Remote Ischemic Conditioning Prevents Lung and Liver Injury After Hemorrhagic Shock/Resuscitation: Potential Role of a Humoral Plasma Factor.

OBJECTIVE: To evaluate the efficacy of remote ischemic conditioning (RIC) on organ protection after hemorrhagic shock/resuscitation (S/R) in a murine model. BACKGROUND: Ischemia/reperfusion resulting from S/R contributes to multiple organ dysfunction in trauma patients. We hypothesized that RIC before shock (remote ischemic preconditioning), during shock (remote ischemic "PER"conditioning), or during resuscitation (remote ischemic "POST"conditioning) could confer organ protection. We also tested the effect of ischemic conditioned plasma on neutrophil migration in vivo using transgenic zebrafish models. METHODS: C57Bl/6 mice were subjected to S/R with or without hindlimb RIC. Serum levels of alanine aminotransferase and tumor necrosis factor-alpha, and liver tumor necrosis factor-alpha and interleukin 1ß mRNA were evaluated. In some experiments, lung protein leakage, cytokines, and myeloperoxidase activity were investigated. Plasma from mice subjected to RIC was microinjected into zebrafish, and neutrophil migration was assessed after tailfin transection or copper sulfate treatment. RESULTS: In mice subjected to S/R, remote ischemic preconditioning, remote ischemic "PER"conditioning, and remote ischemic "POST"conditioning each significantly reduced serum alanine aminotransferase and liver mRNA expression of tumor necrosis factor-alpha and interleukin 1ß and improved liver histology compared with control S/R mice. Lung injury and inflammation were also significantly reduced in mice treated with remote ischemic preconditioning. Zebrafish injected with plasma or dialyzed plasma (fraction >14 kDa) from ischemic conditioned mice had reduced neutrophil migration toward sites of injury compared with zebrafish injected with control plasma. CONCLUSIONS: RIC protects against S/R-induced organ injury, in part, through a humoral factor(s), which alters neutrophil function. The beneficial effects of RIC, performed during the S/R phase of care, suggest a role for its application early in the posttrauma period.

Remote cardioprotection by transfer of coronary effluent from ischemic preconditioned rabbit heart preserves mitochondrial integrity and function via adenosine receptor activation.

BACKGROUND: Coronary effluent from an isolated perfused heart undergoing ischemic preconditioning can be transferred to precondition another naïve isolated heart. We investigated the effects of this effluent on mitochondrial integrity and function following a global infarct model of ischemia/reperfusion and the role of adenosine in this model of remote preconditioning. METHODS AND RESULTS: Coronary effluent from isolated perfused rabbit hearts was collected prior to (control effluent) and during three cycles of 5-min ischemia and 10-min reperfusion (IPC effluent). Adenosine concentration was significantly increased in IPC effluent (2.6 ± 1.1 µM) versus control effluent (0.21 ± 0.06 µM, P < 0.01). Infarct size (% necrotic LV mass) after 30-min global ischemia and 90-min reperfusion was significantly reduced in hearts preconditioned with IPC effluent (IPC(eff), 23 ± 7 %) and control effluent supplemented with 2.5 µM exogenous adenosine (C(eff)+ 2.5 µM ADO, 25 ± 10 %) when compared to control effluent perfused hearts (C(eff), 41 ± 8 %, P < 0.05). Compared to C(eff) mitochondria, IPC(eff) mitochondria had preserved complex I/State3 and complex IV/State 3 respiration and outer membrane integrity, and reduced cytochrome c release. In contrast, C(eff) + 2.5 µM ADO mitochondria had improved state 2 respiration and coupling to oxidative phosphorylation, reduced reactive oxygen species production and preserved outer membrane integrity. Administration of adenosine receptor blocker 8-(p-sulfophenyl)theophylline abolished the infarct limiting effect (46 ± 7 %) and the mitochondrial integrity and function preservation of IPC effluent. CONCLUSION: Remote cardioprotection by IPC effluent preserves mitochondrial integrity and function in an adenosine receptor dependent mechanism, and although infarct size reduction can be mimicked by adenosine, IPC effluent contains additional factor(s) contributing to modulation of the mitochondrial response to ischemia/reperfusion injury.

ACTIVATION OF THE MITOCHONDRIAL ANTIVIRAL SIGNALING PROTEIN (MAVS) FOLLOWING LIVER ISCHEMIA/REPERFUSION AND ITS EFFECT ON INFLAMMATION AND INJURY.

ABSTRACT: Resuscitation of trauma patients after hemorrhagic shock causes global I/R, which may contribute to organ dysfunction. Oxidative stress resulting from I/R is known to induce signaling pathways leading to the production of inflammatory molecules culminating in organ dysfunction/injury. Our recent work demonstrated that oxidative stress was able to induce activation of the mitochondrial antiviral signaling protein (MAVS), a protein known to be involved in antiviral immunity, in an in vitro model. We therefore hypothesized that the MAVS pathway might be involved in I/R-induced inflammation and injury. The present studies show that MAVS is activated in vivo by liver I/R and in vitro in RAW 264.7 cells by hypoxia/reoxygenation (H/R). We utilized both in vivo (liver I/R in MAVS knockout mice) and in vitro (MAVS siRNA in RAW 264.7 cells followed by H/R) models to study the role of MAVS activation on downstream events. In vivo , we demonstrated augmented injury and inflammation in MAVS knockout mice compared with wild-type animals; as shown by increased hepatocellular injury, induction of hepatocyte apoptosis augmented plasma TNF-α levels. Further, in vitro silencing of MAVS by specific siRNA in RAW 264.7 and exposure of the cells to H/R caused activation of mitophagy. This may represent a compensatory response to increased liver inflammation. We conclude that activation of MAVS by hypoxia/reoxygenation dampens inflammation, potentially suggesting a novel target for intervention.

Plasma obtained following murine hindlimb ischemic conditioning protects against oxidative stress in zebrafish models through activation of nrf2a and downregulation of duox.

Ischemia/reperfusion of organ systems in trauma patients with resuscitated hemorrhagic shock (HSR) contributes to tissue injury and organ dysfunction. Previous studies using a murine model of HSR showed that remote ischemic preconditioning (RIC) protected against organ injury and that the plasma was able to prevent neutrophil migration in a zebrafish tailfin-cut inflammation model. In this study, we hypothesized that RIC plasma inhibits neutrophil function through a decrease in reactive oxygen species (ROS) production via the upregulation of the transcription factor Nrf2 and downstream antioxidative genes. Plasma from mice subjected to RIC (4 cycles of 5-min hindlimb ischemia/reperfusion) was microinjected into zebrafish. The results show that RIC plasma caused a reduction of ROS generation in response to tail injury. In addition, RIC plasma protected the fish larvae in the survival studies when exposed to either H2O2 or LPS. Oxidative stress PCR Array showed that RIC plasma treatment led to upregulation of antioxidative related genes including hsp70, hmox1a, nqo1 as well as downregulation of duox, the producer of H2O2. To explore the role of nrf2 in RIC, RIC plasma from Nrf2 KO mice were injected to the zebrafish and showed no inhibitory effect on neutrophil migration. Moreover, knockdown of nrf2a attenuated the anti-inflammatory and protective effect of RIC plasma. The downregulation of duox and upregulation of hmox1a were confirmed to require the activation of nrf2a. Therefore, we show that the protective effect of RIC may be related to the elaboration of humoral factors which counter injury-induced ROS generation in a nrf2-dependent fashion.

Nuclear Factor (Erythroid-Derived 2)-Like 2 Regulates the Hepatoprotective Effects of Remote Ischemic Conditioning in Hemorrhagic Shock.

AIMS: Remote ischemic conditioning (RIC) protects against organ ischemia/reperfusion injury in experimental and clinical settings. We have demonstrated that RIC prevents liver and lung inflammation/injury after hemorrhagic shock/resuscitation (S/R). In this study, we used a murine model of S/R to investigate the role of nuclear factor (erythroid-derived 2)-like 2 (Nrf2) in mediating hepatoprotection. RESULTS: The combination of RIC with S/R caused a synergistic rise in Nrf2 and its translocation to the nucleus in the liver. Increased activation of Nrf2 by RIC augmented heme oxygenase-1 (HO-1) and autophagy and exerted hepatoprotection, concurrent with reductions in S/R-induced TNF-α (tumor necrosis factor alpha) and IL-6 (interleukin-6). In Nrf2 knockout (KO) animals, RIC did not exert hepatoprotection, and it failed to upregulate HO-1 and autophagy. Further, resuscitating wildtype (WT) animals with blood from donor WT animals undergoing RIC was hepatoprotective, but not in Nrf2 KO recipient animals. Interestingly, RIC blood from Nrf2 KO donor animals was also not protective when used to resuscitate WT animals, suggesting a role for Nrf2 both in the afferent arm of RIC where protective factors are generated and also in the efferent arm where organ protection is exerted. Finally, RIC plasma prevented oxidant-induced zebrafish mortality, but not in Nrf2a morpholino knockdown fish. INNOVATION: Activation of Nrf2 is an essential mechanism underlying the hepatoprotective effects of RIC. Nrf2 appears to play a role in the afferent limb of RIC protection, as its absence precludes the generation of the protective humoral factors induced by RIC. CONCLUSION: Our studies demonstrate the critical role of Nrf2 in the ability of RIC to prevent organ injury after S/R.

Hemorrhagic Shock/Resuscitation Reduces the M2 Phenotype of Alveolar Macrophages: A Potential Mechanism Contributing to Increased LPS-Induced Lung Injury.

Major hemorrhage is a significant contributor to the morbidity and mortality resulting from traumatic injury. In addition to its role in in early mortality, hemorrhagic shock followed by resuscitation (HS/R) is known to initiate immunological events that contribute to the development of organ dysfunction. The pathogenesis of acute lung injury following HS/R involves macrophage activation. Recent studies have shown that macrophage function may in part be regulated by polarization toward classical M1 pro-inflammatory cells or alternatively activated anti-inflammatory M2 cells. We hypothesized that alteration in the M1/M2 phenotypic balance of alveolar macrophages in the lung may contribute to a pro-inflammatory state following HS/R. Using a murine model, we show that HS/R causes a rapid reduction in surface cluster of differentiation (CD)206 and CD36, markers of M2 cells, as well as in CD206 messenger ribonucleic acid (mRNA). M1 markers including surface CD80 and tumour necrosis factor alpha and inducible nitric oxide synthase mRNA were increased, albeit in a somewhat delayed time course. The prostaglandin 5-deoxyDelta12,14 prostaglandin J2 (15d-PGJ2), known to polarize cells toward M2, restored levels of M2 macrophages toward control and prevented lung injury, as assessed by bronchoalveolar protein content. Adoptive cell transfer of in vitro M2 polarized macrophages also reduced lung inflammation/injury following hemorrhagic shock. Together, these studies demonstrate that HS/R increases M1/M2 ratio, predominantly by lowering M2 cells, and thus enhances the proinflammatory state. Various strategies aimed at promoting M2 polarization may lessen the magnitude of inflammation and injury. This represents a novel approach to the prevention/treatment of lung injury in critically ill trauma patients.

Pulmonary vein stenosis and the pathophysiology of "upstream" pulmonary veins.

BACKGROUND: Surgical and catheter-based interventions on pulmonary veins are associated with pulmonary vein stenosis (PVS), which can progress diffusely through the "upstream" pulmonary veins. The mechanism has been rarely studied. We used a porcine model of PVS to assess disease progression with emphasis on the potential role of endothelial-mesenchymal transition (EndMT). METHODS: Neonatal piglets underwent bilateral pulmonary vein banding (banded, n = 6) or sham operations (sham, n = 6). Additional piglets underwent identical banding and stent implantation in a single-banded pulmonary vein 3 weeks postbanding (stented, n = 6). At 7 weeks postbanding, hemodynamics and upstream PV pathology were assessed. RESULTS: Banded piglets developed pulmonary hypertension. The upstream pulmonary veins exhibited intimal thickening associated with features of EndMT, including increased transforming growth factor (TGF)-ß1 and Smad expression, loss of endothelial and gain of mesenchymal marker expression, and coexpression of endothelial and mesenchymal markers in banded pulmonary vein intimal cells. These immunopathologic changes and a prominent myofibroblast phenotype in the remodeled pulmonary veins were consistently identified in specimens from patients with PVS, in vitro TGF-ß1-stimulated cells isolated from piglet and human pulmonary veins, and human umbilical vein endothelial cells. After stent implantation, decompression of a pulmonary vein was associated with reappearance of endothelial marker expression, suggesting the potential for plasticity in the observed pathologic changes, followed by rapid in-stent restenosis. CONCLUSIONS: Neonatal pulmonary vein banding in piglets recapitulates critical aspects of clinical PVS and highlights a pathologic profile consistent with EndMT, supporting the rationale for evaluating therapeutic strategies designed to exploit reversibility of upstream pulmonary vein pathology.

Transient mitochondrial permeability transition pore opening after neonatal cardioplegic arrest.

BACKGROUND: Neonatal cardioplegic arrest is associated with apoptosis-related mitochondrial dysfunction, including Bax translocation to the mitochondria, mitochondrial permeabilization, cytochrome c release, and electron transport chain dysfunction. We sought to characterize the time course and mode of postcardioplegic mitochondrial membrane permeabilization and hypothesize that permeabilization is transient and mediated by the mitochondrial permeability transition pore. METHODS: Isolated, perfused neonatal rabbit hearts underwent 60 minutes of warm crystalloid cardioplegic arrest followed by 120 minutes of reperfusion. Mitochondrial permeabilization was evaluated by means of infusion of 2-deoxy [(3)H] glucose and subsequent detection of entrapment in isolated mitochondrial fractions. Groups included preloading with 2-deoxy [(3)H] glucose followed by cardioplegia and reperfusion (CCP), cardioplegia and cyclosporin A (specific inhibitor of mitochondrial permeability transition pore opening; CCP + CsA) or HA14-1 (Bcl-2 inhibitor; CCP + HA), and noncardioplegia control hearts (non-CCP). Reconstitution of mitochondrial integrity was tested by means of delayed infusion of 2-deoxy [(3)H] glucose 30 minutes after reperfusion (P-CCP). RESULTS: Cardioplegic arrest was associated with mitochondrial permeability transition pore opening, Bax translocation, cytochrome c release, radical oxygen species production, and electron transport chain dysfunction. Inhibition of mitochondrial permeability transition pore opening by cyclosporin A ameliorated this response, whereas inhibition of Bcl-2 exacerbated these changes. Postreperfusion entrapment of 2-deoxy [(3)H] glucose was significantly reduced in comparison with that seen in CCP hearts, suggesting that closure of the mitochondrial permeability transition pore ensues within 30 minutes after reperfusion. CONCLUSIONS: Apoptosis-related mitochondrial dysfunction in postcardioplegic neonatal hearts is mediated by mitochondrial permeability transition pore opening, which is transient and associated with deficits in electron transport. Clinical strategies directed to minimize mitochondrial permeability transition pore opening are likely to improve postoperative myocardial dysfunction after neonatal cardiac surgery.