IL-33 Mediates Pseudomonas Induced Airway Fibrogenesis and Is Associated with CLAD

BACKGROUND: Long term outcomes of lung transplantation are impacted by the occurrence of chronic lung allograft dysfunction (CLAD). Recent evidence suggests a role for the lung microbiome in the occurrence of CLAD, but the exact mechanisms are not well defined. We hypothesize that the lung microbiome inhibits epithelial autophagic clearance of pro-fibrotic proteins in an IL-33 dependent manner, thereby augmenting fibrogenesis and risk for CLAD. METHODS: Autopsy derived CLAD and non-CLAD lungs were collected. IL-33, P62 and LC3 immunofluorescence was performed and assessed using confocal microscopy. Pseudomonas aeruginosa (PsA), Streptococcus Pneumoniae (SP), Prevotella Melaninogenica (PM), recombinant IL-33 or PsA-lipopolysaccharide was co-cultured with primary human bronchial epithelial cells (PBEC) and lung fibroblasts in the presence or absence of IL-33 blockade. Western blot analysis and quantitative reverse transcription (qRT) PCR was performed to evaluate IL-33 expression, autophagy, cytokines and fibroblast differentiation markers. These experiments were repeated after siRNA silencing and upregulation (plasmid vector) of Beclin-1. RESULTS: Human CLAD lungs demonstrated markedly increased expression of IL-33 and reduced basal autophagy compared to non-CLAD lungs. Exposure of co-cultured PBECs to PsA, SP induced IL-33, and inhibited PBEC autophagy, while PM elicited no significant response. Further, PsA exposure increased myofibroblast differentiation and collagen formation. IL-33 blockade in these co-cultures recovered Beclin-1, cellular autophagy and attenuated myofibroblast activation in a Beclin-1 dependent manner. CONCLUSION: CLAD is associated with increased airway IL-33 expression and reduced basal autophagy. PsA induces a fibrogenic response by inhibiting airway epithelial autophagy in an IL-33 dependent manner

Thrombin regulation of endothelin-1 gene in isolated human pulmonary endothelial cells

Endothelin (ET)-1 is a potent vasoconstrictor elicited from endothelial cells in response to a variety of stimuli and an important mediator for a variety of vascular diseases including pulmonary hypertension. In this paper, we describe the molecular regulation of the ET-1 gene in response to a vasoactive mediator, thrombin, in human pulmonary endothelial cells. Thrombin induces preproET-1 mRNA through a transcriptionally dependent mechanism, with a peak induction after 1 h of exposure. Analysis of chromatin structure identified several DNase I-hypersensitive regions under both basal and thrombin-stimulated conditions that reside in the 5′-promoter region, indicating that the ET-1 promoter is a constitutive promoter. Deletion analysis was employed as a functional assay to identify regions of the ET-1 promoter that are important in transcriptional regulation. We found that sites between −141 and −378 bp are essential for basal activity and that those between −378 and −484 bp are essential for thrombin-stimulated activity. However, full expression under both conditions required an element(s) within −952 bp.</jats:p

Pirfenidone inhibits inflammatory responses and ameliorates allograft injury in a rat lung transplant model

ObjectiveTumor necrosis factor α is a proinflammatory cytokine that has been proved to play a crucial role in inducing posttransplantation lung injury. The present study was performed to determine whether pirfenidone, a new nonpeptide drug with potent anti–tumor necrosis factor α activity, promotes protection against acute allograft injury through inhibiting pulmonary inflammatory responses in a rat model of orthotopic lung transplantation.MethodsThree transplant groups were formed: isografts, untreated allografts, and allografts treated with pirfenidone (0.5% chow starting on day 1 after transplantation). The implants were harvested on day 21 after transplantation. Acute cellular rejection grade and degree of allograft injury were evaluated on the basis of hematoxylin-and-eosin staining. The pulmonary inflammatory response and inflammation-induced oxidative stress were assessed on the basis of neutrophil accumulation (myeloperoxidase immunoreactivity and enzymatic activity) and iron deposition (Prussian blue staining). In addition, circulating levels of tissue necrosis factor α in all animals were measured.ResultsThe degree of allograft injury was significantly reduced in pirfenidone-treated allografts relative to untreated allografts (P < .01). The beneficial effect of pirfenidone was associated with decreased lung myeloperoxidase immunoreactivity (P < .05) and enzymatic activity (P < .01). Moreover, the untreated allografts contained a high concentration of iron, which was strikingly reduced by pirfenidone. Treatment with pirfenidone resulted in a lower level of plasma tissue necrosis factor α, which correlated positively with lung myeloperoxidase enzymatic activity (P < .0001).ConclusionThese results suggest that pirfenidone, with its anti–tissue necrosis factor α activity, reduced neutrophil recruitment and iron accumulation, hence limiting the acute lung allograft injury

Reduced Cytotoxic Function of Effector CD8+ T Cells Is Responsible for Indoleamine 2,3-Dioxygenase-Dependent Immune Suppression

Abstract Indoleamine 2,3-dioxygenase (IDO), a potent immunosuppressive enzyme, contributes to tumoral escape, immune tolerance, and protection against allograft injury. In this paper, we report that inhibition of CD8+ T cell-mediated cytotoxic function is an important mechanism behind IDO’s immune-modulating property. The experimental rat lung allograft proved attractive for evaluating effector CD8+ T cells. Enhanced IDO activity achieved by using a lung-tissue-targeted nonviral human IDO gene transfer approach reduced, but did not eliminate, infiltrating CD8+ T cells. Although CD8+ T cells existed in the IDO-high lung allografts, CD8+ T cells remained viable and could proliferate for an extended period. However, cells lost their ability to attack allogeneic donor lung cells in vivo and allogeneic target cells in vitro. The impaired cytotoxic function seen in the IDO-treated CD8+ T cells was accompanied by defects in production of granule cytotoxic proteins, including perforin and granzyme A and B. Furthermore, we discovered that IDO leads to an impaired bioenergetic condition in active CD8+ T cells via selective inhibition of complex I in the mitochondrial electron transfer chain. These intriguing findings provide a base for establishing a novel mode of IDO’s immune-suppressing action. Additionally, donor lung IDO delivery, a direct and/or leukocyte passenger effect, impaired CD8+ effector cell function.</jats:p