Molecular mechanisms of large-conductance ca (2+) -activated potassium channel activation by ginseng gintonin.

Gintonin is a unique lysophosphatidic acid (LPA) receptor ligand found in Panax ginseng. Gintonin induces transient [Ca(2+)]i through G protein-coupled LPA receptors. Large-conductance Ca(2+)-activated K(+) (BKCa) channels are expressed in blood vessels and neurons and play important roles in blood vessel relaxation and attenuation of neuronal excitability. BKCa channels are activated by transient [Ca(2+)]i and are regulated by various Ca(2+)-dependent kinases. We investigated the molecular mechanisms of BKCa channel activation by gintonin. BKCa channels are heterologously expressed in Xenopus oocytes. Gintonin treatment induced BKCa channel activation in oocytes expressing the BKCa channel α subunit in a concentration-dependent manner (EC50 = 0.71 ± 0.08 µg/mL). Gintonin-mediated BKCa channel activation was blocked by a PKC inhibitor, calphostin, and by the calmodulin inhibitor, calmidazolium. Site-directed mutations in BKCa channels targeting CaM kinase II or PKC phosphorylation sites but not PKA phosphorylation sites attenuated gintonin action. Mutations in the Ca(2+) bowl and the regulator of K(+) conductance (RCK) site also blocked gintonin action. These results indicate that gintonin-mediated BKCa channel activations are achieved through LPA1 receptor-phospholipase C-IP3-Ca(2+)-PKC-calmodulin-CaM kinase II pathways and calcium binding to the Ca(2+) bowl and RCK domain. Gintonin could be a novel contributor against blood vessel constriction and over-excitation of neurons.

Characterization of a new HLA-DRB1*1405 variant, HLA-DRB1*140503, identified by sequence-based typing.

A new human leukocyte antigen-DRB1*140503 differs from DRB1*140501 with T to C transition at codon 78 (TAT-->TAC) of exon 2 without coding change.

Identification of a novel HLA-A*26 allele, HLA-A*2632, by sequence-based typing in the Korean population.

HLA-A*2632 shows three nucleotides difference with HLA-A*260101 and HLA-A*2624 in exon 3 at codon 95 (ATC--> ATG) and codon 97 (AGG --> GTG), resulting in two amino acids change from Ile to Met (I95M) and Arg to Val (R97V).

HLA-A*2634, a new allele identified by sequence-based typing in the Korean population.

A new HLA-A*2634 allele differs from A*260101 by a change from C to T at the nucleotide 559 of exon 3, with a coding change R163W.

Inhibitory effects of berberine against morphine-induced locomotor sensitization and analgesic tolerance in mice.

We previously reported that a methanolic extract of Coptis japonica, which is a well-known traditional oriental medicine, inhibits morphine-induced conditioned place preference (CPP) in mice. Berberine is a major component of Coptis japonica extract, and it has been established that the adverse effects of morphine on the brain involve dopamine (DA) receptors. However, to our knowledge, no study has investigated the inhibitory effects of berberine on morphine-induced locomotor sensitization and analgesic tolerance in mice. Here, we investigated the effects of berberine on morphine-induced locomotor sensitization and on the development of analgesic tolerance. Furthermore, we examined the effects of berberine treatment on N-methyl-D-aspartate (NMDA) receptor channel activity expressed in Xenopus laevis oocytes. Berberine was found to completely block both morphine-induced locomotor sensitization and analgesic tolerance, and reduce D(1) and NMDA receptor bindings in the cortex. Moreover, berberine markedly inhibited NMDA current in Xenopus laevis oocytes expressing NMDA receptor subunits. Our results suggest that the inhibitory effects of berberine on morphine-induced locomotor sensitization and analgesic tolerance are closely related to the modulation of D1 and NMDA receptors, and that berberine should be viewed as a potential novel means of attenuating morphine-induced sensitization and analgesic tolerance.

Modification of radiation response in mice by Panax ginseng and diethyldithiocarbamate.

The aim of this study was to determine the effect of Panax ginseng and its fractions on jejunal crypt survival, endogenous spleen colony formation and apoptosis in jejunal crypt cells of mice irradiated with high- and low-dose of gamma-irradiation. The radioprotective effect of ginseng was compared with the effect of diethyldithiocarbamate (DDC). Ginseng administration before irradiation protected the jejunal crypts (p < 0.005), increased the formation of endogenous spleen colony (p < 0.005) and reduced the frequency of radiation-induced apoptosis (p < 0.05). The radioprotective effect on jejunal crypts and apoptosis in the DDC-treated group appeared similar to that in the ginseng--treated groups. Treatment with DDC showed no significant modifying effects on the formation of endogenous spleen colony. In the experiment on the effect of fractions of ginseng, the result indicated that the lipophilic non-polar compounds (Fraction 1), lipophilic-acidic compounds (Fraction 2), free sugars (Fraction 7) and saponin compounds (Fraction 8) might have a major radioprotective effect. Although the mechanisms of this inhibitory effect remain to be elucidated, these results indicated that ginseng might be a useful radioprotector, especially since it is a relatively nontoxic natural product. Further studies are needed to fully characterize the protective nature of ginseng extract and its components.

G alpha(q/11) coupled to mammalian phospholipase C beta 3-like enzyme mediates the ginsenoside effect on Ca(2+)-activated Cl(-) current in the Xenopus oocyte.

Recently we demonstrated that ginsenosides, the active ingredients of Panax ginseng, enhanced Ca(2+)-activated Cl(-) current in the Xenopus oocyte through a signal transduction mechanism involving the activation of pertussis toxin-insensitive G protein and phospholipase C (PLC). However, it has not yet been determined precisely which G protein subunit(s) and which PLC isoform(s) participate in the ginsenoside signaling. To provide answers to these questions, we investigated the changes in ginsenoside effect on the Cl(-) current after intraoocyte injections of the cRNAs coding various G protein subunits, a regulator of G protein signaling (RGS2), and G beta gamma-binding proteins. In addition, we examined which of mammalian PLC beta 1-3 antibodies injected into the oocyte inhibited the action of ginsenosides on the Cl(-) current. Injection of G alpha(q) or G alpha(11) cRNA increased the basal Cl(-) current recorded 48 h after, and it further prevented ginsenosides from enhancing the Cl(-) current, whereas G alpha(i2) and G alpha(oA) cRNA injection had no significant effect. The changes following G alpha(q) cRNA injection were prevented when G beta(1)gamma(2) and G alpha(q) subunits were co-expressed by simultaneous injection of the cRNAs coding these subunits. Injection of cRNA coding G alpha(q)Q209L, a constitutively active mutant that does not bind to G beta gamma, produced effects similar to those of G alpha(q) cRNA injection. The effects of G alpha(q)Q209L cRNA injection, however, were not prevented by co-injection of G beta(1)gamma(2) cRNA. Injection of the cRNA coding RGS2, which interacts most selectively with G alpha(q/11) among various identified RGS isoforms and stimulates the hydrolysis of GTP to GDP in active GTP-bound G alpha subunit, resulted in a severe attenuation of ginsenoside effect on the Cl(-) current. Finally, antibodies against PLC beta 3, but not -beta 1 and -beta 2, markedly attenuated the ginsenoside effect examined at 3-h postinjection. These results suggest that G alpha(q/11) coupled to mammalian PLC beta 3-like enzyme mediates ginsenoside effect on Ca(2+)-activated Cl(-) current in the Xenopus oocyte.

Changes of [3H]MK-801, [3H]muscimol and [3H]flunitrazepam binding in rat brain by the prolonged ventricular infusion of ginsenoside Rc and Rg1.

In the present study, we have investigated the effects of centrally administered ginsenoside Rc and Rg1 on the modulation of the NMDA receptor and GABA(A)receptor binding in rat brain. The NMDA receptor binding was analysed by quantitative autoradiography using [(3)H]MK-801 binding, and the GABA(A)receptor bindings were analysed by using [(3)H]muscimol and [(3)H]flunitrazepam binding in rat brain slices. Rats were infused with ginsenoside Rc or Rg1 (10 microg/10 microl h(-1), i.c.v.) for 7 days, through pre-implanted cannula using osmotic minipumps (Alzet, model 2ML). The levels of [(3)H]MK-801 binding were highly decreased in part of the parietal layers of the cortex and cingulated by ginsenoside Rc and Rg1. The levels of [(3)H]muscimol binding were strongly elevated in almost all regions of the frontal cortex by the treatment of ginsenoside Rc but decreased by ginsenoside Rg1. However, the [(3)H]flunitrazepam binding was not modulated by ginsenoside Rc or Rg1 infusion. These results suggest that prolonged infusion of ginsenosides could differentially modulate [(3)H]MK-801 and [(3)H]muscimol binding in a region-specific manner.

A novel activation of Ca(2+)-activated Cl(-) channel in Xenopus oocytes by Ginseng saponins: evidence for the involvement of phospholipase C and intracellular Ca(2+) mobilization.

1. The signal transduction mechanism of ginsenosides, the active ingredients of ginseng, was studied in Xenopus oocytes using two-electrode voltage-clamp technique. Ginseng total saponin (GTS), i.e., an unfractionated mixture of ginsenosides produced a large outward current at membrane potentials more positive than -20 mV when it was applied to the exterior of oocytes, but not when injected intracellularly. The effect of GTS was concentration-dependent (EC(50): 4.4 microg ml(-1)) and reversible. 2. Certain fractionated ginsenosides (Rb(1), Rb(2), Rc, Rf, Rg(2) and Ro) also produced an outward current in a concentration-dependent manner with the order of potency of Rf>Ro>Rb(1)=Rb(2)>Rg(2)>Rc. Other ginsenosides (Rd, Re and Rg(1)) had little or no effect. 3. The GTS effect was completely blocked by bath application of the Ca(2+)-activated Cl(-) channel blocker niflumic acid and by intracellular injection of the calcium chelator BAPTA or the IP(3) receptor antagonist heparin. Also, the effect was partially blocked by bath-applied U-73122, a phospholipase C (PLC) inhibitor and by intracellularly injected GTP gamma S, a non-hydrolyzable GTP analogue. Whereas, it was not altered by pertussin toxin (PTX) pretreatment. 4. These results indicate that: (1) interaction of ginsenosides with membrane component(s) at the extracellular side leads to Ca(2+)-activated Cl(-) channel opening in Xenopus oocyte membrane; and (2) this process involves PLC activation, the release of Ca(2+) from the IP(3)-sensitive intracellular store and PTX-insensitive G protein activation.

Effects of ginsenosides on vanilloid receptor (VR1) channels expressed in Xenopus oocytes.

Ginsenosides, or ginseng saponins, are biologically active ingredients of Panax ginseng. Accumulating evidence suggests that ginsenosides can alleviate pain from injections of noxious chemicals, such as capsaicin [Nah et al. (2000)]. In this study we examined the effects of ginsenoside Rc on the capsaicin-induced inward current in Xenopus oocytes that expresses the vanilloid receptor 1 (VR1). Ginsenoside Rc enhanced the capsaicin-induced inward current in a concentration-dependent and reversible manner, but ginsenoside Rc itself elicited no membrane currents. The VR1 antagonist capsazepine almost completely blocked the inward current that was elicited by capsaicin plus ginsenoside Rc. We also tested the effect of seven other fractionated ginsenosides (i.e., Rb1, Rb2, Rd, Re, Rf, Rg1, and Rg2) in addition to ginsenoside Rc. We found that six of them significantly enhanced the inward current that is induced by capsaicin with the following order of potency: Rc > Rf > Rg1 approximately Rd > Rb2 > Rb1. These results show the possibility that the in vivo effect of ginsenosides against capsaicin-induced pain is derived from their modulation of the VR1 channel function.

Effect of ginsenosides, active components of ginseng, on capsaicin-induced pain-related behavior.

Our recent study demonstrated that ginsenosides had antinociceptive effects by reducing some types of pain-related behavior in mice (Yoon et al., 1998. Ginsenosides induce differential antinociception and inhibit substance P-induced nociceptive response in mice. Life Science 62, PL319-PL325). In the present study we further investigated whether ginsenosides produce antinociceptive effects through an action at central or peripheral site(s) and whether these effects are mediated by the opioid system. Intraperitoneally injected ginsenosides suppressed in a dose-dependent manner the pain-related behavior produced by capsaicin injection into the plantar surface of the hind paw; the ED(50) was 49 mg/kg [26-92 mg/kg, 95% confidence interval (C.I.)]. Intrathecally or intracerebroventricularly administered ginsenosides also suppressed the capsaicin-induced pain-related behavior in a dose-dependent manner; the ED(50)s were 1.72 mg/kg (0.8-3.72 mg/kg, 95% C.I.) and 1. 48 mg/kg (0.8-2.6 mg/kg, 95% C.I.), respectively. On the other hand, subcutaneously injected ginsenosides to the plantar surface prior to the capsaicin injection did not alter the pain-related behavior. Naloxone pretreatment was without effect in blocking the antinociceptive effect of intrathecally administered ginsenosides. Intraperitoneally injected ginsenosides also did not significantly affect the motor response of animals. These results suggest that ginsenosides produce antinociceptive effects through their action at the spinal and/or supraspinal site(s), not at nociceptors in the periphery. In addition, the results suggest that the antinociceptive effects are not mediated by opioid receptors.

Evidence that ginsenosides prevent the development of opioid tolerance at the central nervous system.

The analgesic effect of ginsenosides or morphine was first determined following intrathecal (i.t.) administration in rat tail-flick test. The effect of chronic i.t. co-administration of ginsenosides with morphine on the development of opioid tolerance were also examined using rat tail-flick test. Administration of ginsenosides (i.t.) produced a weak antinociception in a dose-dependent manner. Administration of morphine (i.t.) also produced antinociception in a dose-dependent manner. The ED50 was 1.20 microg (1.14-1.29 microg). However, acute i.t. co-administration of ginsenosides with morphine was not additive in antinociception. Repeated i.t. co-administration of 200 microg ginsenosides with 10 microg morphine inhibited the development of tolerance induced by 10 microg morphine in rat tail-flick test, although i.t. co-administration of 50 or 100 microg ginsenosides with morphine was without effect. In conclusion, these results indicate that i.t. administered ginsenosides produce an antinociception in rat tail-flick test and also prevent opioid tolerance caused by chronic treatment with morphine at the spinal sites.

Ginsenosides inhibit capsaicin-activated channel in rat sensory neurons.

Ginsenosides isolated from ginseng are biologically active components. In this study, whole-cell and inside-out configurations of patch clamp technique had been used to test the effect of ginsenosides on the capsaicin-activated channels in cultured small diameter sensory neurons of young rat. Ginsenosides (100 microg/ml) decreased the amplitude of capsaicin-activated currents by 78.2% in whole cell mode. Similarly, ginsenosides decreased capsaicin-activated single-channel activities in a dose-dependent manner in inside-out patches. These results indicate that ginsenosides might directly block capsaicin-activated channels, resulting in attenuation of the currents in rat sensory neurons.

Preparation of monoclonal antibody against ginsenoside Rf and its enzyme immunoassay.

A rapid and sensitive indirect competitive enzyme immunoassay method has been developed for quantitating ginsenoside Rf (Rf) in crude total Panax ginseng saponins and in rat plasma using high titer mouse monoclonal antibody (mAb) raised against a conjugate of Rf and bovine serum albumin (BSA). The isotype of mAb against Rf was IgG3 with a K chain. The presence of Rf inhibited the binding of the mouse anti-Rf mAb to a Rf-BSA solid phase coating antigen. The working range was 0.01-10 ng/assay and detection limits were 20 pg in various ginseng extract fractions or 34 pg in rat plasma per assay. The anti-Rf mAb cross-reacted with ginsenoside Rg2 by 57.5%, but not with other ginsenosides. However, this anti-Rf mAb did not cross-react with BSA or cellubiose, which is a carbohydrate component of Rf. Using this standard curve, we could measure the amount of Rf in ginseng total extract, ginseng total saponins, protopanaxadiol saponins, and propanaxatriol saponins. We could also measure the amount of Rf in rat plasma after the oral administration of Rf and found that Rf reached a maximum level in rat plasma after 16 h. These results indicate that the anti-Rf mAb could be useful for the quantitation of Rf in crude ginseng fractions and in body fluids.