• The Journal of Korean Medicine
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• v.19 no.2
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• pp.36-49
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• 1998

HERBA SAURURI (HS) has been known to use antiinflammatory drug. To investigated the mechanism of HS-induced NO synthesis, I evaluated the ability of protein kinase C (PKC) inhibitors such as staurosporine (STSN) or polyymyxin B to block HS-induced effects. HS alone had only a small effect, whereas in combination with $rIFN-{\gamma}$, markedly increased NO synthesis in a dose dependent manner. STSN and polymyxin B decreased NO synthesis, which had been induced by $rIFN-{\gamma}$, plus HS. Furthermore, prolonged incubation of the cells with phorbol ester, which down-regulates PKC activity abolished synergistic cooperative effect of HS with $rIFN-{\gamma}$ on NO synthesis. STSN and Polymyxin B potently inhibited HS-induced $TNF-{\alpha}$ secretion by $rIFN-{\gamma}$ plus HS. However, $rIFN-{\gamma}$ plus $TNF-{\alpha}-induced$ NO synthesis was not blocked by STSN or polymyxin B. On the other hand, tyrosine kinase inhibitor, genistein, blocked the NO synthesis and $TNF-{\alpha}$ secretion by $rIFN-{\gamma}$ plus HS. In conlusion, the present results strongly suggest that the capacity of HS to increase NO synthesis from $rIFN-{\gamma}-primed$ macrophages is the result of HS-induced $TNF-{\alpha}$ secretion via the signal transduction pathway of PKC and tyrosine kinase.

• The Korean Journal of Physiology and Pharmacology
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• v.15 no.3
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• pp.143-147
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• 2011

Defensins, cysteine-rich cationic polypeptides released from neutrophils, are known to have powerful antimicrobial properties. In this study, we sacrificed 30 rats to investigate the effects of ${\alpha}$-defensin 1 on detrusor muscle contractions in isolated rat bladder. From the experiments we found relaxing effects of ${\alpha}$-defensin 1 on the contractions induced by phenylephrine (PE) but not by bethanechol (BCh) in the detrusor smooth muscles. To determine the mechanisms of the effects of ${\alpha}$-defensin 1, the changes of effects on PE-induced contraction by ${\alpha}$-defensin 1 pretreatment were observed after pretreatment of Rho kinase inhibitor (Y-27632), protein kinase C (PKC) inhibitor (Calphostin C), potent activator of PKC (PDBu; phorbol 12,13-dibutyrate), and NF-${\kappa}B$ inhibitors (PDTC; pyrrolidinedithiocarbamate and sulfasalazine). The contractile responses of PE ($10^{-9}{\sim}10^{-4}$ M) were significantly decreased in some concentrations of ${\alpha}$-defensin 1 ($5{\times}10^{-9}$ and $5{\times}10^{-8}$ M). When strips were pretreated with NF-kB inhibitors (PDTC and sulfasalazine; $10^{-7}{\sim}10^{-6}$ M), the relaxing responses by ${\alpha}$-defensin 1 pretreatment were disappeared. The present study demonstrated that ${\alpha}$-defensin 1 has relaxing effects on the contractions of rat detrusor muscles, through NF-${\kappa}B$ pathway. Further studies in vivo are required to clarify whether ${\alpha}$-defensin 1 might be clinically related with bladder dysfunction by inflammation process.

• Journal of Ginseng Research
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• v.44 no.2
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• pp.274-281
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• 2020

Background: Ultraviolet (UV) goes through the epidermis and promotes release of inflammatory cytokines in keratinocytes. Granulocyte-macrophage colony-stimulating factor (GM-CSF), one of the keratinocyte-derived cytokines, regulates proliferation and differentiation of melanocytes. Extracellular signal-regulated kinase (ERK1/2) and protein kinase C (PKC) signaling pathways regulate expression of GM-CSF. Based on these results, we found that ginsenoside Rh3 prevented GM-CSF production and release in UV-B-exposed SP-1 keratinocytes and that this inhibitory effect resulted from the reduction of PKCδ and ERK phosphorylation. Methods: We investigated the mechanism by which ginsenoside Rh3 from Panax ginseng inhibited GM-CSF release from UV-B-irradiated keratinocytes. Results: Treatment with 12-O-tetradecanoylphorbol-13-acetate (TPA) or UV-B induced release of GM-CSF in the SP-1 keratinocytes. To elucidate whether the change in GM-CSF expression could be related to PKC signaling, the cells were pretreated with H7, an inhibitor of PKC, and irradiated with UV-B. GM-CSF was decreased by H7 in a dose-dependent manner. When we analyzed which ginsenosides repressed GM-CSF expression among 15 ginsenosides, ginsenoside Rh3 showed the largest decline to 40% of GM-CSF expression in enzyme-linked immunosorbent assay. Western blot analysis showed that TPA enhanced the phosphorylation of PKCδ and ERK in the keratinocytes. When we examined the effect of ginsenoside Rh3, we identified that ginsenoside Rh3 inhibited the TPA-induced phosphorylation levels of PKCδ and ERK. Conclusion: In summary, we found that ginsenoside Rh3 impeded UV-B-induced GM-CSF production through repression of PKCδ and ERK phosphorylation in SP-1 keratinocytes.

• Journal of Pharmacopuncture
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• v.16 no.4
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• pp.36-42
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• 2013

Objectives: Shengmaisan (SMS) is a traditional Chinese medicine prescription widely used for the treatment of diverse organs in Korea. The interstitial cells of Cajal (ICCs) are pacemaker cells that play an important role in the generation of coordinated gastrointestinal (GI) motility. We have aimed to investigate the effects of SMS in the ICCs in the mouse small intestine. Methods: To dissociate the ICCs, we used enzymatic digestions from the small intestine in a mouse. After that, the ICCs were identified immunologically by using the anti-c-kit antibody. In the ICCs, the electrophysiological whole-cell patch-clamp configuration was used to record pacemaker potentials in the cultured ICCs. Results: The ICCs generated pacemaker potentials in the mouse small intestine. SMS produced membrane depolarization with concentration-dependent manners in the current clamp mode. Pretreatment with a $Ca^{2+}$ free solution and thapsigargin, a $Ca^{2+}$-ATPase inhibitor in the endoplasmic reticulum, stopped the generation of the pacemaker potentials. In the case of $Ca^{2+}$-free solutions, SMS induced membrane depolarizations. However, when thapsigargin in a bath solution was applied, the membrane depolarization was not produced by SMS. The membrane depolarizations produced by SMS were inhibited by U-73122, an active phospholipase C (PLC) inhibitors. Furthermore, chelerythrine and calphostin C, a protein kinase C (PKC) inhibitors had no effects on SMS-induced membrane depolarizations. Conclusions: These results suggest that SMS might affect GI motility by modulating the pacemaker activity through an internal $Ca^{2+}$- and PLC-dependent and PKC-independent pathway in the ICCs.

• Biomedical Science Letters
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• v.15 no.4
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• pp.287-293
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• 2009

Phospholipase D (PLD) is an enzyme hydrolyzing phosphatidylcholine to phosphatidic acid (PA) and choline. We investigated the involvement of PLD1 in the uptake of norepinephrine (NE) in PC12 cells, pheochromocytoma cells. NE uptake was specific in PC12 cells because nomifensine, a specific blocker of NE transporter, blocked NE uptake. Inhibition of PLD function in PC12 cells by the treatment of butanol suppressed the NE uptake. In contrast, overexpression of PLD1 in PC12 cells increased NE uptake efficiently. These results suggest that PLD activity is involved in NE uptake. We explored the action mechanism of PLD in NE uptake. PA phosphatase inhibitor, propranolol, blocks the formation of PKC activator diacylglycerol from PA. Propranolol treatment to PC12 cells blocked dramatically the uptake of NE. Specific PKC inhibitors, GF109203X and Ro31-8220, blocked NE uptake. Taken together, we suggest for the first time that PLD1 activity is involved in NE uptake via the activation of PKC.

• Biomedical Science Letters
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• v.23 no.1
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• pp.44-47
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• 2017

S100A8 and S100A9 are associated with myeloid cell differentiation, chemotactic activities, adhesion of neutrophils, and apoptosis. In this study, we investigated the contribution of S100A8 and S100A9 to differentiation of the human eosinophilic leukemia cell line, EoL-1. S100A8 and S100A9 increased the number of vacuole per one cell and the protein expression of EPO and MBP. Rottlerin, an inhibitor of protein kinase C delta ($PKC{\delta}$), inhibited the EoL-1 cell differentiation induced by S100A8 and S100A9. These results suggest that S100A8 and S100A9 may regulate the differentiation of eosinophilic progenitors. Moreover, these findings may shed light on elucidation of eosinophil differentiation due to S100 proteins.

• BMB Reports
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• v.45 no.11
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• pp.659-664
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• 2012

Extracellular superoxide dismutase (EC-SOD) overexpression modulates cellular responses such as tumor cell suppression and is induced by $IFN{\gamma}$. Therefore, we examined the role of EC-SOD in $IFN{\gamma}$-mediated tumor cell suppression. We observed that the dominant-negative protein kinase C delta ($PKC{\delta}$) suppresses $IFN{\gamma}$-induced EC-SOD expression in both keratinocytes and melanoma cells. Our results also showed that $PKC{\delta}$-induced EC-SOD expression was reduced by pretreatment with a PKC-specific inhibitor or a siRNA against $PKC{\delta}$. $PKC{\delta}$-induced EC-SOD expression suppressed cell proliferations by the up-regulation of p21 and Rb, and the downregulation of cyclin A and D. Finally, we demonstrated that increased expression of EC-SOD drastically suppressed lung melanoma proliferation in an EC-SOD transgenic mouse via p21 expression. In summary, our findings suggest that $IFN{\gamma}$-induced EC-SOD expression occurs via activation of $PKC{\delta}$. Therefore, the upregulation of EC-SOD may be effective for prevention of various cancers, including melanoma, via cell cycle arrest.

• Biomedical Science Letters
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• v.19 no.2
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• pp.83-89
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• 2013

Parkin is a protein known to have tumor suppressive functions. In a previous study, we determined that Parkin expression restores susceptibility to TNF-${\alpha}$-induced death in HeLa cells. ${\beta}$-catenin is a key protein in the Wnt signaling pathway and excessive activation of the ${\beta}$-catenin pathway can promote cancer development. In this study, we found that ${\beta}$-catenin levels decreased dramatically in Parkin over-expressing HeLa cells treated with TNF-${\alpha}$. We used chemical inhibitors of cell signaling pathways to identify the signaling molecules involved in ${\beta}$-catenin down-regulation. Our results indicate that the PKC inhibitor (RO-31-7549) blocked parkin-induced down-regulation of ${\beta}$-catenin. We also show that Parkin-induced decrease in cell viability in TNF-${\alpha}$-treated HeLa cells is alleviated upon treatment with a PKC inhibitor. Taken together, these results suggest the possibility that ${\beta}$-catenin reduction may be associated with Parkin-induced decrease of cell viability in TNF-${\alpha}$ treated HeLa cells.

• The Korean Journal of Physiology and Pharmacology
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• v.21 no.6
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• pp.687-694
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• 2017

Plumbagin, a hydroxy 1,4-naphthoquinone compound from plant metabolites, exhibits anticancer, antibacterial, and antifungal activities via modulating various signaling molecules. However, its effects on vascular functions are rarely studied except in pulmonary and coronary arteries where NADPH oxidase (NOX) inhibition was suggested as a mechanism. Here we investigate the effects of plumbagin on the contractility of skeletal artery (deep femoral artery, DFA), mesenteric artery (MA) and renal artery (RA) in rats. Although plumbagin alone had no effect on the isometric tone of DFA, $1{\mu}M$ phenylephrine (PhE)-induced partial contraction was largely augmented by plumbagin (${\Delta}T_{Plum}$, 125% of 80 mM KCl-induced contraction at $1{\mu}M$). With relatively higher concentrations (>$5{\mu}M$), plumbagin induced a transient contraction followed by tonic relaxation of DFA. Similar biphasic augmentation of the PhE-induced contraction was observed in MA and RA. VAS2870 and GKT137831, specific NOX4 inhibitors, neither mimicked nor inhibited ${\Delta}T_{Plum}$ in DFA. Also, pretreatment with tiron or catalase did not affect ${\Delta}T_{Plum}$ of DFA. Under the inhibition of PhE-contraction with L-type $Ca^{2+}$ channel blocker (nifedipine, $1{\mu}M$), plumbagin still induced tonic contraction, suggesting $Ca^{2+}$-sensitization mechanism of smooth muscle. Although ${\Delta}T_{Plum}$ was consistently observed under pretreatment with Rho A-kinase inhibitor (Y27632, $1{\mu}M$), a PKC inhibitor (GF 109203X, $10{\mu}M$) largely suppressed ${\Delta}T_{Plum}$. Taken together, it is suggested that plumbagin facilitates the PKC activation in the presence of vasoactive agonists in skeletal arteries. The biphasic contractile effects on the systemic arteries should be considered in the pharmacological studies of plumbagin and 1,4-naphthoquinones.

• Molecular & Cellular Toxicology
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• v.3 no.4
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• pp.215-221
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• 2007

Neuronal cell toxicity induced by decreased nitric oxide (NO) production may be caused by modulation of constitutive neuronal NO synthase (nNOS). We used lead acetate ($Pb^{2+}$) to modulate physiological NO release and the related pathways of protein kinases like PKC, CaM-KII, and PKA in CATH.a cells, a dopaminergic cell line that has constitutive nNOS activity. In the cells treated with $Pb^{2+}$, cell viability and modulation (phosphorylation) levels of nNOS were determined by MTT assay and Western blot analysis, respectively. nNOS reductase activity (cytochrome c) was also assessed to compare the phosphorylation site-specific nNOS activity. nNOS activity was also determined by NADPH consumption rates. $Pb^{2+}$ treatment alone increased the phosphorylation of nNOS with decreased reductase activity. The phosphorylation levels increased markedly with decreased nNOS reductase activity, when $Pb^{2+}$ was combined with inhibitors for two (PKC and CaM-KII) or three (PKA, PKC and CaM-KII) protein kinases. Interestingly, when the cells were exposed to $Pb^{2+}$ plus PKC or CaM-KII inhibitor, the nNOS was phosphorylated strongly with the lowest activity. However, the levels of phosphorylated nNOS following $Pb^{2+}$ treatment decreased significantly after combined treatment with the PKA inhibitor, and $Pb^{2+}$-induced suppression of reductase activity did not occur. These results demonstrate that physiological NO release in the neuronal cells exposed to $Pb^{2+}$ can be decreased by PKA-mediated nNOS phosphorylation that may be caused by interactions with PKC and/or CaM-KII.