The overall objective of this application is to understand how autophagy and inflammation, particularly in the context of lung endothelium, are activated in association to control acute lung injury (ALI). The rationale for the study is based on our novel finding that phospholipase C epsilon (PLC?), a bifunctional PLC isoform with primary sites of expression in the lung and heart, acts as a critical regulator of autophagy and inflammation in the lung and that inhibiting autophagy ameliorates LPS-induced lung vascular leak. Our published data and ongoing work show that mechanistic (formerly mammalian) target of rapamycin (MTOR), a known inhibitor of autophagy, also functions as endogenous modulator of EC inflammation. Furthermore, we have identified an important role of PLC? in causing down-regulation of MTOR levels in the lungs of mice challenged with LPS. Based on these findings, we propose to test the hypothesis that activation of endothelial PLC? down-regulates MTOR levels/signaling to induce autophagy in association with inflammation to cause ALI.
Aim 1 will (i) ascertain the role of PLC? in mediating EC autophagy and inflammation, (ii) assess the contribution of autophagy to EC inflammation and apoptosis, (iii) determine the in vivo role of endothelial PLC? in causing lung inflammation and injury, and (iv) address the in vivo role of endothelial PLC? in causing lung autophagy and evaluate the contribution of this event in the mechanism of lung inflammation and injury.
Aim 2 will (i) determine the role of PLC? in suppressing MTOR levels/signaling to cause EC autophagy and inflammation, (ii) determine the in vivo relevance of suppression of endothelial MTOR levels/signaling in causing lung vascular autophagy and inflammatory injury, and (iii) evaluate the therapeutic potential of autophagy inhibition against evolving ALI. These studies will utilize multidisciplinary approaches ranging from biochemical, cellular, and molecular biology to in vivo gene delivery and lung physiology, and take advantage of conditional PLC? and MTOR knockout mice. The creative integration of in vitro and in vivo studies will provide novel insights into the integrated regulation of EC autophagy and inflammation in ALI and may lead to novel therapeutic interventions to control ALI/ARDS.
This project will identify how the two fundamental processes, autophagy and inflammation, are linked in the lung endothelium and collaborate in causing acute lung injury (ALI). Information gained from this study may lead to development of novel therapeutic strategies against ALI and Acute Respiratory Distress Syndrome (ARDS), and possibly against other autophagy/inflammation-associated diseases.
|Sureshbabu, Angara; Syed, Mansoor; Das, Pragnya et al. (2016) Inhibition of Regulatory-Associated Protein of Mechanistic Target of Rapamycin Prevents Hyperoxia-Induced Lung Injury by Enhancing Autophagy and Reducing Apoptosis in Neonatal Mice. Am J Respir Cell Mol Biol 55:722-735|
|Solleti, Siva Kumar; Srisuma, Sorachai; Bhattacharya, Soumyaroop et al. (2016) Serpine2 deficiency results in lung lymphocyte accumulation and bronchus-associated lymphoid tissue formation. FASEB J 30:2615-26|
|Bijli, Kaiser M; Fazal, Fabeha; Slavin, Spencer A et al. (2016) Phospholipase C-? signaling mediates endothelial cell inflammation and barrier disruption in acute lung injury. Am J Physiol Lung Cell Mol Physiol 311:L517-24|
|Bijli, Kaiser M; Kanter, Bryce G; Minhajuddin, Mohammad et al. (2014) Regulation of endothelial cell inflammation and lung polymorphonuclear lymphocyte infiltration by transglutaminase 2. Shock 42:562-9|
|Leonard, Antony; Marando, Catherine; Rahman, Arshad et al. (2013) Thrombin selectively engages LIM kinase 1 and slingshot-1L phosphatase to regulate NF-*B activation and endothelial cell inflammation. Am J Physiol Lung Cell Mol Physiol 305:L651-64|