Time-dependent Inhibition of G Protein-coupled Receptor Signaling by Local Anesthetics

Background: Several beneficial effects of local anesthetics (LAs) were shown to be due to inhibition of G protein-coupled receptor signaling. Differences in exposure time might explain discrepancies in concentrations of LAs required to achieve these protective effects in vivo and in vitro (approximately 100-fold higher). Using Xenopus oocytes and human neutrophils, the authors studied time-dependent effects of LAs on G protein-coupled receptor signaling and characterized possible mechanisms and sites of action.

Methods: Measurement of agonist-induced Ca2+-activated Cl- currents, using a two-electrode voltage clamp technique, and determination of superoxide anion production by cytochrome c assay were used to assess the effects of LAs on G protein-coupled receptor signaling in oocytes and primed and activated human neutrophils, respectively. Antisense knockdown of G[alpha]q protein and inhibition of various proteins within the signaling pathway served for defining mechanisms and sites of action more specifically.

Results: LAs attenuated G protein-coupled receptor signaling in both models in a time-dependent and reversible manner (lidocaine reduced lysophosphatidic acid signaling to 19 +/- 3% after 48 h and 25 +/- 2% after 6 h of control response in oocytes and human neutrophils, respectively). Whereas no effect was observed after extracellularly applied or intracellularly injected QX314, a lidocaine analog, using G[alpha]q-depleted oocytes, time-dependent inhibition also occurred after intracellular injection of QX314 into undepleted oocytes. Inhibition of phosphatases or protein kinases and agonist-independent G-protein stimulation, using guanosine 5'-O-3-thiotriphosphate or aluminum fluoride, did not affect time-dependent inhibition by LAs.     

Lidocaine Enhances Gαi Protein Function

Background: Local anesthetics inhibit several G protein-coupled receptors by interaction with the G[alpha]q protein subunit. It is not known whether this effect on G protein function can be extrapolated to other classes of G proteins. The authors investigated interactions of lidocaine with the human adenosine 1 receptor (hA1R)-coupled signaling pathway. Activated A1Rs couple to adenylate cyclase via the pertussis toxin sensitive G[alpha]i protein, thereby decreasing cyclic adenosine monophosphate formation. A1Rs are widely expressed and abundant in the spinal cord, brain, and heart. Interactions of LAs with the hA1R-coupled transduction cascade therefore might produce a broad range of clinically relevant effects.

Methods: The function of hA1Rs stably expressed in Chinese hamster ovary cells was determined with assays of cyclic adenosine monophosphate, receptor binding, and guanosine diphosphate/guanosine triphosphate [gamma]35S exchange by using reconstituted defined G protein subunits. Involvement of phosphodiesterase and G[alpha]i was characterized by using the phosphodiesterase inhibitor rolipram and pertussis toxin, respectively.

Results: Lidocaine (10-9-10-1 M) had no significant effects on agonist or antagonist binding to the hA1R or on receptor-G protein interactions. However, cyclic adenosine monophosphate levels were reduced significantly to 50% by the LAs, even in the absence of an A1R agonist or presence of an A1R antagonist. This effect was unaffected by rolipram (10 [mu]m), but abolished completely by pretreatment with pertussis toxin, which inactivates the G[alpha]i protein. Therefore, the main target site for LAs in this pathway is located upstream from adenylate cyclase.     

Local anesthetic inhibition of m1 muscarinic acetylcholine signaling

BACKGROUND: Local anesthetics inhibit lipid mediator signaling (lysophosphatidate, thromboxane) by acting on intracellular domains of the receptor or on the G protein. On receptors for polar agonists, the ligand-binding pocket could form an additional site of interaction, possibly resulting in superadditive inhibition. The authors therefore investigated the effects of local anesthetics on m1 muscarinic receptor functioning. METHODS: The authors expressed receptors in isolation using Xenopus oocytes. Using a two-electrode voltage clamp, the authors measured the effects of lidocaine, QX314 (permanently charged), and benzocaine (permanently uncharged) on Ca2+-activated Cl- currents elicited by methylcholine. The authors also characterized the interaction of lidocaine with [3H] quinuclydinyl benzylate ([3H]QNB) binding to m1 receptors. RESULTS: Lidocaine inhibited muscarinic signaling with a half-maximal inhibitory concentration (IC50 18 nm) 140-fold less than that of extracellularly administered QX314 (IC50 2.4 microm). Intracellularly injected QX314 (IC50 0.96 mm) and extracellularly applied benzocaine (IC50 1.2 mm) inhibited at high concentrations only. Inhibition of muscarinic signaling by extracellularly applied QX314 and lidocaine was the result of noncompetitive antagonism. Intracellularly injected QX314 and benzocaine inhibited muscarinic and lysophosphatidate signaling at similar concentrations, suggesting an action on the common G-protein pathway. Combined administration of intracellularly injected (IC50 19 microm) and extracellularly applied QX314 (IC50 49 nm) exerted superadditive inhibition. Lidocaine did not displace specific [3H]QNB binding to m1 receptors. CONCLUSIONS: m1 Muscarinic signaling is inhibited by clinically relevant concentrations of lidocaine and by extracellularly administered QX314, suggesting that the major site of action is a extracellular domain of the muscarinic receptor. An additional less potent but superadditive inhibitory effect on the G-protein is suggested.     

Local Anesthetic Inhibition of m1 Muscarinic Acetylcholine Signaling

Background: Local anesthetics inhibit lipid mediator signaling (lysophosphatidate, thromboxane) by acting on intracellular domains of the receptor or on the G protein. On receptors for polar agonists, the ligand-binding pocket could form an additional site of interaction, possibly resulting in superadditive inhibition. The authors therefore investigated the effects of local anesthetics on m1 muscarinic receptor functioning.

Methods: The authors expressed receptors in isolation using Xenopus oocytes. Using a two-electrode voltage clamp, the authors measured the effects of lidocaine, QX314 (permanently charged), and benzocaine (permanently uncharged) on Ca2+-activated Cl- currents elicited by methylcholine. The authors also characterized the interaction of lidocaine with [3H] quinuclydinyl benzylate ([3H]QNB) binding to m1 receptors.

Results: Lidocaine inhibited muscarinic signaling with a half-maximal inhibitory concentration (IC50 18 nm) 140-fold less than that of extracellularly administered QX314 (IC50 2.4 [mu]m). Intracellularly injected QX314 (IC50 0.96 mm) and extracellularly applied benzocaine (IC50 1.2 mm) inhibited at high concentrations only. Inhibition of muscarinic signaling by extracellularly applied QX314 and lidocaine was the result of noncompetitive antagonism. Intracellularly injected QX314 and benzocaine inhibited muscarinic and lysophosphatidate signaling at similar concentrations, suggesting an action on the common G-protein pathway. Combined administration of intracellularly injected (IC50 19 [mu]m) and extracellularly applied QX314 (IC50 49 nm) exerted superadditive inhibition. Lidocaine did not displace specific [3H]QNB binding to m1 receptors.     

Lidocaine enhances Galphai protein function

BACKGROUND: Local anesthetics inhibit several G protein-coupled receptors by interaction with the Galphaq protein subunit. It is not known whether this effect on G protein function can be extrapolated to other classes of G proteins. The authors investigated interactions of lidocaine with the human adenosine 1 receptor (hA1R)-coupled signaling pathway. Activated A1Rs couple to adenylate cyclase via the pertussis toxin sensitive Galphai protein, thereby decreasing cyclic adenosine monophosphate formation. A1Rs are widely expressed and abundant in the spinal cord, brain, and heart. Interactions of LAs with the hA1R-coupled transduction cascade therefore might produce a broad range of clinically relevant effects. METHODS: The function of hA1Rs stably expressed in Chinese hamster ovary cells was determined with assays of cyclic adenosine monophosphate, receptor binding, and guanosine diphosphate/guanosine triphosphate gamma35S exchange by using reconstituted defined G protein subunits. Involvement of phosphodiesterase and Galphai was characterized by using the phosphodiesterase inhibitor rolipram and pertussis toxin, respectively. RESULTS: Lidocaine (10-9-10-1 M) had no significant effects on agonist or antagonist binding to the hA1R or on receptor-G protein interactions. However, cyclic adenosine monophosphate levels were reduced significantly to 50% by the LAs, even in the absence of an A1R agonist or presence of an A1R antagonist. This effect was unaffected by rolipram (10 mum), but abolished completely by pretreatment with pertussis toxin, which inactivates the Galphai protein. Therefore, the main target site for LAs in this pathway is located upstream from adenylate cyclase. CONCLUSIONS: Lidocaine potentiates Galphai-coupled A1R signaling by reducing cyclic adenosine monophosphate production. The study suggests an interaction site for LAs in a Galphai-coupled signaling pathway, with the Galphai protein representing the prime candidate. Taken together with previous results showing inhibitory LA interactions on the Galphaq protein subunit, the data in the current study support the hypothesis that specific G protein subunits represent alternative sites of LA action.     

Differential Inhibition of Lysophosphatidate Signaling by Volatile Anesthetics

Background: Volatile anesthetics have been found to interfere with the functioning of several G protein-coupled receptors, effects that may be relevant to the mechanism of anesthetic action. Lysophosphatidate (1-acyl-2-sn-glycero-3-phosphate; LP) is the simplest natural phospholipid. It has pronounced biological effects and signals through a specific G protein-coupled receptor. Because of its lipophilicity, the LP receptor is a feasible site of anesthetic interaction. Therefore, the authors investigated the effects of halothane and isoflurane on LP signaling using Xenopus oocytes.

Methods: Mature oocytes were harvested from Xenopus frogs, isolated, and defolliculated manually. Lysophosphatidate receptors are endogenously present in these cells. Angiotensin receptors were expressed recombinantly to study anesthetic effects on intracellular signaling. Oocytes were studied individually with a two-electrode voltage clamp at room temperature. Integrated Ca2+ -activated Cl sup - currents (ICl(Ca)) were used to evaluate the effects of anesthetics on changes in intracellular Ca2+ concentration in response to receptor agonists (10 sup -7 M LP or 10 sup -7 M angiotensin II) or intracellular inositoltrisphosphate (IP3) injection.

Results: Halothane depressed LP signaling in a concentration-dependent manner, with half-maximal inhibition at 0.23 mM and virtually complete inhibition at 0.34 mM. Responses could be recovered after an anesthetic-free wash. Oocyte injection with heparin, an IP3 receptor antagonist, completely blocked LP and angiotensin signaling, indicating similar IP3 -dependent pathways. However, ICl(Ca) induced by angiotensin receptor activation or intracellular IP3 injection were not inhibited by halothane. Isoflurane, at comparable concentrations, did not depress LP responses in oocytes significantly.     

Inhibition of Lysophosphatidate Signaling by Lidocaine and Bupivacaine

Background: Lidocaine and bupivacaine impair wound healing, but the mechanism of this side effect has not been determined. The phospholipid messenger lysophosphatidate is released from activated platelets and induces fibroblast and smooth muscle proliferation. Because it may play a role in wound healing, the authors studied the effects of local anesthetics on lysophosphatidate signaling in Xenopus oocytes.

Methods: Defolliculated Xenopus oocytes expressing endogenous G protein-coupled lysophosphatidate receptors were voltage clamped and studied in the presence or absence of lidocaine or bupivacaine. Lysophosphatidate-induced Ca2+ -activated Cl sup - currents (ICl(Ca)) were measured. To determine the site of action of the local anesthetics on the signaling pathway, the authors studied 1) the effects of local anesthetics on signaling induced by intracellular injection of the second messenger inositoltrisphosphate, and 2) the effects of local anesthetics on functioning of recombinantly expressed angiotensin II receptor signaling through the same pathways as the lysophosphatidate receptor.

Results: Lysophosphatidate signaling was inhibited in the presence of local anesthetics. The half maximal inhibitory concentration (IC50 s) for lidocaine and bupivacaine were 29.6 mM and 4.7 mM, respectively. Neither responses induced by inositoltrisphosphate injection nor angiotensin signaling were influenced by local anesthetics.     

Inhibition of mammalian Gq protein function by local anesthetics

BACKGROUND: Local anesthetics have been shown to selectively inhibit functioning of Xenopus laevis Gq proteins. It is not known whether a similar interaction exists with mammalian G proteins. The goal of this study was to determine whether mammalian Gq protein is inhibited by local anesthetics. METHODS: In Xenopus oocytes, the authors replaced endogenous Gq protein with mouse Gq (expressed in Sf9 cells using baculovirus vectors). Cells endogenously expressing lysophosphatidic acid or recombinantly expressing muscarinic m3 receptors were injected with phosphorothioate DNA antisense (or sense as control) oligonucleotides against Xenopus Gq. Forty-eight hours later, oocytes were injected with purified mouse Gq (5 x 10(-8) M) or solvent as control. Two hours later, the authors injected either lidocaine, its permanently charged analog QX314 (at IC50, 50 nl), or solvent (KCl 150 mM) as control and measured Ca-activated Cl currents in response to lysophosphatidic acid or methylcholine (one tenth of EC50). RESULTS: Injection of anti-Gq reduced the mean response size elicited by lysophosphatidic acid to 33 +/- 7% of the corresponding control response. In contrast, responses were unchanged (131 +/- 29% of control) in cells in addition injected with mouse Gq protein. Injection of mouse Gq protein "rescued" the inhibitory effect of intracellularly injected QX314: whereas QX314 was without effect on Gq-depleted oocytes, responses to lysophosphatidic acid after QX314 injection were inhibited to 44 +/- 10% of control response in cells in addition injected with mouse Gq protein (5 x 10(-8) M). Similar results were obtained for m3 signaling and intracellularly injected lidocaine. CONCLUSION: Inhibition of Gq function by local anesthetics is not restricted to Xenopus G proteins. Therefore, Gq should be considered as one additional intracellular target site for local anesthetics, especially relevant for those effects not explainable by sodium channel blockade (e.g., antiinflammatory effects).     

Modulation of Xenopus laevis Ca-activated Cl currents by protein kinase C and protein phosphatases: implications for studies of anesthetic mechanisms

Ca-activated Cl currents (I(Cl(Ca))) are used frequently as reporters in functional studies of anesthetic effects on G protein-coupled receptors using Xenopus laevis oocytes. However, because anesthetics affect protein kinase C (PKC), they could indirectly affect I(Cl(Ca)) if this current is regulated by phosphorylation. We therefore studied the effect of modulation of either PKC or protein phosphatases PP1alpha and PP2A on I(Cl(Ca)) stimulated either by lysophosphatidate (LPA) signaling or by microinjection of Ca. X. laevis oocytes were studied under voltage clamp. Rat PP1alpha and PP2A were overexpressed in oocytes. PP, inositoltrisphosphate (IP(3)), the PP inhibitor okadaic acid (OA), the PKC inhibitor chelerythrine, or CaCl(2) were directly injected into the oocyte. Responses to agonists (LPA 10(-6) M, IP(3) 10(-4) M, CaCl(2) 0.5 M) were measured at a holding potential of -70 mV in the presence or absence of the PP inhibitors cantharidin or OA. PP1 alpha and PP2A inhibited I(Cl(Ca)) from 7.6 +/- 0.9 microC to 2.5 +/- 0.9 microC and 3.2 +/- 1.4 microC, respectively. PP inhibition enhanced I(Cl(Ca)) in control oocytes and reversed the inhibitory effect in oocytes expressing PP1 alpha or PP2A. PKC inhibition by chelerythrine enhanced both LPA- and CaCl(2)-induced I(Cl(Ca)). Our data indicate that the Xenopus I(Cl(Ca)) is modulated by phosphorylation. This may complicate design and interpretation of studies of G protein-coupled receptors using this model.     

Local anesthetics suppress nerve growth factor-mediated neurite outgrowth by inhibition of tyrosine kinase activity of TrkA

Local anesthetics (LAs) suppress sympathetic sprouting, which correlates with neuropathic pain. However, the precise mechanism of the suppression is unknown. Nerve growth factor (NGF) contributes to the sympathetic sprouting, and NGF signaling starts with NGF-stimulated autophosphorylation of TrkA, which is a high affinity receptor of NGF. We examined the effects of lidocaine, bupivacaine, and procaine on NGF signaling under suppression of NGF-stimulated neurite outgrowth in PC12 cells, which is a cellular model of sympathetic sprouting. To investigate the effect of these LAs on NGF-mediated neurite outgrowth of PC12 cells, cells were incubated with 40, 400, and 4000 microM of each LA. The effect of LAs on NGF-stimulated TrkA activity was examined to analyze autophosphorylation of TrkA using immunoprecipitation and immunoblotting. Cytotoxic effects of LAs on PC12 cells were also assessed by lactate dehydrogenase release and by propidium iodide staining. Lidocaine (400 microM), bupivacaine (40 and 400 microM), or procaine (4000 microM) suppressed either neurite outgrowth or autophosphorylation significantly without cytotoxicity. The inhibition of NGF-stimulated tyrosine kinase activity of TrkA might be involved in the mechanisms of suppression of neurite outgrowth induced by LAs.     

Synergistic inhibition of lysophosphatidic acid signaling by charged and uncharged local anesthetics.

We investigated the mechanism of benzocaine (permanently uncharged) and QX314 (permanently charged) inhibition of lysophosphatidic acid (LPA) signaling. To determine their site of action, we studied effects of these drugs, alone and in combination, on LPA-induced Ca2+-dependent Cl currents (I(Cl(Ca))) in Xenopus oocytes. After 10 min exposure to benzocaine, QX314 (10(-6)-10(-2) M), or both, we measured effects on I(Cl(Ca)) induced by LPA (with and without protein kinase [PKC] activation/inhibition) and on I(Cl(Ca)) induced by the intracellular injection of IP3 and GTPgammaS. LPA application to oocytes resulted in I(Cl(Ca)) (50% effective concentration approximately 10(-8) M). Both anesthetics inhibited LPA signaling concentration-dependently (50% inhibitory concentration [IC50] benzocaine 0.9 mM, QX314 0.66 mM). The combination acted synergistically (IC50 benzocaine 0.097 mM/QX314 0.048 mM). Intracellular signaling pathways were not affected. This study shows that benzocaine and QX314 inhibit LPA signaling and act synergistically, which is most easily explained by the existence of two different binding sites. Lack of inhibition of IP3 or GTPgammaS-induced I(Cl(Ca)) identifies the receptor as a target. Activation of PKC can be excluded as a potential mechanism. IMPLICATIONS: Lysophosphatidic acid may play a role in wound healing, and its signaling is inhibited by local anesthetics. We identified the membrane receptor as the local anesthetic site of action and showed that charged (QX314) and uncharged (benzocaine) local anesthetics inhibit lysophosphatidic acid signaling synergistically, which can be explained by the presence of different binding sites.     

Inhibition of Mammalian Gq Protein Function by Local Anesthetics

Background: Local anesthetics have been shown to selectively inhibit functioning of Xenopus laevis Gq proteins. It is not known whether a similar interaction exists with mammalian G proteins. The goal of this study was to determine whether mammalian Gq protein is inhibited by local anesthetics.

Methods: In Xenopus oocytes, the authors replaced endogenous Gq protein with mouse Gq (expressed in Sf9 cells using baculovirus vectors). Cells endogenously expressing lysophosphatidic acid or recombinantly expressing muscarinic m3 receptors were injected with phosphorothioate DNA antisense (or sense as control) oligonucleotides against Xenopus Gq. Forty-eight hours later, oocytes were injected with purified mouse Gq (5 x 10-8 m) or solvent as control. Two hours later, the authors injected either lidocaine, its permanently charged analog QX314 (at IC50, 50 nl), or solvent (KCl 150 mm) as control and measured Ca-activated Cl currents in response to lysophosphatidic acid or methylcholine (one tenth of EC50).

Results: Injection of anti-Gq reduced the mean response size elicited by lysophosphatidic acid to 33 +/- 7% of the corresponding control response. In contrast, responses were unchanged (131 +/- 29% of control) in cells in addition injected with mouse Gq protein. Injection of mouse Gq protein "rescued" the inhibitory effect of intracellularly injected QX314: whereas QX314 was without effect on Gq-depleted oocytes, responses to lysophosphatidic acid after QX314 injection were inhibited to 44 +/- 10% of control response in cells in addition injected with mouse Gq protein (5 x 10-8 m). Similar results were obtained for m3 signaling and intracellularly injected lidocaine.     

The inhibitory effect of bupivacaine on prostaglandin E(2) (EP(1)) receptor functioning: mechanism of action

Prostaglandin E(2) receptors, subtype EP(1) (PGE(2)EP(1)) have been linked to several physiologic responses, such as fever, inflammation, and mechanical hyperalgesia. Local anesthetics modulate these responses, which may be due to direct interaction of local anesthetics with PGE(2)EP(1) receptor signaling. We sought to characterize the local anesthetic effects on PGE(2)EP(1) signaling and elucidate mechanisms of anesthetic action. In Xenopus laevis oocytes, recombinant expressed PGE(2)EP(1) receptors were functional (half maximal effect concentration, 2.09 +/- 0.98 x 10(-6) M). Bupivacaine, after incubation for 10 min, inhibited concentration-dependent PGE(2)EP(1) receptor functioning (half-maximal inhibitory effect concentration, 3.06 +/- 1.26 x 10(-6) M). Prolonged incubation in bupivacaine (24 h) inhibited PGE(2)-induced calcium-dependent chloride currents (I(Cl(Ca))) even more. Intracellular pathways were not significantly inhibited after 10 min of incubation in bupivacaine. But I(Cl(Ca)) activated by intracellular injection of GTPgammaS (a nonhydrolyzable guanosine triphosphate [GTP] analog that activates G proteins, irreversible because it cannot be dephosphorylated by the intrinsic GTPase activity of the alpha subunit of the G protein) was reduced after 24 h of incubation in bupivacaine, indicating a G protein-dependent effect. However, inositol 1,4,5-trisphosphate- and CaCl(2)- induced I(Cl(Ca)) were unaffected by bupivacaine at any time points tested. Therefore, bupivacaine's effect is at phospholipase C or at the G protein or the PGE(2)EP(1) receptor. All inhibitory effects were reversible. We conclude that bupivacaine inhibited PGE(2)EP(1) receptor signaling at clinically relevant concentrations. These effects could, at least in part, explain how local anesthetics affect physiologic responses such as fever, inflammation, and hyperalgesia during the perioperative period.     

Differential Effects of Volatile Anesthetics on M3 Muscarinic Receptor Coupling to the Gαq Heterotrimeric G Protein

Background: Halothane inhibits airway smooth muscle contraction in part by inhibiting the functional coupling between muscarinic receptors and one of its cognate heterotrimeric G proteins, G[alpha]q. Based on previous studies indicating a more potent effect of halothane and sevoflurane on airway smooth muscle contraction compared with isoflurane, the current study hypothesized that at anesthetic concentrations of 2 minimum alveolar concentration (MAC) or less, halothane and sevoflurane but not isoflurane inhibit acetylcholine-promoted G[alpha]q guanosine nucleotide exchange.

Methods: G[alpha]q guanosine nucleotide exchange was measured in crude membranes prepared from COS-7 cells transiently coexpressing the human M3 muscarinic receptor and human G[alpha]q. A radioactive, nonhydrolyzable analog of guanosine-5'-triphosphate, [35S]GTP[gamma]S, was used as a reporter for nucleotide exchange at G[alpha]q.

Results: Acetylcholine caused a concentration-dependent increase in G[alpha]q [35S]GTP[gamma]S-GDP exchange. Neither anesthetic affected constitutive G[alpha]q [35S]GTP[gamma]S-GDP exchange in the absence of acetylcholine. Conversely, each anesthetic caused a concentration-dependent and reversible inhibition of G[alpha]q [35S]GTP[gamma]S-GDP exchange when promoted by acetylcholine. At concentrations of 3 MAC or less, the effect of halothane and sevoflurane were significantly greater than that of isoflurane, with only a minimal inhibition by isoflurane observed at 2 MAC.     

Effects of antidepressants on G protein-coupled receptor signaling and viability in Xenopus laevis oocytes

BACKGROUND: Tricyclic antidepressants are structurally related to local anesthetics, suggesting that part of their analgesic action may result from properties shared with local anesthetics. Because local anesthetics block G protein-coupled receptor signaling (which explains, in part, their inflammatory modulating properties), the authors studied whether antidepressants have similar effects. METHODS: Peak Ca-activated Cl currents induced in Xenopus laevis oocytes by lysophosphatidic acid (10(-4) m) were measured using a voltage clamp. The effects of a 30-, 120-, or 240-min incubation in amitriptyline, nortriptyline, imipramine, or fluoxetine were determined. RESULTS: After a 30-min incubation, low concentrations (10(-7)-10(-5) m) of antidepressants had no effect on lysophosphatidic acid-induced currents. After prolonged incubation, only amitriptyline or nortriptyline inhibited lysophosphatidic acid signaling (each to 58% of the control response at 10(-7) m after 240 min). At low concentrations, none of the compounds induced membrane damage (defined as a holding current of > 1 microA, 2% in control cells). Imipramine at 10(-3) m induced damage in 100% of oocytes, and fluoxetine at 10(-4) m induced damage in 71% of oocytes (P < 0.05 vs. control). Amitriptyline and nortriptyline had no effect. CONCLUSIONS: These findings are in part different from those obtained with local anesthetics and suggest that interference with G protein-coupled signaling might explain, in part, the analgesic properties of some antidepressants. However, use of antidepressants in high concentrations may be associated with cellular toxicity.     

Neurotoxicity of lidocaine involves specific activation of the p38 mitogen-activated protein kinase, but not extracellular signal-regulated or c-jun N-terminal kinases, and is mediated by arachidonic acid metabolites

BACKGROUND: Pharmacologic inhibition of the p38 mitogen-activated protein kinase (MAPK) leads to a reduction in lidocaine neurotoxicity in vitro and in vivo. The current study investigated in vitro the hypotheses that lidocaine neurotoxicity is specific for dorsal root ganglion cells of different size or phenotype, involves time-dependent and specific activation of the p38 MAPK, that p38 MAPK inhibitors are only effective if applied with local anesthetic, and that p38 MAPK activation triggers activation of lipoxygenase pathways. METHODS: The authors used primary sensory neuron cultures and pheochromocytoma cell line cultures to detect time-dependent activation of the p38 MAPK or related pathways such as extracellular signal-regulated kinases and c-jun N-terminal kinases. Cells were divided by size or by immunoreactivity for calcitonin gene-related peptide or isolectin B4, indicative of nociceptive phenotype. The authors also investigated whether arachidonic acid pathways represent a downstream effector of the p38 MAPK in local anesthetic-induced neurotoxicity. RESULTS: All types of dorsal root ganglion cells were subject to neurotoxic effects of lidocaine, which were mediated by specific activation of the p38 MAPK but not extracellular signal-regulated kinases or c-jun N-terminal kinases. Neuroprotective efficacy of p38 MAPK inhibitors declined significantly when administered more than 1 h after lidocaine exposure. Activation of p38 MAPK preceded activation of arachidonic acid pathways. Neurotoxicity of lidocaine, specific activation of p38 MAPK, and neuroprotective effects of a p38 MAPK inhibitor were further confirmed in pheochromocytoma cell line cultures. CONCLUSIONS: Specific and time-dependent activation of the p38 MAPK is involved in lidocaine-induced neurotoxicity, most likely followed by activation of lipoxygenase pathways.     

Neurotoxicity of Lidocaine Involves Specific Activation of the p38 Mitogen-activated Protein Kinase, but Not Extracellular Signal-regulated or c-jun N-Terminal Kinases, and Is Mediated by Arachidonic Acid Metabolites

Background: Pharmacologic inhibition of the p38 mitogen-activated protein kinase (MAPK) leads to a reduction in lidocaine neurotoxicity in vitro and in vivo. The current study investigated in vitro the hypotheses that lidocaine neurotoxicity is specific for dorsal root ganglion cells of different size or phenotype, involves time-dependent and specific activation of the p38 MAPK, that p38 MAPK inhibitors are only effective if applied with local anesthetic, and that p38 MAPK activation triggers activation of lipoxygenase pathways.

Methods: The authors used primary sensory neuron cultures and pheochromocytoma cell line cultures to detect time-dependent activation of the p38 MAPK or related pathways such as extracellular signal-regulated kinases and c-jun N-terminal kinases. Cells were divided by size or by immunoreactivity for calcitonin gene-related peptide or isolectin B4, indicative of nociceptive phenotype. The authors also investigated whether arachidonic acid pathways represent a downstream effector of the p38 MAPK in local anesthetic-induced neurotoxicity.

Results: All types of dorsal root ganglion cells were subject to neurotoxic effects of lidocaine, which were mediated by specific activation of the p38 MAPK but not extracellular signal-regulated kinases or c-jun N-terminal kinases. Neuroprotective efficacy of p38 MAPK inhibitors declined significantly when administered more than 1 h after lidocaine exposure. Activation of p38 MAPK preceded activation of arachidonic acid pathways. Neurotoxicity of lidocaine, specific activation of p38 MAPK, and neuroprotective effects of a p38 MAPK inhibitor were further confirmed in pheochromocytoma cell line cultures.     

Halothane Inhibits Signaling through m1 Muscarinic Receptors Expressed in Xenopus Oocytes

Background: Interactions between volatile anesthetics and muscarinic acetylcholine receptors have been studied primarily in binding assays or in functional systems derived from tissues or cells, often containing multiple receptor subtypes. Because interactions with muscarinic signaling systems may explain some effects and side effects of anesthetics and form a model for anesthetic-protein interactions in general, the author studied anesthetic inhibition of muscarinic signaling in an isolated system.

Methods: mRNA encoding the m1 muscarinic receptor subtype was prepared in vitro and expressed in Xenopus oocytes. Effects of halothane on methylcholine-induced intracellular Calcium2+ release was measured. Angiotensin II receptors were expressed to evaluate anesthetic effects on intracellular signaling.

Results: m1 Receptors expressed in oocytes were functional, and could be inhibited by atropine and pirenzepine. Halothane depressed m1 muscarinic signaling in a dose-dependent manner: half-maximal inhibition of 10 sup -7 M methylcholine was obtained with 0.3 mM halothane. The effect was reversible and could be overcome by high concentrations of muscarinic agonist. Angiotensin II signaling was unaffected by 0.34 mM halothane.     

Local anaesthetics inhibit signalling of human NMDA receptors recombinantly expressed in Xenopus laevis oocytes: role of protein kinase C

Background. N-methyl-D-aspartate (NMDA)-receptor activationcontributes to postoperative hyperalgesia. Studies in volunteershave shown that intravenous local anaesthetics (LAs) preventthe development of hyperalgesic pain states. One potential explanationfor this beneficial effect is the inhibition of NMDA receptoractivation. Therefore, we studied the effects of LA on NMDAreceptor function. Methods. The human NR1A/NR2A NMDA receptor was expressed recombinantlyin Xenopus laevis oocytes. Peak currents were measured by voltageclamp in Mg- and Ca²⁺-free, Ba²⁺-containing Tyrode's solution.Holding potential was –70 mV. Oocytes were stimulatedwith glutamate/glycine (at EC₅₀) with or without 10 min priorincubation in bupivacaine, levobupivacaine, S-(–)-ropivacaine,or lidocaine (all at 10^–9–10^–4 M), procaine(10^–4 M), R-(+)-ropivacaine (10^–4 M), QX314 (permanentlycharged, 5x10^–4 M) extracellularly or intracellularlyor benzocaine (permanently uncharged, 5x10^–3 M). We alsodetermined the effect of the protein kinase C (PKC) inhibitorschelerythrine (5x10^–5 M), calphostin C (3x10^–6 M)and Ro 31-8220 (10^–7 M), and the effect of PKC activationwith phorbolester (10^–6 M). Results. Non-injected oocytes were unresponsive to agonist application,but oocytes expressing NMDA receptors responded with inwardcurrents (1.1±0.08 µA). All LA concentration-dependentlyinhibited agonist responses. The inhibition was reversible andstereoselective. Intracellular QX314 reduced responses to 59%of control, but extracellular QX314 was without effect. Benzocainereduced responses to 33% of control. PKC inhibitors had no additionalinhibitory effect beyond that of bupivacaine. The effect ofPKC activation was abolished in the presence of bupivacaine. Conclusion. All LA tested inhibited the activation of humanNMDA receptors in a concentration dependent fashion. This effectmay contribute to reduced hyperalgesia and opiate toleranceobserved after systemic administration of LA. The effect isindependent of the charge of LA; site of action is intracellular.The mechanism of action may be mediated by inhibition of PKC.