Polymorphonuclear leukocyte (PMN) superoxide (SO) production by NADPH oxidase (NOX‐2) activation contributes to myocardial ischemia‐reperfusion (I/R) injury. Protein kinase C beta‐II (PKC βII) is a principal mediator of NOX‐2 activation via phosphorylation of NOX‐2 cytosolic protein p47phox. Phorbol 12‐myristate 13‐acetate (PMA) is a known broad‐spectrum PKC agonist that induces PMN SO release. In prior studies, selective PKCβII inhibition with myristoylated PKCβII peptide inhibitor (N‐myr‐SLNPEWNET; myr‐PKCβII‐) attenuated PMA‐induced PMN SO release and myocardial I/R injury in a dose‐dependent manner. However, the role of myristoylation mediating the inhibitory effects of myr‐PKCβII‐ on PMN SO release needs to be determined. Therefore, we aim to confirm the role of PKCβII by using myristoylated PKCβII peptide activator (N‐myr‐SVEIWD; myr‐PKCβII+) and myr‐PKCβII‐ that influence PKCβII translocation. Whereas, myr‐scrambled PKCβII‐ (N‐myr‐WNPESLNTE; myr‐PKCβII‐scram) is a control for myristoylation. We hypothesize that myr‐PKCβII+ should augment, myr‐PKCβII‐should attenuate, and myr‐PKCβII‐scram should have no effect on PMA‐induced PMN SO release compared to non‐treated and unconjugated peptide controls. PMNs (5×106) isolated from male Sprague‐Dawley rats (~400g) were incubated for 15 min at 37°C in the presence/absence of SO dismutase (SOD; 10μg/mL, positive control), unconjugated PKCβII+/− (20 μM), myr‐PKCβII+/− (20 μM), or myr‐PKCβII‐scram (20 μM). SO release was evaluated by the absorbance change (at 550 nm) via ferricytochrome c reduction after PMA stimulation (100 nM) for 390 sec. Data were analyzed by ANOVA using Bonferroni‐Dunn post‐hoc analysis. Myr‐PKCβII‐ significantly attenuated PMA‐induced PMN SO release (0.29±0.02; n=36; p<0.05) when compared to myr‐PKCβII+ (0.42±0.03; n=29), myr‐PKCβII‐scram (0.53±0.05; n=10), and non‐treated controls (0.41±0.02; n=55). Unconjugated PKCβII+ (0.41±0.04; n=16) and PKCβII‐(0.40±0.04; n=28) were similar to non‐treated controls. SOD (n=8) significantly reduced SO release by 94±7% compared to all groups (p<0.01). Cell viability determined by 0.2% trypan blue exclusion was similar in all groups, 94±2%. Unexpectedly, myr‐PKCβII‐scram rather than myr‐PKCβII+ PMNs exhibited the highest PMA‐induced PMN SO release but was not significantly different from untreated controls. Additional experiments will determine whether myr‐PKCβII‐scram significantly enhances SO release. Results suggest myr‐ conjugation improved myr‐PKCβII‐ delivery compared to unconjugated PKCβII‐ but does not contribute to the inhibitory effects of PMA‐induced PMN SO release. Therefore, myr‐PKCβII‐ may be an effective therapeutic intervention to limit inflammation‐induced I/R injury.
Support or Funding Information
This research was supported by the Division of Research, Department of Biomedical Sciences, and the Center for Chronic Disorders of Aging at Philadelphia College of Osteopathic Medicine. Current license is supported by Young Therapeutics, LLC.
multivariable regressions with generalized linear models with gamma distributions. All costs were adjusted to reflect 2019 U.S. dollars using the consumer price index.RESULTS: In a cohort of 13,661 men, there were 80% (n [10,926) receiving ADT monotherapy, 8% (n[1,084) receiving novel hormonal treatments, and 12% (n[1,651) receiving non-hormonal treatments.
Protein kinase C beta II (PKCβII) activates polymorphonuclear leukocyte (PMN) superoxide (SO) production via NADPH oxidase (NOX-2) phosphorylation to exacerbate myocardial ischemia/reperfusion (I/R) injury. In prior studies, myristoylation (myr) of PKCβII peptide inhibitor (N-myr-SLNPEWNET; myr-PKCβII-), which disrupts PKCβII translocation/phosphorylation of NOX-2, was shown to dose-dependently attenuate PMN SO release induced by phorbol 12-myristate 13-acetate (PMA), a broad-spectrum PKC agonist. However, the role of myr on the inhibitory effects of myr-PKCβII- has yet to be elucidated. We hypothesized that myr-PKCβII peptide activator (N-myr-SVEIWD; myr-PKCβII+) would augment, myr-PKCβII- would attenuate, and scrambled myr-PKCβII- (N-myr-WNPESLNTE; myr-PKCβII-scram), a control for myr, would not affect PMA-induced PMN SO release compared to unconjugated peptides and nontreated controls. Rat PMNs (5х10
6
) were incubated for 15 min at 37
o
C in the presence/absence of SO dismutase (SOD; 10 μg/mL), unconjugated PKCβII+/-, myr-PKCβII+/-, or myr-PKCβII-scram (all 20 μM). SO release was measured by the change in absorbance at 550 nm via ferricytochrome
c
reduction after PMA (100 nM) stimulation for 390 sec. Data were analyzed by ANOVA using Student-Newman-Keuls post hoc analysis. Myr-PKCβII- significantly attenuated SO release (0.30±0.02; n=27; p<0.05) compared to nontreated controls (0.46±0.01; n=73), myr-PKCβII+ (0.46±0.03; n=25), unconjugated PKCβII+ (0.43±0.04; n=15), PKCβII- (0.43±0.02; n=22) and myr-PKCβII-scram (0.65±0.04; n=22). SOD (n=8), which rapidly converts SO to H
2
O
2
, significantly reduced absorbance by 94±7%, indicating that absorbance increased mainly due to PMA stimulation. Cell viability (trypan blue exclusion) was similar in all groups (94±2%). Unexpectedly, myr-PKCβII-scram significantly stimulated the highest increase in absorbance compared to all groups (p<0.01). Future studies will determine whether myr-PKCβII-scram augments absorbance by a different mechanism. Results suggest that myr improves myr-PKCβII- delivery compared to unconjugated PKCβII- but does not affect inhibition of PMA-induced PMN SO release. Myr-PKCβII- may thus effectively limit inflammation-induced I/R injury.
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