. The FPEs and PE had positive chronotropic and inotropic effects in isolated guinea-pig atria apparently through the activation of a beta-adrenoceptor, since pindolol blocked the response while prazosin did not. 6-FPE appeared less active than the other PEs in atria. In fat cell membranes, 2-FPE was more potent than PE in stimulating adenylate cyclase via a beta-adrenoceptor, while 4-FPE and 6-FPE were inactive. Both, 2-FPE and PE were partial agonists in fat cells compared to isoproterenol. Of the three FPEs, 6-FPE represents a more potent and more selective agonist for alpha-adrenoceptors compared to beta-adrenoceptors than PE, while 4-FPE and, in particular, 2-FPE are less potent and selective as alpha-agonists.

The sodium channel in membranes of electroplax. Binding of batrachotoxinin-a [(3)H]benzoate to particulate preparations from electric eel (electrophorus).

Batrachotoxinin-A [(3)H]benzoate ([(3)H]BTX-B) binds specifically and with high affinity (K(D) 48 nM) to sites (B(max) 2.1 pmol/mg protein) associated with voltage-dependent sodium channels in rodent brain vesicular preparations. High affinity binding requires the presence of scorpion (Leiurus) venom and a membrane potential. Local anesthetics antagonize the binding. Nonspecific binding is defined in the presence of veratridine. In particulate preparations from electroplax of the eel Electrophorus electricus, [(3)H]BTX-B binds with a K(D) of about 140 nM and a B(max) of 2.5 pmol/mg protein in the presence of scorpion venom. Higher concentrations of scorpion venom are required to enhance binding in Electrophorus preparations than in brain preparations. Local anesthetics antagonize binding in Electrophorus preparations with potencies similar to those in brain preparations. Veratridine and batrachotoxin are less potent in blocking binding in Electrophorus than in brain preparations. It appears likely that binding in Electrophorus preparations is primarily to membrane fragments rather than vesicular entities as in brain. Binding of [(3)H]BTX-B to particulate preparations from electroplax of the ray Torpedo californica and the catfish Malapterurus electricus is mainly nonspecific. Scorpion venom does not enhance total binding and local anesthetics are not effective in antagonizing binding.

Biochemical characterization of a filtered synaptoneurosome preparation from guinea pig cerebral cortex: cyclic adenosine 3':5'-monophosphate-generating systems, receptors, and enzymes.

A particulate preparation was obtained by low speed centrifugation of guinea pig cerebral cortical homogenates prepared with a Krebs-Henseleit buffer. Light microscopic examination, using a reflected light differential interference contrast system, reveals the presence of intact neurons, axonal fragments, glial cells, and erythrocytes along with an abundance of small spherical entities (diameter about 1.1 micron) and snowman-shaped entities (diameter of larger sphere about 1.1 micron, diameter of attached smaller sphere about 0.6 micron). Many unattached smaller spherical entities are also present (diameter about 0.6 micron). Pressure filtration through 5- or 10-micron Millipore filters, followed by low speed centrifugation and resuspension, removes most of the larger entities to afford a suspension composed mainly of the small spherical and snowman-shaped entities. Electron microscopic examination reveals the presence of many synaptosomes with attached resealed postsynaptic entities. It is proposed that these correspond to the snowman-shaped entities to be termed synaptoneurosomes. Accumulations of cyclic AMP elicited by 2-chloroadenosine and histamine, and by combinations of 2-chloroadenosine, histamine, norepinephrine, and forskolin, are lower in filtered than in unfiltered preparations, whereas accumulations elicited by forskolin are unchanged. Levels of adenylate cyclase are reduced by filtration, whereas levels of phosphodiesterase are unchanged. Filtration reduces levels of markers for whole cells and endothelial cells, whereas neuronal markers such as acetylcholinesterase activity and norepinephrine uptake are increased. Levels of S-100 protein, a marker for glial cells, are not significantly decreased. There is no apparent change in the density of many receptors or ion channels. Levels of A1-adenosine and H1-histamine receptors are increased, whereas levels of so-called peripheral benzodiazepine-binding sites are decreased.

A new class of cardiotonic agents: structure-activity correlations for natural and synthetic analogues of the alkaloid A new class of A new class of cardiotonic agents: structure-activity correlations for natural and synthetic analogues of the alkaloid pumiliotoxin B (8-hydroxy-8-methyl-6-alkylidene-1-azabicyclo[4.3.0]nonanes).

Pumiliotoxin B (PTX-B, 6-(6',7'-dihydroxy-2',5'-dimethyl-(E)-4'-octenylidene)-8-hydroxy-8 -methyl-1- azabicyclo-[4.3.0] nonane) increases the force of contractures of spontaneously beating guinea pig atrial strips by 3- to 5-fold with half-maximal effects at about 3 microM and increases rates of atrial contractions by 2- to 3-fold with half-maximal effects at about 6 microM. The presence of an axial 7-hydroxy substituent (PTX 339A) decreases the efficacy but not the potency of PTX-B as a positive inotropic agent while having only slight effects on activity as a positive chronotropic agent. The presence of an equatorial 7-hydroxy substituent (PTX 339B) greatly decreases efficacy and potency of PTX-B as a positive chronotropic and inotropic agent. Pumiliotoxin A which lacks the side-chain 7'-hydroxy group of PTX-B causes only a 2-fold increase in force of contracture at 54 microM while having minimal effects on rate. The presence of an axial 7-hydroxy substituent (PTX 323B' and 323B", epimeric at the 6'-hydroxy) markedly enhances positive inotropic and chronotropic effects of PTX-A. Another congener, PTX 251D with a 6-(2'-methylhexylidene) side chain, and a synthetic analogue with a 6-(6'-heptenylidene) side chain are cardiac depressants. Both lack hydroxyl groups in the side chain. The presence of an omega-1 hydroxy group in the side chain of PTX 251D yields an alkaloid (267C) with weak positive inotropic effects and minimal chronotropic effects. The presence of an axial 7-hydroxy group in the indolizidine ring of PTX 251D results in a compound (PTX 267A) with very weak positive inotropic effects while retaining the negative chronotropic effects of PTX 251D. A synthetic analogue with a 6-(7'-hydroxyheptylidene) side chain is a cardiac depressant even though it contains a side-chain hydroxyl corresponding in position to the 7'-hydroxyl of the side chain of PTX-B. The positive chronotropic and inotropic effects of pumiliotoxin B are reversed only by relatively high concentrations of the calcium channel blockers nifedipine and verapamil, suggesting that pumiliotoxin B may owe its cardiotonic activities to effects on internal mobilization of calcium.

[3H]Batrachotoxinin A 20 alpha-benzoate binding to voltage-sensitive sodium channels: a rapid and quantitative assay for local anesthetic activity in a variety of drugs.

[3H]Batrachotoxinin A benzoate ( [3H]BTX-B) binds with high affinity to sites on voltage-dependent sodium channels in a vesicular preparation from guinea pig cerebral cortex. In this preparation, local anesthetics competitively antagonize the binding of [3H]BTX-B. The potencies of some 40 classical local anesthetics and a variety of catecholamine, histamine, serotonin, adenosine, GABA, glycine, acetylcholine, and calcium antagonists, tranquilizers, antidepressants, barbiturates, anticonvulsants, steroids, vasodilators, antiinflammatories, anticoagulants, analgesics, and other agents have been determined. An excellent correlation with the known local anesthetic activity of many of these agents indicate that antagonism of binding of [3H]BTX-B binding provides a rapid, quantitative, and facile method for the screening and investigation of local anesthetic activity.

Local anesthetic properties of opioids and phencyclidines: interaction with the voltage-dependent, batrachotoxin binding site in sodium channels.

[3H]Batrachotoxinin-A 20-alpha-benzoate ([3H]BTX-B) binds specifically and with high affinity (Kd = 30 nM) to a site on voltage-dependent Na+ channels. Compounds with local anesthetic activity inhibit the binding of [3H]BTX-B by a mutually exclusive, allosteric mechanism. The potential local anesthetic potency of a series of 23 opioids and phencyclidine-like compounds has been estimated by their inhibition of [3H]BTX-B binding to Na+ channels in a preparation of synaptoneurosomes from guinea pig cerebral cortex. The potency of these compounds were also tested as inhibitors of the specific binding of [3H]phencyclidine ([3H]PCP) to a high affinity site on rat brain membranes. Opioids such as morphine and codeine show little affinity for the [3H]BTX-B binding site or for the [3H]PCP binding site. Other analgesics, many of the PCP-like compounds and dioxadrol derivatives are potent versus [3H]BTX-B binding and display both stereospecificity and high affinity towards the PCP-binding site. However, there was no correlation between local anesthetic potency assessed as antagonism of [3H]BTX-B binding and affinity towards the PCP site. Five classical local anesthetics had no affinity for the PCP-site, but did displace [3H]BTX-B from its binding site.

Batrachotoxin-induced depolarization and [3H]batrachotoxinin-a 20 alpha-benzoate binding in a vesicular preparation from guinea pig cerebral cortex.

The sodium channel-specific agent batrachotoxin (BTX) has been shown to induce a time- and concentration-dependent depolarization of a vesicular preparation from guinea pig cerebral cortex. The K0.5 for depolarization by BTX was 0.011 microM at 30 min. Membrane potential was determined by the equilibrium distribution of [3H]triphenylmethylphosphonium ion. A series of seven local anesthetics was shown to inhibit BTX-induced depolarization competitively with Ki values ranging from 0.9 microM for dibucaine to 780 microM for lidocaine ethiodide. The specific binding of labeled batrachotoxinin-A 20 alpha-benzoate ([3H]BTX-B) to voltage-sensitive channels in vesicular preparations from mouse cerebral cortex in the presence of scorpion venom was measured and found to yield a range of Kd values from 25 to 30 nM and Bmax values of 0.5 and 1.0 pmole/mg of protein; the same preparation from guinea pig cerebral cortex was found to yield Kd values from 13 to 56 nM and Bmax values of 0.8-2.2 pmoles/mg of protein. A series of 14 local anesthetics was shown to inhibit the specific binding of [3H]BTX-B with Ki values ranging from 0.6 microM for dibucaine to 400 microM for benzocaine. The rank order of potency of the local anesthetics as antagonists of [3H]BTX-B binding was as follows: dibucaine greater than tetracaine greater than bupivacaine greater than diphenhydramine greater than piperocaine greater than cocaine greater than procaine greater than lidocaine greater than benzocaine. The quaternary local anesthetic dimethyl-di(phenylcarbamoylmethyl)ammonium chloride was comparable in potency to tetracaine. The rank order and relative potency of the local anesthetics tested in both paradigms were similar with the exception of lidocaine ethiodide, which was 18 times more potent as an inhibitor of binding of [3H]BTX-B than it was as an inhibitor of BTX-elicited depolarization.

Influence of fluorine substitution on the site of enzymatic O-methylation of fluorinated norepinephrines.

The extent of meta- and para-O-methylation by catechol O-methyltransferase of 2-fluoro-, 5-fluoro-, and 6-fluoronorepinephrine (FNE) at pH 7 and 9 was determined. The rank order of preference for para-O-methylation is 5FNE much greater than NE greater than 6FNE greater than 2FNE. In all cases, increasing the pH to 9 results in an increase in para-O-methylation. Results with 2F- and 5FNE demonstrate the importance of ionization in the methyltransferase reaction when fluorine is situated ortho to one of the phenolic groups. To establish unequivocally the identities of the products, the isomeric, monofluorinated vanillins and isovanillins were synthesized and directly related to the products formed enzymatically from the monofluorinated norepinephrines.

Membrane potentials in cell-free preparations from guinea pig cerebral cortex: effect of depolarizing agents and cyclic nucleotides.

The distribution of [3H]triphenylmethylphosphonium ion between the medium and vesicular entities was examined in a cell-free, particulate preparation from guinea pig cerebral cortex. This distribution followed the Nernst relationship with regard to the external potassium ion concentration and, in physiological media, indicated the maintenance of a mean trans-membrane potential ranging from -58 to -78 mV. The neurotoxins batrachotoxin, veratridine, and grayanotoxin I, partially depolarized the preparation. Tetrodotoxin blocked the depolarization by batrachotoxin, veratridine, and gray-anotoxin I. The depolarization by these neurotoxins was potentiated by the presence of anemone toxin II and presumably reflected the response of vesicular components of neuronal origin. An additional potassium-sensitive depolarization probably represented the response of vesicular components of glial origin with an apparent transmembrane potential of -8 to -35 mV. No correlation could be demonstrated between changes in transmembrane potential and stimulation of cyclic AMP generation by a variety of agents in this preparation.

Cyclic AMP-generating systems in cell-free preparations from guinea pig cerebral cortex: loss of adenosine and amine responsiveness due to low levels of endogenous adenosine.

The accumulations of radioactive cyclic AMP elicited by adenosine, norepinephrine, and histamine in adenine-labeled vesicular entities of a particulate fraction from guinea pig cerebral cortex are greatly reduced as a result of prolonged preincubation. The presence of adenosine deaminase during preincubations largely prevents the loss of adenosine, norepinephrine and histamine responses. Adenosine deaminase was inactivated by deoxycoformycin prior to stimulation of cyclic AMP accumulation by adenosine or amines. If adenosine deaminase is not inactivated, responses to norepinephrine are not significant and histamine responses are reduced by 50%. Adenosine deaminase cannot restore responsiveness of the cyclic AMP-generating systems. It is proposed that, in particulate fractions of guinea pig cerebral cortex, low levels of adenosine cause a slow loss of receptors and/or coupling of receptors to cyclic AMP-generating systems.