Saxitoxin binding to sodium channels in head extracts from wild-type and tetrodotoxin-sensitive strains of Drosophila melanogaster

Extracts prepared from heads of Drosophila melanogaster show high-affinity binding ($\text{K}{}_{\mathrm{<mtext>D</mtext>}}\text{= 1.9}\text{nM}$) of [³H]saxitoxin, a compound known to bind to and block voltage-sensitive sodium channels in other organisms. The interaction between saxitoxin and the Drosophila saxitoxin receptor is non-cooperative and reversible with a half-life of 18.3 s for binding at 4°C. The saturable binding is specifically inhibited by tetrodotoxin with a $\text{K}{}_{\mathrm{<mtext>I</mtext>}}\text{= 0.30}\text{nM}$. The number of saturable binding sites in the extract is 97 fmol/mg protein. Since approx. 50% of the binding activity is recovered in the extract, the number of binding sites in the head is estimated to be 6.4 fmol/mg head. Nerve conduction in Drosophila larvae is completely blocked after 20 min in a bathing solution containing 200 nM tetrodotoxin. A comparison between the binding and the electrophysiological studies in Drosophila and other organisms suggests that the Drosophila saxitoxin receptor is part of the voltage-sensitive sodium channel involved in the propagation of action potentials. A mutant (ttx^s), which is abnormally sensitive to dietary tetrodotoxin, is shown to be indistinguishable from wild type with respect to [³H]saxitoxin-binding properties and physiological sensitivity to tetrodotoxin. These studies provide techniques which can be used to identify mutants with defects in the saxitoxin-binding component of the sodium channel.     

Specific inhibition of [3H] saxitoxin binding to skeletal muscle sodium channels by geographutoxin II, a polypeptide channel blocker

Geographutoxin II (GTX II), a peptide toxin isolated from Conus geographus, inhibited [3H]saxitoxin binding to receptor sites associated with voltage-sensitive Na channels in rat skeletal muscle homogenates and rabbit T-tubular membranes with K0.5 values of 60 nM for homogenates and 35 nM for T-tubular membranes in close agreement with concentrations that block muscle contraction. Scatchard analysis of [3H]saxitoxin binding to T-tubular membranes gave values of KD = 9.3 nM and Bmax = 300 fmol/mg of protein and revealed a primarily competitive mode of inhibition of saxitoxin binding by GTX II. The calculated KD values for GTX II were 24 nM for T-tubules and 35 nM for homogenates, respectively. In rat brain synaptosomes, GTX II caused a similar inhibitory effect on [3H]saxitoxin binding at substantially higher concentrations (K0.5 = 2 microM). In contrast, binding of [3H]batrachotoxin A 20-alpha-benzoate and 125I-labeled scorpion toxin to receptor sites associated with Na channels in synaptosomes was not affected by GTX II at concentrations up to 10 microM. Furthermore, [3H]saxitoxin binding to membranes of rat superior cervical ganglion was only blocked 10% by GTX II at 10 microM. These results indicate that GTX II interacts competitively with saxitoxin in binding at neurotoxin receptor site 1 on the sodium channel in a highly tissue-specific manner. GTX II is the first polypeptide ligand for this receptor site and the first to discriminate between this site on nerve and adult muscle sodium channels.     

Biphasic regulation of development of the high-affinity saxitoxin receptor by innervation in rat skeletal muscle

Specific binding of 3H-saxitoxin (STX) was used to quantitate the density of voltage-sensitive sodium channels in developing rat skeletal muscle. In adult triceps surae, a single class of sites with a KD = 2.9 nM and a density of 21 fmol/mg wet wt was detected. The density of these high-affinity sites increased from 2.0 fmol/mg wet wt to the adult value in linear fashion during days 2-25 after birth. Denervation of the triceps surae at day 11 or 17 reduced final saxitoxin receptor site density to 10.4 or 9.2 fmol/mg wet wt, respectively, without changing KD. Denervation of the triceps surae at day 5 did not alter the subsequent development of saxitoxin receptor sites during days 5-9 and accelerated the increase of saxitoxin receptor sites during days 9-13. After day 13, saxitoxin receptor development abruptly ceased and the density of saxitoxin receptor sites declined to 11 fmol/wg wet wt. These results show that the regulation of high-affinity saxitoxin receptor site density by innervation is biphasic. During the first phase, which is independent of continuing innervation, the saxitoxin receptor density increases to 47-57% of the adult level. After day 11, the second phase of development, which is dependent on continuing innervation, gives rise to the adult density of saxitoxin receptors.     

Binding of [3H]batrachotoxinin A-20-alpha-benzoate to a high affinity site associated with house fly head membranes

1. [3H]Batrachotoxinin A-20-alpha-benzoate (BTX-B), a radioligand that labels the alkaloid activator recognition site of the voltage-sensitive sodium channel, was bound specifically to high affinity, saturable sites in a subcellular preparation from house fly (Musca domestica L.) heads that was shown previously to contain binding sites for other sodium channel-directed ligands. 2. Specific binding of [3H]BTX-B was observed in the presence of 140 mM sodium or potassium and was inhibited by choline ion. 3. Saturating concentrations of scorpion (Leiurus quinquestriatus) venom stimulated the specific binding of [3H]BTX-B four-fold, increasing the proportion of specific binding of 10 nM [3H]BTX-B from less than 15% to 40%. Equilibrium dissociation studies in the presence of scorpion venom gave an equilibrium dissociation constant (KD) for [3H]BTX-B of 80 nM and a maximal binding capacity (Bmax) of 1.5 pmol/mg protein. 4. Parallel experiments in the absence of venom gave a KD value of 140 nM and a Bmax of 1.3 pmol/mg protein, indicating that scorpion venom stimulated [3H]BTX-B binding by increasing the affinity of this site approximately two-fold. 5. The specific binding of [3H]BTX-B was inhibited by the sodium channel activators aconitine and batrachotoxin and, to a lesser extent, by the anticonvulsant diphenylhydantoin. However, several other sodium channel-directed neurotoxins known to exert allosteric effects on the binding of [3H]BTX-B to mammalian brain preparations did not affect the binding of [3H]BTX-B to house fly head membranes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification and affinity labeling of very high affinity binding sites for the phenylalkylamine series of Ca+ channel blockers in the Drosophila nervous system

The interaction of putative Ca2+ channels of Drosophila head membranes with molecules of the phenylalkylamine series was studied from binding experiments using (-)-[3H]D888 and (+/-)-[3H]verapamil. These ligands recognize a single class (Kd = 0.1-0.4 nM; Bmax = 1600-1800 fmol/mg of protein) of very high affinity binding sites. The most potent molecule in the phenylalkylamine series was (-)-verapamil with a Kd value as exceptionally low as 4.7 pM. Molecules in the benzothiazepine and diphenylbutylpiperidine series of Ca2+ channel blockers as well as bepridil inhibited (-)-[3H]D888 binding in a competitive way with Kd values between 12 and 190 nM, suggesting a close correlation, as in the mammalian system, between these receptor sites and those recognizing phenylalkylamines. A tritiated (arylazido)phenylalkylamine with high affinity for the Drosophila head membranes, phenylalkylamine receptor Kd = 0.24 nM), was used in photoaffinity experiments. A protein of Mr 135,000 +/- 5,000 was specifically labeled after ultraviolet irradiation.     

Purification and functional reconstitution of the voltage-sensitive sodium channel from rabbit T-tubular membranes

The voltage-sensitive sodium channel has been purified from rabbit T-tubular membranes and reconstituted into defined phospholipid vesicles. Membranes enriched in T-tubular elements (specific [3H]nitrendipine binding = 41 +/- 9 pmol/mg of protein, n = 7) were isolated from fast skeletal muscle. After solubilization with Nonidet P-40, the sodium channel protein was purified to greater than 95% of theoretical homogeneity based on the specific activity of [3H]saxitoxin binding. Two subunits of Mr approximately 260,000 and 38,000 were found; these bands co-distributed with the peak of [3H]saxitoxin binding on sucrose gradients. The purified protein was reconstituted into egg phosphatidylcholine vesicles and retained the ability to gate specific 22Na+ influx in response to activation by batrachotoxin or veratridine. All activated fluxes were blocked by saxitoxin and tetrodotoxin. On sucrose gradients, the distribution of protein capable of functional channel activity paralleled the distribution of specific [3H]saxitoxin binding and of the Mr 260,000 and 38,000 components. The cation selectivity for the reconstituted, batrachotoxin-activated channel was Na+ greater than K+ greater than Rb+ greater than Cs+, with flux ratios of 1:0.13:0.02:0.008. Nine of 25 monoclonal antibodies raised against the rat sarcolemmal sodium channel cross-reacted with the rabbit T-tubular sodium channel in a solid-phase radioimmunoassay. Six of these antibodies showed specific binding to immunoblot transfers of T-tubular membrane proteins. Each labeled a single band at Mr approximately 260,000 corresponding in mobility to the large subunit of the sodium channel.     

Reconstitution of neurotoxin-stimulated sodium transport by the voltage-sensitive sodium channel purified from rat brain

Incorporation of the saxitoxin receptor of the sodium channel solubilized with Triton X-100 and purified 250-fold from rat brain into phosphatidylcholine vesicles is described. Fifty to 80% of the saxitoxin receptor sites are recovered in the reconstituted vesicles (KD = 3 nM). Unlike the detergent-solubilized saxitoxin receptor, the reconstituted saxitoxin binding activity is stable to incubation at 36 degrees C. Approximately 75% of the reconstituted saxitoxin receptor sites are externally oriented and 25% are inside-out. The initial rate of 22Na+ uptake into reconstituted vesicles is increased up to 3- to 4-fold by veratridine with a K0.5 of 11 microM. Seventy per cent of this increase is blocked by external tetrodotoxin (TTX) with a Ki of 10 nM. All of the veratridine-stimulated 22Na+ uptake is blocked when TTX is present on both sides of the vesicle membrane, or when tetracaine is added to the external medium. The apparent binding constants for veratridine, saxitoxin, and TTX are essentially identical to those in intact rat brain synaptosomes. The results demonstrate reconstitution of sodium transport, as well as neurotoxin binding and action, from substantially purified sodium channel preparations.     

Modulation of A2A adenosine receptor(s) by K+(ATP) channels in bovine brain striatal membranes

The modulation of adenosine receptor with K+(ATP) channel blocker, glibenclamide, was investigated using the radiolabeled A2A-receptor selective agonist [3H]CGS 21680. Radioligand binding studies in bovine brain striatal membranes (BBM) indicated that unlabeled CGS 21680 displaced the bound [3H]CGS 21680 in a concentration-dependent manner with a maximum displacement being approximately 65% at 10(-4) M. In the presence of 10(-5) M glibenclamide, unlabeled CGS 21680 increased the displacement of bound [3H]CGS 21860 by approximately 28% at 10(-4) M. [3H]CGS 21680 bound to BBM in a saturable manner to a single binding site (Kd = 10.6+/-1.71 nM; Bmax = 221.4+/-6.43 fmol/mg of protein). In contrast, [3H]CGS 21680 showed saturable binding to two sites in the presence of 10(-5) M glibenclamide; (Kd = 1.3+/-0.22 nM; Bmax = 74.3+/-2.14 fmol/mg protein; and Kd = 8.9+/-0.64 nM; Bmax = 243.2+/-5.71 fmol/mg protein), indicating modulation of adenosine A2A receptors by glibenclamide. These studies suggest that the K+(ATP) channel blocker, glibenclamide, modulated the adenosine A2A receptor in such a manner that [3H]CGS 21680 alone recognizes a single affinity adenosine receptor, but that the interactions between K+(ATP) channels and adenosine receptors.     

Reconstitution of the voltage-sensitive sodium channel of rat brain from solubilized components

The voltage-sensitive sodium channel of rat brain synaptosomes was solubilized with sodium cholate. The solubilized sodium channel migrated on a sucrose density gradient with an apparent S20,w of approximately 12 S, retained [3H]saxitoxin ([3H]STX) binding activity that was labile at 36 degrees C but no longer bound 125I-labeled scorpion toxin (125I-ScTX). Following reconstitution into phosphatidylcholine vesicles, the channel regained 125I-ScTX binding and thermal stability of [3H]STX binding. Approximately 50% of the [3H]STX binding activity and 58% of 125I-ScTX binding activity were recovered after reconstitution. The reconstituted sodium channel bound STX and ScTX with KD values of 5 and 10 nM, respectively. Under depolarized conditions, veratridine enhanced the binding of 125I-ScTX with a K0.5 of 20 microM. These KD and K0.5 values are similar to those of the native synaptosome sodium channel. 125I-ScTX binding to the reconstituted sodium channel, as with the native channel, was voltage dependent. The KD for 125I-ScTX increased with depolarization. This voltage dependence was used to demonstrate that the reconstituted channel transports Na+. Activation of sodium channels by veratridine under conditions expected to cause hyperpolarization of the reconstituted vesicles increased 125I-ScTX binding 3-fold. This increased binding was blocked by STX with K0.5 = 5 nM. These data indicate that reconstituted sodium channels can transport Na+ and hyperpolarize the reconstituted vesicles. Thus, incorporation of solubilized synaptosomal sodium channels into phosphatidylcholine vesicles results in recovery of toxin binding and action at each of the three neurotoxin receptor sites and restoration of Na+ transport by the reconstituted channels.     

Development of Sodium Channel Protein During Chemically Induced Differentiation of Neuroblastoma Cells

We have previously shown that the [3H]saxitoxin binding site of the sodium channel is expressed independently of the [125I]scorpion toxin binding site in chick muscle cultures and in rat brain. In the present work, we studied the development of the sodium channel protein during chemically induced differentiation of N1E-115 neuroblastoma cells, using [3H]saxitoxin binding, [125I]scorpion toxin binding, and 22Na uptake techniques. When grown in their normal culture medium, these cells are mostly undifferentiated, bind 90 +/- 10 fmol of [3H]saxitoxin/mg of protein and 112 +/- 14 fmol of [125I]scorpion toxin/mg protein, and, when stimulated with scorpion toxin and batrachotoxin, take up 70 +/- 5 nmol of 22Na/min/mg of protein. Cells treated with dimethyl sulfoxide (DMSO) or hexamethylene-bis-acetamide (HMBA) differentiate morphologically within 3 days. At this time, the [3H]saxitoxin binding, the [125I]scorpion toxin binding, and the 22Na uptake values are not very different from those of undifferentiated cells. With subsequent time in DMSO or HMBA, these values continue to increase, a result indicating that the main period of sodium channel expression occurs well after the cells have assumed the morphologically differentiated state. The data indicate that the expression of sodium channels and morphological differentiation are independently regulated neuronal properties, that the attainment of morphological differentiation is necessary but not in itself sufficient for full expression of the sodium channel proteins, and that, in contrast to the chick muscle cultures and rat brain, the [3H]saxitoxin site and [125I]scorpion toxin site appear to be coregulated in N1E-115 cells.     

Binding of [3H]batrachotoxinin A-20-α-benzoate to a high affinity site associated with house fly head membranes

1. [³H]Batrachotoxinin A-20-α-benzoate (BTX-B), a radioligand that labels the alkaloid activator recognition site of the voltage-sensitive sodium channel, was bound specifically to high affinity, saturable sites in a subcellular preparation from house fly (Musca domestica L.) heads that was shown previously to contain binding sites for other sodium channel-directed ligands.2. Specific binding of [³H]BTX-B was observed in the presence of 140 mM sodium or potassium and was inhibited by choline ion.3. Saturating concentrations of scorpion (Leiurus quinquestriatus) venom stimulated the specific binding of [³H]BTX-B four-fold, increasing the proportion of specific binding of 10 nM [³H]BTX-B from less than 15% to 40%. Equilibrium dissociation studies in the presence of scorpion venom gave an equilibrium dissociation constant (K_D) for [³H]BTX-B of 80 nM and a maximal binding capacity (B_max) of 1.5 pmol/mg protein.4. Parallel experiments in the absence of venom gave a K_D value of 140 nM and a B_max of 1.3 pmol/mg protein, indicating that scorpion venom stimulated [³H]BTX-B binding by increasing the affinity of this site approximately two-fold.5. The specific binding of [³H]BTX-B was inhibited by the sodium channel activators aconitine and batrachotoxin and, to a lesser extent, by the anticonvulsant diphenylhydantoin. However, several other sodium channel-directed neurotoxins known to exert allosteric effects on the binding of [³H]BTX-B to mammalian brain preparations did not affect the binding of [³H]BTX-B to house fly head membranes.6. These studies provide evidence for a high affinity binding site in house fly head membrane preparations that exhibits properties expected of the activator recognition site of the voltage-sensitive sodium channel but does not respond to several compounds known to modify allosterically the binding of [³H]BTX-B to sodium channels in mammalian brain.     

Equilibrium binding characteristics of [3H]thiomuscimol.

The equilibrium binding characteristics of the tritiated GABAA agonist, 5-aminomethyl-3-isothiazolol (thiomuscimol) are described. Using the filtration technique to separate bound- from free-ligand, [3H]thiomuscimol was shown to bind to the GABA(A) receptor site(s) in a saturable manner with a Kd value of 28+/-6.0 nM and a Bmax value of 50+/-4.0 fmol/mg original tissue. In parallel binding experiments, the Kd and Bmax values for [3H]muscimol were determined to be 5.4+/-2.8 nM and 82+/-11 fmol/mg original tissue, respectively. In binding assays using the centrifugation technique, Kd and Bmax values for [3H]thiomuscimol were found to be 116+/-22 nM and 154 13 fmol/mg original tissue, respectively, whereas a Kd value of 16+/-1.8 nM and a Bmax value of 155+/-8.0 fmol/mg original tissue were determined for [3H]muscimol. In comparative inhibition studies using the GABA(A) antagonist SR 95531 and a series of specific GABAA agonists, the binding sites for [3H]thiomuscimol and [3H]muscimol were shown to exhibit similar pharmacological profiles. Autoradiographic studies disclosed similar regional distribution of [3H]thiomuscimol and [3H]muscimol binding sites in rat brain. Highest densities of binding sites were detected in cortex, hippocampus, and cerebellum, whereas low densities were measured in the midbrain structures of rat cortex. In conclusion, the equilibrium GABA(A) receptor binding characteristics of [3H]thiomuscimol are very similar to those of [3H]muscimol.     

Solubilization of an Adenosine Uptake Site in Brain

Procedures are described for the solubilization of adenosine uptake sites in guinea pig and rat brain tissue. Using [3H]nitrobenzylthioinosine [( 3H]NBI) the solubilized site is characterized both kinetically and pharmacologically. The binding is dependent on protein concentration and is saturable, reversible, specific, and high affinity in nature. The KD and Bmax of guinea pig extracts are 0.13 +/- 0.02 nM and 133 +/- 18 fmol/mg protein, respectively, with linear Scatchard plots obtained routinely. Similar kinetic parameters are observed in rat brain. Adenosine uptake inhibitors are the most potent inhibitors of [3H]NBI binding with the following order of potency, dilazep greater than hexobendine greater than dipyridamole. Adenosine receptor ligands are much less potent inhibitors of binding, and caffeine is without effect. The solubilized adenosine uptake site is, therefore, shown to have virtually identical properties to the native membrane site. The binding of the adenosine A1 receptor agonist [3H]cyclohexyladenosine [( 3H]CHA) to the solubilized brain extract was also studied and compared with that of [3H]NBI. In contrast to the [3H]NBI binding site [3H]CHA binds to two apparent populations of adenosine receptor, a high-affinity site with a KD of 0.32 +/- 0.06 nM and a Bmax of 105 +/- 30 fmol/mg protein and a lower-affinity site with a KD of 5.50 +/- 0.52 nM and Bmax of 300 +/- 55 fmol/mg protein. The pharmacology of the [3H]CHA binding site is consistent with that of the adenosine receptor and quite distinct from that of the uptake [( 3H]NBI binding) site. Therefore, we show that the adenosine uptake site can be solubilized and that it retains both its binding and pharmacologic properties in the solubilized state.     

Constitution and properties of axonal membranes of crustacean nerves.

The purification of axonal membranes of crustaceans was followed by measuring enrichment in [3H]tetrodotoxin binding capacity and in Na+, K+-ATPase activity. A characteristic of these membranes is their high content of lipids and their low content of protein as compared to other types of plasmatic membranes. The axonal membrane contains myosin-like, actin-like, tropomyosin-like, and tubulin-like proteins. It also contains Na+, K+-ATPase and acetylcholinesterase. The molecular weights of these two enzymes after solubilization are 280,000 and 270,000, respectively. The molecular weights of the catalytic subunits are 96,000 for ATPase and 71,000 for acetylcholinesterase. We confirmed the presence of a nicotine binding component in the axonal membrane of the lobster but we have been unable to find [3H]nicotine binding to crab axonal membranes. The binding to axonal membranes og of the sodium channel, has been studied in detail. The dissociation constant for the binding of [3H]tetrodotoxin to the axonal membrane receptor is 2.9 nM at pH 7.4. The concentration of the tetrodotoxin receptor in crustacean membranes is about 10 pmol/mg of membrane protein, 7 times less than the acetylcholinesterase, 30 times less than the Na+, K+-ATPase, and 30 times less than the nicotine binding component in the lobster membrane. A reasonable estimate indicates that approximately only one peptide chain in 1000 constitutes the tetrodotoxin binding part of the sodium channel in the axonal membrane. Veratridine, which acts selectively on the resting sodium permeability, binds to the phospholipid part of the axonal membrane. [3H]Veratridine binding to membranes parallels the electrophysiological effect. Veratridine and tetrodotoxin have different receptor sites. Although tetrodotoxin can repolarize the excitable membrane of a giant axon depolarized by veratridine, veratridine does not affect the binding of [3H]tetrodotoxin to purified axonal membranes. Similarly, tetrodotoxin does not affect the binding of [3H]veratridine to axonal membranes. Scorpion neurotoxin I, a presynaptic toxin which affects both the Na+ and the K+ channels, does not interfere with the binding of [3H]tetrodotoxin or [3H]veratridine to axonal membranes. Tetrodotoxin, veratridine, and scorpion neurotoxin I, which have in common the perturbation of the normal functioning of the sodium channel, act upon three different types of receptor sites.     

Evidence for an androgen receptor in the seminiferous tubules of the human testis

Androgen receptors (AR) were studied in seminiferous tubule cytosol and testicular nuclear extracts prepared from testes of previously untreated elderly men undergoing orchiectomy as therapy for prostatic carcinoma. Cytosol exhibited high affinity (Kd = 0.8 nM), saturable binding of [3H]methyltrienolone; however, the synthetic progestin, promegestone was a stronger competitor for MT binding sites than were 5 alpha-dihydrotestosterone (DHT) or testosterone (T), suggesting the presence of progesterone-like binding sites. Addition of triamcinolone acetonide (TA) produced the usual relative steroid specificity for AR binding and reduced the measured AR binding capacity by 19 +/- 8% (Mean +/- SD, n = 3). The umber of MT binding sites was 30-40 fmol/mg protein, or an average of 65 fmol/g testis, and the equilibrium dissociation constant at 0 degrees C was 0.6-1.4 nM. In the presence of sodium molybdate, binding was stable for 40 h at 0 degrees C and the half-time of dissociation of the MT-AR complex was 12-16 h. The binding of salt extractable (600 mM KCl) nuclear sites to MT was saturable and was specific for androgens. The number of binding sites in nuclear extracts was 170 fmol/g testis and the apparent equilibrium dissociation constant was 4.2 nM. Thus, the binding of MT to human seminiferous tubule cytosol and testicular nuclear extract exhibits properties which are nearly identical to those of the prostate AR. Further study of this androphilic protein may provide insight into the role of androgen in normal and abnormal spermatogenesis in man.     

Solubilization of Calcium Channel Antagonist Binding Sites from Rat Brain

Calcium antagonist binding sites were solubilized from rat brain membranes using the detergent 3-[(3-cholamidopropyl)dimethylammonio] 1-propanesulfonate (CHAPS). CHAPS-solubilized [3H]nitrendipine binding sites are saturable over a range of 0.05-4 nM and Scatchard analysis reveals a single, high-affinity (KD = 0.49 +/- 0.10 nM), low-capacity (Bmax = 56 +/- 4 fmol/mg of protein) binding site. Reversible ligand competition experiments using solubilized binding sites demonstrated appropriate pharmacologic specificity, with dihydropyridines (nifedipine = nitrendipine greater than Bay K 8644) completely displacing binding, verapamil partially displacing binding, and diltiazem enhancing binding, as previously described in membrane preparations. Lyophilized Crotalus atrox venom was purified by ion exchange chromatography followed by gel filtration to a single peptide band on sodium dodecyl sulfatepolyacrylamide gel electrophoresis. This fraction of molecular weight 60,000 competitively inhibits [3H]nitrendipine binding to both membrane and soluble preparations with an IC50 of 5 micrograms/ml. This polypeptide should serve as a useful ligand for future efforts in purifying the dihydropyridine calcium channel binding site in brain.     

Studies on the properties of muscarinic cholinergic receptor sites in bovine pineal gland

1. Using the tritiated muscarinic receptor antagonist, quinuclidinyl benzilate ([3H]QNB) as a ligand, muscarinic cholinergic receptors have been identified and characterized in the pineal glands of cow and swamp buffalo. 2. At 25 degrees C, the specific binding reached equilibrium within 60 min and remained constant for an additional two hours. Furthermore, the specific binding was saturable, reversible and tissue dependent in nature. 3. The kinetic analyses of muscarinic cholinergic receptor sites revealed KD values of 0.423 +/- 0.01 nM and 0.218 +/- 0.01 nM, and Bmax values of 69.75 +/- 20.91 fmol/mg protein and 74.19 +/- 32.73 fmol/mg protein for the cow's- and the swamp buffalo's pineal glands, respectively. 4. The presence of muscarinic cholinergic receptor sites originating from cholinergic innervation of the pineal gland is suggested.     

Binding of [3H]batrachotoxinin A-20-α-benzoate and [3h]saxitoxin to receptor sites associated with sodium channels in trout brain synaptoneurosomes

1. [³H]Batrachotoxinin A-20-α-benzoate ([³H]BTX-b) and [³H]saxitoxin ([³H]STX), radioligands that bind to distinct sites on the voltage-sensitive sodium channel, were bound specifically to saturable sites in rainbow trout (Oncorhynchus mykiss) brain synaptoneurosomes.2. Specific [³H]BTX-B binding was temperature dependent with highest levels of specific [³H]BTX-B binding observed at 7°C. Specific binding was inversely correlated with assay temperature at temperatures above 7°C.3. Saturating concentrations of scorpion (Leiurus quinquestriatus) venom (ScV) stimulated specific [³H]BTX-B binding at 27°C, but not at 7°C. The dihydropyrazole insecticide RH 3421 inhibited specific [³H]BTX-B binding at 7°C but had no effect on specific binding at 27°C. The sodium channel activators veratridine and aconitine and the local anesthetic dibucaine inhibited specific [³H]BTX-B binding at both 7°C and 27°C.4. Displacement experiments in the presence of ScV at 27°C gave an equilibrium dissociation constant (K_d) for [³H]BTX-B of 710 nM and a maximal binding capacity (B_max) of 11.3 pmol/mg protein. Kinetic experiments established the rates of association (1.17 × 10⁵min⁻¹ nM⁻¹) and dissociation (0.0514min⁻¹) of the ligand-receptor complex.5. The binding of [³H]STX reached apparent saturation at 7.5 nM. Scatchard analysis of the saturation data indicated a K_d of 3.8nM and a B_max of 1.9 pmol/mg protein.6. These studies provide evidence for high affinity, saturable binding sites for [³H]BTX-B and [³H]STX in trout brain preparations. Whereas certain neurotoxins modified the specific binding of [³H]BTX-B in trout brain synaptoneurosomes in a predictable fashion, other compounds known to affect specific [³H]BTX-B binding in mammalian brain preparations had no effect on specific [³H]BTX-B binding in the trout.     

Purification and characterization of neurotensin receptor from rat brain with special reference to comparison between newborn and adult age rats.

Scatchard analysis of saturation curves was performed to compared newborn and adult rat neurotensin receptor using [3H] neurotensin as a tracer. The membrane fraction of newborn rat cerebral cortex has a single population of neurotensin receptor (Kd = 0.13 nM, Bmax = 710 fmol/mg protein), whereas adults have two distinct neurotensin binding sites (high affinity site, Kd1 = 0.13 nM; low affinity site, Kd2 = 20 nM). High affinity neurotensin receptor, solubilized with digitonin, was purified from newborn rat cortex by affinity chromatography. An overall purification of 14,000-fold was achieved. The binding of [3H] neurotensin to the purified receptor is saturable and specific, with a Kd of 0.45 nM. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in the presence of 2-mercaptoethanol revealed purified material of a single major band of Mr = 55,000.     

[3H]Dipyridamole Binding to Guinea Pig Brain Membranes: Possible Heterogeneity of Central Adenosine Uptake Sites

The binding of [3H]dipyridamole ([3H]DPR) to guinea pig brain membranes is described and compared to that of [3H]nitrobenzylthioinosine ([3H]NBI). The binding of [3H]DPR is saturable, reversible, and specific with pharmacologic evidence indicating that this ligand is binding to the adenosine uptake site. Compared to [3H]NBI the binding of [3H]DPR is of higher capacity (Bmax = 208 +/- 16 fmol/mg protein for [3H]NBI and 530 +/- 40 fmol/mg protein for [3H]DPR) and lower affinity (KD = 0.35 +/- 0.02 nM for [3H]NBI and 7.6 +/- 0.7 nM for [3H]DPR). The adenosine uptake inhibitors are the most potent inhibitors of binding (Ki of 10(-8)-10(-7) M) whereas adenosine receptor ligands such as cyclohexyladenosine, 2-chloroadenosine, and various methylxanthines are several orders of magnitude less potent (Ki 10(-5)-10(-2). The inhibition of [3H]DPR binding by NBI is biphasic, with only 40% of binding being susceptible to inhibition of NBI concentrations less than 10(-5) M. The tissue distribution of [3H]DPR binding parallels that of [3H]NBI although in most cases significantly more sites are observed with [3H]DPR. Calcium channel blocking agents such as nifedipine, nimodipine, and verapamil are also inhibitors of [3H]DPR binding with potencies in the micromolar range. The data are consistent with [3H]DPR being a useful additional ligand for the adenosine uptake site and provide evidence that multiple uptake binding sites exist of which only about 40% are NBI-sensitive.