Recent studies indicate that critically ill patients experience poor sleep, frequent disruptions, loss of circadian rhythm and a marked reduction of the percentage of sleep time spent in restorative stages. Importantly, sleep deprivation in these patients may have adverse consequences. In keeping with this concept, two recent animal studies found that sleep deprivation markedly increases death in sepsis, but the mechanisms responsible for this phenomenon are completely unknown. We will test the specific hypotheses that sleep deprivation interacts with infection to activate endoplasmic reticulum (ER) stress pathways and that ER stress pathway activation, in turn, causes failure of multiple organs.
Aim 1 will determine if infection and sleep deprivation synergistically induce ER stress in multiple tissues and if ER stress pathway activation produces organ failure. Studies will be performed using animal models of sepsis (cecal ligation and puncture, CLP) and sleep deprivation (SD). Experiment 1.1 will test the hypothesis that sepsis and sleep deprivation interact to induce ER stress, with ER stress pathways activated in parallel with development of organ failure. Experiment 1.2 will test the hypothesis that chemical activation of ER stress triggers pathological alterations (e.g. activation of downstream proteolytic pathways) that produce organ dysfunction.
Aim 2 will elucidate the upstream mechanisms by which sepsis and sleep deprivation activate ER stress pathways. Experiment 2.1 will test the hypothesis that cytokine-induced production of reactive oxygen species (ROS) is the key upstream trigger that activates ER stress in sepsis. Experiment 2.2 will test the hypothesis that upstream alterations in peripheral tissue clock gene function activate ER stress pathways in response to sleep deprivation. Experiment 2.3 will test the hypothesis that disruption of peripheral tissue clock function increases ROS generation, and activates ER stress pathways.
Aim 3 will determine if administration of pharmacological inhibitors of ER stress pathways improves organ function in sepsis and sleep deprivation. Experiments 3.1, 3.2, and 3.3 will test the hypothesis that either z- ATAD-fmk (a caspase 12 inhibitor), salubrinal (a selective inhibitor of eIF2 dephosphorylation), or melatonin (an endogenous hormone that inhibits the IRE1 pathway) will block ER stress pathway dependent cell damage and improve organ function in CLP+SD. Experiment 3.4 will test the hypothesis that delayed administration of the pharmacologic agent to found to produce the best therapeutic effect will block ER stress pathway dependent cell damage and improve organ function in CLP+SD.

Public Health Relevance

During hospitalization, patients' sleep is constantly disrupted due to diagnostic tests, frequent nursing interventions, noise from alarms, and changes in light levels. Recent studies show that sleep deprivation increases death when combined with infection, but how this occurs is not known. We have discovered that sleep disruption during infection activates pathways that cause several of the body's organs to fail, so the purpose of our proposal is to determine the cellular mechanisms responsible for the interaction of sleep deprivation and infection and to define new treatments which may improve survival and recovery in hospitalized patients.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
4R01HL112085-04
Application #
8998976
Study Section
Surgery, Anesthesiology and Trauma Study Section (SAT)
Program Officer
Laposky, Aaron D
Project Start
2013-02-15
Project End
2018-01-31
Budget Start
2016-02-01
Budget End
2018-01-31
Support Year
4
Fiscal Year
2016
Total Cost
Indirect Cost
Name
University of Kentucky
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
939017877
City
Lexington
State
KY
Country
United States
Zip Code
40506
Supinski, Gerald S; Morris, Peter E; Dhar, Sanjay et al. (2018) Diaphragm Dysfunction in Critical Illness. Chest 153:1040-1051
Supinski, Gerald S; Alimov, Alexander P; Wang, Lin et al. (2016) Calcium-dependent phospholipase A2 modulates infection-induced diaphragm dysfunction. Am J Physiol Lung Cell Mol Physiol 310:L975-84
Callahan, Leigh A; Supinski, Gerald S (2016) Early Mobilization in the ICU: Help or Hype? Crit Care Med 44:1239-40
Supinski, Gerald S; Alimov, Alexander P; Wang, Lin et al. (2015) Neutral sphingomyelinase 2 is required for cytokine-induced skeletal muscle calpain activation. Am J Physiol Lung Cell Mol Physiol 309:L614-24
Supinski, Gerald S; Callahan, Leigh A (2015) How Important is Diaphragm Function as a Determinant of Outcomes for MICU Patients in Respiratory Failure? Physiology (Bethesda) 30:336-7
Supinski, Gerald S; Callahan, Leigh A (2014) ?-hydroxy-?-methylbutyrate (HMB) prevents sepsis-induced diaphragm dysfunction in mice. Respir Physiol Neurobiol 196:63-8
Chung, Charles S; Mitov, Mihail I; Callahan, Leigh Ann et al. (2014) Increased myocardial short-range forces in a rodent model of diabetes reflect elevated content of ? myosin heavy chain. Arch Biochem Biophys 552-553:92-9
Supinski, Gerald S; Wang, Lin; Song, Xiao-Hong et al. (2014) Muscle-specific calpastatin overexpression prevents diaphragm weakness in cecal ligation puncture-induced sepsis. J Appl Physiol (1985) 117:921-9
Callahan, Leigh A; Supinski, Gerald S (2014) Hyperglycemia-induced diaphragm weakness is mediated by oxidative stress. Crit Care 18:R88
Callahan, Leigh Ann; Supinski, Gerald S (2013) Prevention and treatment of ICU-acquired weakness: is there a stimulating answer? Crit Care Med 41:2457-8

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