A cell-penetrating PHLPP peptide improves cardiac arrest survival in murine and swine models
Jing Li, … , Henry R. Halperin, Terry L. Vanden Hoek
Jing Li, … , Henry R. Halperin, Terry L. Vanden Hoek
Published May 1, 2023
Citation Information: J Clin Invest. 2023;133(9):e164283. https://doi.org/10.1172/JCI164283.
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Research Article

A cell-penetrating PHLPP peptide improves cardiac arrest survival in murine and swine models

Abstract

Out-of-hospital cardiac arrest is a leading cause of death in the US, with a mortality rate over 90%. Preclinical studies demonstrate that cooling during cardiopulmonary resuscitation (CPR) is highly beneficial, but can be challenging to implement clinically. No medications exist for improving long-term cardiac arrest survival. We have developed a 20–amino acid peptide, TAT-PHLPP9c, that mimics cooling protection by enhancing AKT activation via PH domain leucine-rich repeat phosphatase 1 (PHLPP1) inhibition. Complementary studies were conducted in mouse and swine. C57BL/6 mice were randomized into blinded saline control and peptide-treatment groups. Following a 12-minute asystolic arrest, TAT-PHLPP9c was administered intravenously during CPR and significantly improved the return of spontaneous circulation, mean arterial blood pressure and cerebral blood flow, cardiac and neurological function, and survival (4 hour and 5 day). It inhibited PHLPP-NHERF1 binding, enhanced AKT but not PKC phosphorylation, decreased pyruvate dehydrogenase phosphorylation and sorbitol production, and increased ATP generation in heart and brain. TAT-PHLPP9c treatment also reduced plasma taurine and glutamate concentrations after resuscitation. The protective benefit of TAT-PHLPP9c was validated in a swine cardiac arrest model of ventricular fibrillation. In conclusion, TAT-PHLPP9c may improve neurologically intact cardiac arrest survival without the need for physical cooling.

Authors

Jing Li, Xiangdong Zhu, Matt T. Oberdier, Chunpei Lee, Shaoxia Lin, Sarah J. Fink, Cody N. Justice, Kevin Qin, Andrew W. Begeman, Frederick C. Damen, Hajwa Kim, Jiwang Chen, Kejia Cai, Henry R. Halperin, Terry L. Vanden Hoek

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Figure 5

TAT-PHLPP9c decreased PDH phosphorylation, reduced sorbitol generation, and increased ATP content at R15 after ROSC in heart and brain.

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TAT-PHLPP9c decreased PDH phosphorylation, reduced sorbitol generation, ...
α-Tubulin and β-actin were used as loading controls for heart and brain, respectively. (A) Representative PDH phosphorylation at R15 in heart and brain. (B) Densitometric analysis of PDH phosphorylation in heart and brain. Paired, 2-tailed t test was used. #P < 0.05 between saline control and TAT-PHLPP9c; *P < 0.01 between saline and TAT-PHLPP9c. Data are represented as mean ± SD for 4 mice. (C) Sorbitol contents at R15 in heart and brain. Paired, 2-tailed t test was used. *P < 0.01 between saline and TAT-PHLPP9c. Data are represented as mean ± SD for 4 mice. (D) ATP contents at R15 in heart and brain. Paired, 2-tailed t test was used. #P < 0.05 between saline and TAT-PHLPP9c. Data are represented as mean ± SD for 4 mice.