Aims: We investigated the effects of [studies using cell cultures these

Aims: We investigated the effects of [studies using cell cultures these endomorphin antagonists reversed the inhibition by naloxone and naltrexone on the binding of [35S]GTPγS the biochemical assessment of G-protein interaction with opioid receptors in isolated cell membranes from cells pretreated with morphine or ethanol (Marczak comparisons when appropriate. eIPSC amplitude and sIPSC frequency. Fig. ?Fig.1A1A shows representative traces of eIPSCs evoked by single stimuli. Fig. ?Fig.1B1B illustrates that 1?μM TL-319 did not alter the eIPSC amplitude: the average amplitude of eIPSCs was 196.2 ± 25.2 and 204.9 ± 39.8 pA before and after bath application of 1 1?μM TL-319 respectively; the paired 0.05= 7). Similarly 1 TL-319 did not significantly alter the mean frequency of sIPSCs: control frequency 4.55 ± 0.78 Hz and during TL-319 application 4.35 0.69 Hz (paired > 0.05 = 7 data not BMS-345541 HCl shown). Fig. 1 Amplitude of evoked IPSCs of CA1 pyramidal cells is not affected by TL-319. (A) Top panel: traces showing average response to stimulation before and during bath application of 1 1?μM TL-319. Whole-cell voltage-clamp recording from a CA1 … BMS-345541 HCl Since bath application of 60 mM EtOH reliably increases the frequency of sIPSCs in CA1 pyramidal cells (Li < 0.01 K-S test Fig. ?Fig.2B).2B). This EtOH-induced increase in sIPSC frequency was significantly reduced by 1?μM TL-319 (< 0.01 K-S test Fig. ?Fig.2B).2B). Neither EtOH nor TL-319 changed the distribution pattern of sIPSC amplitude (> 0.05 K-S test Fig. ?Fig.22C). Fig. 2 Ethanol BMS-345541 HCl effects on sIPSCs of CA1 pyramidal cells are blocked by TL-319. (A) Traces showing sIPSCs of a CA1 pyramidal cell before and during bath application of 60 mM EtOH and 60 mM EtOH plus 1 μM TL-319. Whole-cell voltage-clamp recording from … The effect of TL-319 on the EtOH-induced increase in sIPSC frequency was concentration dependent. While 10 nM TL-319 had no effect and 100 nM TL-319 attenuated EtOH-induced increases in sIPSC frequency in only two of seven Rabbit polyclonal to ZNF483. pyramidal cells (a statistically non-significant effect) both 500 and 1000 nM TL-319 significantly attenuated the EtOH-induced increase in sIPSC frequency (one-way ANOVA = 9.42×10?5). analyses revealed that TL-319 suppressed the EtOH-induced increase in the frequency of sIPSCs in a concentration-dependent manner (Fig. ?(Fig.22D). The decay kinetics of sIPSCs were also unaffected by EtOH or TL-319. sIPSC decay kinetics under each condition were fitted as a biexponential equation. Representative examples are shown in Fig. ?Fig.2E2E (top panel). There were no significant changes in the mean fast and slow decay times (tau) under either treatment condition compared to control (Fig. ?(Fig.2E 2 bottom panel). This suggests a non-postsynaptic mechanism for the effect of TL-319 on EtOH-induced enhancement of sIPSCs. Studies in both humans and animal models have shown that the non-selective μ-opioid receptor antagonist naltrexone reduces ethanol consumption (Croop < 0.01 K-S test Fig. ?Fig.3B) 3 and 60 μM naltrexone diminished this effect (< 0.01 K-S test Fig. ?Fig.3B).3B). While neither 30 μM nor 60 μM naltrexone altered the amplitude of sIPSCs (> 0.05 K-S test Fig. ?Fig.3C) 3 60 μM naltrexone BMS-345541 HCl attenuated the EtOH-induced increase BMS-345541 HCl in sIPSC frequency (paired < 0.05 = 6) (Fig. ?(Fig.33D). Fig. 3 Reversal of ethanol effects on sIPSCs of CA1 pyramidal cells by naltrexone. (A) Traces showing sIPSCs of a CA1 pyramidal cell before and during bath application of 60 mM EtOH and 60 mM EtOH plus 60 μM naltrexone. Whole-cell voltage-clamp recording ... Discussion The μ-opioid receptor system represents a potential target for therapeutic treatment of ethanol dependence particularly since its impact on the physiological effects of ethanol can be altered by high-potency antagonists. The present data show that TL-319 a selective and potent μ-opioid receptor antagonist (Li effects of specific μ-opioid receptor antagonists. For example central or systemic administration of the specific μ-opioid receptor antagonists CTOP (Hyytia 1993 Hyytia and Kiianmaa 2001 β-funaltrexamine (Stromberg study in which pretreatment with 30?mg/kg naltrexone but not 3 mg/kg reduced ethanol-induced increases in the firing rate of dopamine neurons (Inoue 2000 We cannot however exclude the possibility that naltrexone antagonizes the effect of EtOH on sIPSCs through multiple mechanisms (Gonzales and Weiss 1998 In conclusion TL-319 a selective and potent μ-opioid receptor antagonist.