The Effects of Protein Kinase C Beta II Peptide Modulation on Superoxide Release in Rat Polymorphonuclear Leukocytes

Phorbol 12-myristate 13-acetate (PMA; a diacylglycerol mimetic) is known to augment polymorphonuclear leukocyte (PMN) superoxide (SO) release via protein kinase C (PKC) activation. However, the role of PKC beta II (βII) mediating this response is not known. It’s known that myristic acid (myr-) conjugation facilitates intracellular delivery of the cargo sequence, and that putative PKCβII activator and inhibitor peptides work by augmenting or attenuating PKCβII translocation to cell membrane substrates (e.g. NOX-2). Therefore, we hypothesize that myr- conjugated PKCβII peptide-activator (N-myr-SVEIWD; myr-PKCβ+) would increase PMA-induced rat PMN SO release, whereas, myr-PKCβII peptide-inhibitor (N-myr-SLNPEWNET; myr-PKCβ-) would attenuate this response compared to non-drug treated controls. Rat PMNs (5x106) were incubated for 15min at 370C in the presence/absence of myr-PKCβ+/- (20 μM) or SO dismutase (SOD;10μg/mL; n=8) as positive control. PMA (100nM) induced PMN SO release was measured spectrophotometrically at 550nm via reduction of ferricytochrome c for 390 sec. PMN SO release increased absorbance to 0.39±0.04 in non-drug treated controls (n=28), and 0.49±0.05 in myr-PKCβ+(n=16). This response was significantly increased from 180 seconds to 240 seconds (p\u3c0.05). By contrast, myr-PKCβ- (0.26±0.03; n=14) significantly attenuated PMA-induced SO release compared to non-drug controls and myr-PKCβ+ (p\u3c0.05). SOD-treated samples showed \u3e90% reduction of PMA-induced SO release and was significantly different from all groups (p\u3c0.01). Cell viability ranged between 94± to 98±2% in all groups as determined by 0.2% trypan blue exclusion. Preliminary results suggest that myr-PKCβ- significantly attenuates PMA-induced SO release, whereas myr-PKCβ+ significantly augments PMA-induced SO release, albeit transiently. Additional dose response and western blot experiments are planned with myr-PKCβ+/- in PMA-induced PMN SO release assays. This research was supported by the Department of Bio-Medical Sciences and the Division of Research at PCOM and by Young Therapeutics, LLC

Protein Kinase C Beta II Peptide Inhibitor Elicits Robust Effects on Attenuating Myocardial Ischemia/Reperfusion Injury

Reperfusion injury contributes to myocardial tissue damage following a heart attack partly due to the generation of reactive oxygen species (ROS) upon cardio-angioplasty. Protein kinase C beta II (PKCβII) inhibition during reperfusion with peptide inhibitor (N-myr-SLNPEWNET; PKCβII-) decreases ROS release and leukocyte infiltration in rat hind-limb and myocardial ischemia/reperfusion (I/R) studies, respectively. However, the role of activating PKCβII during reperfusion has not been previously determined. In this study, we hypothesize that myristoylated (myr)-PKCβII- will decrease infarct size and improve post-reperfused cardiac function compared to untreated controls, whereas PKCβII peptide activator (N-myr-SVEIWD; myr-PKCβII+) will show no improvement compared to control. Myristoylation of PKCβII peptides facilitate their entry into the cell in order to affect PKCβII activity by either augmenting or attenuating its translocation to cell membrane proteins, such as NOX-2. Isolated perfused rat hearts were subjected to global I(30min)/R(50min) and infused with myr-PKCβII+ (20μM; n=9), myr-PKCβII- (20µM; n=8), or plasma (control; n=9) at reperfusion. Hearts were frozen (-20oC), sectioned and stained using 1% triphenyltetrazolium chloride to differentiate necrotic tissue. The measurement of Left ventricular (LV) cardiac function was determined using a pressure transducer and infarct size was calculated as percent dead tissue vs. total heart tissue weight. Myr-PKCβII- significantly improved LV end-diastolic pressure 37±7 mmHg compared to control (58±5; p\u3c0.01) and myr-PKCβII+ (58±4; p\u3c0.01). Myr-PKCβII- significantly reduced infarct size to 14±3% compared to control (26±5%; p\u3c0.01), while myr-PKCβII+ (25±3%) showed no difference. The data indicate that myr-PKCβII- may be a putative treatment to reduce myocardial reperfusion injury when given to heart attack patients during cardio-angioplasty. Future studies are planned to determine infarct size by Image J analysis