Enhanced PKC beta II translocation and PKC beta II-RACK1 interactions in PKC epsilon-induced heart failure: a role for RACK1.

Recent investigations have established a role for the beta II-isoform of protein kinase C (PKC beta II) in the induction of cardiac hypertrophy and failure. Although receptors for activated C kinase (RACKs) have been shown to direct PKC signal transduction, the mechanism through which RACK1, a selective PKC beta II RACK, participates in PKC beta II-mediated cardiac hypertrophy and failure remains undefined. We have previously reported that PKC epsilon activation modulates the expression of RACKs, and that altered epsilon-isoform of PKC (PKC epsilon)-RACK interactions may facilitate the genesis of cardiac phenotypes in mice. Here, we present evidence that high levels of PKC epsilon activity are commensurate with impaired left ventricular function (dP/dt = 6,074 +/- 248 mmHg/s in control vs. 3,784 +/- 269 mmHg/s in transgenic) and significant myocardial hypertrophy. More importantly, we demonstrate that high levels of PKC epsilon activation induce a significant colocalization of PKC beta II with RACK1 (154 +/- 7% of control) and a marked redistribution of PKC beta II to the particulate fraction (17 +/- 2% of total PKC beta II in control mice vs. 49 +/- 5% of total PKC beta II in hypertrophied mice), without compensatory changes of the other eight PKC isoforms present in the mouse heart. This enhanced PKC beta II activation is coupled with increased RACK1 expression and PKC beta II-RACK1 interactions, demonstrating PKC epsilon-induced PKC beta II signaling via a RACK1-dependent mechanism. Taken together with our previous findings regarding enhanced RACK1 expression and PKC epsilon-RACK1 interactions in the setting of cardiac hypertrophy and failure, these results suggest that RACK1 serves as a nexus for at least two isoforms of PKC, the epsilon-isoform and the beta II-isoform, thus coordinating PKC-mediated hypertrophic signaling.

PKCepsilon modulates NF-kappaB and AP-1 via mitogen-activated protein kinases in adult rabbit cardiomyocytes.

We have previously shown that protein kinase C (PKC)-epsilon, nuclear factor (NF)-kappaB, and mitogen-activated protein kinases (MAPKs) are essential signaling elements in ischemic preconditioning. In the present study, we examined whether activation of PKCepsilon affects the activation of NF-kappaB in cardiac myocytes and whether MAPKs are mediators of this signaling event. Activation of PKCepsilon (+108% above control) in adult rabbit cardiomyocytes to a degree that has been previously shown to protect myocytes against hypoxic injury increased the DNA-binding activity of NF-kappaB (+164%) and activator protein (AP)-1 (+127%) but not that of Elk-1. Activation of PKCeta did not have an effect on these transcription factors. Activation of PKCepsilon also enhanced the phosphorylation activities of the p44/p42 MAPKs and the p54/p46 c-Jun NH(2)-terminal kinases (JNKs). PKCepsilon-induced activation of NF-kappaB and AP-1 was completely abolished by inhibition of the p44/p42 MAPK pathway with PD98059 and by inhibition of the p54/p46 JNK pathway with a dominant negative mutant of MAPK kinase-4, indicating that both signaling pathways are necessary. Taken together, these data identify NF-kappaB and AP-1 as downstream targets of PKCepsilon, thereby establishing a molecular link between activation of PKCepsilon and activation of NF-kappaB and AP-1 in cardiomyocytes. The results further demonstrate that both the p44/p42 MAPK and the p54/p46 JNK signaling pathways are essential mediators of this event.

Microvascular endothelial cell control of peripheral vascular resistance during sepsis.

OBJECTIVE: To determine the endothelial-dependent control of decreased peripheral vascular resistance in skeletal muscle microvessels during evolving sepsis. MATERIALS AND INTERVENTIONS: Acute (4 hours, n=7), established (24 hours, n=7), or chronic (72 hours, n=8) infection was induced in Sprague-Dawley rats (150-175 g) by injecting Escherichia coli and Bacteroides fragilis (1 x 10(9) colony-forming units for both) into a subcutaneous sponge. Control animals were injected with an isotonic sodium chloride solution and analyzed at the same time points: (n=6-8 per group). Dilation in response to the topically applied endothelial-dependent agonist acetylcholine (ACH) (1 x 10(-9) to 1 x 10(-5) mol/L) was measured in inflow first-order (A1) and precapillary fourth-order (A4) arterioles in cremaster muscle in vivo with videomicroscopy. Acetylcholine dose-response curves were used to determine vascular reactivity by calculating the concentration of ACH necessary to elicit 50% of the maximal dilator response. MAIN OUTCOME MEASURES: In vivo reactivity of striated muscle microvessels to the dilation agonist ACH during acute, established, and chronic infection. RESULTS: A1 vessels were unresponsive to all doses of ACH at all time points. A4 vessels showed an increased dilator response during short-term treatment, which deteriorated over time to depressed dilation during chronic infection. CONCLUSIONS: Precapillary A4 vessels have increased dilator reactivity during early sepsis, which progresses to depressed levels with chronic infection. A1 microvessels remain dilated and are not substantially influenced by endothelial dilator mechanisms initiated by ACH. Maximum dilation of the large A1 vessels appears to contribute to the decrease in peripheral vascular resistance noted during systemic infection.

Pentoxifylline attenuates pulmonary macromolecular leakage after intestinal ischemia-reperfusion.

OBJECTIVE: To assess the effects of pentoxifylline posttreatment on hemodynamic variables and acute pulmonary injury in the rat intestinal ischemia-reperfusion (I-R) model, using a recently developed method of fluorescent intravital pulmonary videomicroscopy. DESIGN: Anesthetized male Sprague-Dawley rats were cannulated for measurement of mean arterial pressure, heart rate, cardiac output, arterial blood gas values, and hematocrit. Rats underwent isolation of the superior mesenteric artery for intestinal I-R (45 minutes of ischemia, 120 minutes of reperfusion) and right lateral thoracotomy for pulmonary videomicroscopy. Epi-illumination fluorescent videomicroscopy was used to quantitate leakage of intravascular fluorescently labeled albumin into alveoli, while hemodynamic variables were simultaneously recorded. In the treatment groups, pentoxifylline was administered after 30 minutes of intestinal ischemia. Data (mean +/- SEM) were recorded before and during intestinal ischemia and after reperfusion at 30-minute intervals. MAIN OUTCOME MEASURE: The appearance of fluorescently labeled albumin into alveolar airspaces was quantitated off-line by computer and reported as the alveolar leak index. RESULTS: Intestinal I-R caused alveolar macromolecular leakage, marked by a 300% +/- 48% increase from baseline (P < .05) in the alveolar leak index. Intestinal I-R also produced systemic hemodynamic instability demonstrated by a decrease in the mean arterial blood pressure (-36% +/- 5% vs baseline, P < .05) and cardiac output (-42% +/- 6% vs baseline, P < .05), metabolic acidosis (final arterial pH of 7.17, P < .05 vs initial pH), and a 2.3-fold increase in the intravenous fluid requirement when compared with that in sham animals (P < .05). Treatment with pentoxifylline 30 minutes after intestinal ischemia attenuated pulmonary macromolecular leakage (P < .05 vs nontreated I-R) and reduced the decrease in cardiac output (-15% +/- 7% vs baseline, not statistically significant). Pentoxifylline treatment had no effect on the mean arterial blood pressure, heart rate, metabolic acidosis, or intravenous fluid requirement. CONCLUSIONS: Pentoxifylline reduces alveolar capillary membrane injury and subsequent protein leakage and improves cardiac output when administered after 30 minutes of intestinal ischemia. These data suggest that pentoxifylline may be a possible candidate as a future therapy for acute pulmonary dysfunction. Further studies in human patients are necessary.