Sodium Channel Blocking Actions of the κ-Opioid Receptor Agonist U50,488 Contribute to Its Visceral Antinociceptive Effects

Abstract: . Sodium channel blocking actions of the -opioid receptor agonist U50,488 contribute to its visceral antinociceptive effects. J Neurophysiol 87: 1271-1279, 2002; 10.1152/jn.00624.2001. The goal of the present study was to determine whether the -opioid receptor agonist (ORA) U50,488 attenuates behavioral and primary afferent nerve responses to noxious colorectal distension (CRD) by sodium channel blockade. We tested the analgesic -ORA (Ϯ)-trans U50,488, its enantiomers (Ϫ)-trans (1S,2S)-U50,488 and non -ORA (ϩ… Show more

“…This hypothesis was directly addressed by investigating the effects of (Ϫ)-(1S,2S)-U50,488 and (ϩ)-(1R,2R)-U50,488 on voltage-gated sodium currents in colon sensory neurons in the S1 dorsal root ganglion. Both U50,488 enantiomers decreased voltage-gated sodium currents with comparable potencies even in the presence of opioid receptor antagonism (Su et al, 2002). Such findings demonstrate that the two U50,488 enantiomers have comparable potency in blocking voltage-gated sodium channels, but drastically different actions on the KOR.…”

“…Subsequent electrophysiological studies confirmed that this nonopioid effect of U50,488 was due to a direct blockade of voltage-gated sodium channels in cardiac myocytes (Pugsley et al, 1993(Pugsley et al, , 1994. The sodium channel blocking actions of -ORAs have been replicated in hippocampal CA3 neurons (Alzheimer and Bruggencate, 1990), neuroblastoma cells (Zhu and Im, 1992) and more recently in primary sensory neurons in the dorsal root ganglion (Su et al, 2002). Another line of evidence for opioid receptor-independent blockade of sodium channels by -ORAs such as U50,488 derives from experiments using heterogeneous expression of sodium channels in oocytes (Pugsley et al, 2000).…”

“…For example, the antiarrhythmic efficacy of arylacetamide was maintained when enantiomeric pairs such as (ϩ)-PD 129,290 (which lacks affinity for the KOR) and (Ϫ)-PD 129,289 (which has high affinity for the KOR) were examined (Pugsley et al, 1993), giving further support to the notion that these cardiac effects were not mediated by the KOR, but by sodium channel blockade. In studies of visceral nociception, systemically administered (Ϯ)-trans-U50,488, (ϩ)-(1R,2R)-U50,488, and (Ϫ)-(1S,2S)-U50,488 produced dose-dependent antinociception and also dose dependently attenuated responses of decentralized pelvic nerve afferent fibers to noxious colon distension, the latter by a KOR-independent mechanism, suggesting contribution of sodium channel blockade by a nonopioid mechanism (Su et al, 2002). This hypothesis was directly addressed by investigating the effects of (Ϫ)-(1S,2S)-U50,488 and (ϩ)-(1R,2R)-U50,488 on voltage-gated sodium currents in colon sensory neurons in the S1 dorsal root ganglion.…”

“…A series of experiments have established that the cardiovascular effects of -ORAs such as antiarrhythmia and hypotension occur due to their sodium channel blocking actions in cardiac myocytes (Pugsley et al, 1993(Pugsley et al, , 1994. Such actions of -ORAs have also been demonstrated in hippocampal CA3 neurons (Alzheimer and Bruggencate, 1990), neuroblastoma cells (Zhu and Im, 1992), primary sensory neurons in the dorsal root ganglia (Su et al, 2002), and in oocytes heterogeneously expressing sodium channels (Pugsley et al, 2000). The blockade of voltage-gated sodium channels in these studies was opioid-receptor independent, as verified by use of opioid receptor antagonists.…”

“…In contrast, the (ϩ)-trans-(1R,2R)-U50,488 enantiomer has insignificant affinity toward the KOR (K d ϭ 299 nM) and is without effect in KOR-mediated antinociceptive assays. Although U50,488 and both its enantiomers each have a distinct opioid pharmacology, they display comparable potencies in producing a block of voltagegated sodium channels by a nonopioid mechanism (Pugsley et al, 1993;Su et al, 2002).…”

Nonopioid Actions of U50,488 Enantiomers Contribute to Their Peripheral Cutaneous Antinociceptive Effects

“…This hypothesis was directly addressed by investigating the effects of (Ϫ)-(1S,2S)-U50,488 and (ϩ)-(1R,2R)-U50,488 on voltage-gated sodium currents in colon sensory neurons in the S1 dorsal root ganglion. Both U50,488 enantiomers decreased voltage-gated sodium currents with comparable potencies even in the presence of opioid receptor antagonism (Su et al, 2002). Such findings demonstrate that the two U50,488 enantiomers have comparable potency in blocking voltage-gated sodium channels, but drastically different actions on the KOR.…”

“…Subsequent electrophysiological studies confirmed that this nonopioid effect of U50,488 was due to a direct blockade of voltage-gated sodium channels in cardiac myocytes (Pugsley et al, 1993(Pugsley et al, , 1994. The sodium channel blocking actions of -ORAs have been replicated in hippocampal CA3 neurons (Alzheimer and Bruggencate, 1990), neuroblastoma cells (Zhu and Im, 1992) and more recently in primary sensory neurons in the dorsal root ganglion (Su et al, 2002). Another line of evidence for opioid receptor-independent blockade of sodium channels by -ORAs such as U50,488 derives from experiments using heterogeneous expression of sodium channels in oocytes (Pugsley et al, 2000).…”

“…For example, the antiarrhythmic efficacy of arylacetamide was maintained when enantiomeric pairs such as (ϩ)-PD 129,290 (which lacks affinity for the KOR) and (Ϫ)-PD 129,289 (which has high affinity for the KOR) were examined (Pugsley et al, 1993), giving further support to the notion that these cardiac effects were not mediated by the KOR, but by sodium channel blockade. In studies of visceral nociception, systemically administered (Ϯ)-trans-U50,488, (ϩ)-(1R,2R)-U50,488, and (Ϫ)-(1S,2S)-U50,488 produced dose-dependent antinociception and also dose dependently attenuated responses of decentralized pelvic nerve afferent fibers to noxious colon distension, the latter by a KOR-independent mechanism, suggesting contribution of sodium channel blockade by a nonopioid mechanism (Su et al, 2002). This hypothesis was directly addressed by investigating the effects of (Ϫ)-(1S,2S)-U50,488 and (ϩ)-(1R,2R)-U50,488 on voltage-gated sodium currents in colon sensory neurons in the S1 dorsal root ganglion.…”

“…A series of experiments have established that the cardiovascular effects of -ORAs such as antiarrhythmia and hypotension occur due to their sodium channel blocking actions in cardiac myocytes (Pugsley et al, 1993(Pugsley et al, , 1994. Such actions of -ORAs have also been demonstrated in hippocampal CA3 neurons (Alzheimer and Bruggencate, 1990), neuroblastoma cells (Zhu and Im, 1992), primary sensory neurons in the dorsal root ganglia (Su et al, 2002), and in oocytes heterogeneously expressing sodium channels (Pugsley et al, 2000). The blockade of voltage-gated sodium channels in these studies was opioid-receptor independent, as verified by use of opioid receptor antagonists.…”

“…In contrast, the (ϩ)-trans-(1R,2R)-U50,488 enantiomer has insignificant affinity toward the KOR (K d ϭ 299 nM) and is without effect in KOR-mediated antinociceptive assays. Although U50,488 and both its enantiomers each have a distinct opioid pharmacology, they display comparable potencies in producing a block of voltagegated sodium channels by a nonopioid mechanism (Pugsley et al, 1993;Su et al, 2002).…”

Nonopioid Actions of U50,488 Enantiomers Contribute to Their Peripheral Cutaneous Antinociceptive Effects

Models of Visceral Pain: Colorectal Distension (CRD)

Pharmacologic evaluation of pressor and visceromotor reflex responses to bladder distension