The authors show by illustration that procedures used to validate the reliability of single-concentration high-throughput screens such as the signal window and Z′ factor do not ensure sufficient reliability in potency estimates from concentration response assays. They develop the minimum significant ratio as a statistical parameter to characterize the fold change between 2 compounds run in the same experiment that can be considered a real difference and use this parameter to characterize the reliability of the assay. They adapt methods described by Bland and Altman to develop a simple set of 2 experiments to estimate the minimum significant ratio and show that this protocol can identify assays that lack reproducibility. The methods are then extended to validate the equivalency of the same assay run by multiple laboratories. (Journal of Biomolecular Screening 2006:253-261)
Mixed lineage kinase 7 (MLK7) is a mitogen-activated protein kinase kinase kinase (MAPKKK) that activates the pro-apoptotic signaling pathways p38 and JNK. A library of potential kinase inhibitors was screened, and a series of dihydropyrrolopyrazole quinolines was identified as highly potent inhibitors of MLK7 in vitro catalytic activity. Of this series, an aryl-substituted dihydropyrrolopyrazole quinoline (DHP-2) demonstrated an IC 50 of 70 nM for inhibition of pJNK formation in COS-7 cell MLK7/JNK co-transfection assays. In stimulated cells, DHP-2 at 200 nM or MLK7 small interfering RNA completely blocked anisomycin and UV induced but had no effect on interleukin-1 or tumor necrosis factor-␣-induced p38 and JNK activation. Additionally, the compound blocked anisomycin and UV-induced apoptosis in COS-7 cells. Heart tissue homogenates from MLK7 transgenic mice treated with DHP-2 at 30 mg/kg had reduced JNK and p38 activation with no apparent effect on ERK activation, demonstrating that this compound can be used to block MLK7-driven MAPK pathway activation in vivo. Taken together, these data demonstrate that MLK7 is the MAPKKK required for modulation of the stressactivated MAPKs downstream of anisomycin and UV stimulation and that DHP-2 can be used to block MLK7 pathway activation in cells as well as in vivo.The mitogen-activated protein kinases (MAPK) 1 are a highly conserved family of signal transduction molecules that transmits extracellular signals from the membrane to the nucleus. There are three major branches of MAPK signaling that include ERK, c-Jun N-terminal kinase (JNK) and p38. The JNK and p38 branches of the MAPK family are activated by stress stimuli including cytokines, osmotic stress, mitogens, UV irradiation, chemotherapeutic agents, and anisomycin (1, 2). There are three kinases that form a MAPK signaling module where a MAPK is activated by a MAPK kinase (MAPKK), which in turn is regulated by a MAPKK kinase (MAPKKK) (Fig. 1). The upstream activation of JNK and p38 is complex, allowing for activation of this pathway in multiple cells and by multiple stimuli. Cellular and receptor specificity of the pathway is conferred by protein-protein interactions where the MAPK and a MAPKK assemble with a specific MAPKKK on scaffold proteins such as JNK-interacting protein (3, 4) or -arrestin (5). The resulting signaling module acts as a bridge joining the appropriate receptor to the downstream effectors, enabling activation of the stress-activated MAPK.The most distal point at which signal and cell specificity for JNK and p38 activation is conferred is at the MAPKKK level. Mixed lineage kinases (MLKs) are a family of MAPKKKs activating JNK and p38. There are currently seven mammalian kinases belonging to the MLK family that have recently been reviewed (6, 7). These kinases can be divided into three subclasses based on sequence similarity and domain structure, and they include MLK1-4, dual leucine zipper kinases, and the zipper sterile ␣-motif kinases (ZAKs). Although much is known about the mechanisms re...
Glibenclamide has been shown to block ATP-dependent K+ channels in the heart and prevent the shortening of cardiac action potentials caused by hypoxia in vitro. The present study examines the ability of glibenclamide to modify the effect of acute ischaemia on monophasic action potential duration in pentobarbital-anaesthetized rabbits, and on monophasic action potential duration and ventricular fibrillation threshold in pentobarbital-anaesthetized dogs. Left ventricular endocardial monophasic action potential duration was measured using a contact electrode catheter, and ventricular fibrillation threshold was measured by the single pulse method. Ischaemia was produced in rabbits by occluding the circumflex coronary for 5 min and in dogs by occluding the left anterior descending coronary artery for 40 min. In rabbits, glibenclamide (0.3-3 mg/kg, i.v.) had no effect on baseline monophasic action potential duration, but attenuated action potential shortening during ischaemia in a dose-related manner. In dogs, monophasic action potential duration did not shorten during ischaemia in the vehicle group, but tended to increase in the glibenclamide group (0.5 mg/kg, i.v.) both before and during ischaemia (7 +/- 5% and 14 +/- 8%, respectively, NS). Likewise, ventricular effective refractory period was significantly increased by glibenclamide prior to ischaemia (5 +/- 1%). Ventricular fibrillation threshold tended to increase during 40 min of ischaemia in vehicle-treated dogs (40 +/- 29%, NS), but was unchanged during ischaemia in the glibenclamide-treated dogs.(ABSTRACT TRUNCATED AT 250 WORDS)
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