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We used intracellular recording techniques to investigate the actions of clonidine on hypoglossal motoneurons (HMs) in rat brainstem slices. Clonidine (10-100 microM) produced a small (2-6 mV), dose-dependent hyperpolarization in HMs, accompanied by an increase in peak input resistance (RN). It also slowed the time course of the depolarizing 'sag' of the voltage response to constant hyperpolarizing current steps. These effects were mimicked by the alpha2-adrenoceptor (alpha2-AR) agonist guanabenz, but not by the Ih-imidazoline receptor agonists moxonidine or rilmenidine. Recorded in single-electrode voltage clamp mode, clonidine decreased input conductance of HMs and reduced the amplitude of a hyperpolarization-activated inward current (Ih). Clonidine's effect on Ih was three-fold: it shifted the half-activation voltage (V1/2) in the hyperpolarizing direction (by 4.4 +/- 0.7 mV at a dose of 10 microM), decreased the maximal current (by approximately 20%), and slowed the time course of Ih activation at all voltage steps. At the most hyperpolarized potential steps, clonidine slowed activation of Ih dramatically, yielding a striking increase in the activation time constant. The alpha2-AR antagonists yohimbine and idazoxan reduced clonidine's effect on V1/2 and on the Ih activation time course, but neither blocked clonidine's reduction of the maximal current, nor its strong slowing of Ih activation at the most hyperpolarized steps. We were unable to mimic or occlude clonidine's actions with the adenylate cyclase inhibitor SQ 22536 nor with the non-specific protein kinase inhibitor H-7. We conclude that clonidine hyperpolarizes HMs via a reduction of the amount of Ih that is active at rest, and that the response is mediated in part by alpha2-ARs. Some effects of clonidine on these neurons do not appear to be receptor-mediated, and may be due to physical block by clonidine of Ih channels.
Rat brain synaptosomes were isolated to study the effects of protein kinase inhibitors (sphingosine, 1-(5-isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride, N-(6-aminohexyl)-5-chloro-1-naphtalenesulfonamide, staurosporine) on Ca2+-dependent and Ca2+-independent [14C]GABA release. The Ca2+-dependent [14C]GABA release was stimulated by depolarization with a K+-channel blocker, 4-aminopyridine, or high K+ concentration. It has been shown that 4-aminopyridine-evoked [14C]GABA release strongly depends on extracellular Ca2+ while K+-evoked [14C]GABA release only partly decreases in the absence of calcium. The substitution of sodium by choline in Ca2+-free medium completely abolished Ca2+-independent part of K+-evoked [14C]GABA release. So the main effect of 4-aminopyridine is the Ca2+-dependent one while high K+ is able to evoke [14C]GABA release in both a Ca2+-dependent and Na+-dependent manner. In experiments with protein kinase inhibitors, 4-aminopyridine and high K+ concentration were used to study the Ca2+-dependent and the Ca2+-independent [14C]GABA release, respectively. In addition, the Ca2+-independent [14C]GABA release was studied using alpha-latrotoxin as a tool. Pretreatment of synaptosomes with protein kinase inhibitors tested, except of 1-(5-isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride, resulted in a marked inhibition of 4-aminopyridine-stimulated Ca2+-dependent [14C]GABA release. The inhibitory effects of N-(6-aminohexyl)-5-chloro-1-naphtalenesulfonamide and staurosporine on [14C]GABA release were not due to their effects on 4-aminopyridine-promoted 45Ca2+ influx into synaptosomes. Only sphingosine (100 microM) reduced the 45Ca2+ influx. All the inhibitors investigated were absolutely ineffective in blocking the Ca2+-independent [14C]GABA release stimulated by alpha-latrotoxin. Three of them, except for sphingosine, did not affect the Ca2+-independent [14C]GABA release stimulated by high potassium. The inhibitory effect of sphingosine was equal to 30%. Thus, if [14C]GABA release occurred in a Ca2+-independent manner irrespective of whether alpha-latrotoxin or high K+ stimulated this process, it was not inhibited by the drugs decreased the Ca2+-dependent [14C] GABA release. Given the above points it is therefore not unreasonable to assume that the absence of Ca2+ in the extracellular medium created the conditions in which the activation of neurotransmitter release was not accompanied by Ca2+-dependent dephosphorylation of neuronal phosphoproteins, and as a consequence the regulation of exocytotic process was modulated so that the inhibition of protein kinases did not disturb the exocytosis.
We have investigated the vasodilating effects of D-erythro-C2-ceramide (C2-ceramide) in methoxamine-contracted rat mesenteric microvessels. C2-ceramide (10 - 100 microM) caused a concentration-dependent, slowly developing relaxation which reached maximum values after approximately 10 min and partially abated thereafter. Endothelium removal or inhibitors of guanylyl cyclase (3 microM ODQ), protein kinase A (10 microM H7, 1 microM H89) and various types of K(+) channels (10 microM BaCl(2), 3 mM tetraethylammonium, 30 nM charybdotoxin, 30 nM iberiotoxin, 300 nM apamine, 10 microM glibenclamide) had only small if any inhibitory effects against C2-ceramide-induced vasodilation, but some of them attenuated vasodilation by sodium nitroprusside or isoprenaline. A combination of ODQ and charybdotoxin almost completely abolished C2-ceramide-induced vasodilation. A second administration of C2-ceramide caused a detectable but weaker relaxation. L-threo-C2-ceramide (100 microM), which should not be a substrate to ceramide metabolism, had no biphasic time course. The ceramidase inhibitor (1S,2R)-D-erythro-2-(N-myristoylamino)-1-phenyl-1-propanol (100 microM) alone caused some vasodilation, indicating vasodilation by endogenous ceramides, and also hastened relaxation by exogenous C2-ceramide. The late-developing reversal of C2-ceramide-induced vasodilation was absent when alpha-adrenergic tone was removed by addition of 10 microM phentolamine. We conclude that C2-ceramide relaxes rat resistance vessels in an endothelium-independent manner which is prevented only by combined inhibition of guanylyl cyclase and charybdotoxin-sensitive K(+) channels. The vasodilation abates with time partly due to desensitization of the ceramide response and partly due to metabolism of C2-ceramide to an inactive metabolite.
The present study was undertaken to reveal underlying mechanisms of apoptosis in neurons using clonal neuronal cells, ML-DmBG2-c2, derived from Drosophila larval central nervous system 1-(5-Isoquinolinesulfonyl)-2-methylpiperazine (H-7), a protein kinase inhibitor, induced cell death with typical features of apoptosis such as internucleosomal DNA fragmentation, nuclear condensation and apoptotic bodies in the cells. Though H-7 is known to inhibit cAMP-dependent protein kinase (PKA), protein kinase C (PKC), cGMP-dependent protein kinase (PKG), myosin light chain kinase (MLCK), and casein kinase I (CKI), specific inhibitors for these kinases such as H-89, calphostin C, ML-9, or CKI-7 did not induce apoptosis in the cells. Other kinases such as tyrosine kinase. PI3-kinase and Ca2+/CaM kinase II so far examined in the present study were interpreted not to be involved in the apoptotic cascade. Therefore, it is concluded that an H-7-sensitive substance(s) other than these kinases is responsible for the apoptosis in the neuronal cells. Caspase inhibitors prevented apoptosis in the cells treated with H-7. These results suggest that caspase(s) is involved downstream of the H-7-sensitive point in the cascade of the apoptosis.
Chemotaxis and the formation of suicidal neutrophil extracellular traps (suicidal NETosis) are key functions of polymorphonuclear cells (PMNs). Neutrophil extracellular traps in particular are known to be significantly involved in the severity of inflammatory and immunological disorders such as rheumatoid arthritis and Crohn's disease. Therefore, detailed knowledge of PMNs is essential for analyzing the mechanisms involved in, and developing new therapies for, such diseases. To date, no standard method to analyze these cell activities has been established. This study used in vitro live cell imaging to simultaneously observe and analyze PMN functions. To demonstrate this, the effects of phorbol-12-myristat-13-acetat (PMA, 0.1-10 nM), N-formylmethionine-leucyl-phenylalanine (fMLP, 10 nM), and protein kinase C inhibitor 1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H7) on PMN chemotaxis and suicidal NETosis were studied. PMA (1 nM-10 nM) resulted in significant concentration-dependent behavior in chemotaxis and an earlier onset of maximum oxidative burst and NET formation of up to 44%. When adding H7, PMA-triggered PMN functions were reduced, demonstrating that all three functions rely mostly on protein kinase C (PKC) activity, while PKC is not essential for fMLP-induced PMN activity. Thus, the method here described can be used to objectively quantify PMN functions and, especially through the regulation of the PKC pathway, could be useful in further clinical studies of immunological disorders.
The role of protein kinase C (PKC) in mediating the ischemia-induced release of amino acids in the striatum was studied using an in vivo brain dialysis technique in the striatum of spontaneously hypertensive rats (SHRs). Using HPLC combined with fluorescence detection methods, we investigated the concentrations of amino acids in the dialysates produced by 20 min of transient forebrain ischemia. We studied the effects of an inhibitor of PKC, 1-(5-isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride (H7) and another isoquinoline analog (HA1004) with less inhibitory effect on the C kinase in ischemia-induced amino acids release. Bilateral carotid artery occlusion caused a marked reduction in the striatal blood flow by 91 +/- 6%. The extent of the cerebral blood flow (CBF) reduction were essentially the same among H7-, HA1004-, and the vehicle-treated groups. Forebrain ischemia produced a marked increase in glutamate (21-fold of the basal concentration), aspartate (19-fold) and taurine (16-fold). Pretreatment with H7 markedly attenuated the ischemia-in-duced release of these three amino acids to 3, 3 and 4-fold of the basal values, respectively. Increase of gamma-aminobutyric acid (GABA) was also attenuated by H7 (vehicle; 2.46 +/- 1.26 microM, H7; 0.62 +/- 0.75 mM). HA1004 did not affect the release of glutamate, aspartate or GABA during ischemia. The ischemia-induced release of taurine was significantly inhibited by HA1004 but the effect was much smaller than that of H7. These results thus indicate that PKC plays a major role in the ischemia-induced release of amino acids in the striatum of SHR.
Since the alpha and beta isoforms of CaM kinase II are known to be expressed almost exclusively in the brain, we compared the effect of overexpression of the beta isoform of CaM kinase II with that of the alpha isoform. The subcellular distribution of the alpha isoform was different from that of the beta isoform, although the catalytic properties of the alpha and beta isoforms expressed in transfected cells were similar to those of brain CaM kinase II. The alpha isoform was found in the soluble fraction more than in the particulate fraction, whereas most of the beta isoform bound to subcellular structures. In the cell overexpressing alpha and beta isoforms of CaM kinase II, neurite extension was promoted when compared with the morphology of neo transfectants. Neurite outgrowth of cells overexpressing CaM kinase II was further stimulated by the treatment of 1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H-7), a selective but not absolutely specific inhibitor of protein kinase C. The morphological change was rapid and observed within 1 h followed by H-7 treatment. Morphological changes, such as the number of cells with neurites and length of neurites were greater in the beta cells than in the alpha cells. Chelerythrine, a specific inhibitor of protein kinase C, also stimulated the neurite outgrowth of these cells. Some substrates of CaM kinase II related to neurite outgrowth were detected in cells overexpressing CaM kinase II stimulated with H-7. These results suggest that CaM kinase H and protein kinase C play an important role in the control of cell change, and that the subcellular distribution of CaM kinase II is important for regulating cellular functions efficiently.
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