Mechanisms Of Acute Lung Injury Research Articles

Caspase inhibitor zVAD-fmk protects against acute pancreatitis-associated lung injury via inhibiting inflammation and apoptosis

Background/objectivesPulmonary apoptosis is an important pathogenic mechanism of acute lung injury induced by many factors. This study aims to investigate whether the caspase inhibitor zVAD-fmk has a protective effect against lung injury in the severe acute pancreatitis model (SAP) in rats. MethodsSeventy-two Sprague-Dawley rats were randomly divided into Sham, SAP, and SAP + zVAD-fmk groups. The SAP model was established by injection of 5% sodium taurocholate into the pancreatic duct. Animals were sacrificed at 3 h, 6 h, 12 h, and 24 h after operation and then HE staining analysis was performed to assess the lung injury. ELISA was used to detect the activity of myeloperoxidase (MPO) and the concentrations of tumor necrosis factor α (TNF-α) and interleukin 1β (IL-1β). Western blotting was used to detect the expression of cleaved caspase-3 in the lung tissues. ResultsRats in SAP group showed obvious lung injury through pathologic examination. Pretreatment with zVAD-fmk significantly inhibited a post-SAP increase in the activation of MPO, TNF-α, IL-1β, and caspase-3, and decreased lung injury induced by SAP as determined by the pathologic score. ConclusionOur results suggest that apoptosis plays an important role in acute pancreatitis-associated lung injury (APALI), and inhibition of caspase activity may represent a new therapeutic approach for the treatment of APALI.

Hypertonicity contributes to seawater aspiration-induced lung injury: Role of hypoxia-inducible factor 1α

ABSTRACTDrowning is an important public health problem, but the mechanism of acute lung injury induced by near-drowning is rarely reported. The aim of this study is to investigate the role of hypertonicity and HIF-1α in seawater aspiration-induced lung injury. Diverse solutions were used to study the effect of hypertonicity on hypoxia, inflammation, vascular leakage, edema, and HIF-1α expression in lungs of rats. The relationship between hypertonicity and hypoxia, when they induced HIF-1α, was studied and the roles of ATM, PI3K, and p38 in the course of hypertonicity inducing HIF-1α were investigated. At last, our conclusion was verified with HIF-1α inhibitor and inducer in seawater aspiration rats. The results showed that hypertonicity, but not isotonicity and hypotonicity, promoted hypoxia, inflammation, vascular leakage, edema, and HIF-1α expression in lungs. Hypertonicity not only induced HIF-1α in a time- and dose-dependent manner but also could increase HIF-1α synergistically with hypoxia in AEC. Furthermore, hypertonicity increased HIF-1α by promoting its mRNA expression through both ATM and PI3K activation and by suppressing its protein degradation through p38 activation. During hyperosmotic stress, the increased HIF-1α promoted the production of the inflammatory cytokines in NR8383 and elevated monolayer permeability through increasing VEGF in RLMVEC. In conclusion, hypertonicity induced by aspirated seawater aggravated lung injury through increasing HIF-1α which promoted inflammation and edema in lung tissues in rats.

The effect of paraquat on voltage-dependent anion channel and caspase-3, 8, 9 in the mitochondria of rat lung

To investigate the effects of different concentrations of paraquat (PQ) poisoning on the expression of voltage-dependent anion channel (VDAC) and caspase family in the mitochondria of rat lung tissue, and to explore possible mechanisms of acute lung injury induced by acute PQ poisoning. Two hundred healthy adult Wister rats with equal numbers of male and female ones were randomly and equally divided into control group and poisoned group. The control group received one-time gastric lavage with 1 ml of normal saline, and the poisoned group with PQ (50 mg/kg) diluted in 1 ml of normal saline. Twenty rats were collected at 1, 24, 72, 120, and 168 h after lavage with normal saline or PQ and dissected after anesthesia. Mitochondria were separated from rat lung tissue, and the content of VDAC and caspase-3, -8, and -9 were determined. The expression of VDAC and caspase-3, -8, and -9 in the poisoned rats were significantly higher than that in the control group (P < 0.001). At 1, 24, 72, 120, and 168 h after exposure, acute diffuse damages were found in alveolar capillary endothelial cells, alveolar epithelial cells, and pulmonary interstitial cells. Inflammatory cell infiltration in the pulmonary interstitium, alveolar structural disorder, and substantially increased fibroblasts were also found in rat lung tissue. PQ poisoning can up-regulate the expression of VDAC and caspase-3, -8, and -9 in mitochondria of rat lung tissue to induce acute lung injury.

Combinatorial Therapy with Acetylation and Methylation Modifiers Attenuates Lung Vascular Hyperpermeability in Endotoxemia-Induced Mouse Inflammatory Lung Injury

Impairment of tissue fluid homeostasis and migration of inflammatory cells across the vascular endothelial barrier are crucial factors in the pathogenesis of acute lung injury (ALI). The goal for treatment of ALI is to target pathways that lead to profound dysregulation of the lung endothelial barrier. Although studies have shown that chemical epigenetic modifiers can limit lung inflammation in experimental ALI models, studies to date have not examined efficacy of a combination of DNA methyl transferase inhibitor 5-Aza 2-deoxycytidine and histone deacetylase inhibitor trichostatin A (herein referred to as Aza+TSA) after endotoxemia-induced mouse lung injury. We tested the hypothesis that treatment with Aza+TSA after lipopolysaccharide induction of ALI through epigenetic modification of lung endothelial cells prevents inflammatory lung injury. Combinatorial treatment with Aza+TSA mitigated the increased endothelial permeability response after lipopolysaccharide challenge. In addition, we observed reduced lung inflammation and lung injury. Aza+TSA also significantly reduced mortality in the ALI model. The protection was ascribed to inhibition of the eNOS-Cav1-MLC2 signaling pathway and enhanced acetylation of histone markers on the vascular endothelial-cadherin promoter. In summary, these data show for the first time the efficacy of combinatorial Aza+TSA therapy in preventing ALI in lipopolysaccharide-induced endotoxemia and raise the possibility of an essential role of DNA methyl transferase and histone deacetylase in the mechanism of ALI.

The effects of aquaporins in different animal models of acute lung injury

Background Acute lung injury (ALI) is a common syndrome with high mortality and disability rate.The imbalance of water in lung plays a significant role in the complicated pathological mechanisms of ALI.Dysfunction of lung vascular endothelial cells were thought to be accounted for the high permeability,however,the discovery of aquaporins (AQP),brings a novel perspective into this field.Objective Know about aquaporins' functions in different animal models of ALI.Content we will review aquaporins' general features,distribution in the lung,and functions in different animal models of acute lung injury.Trend Explore functions of aquaporins in the pathological mechanism of ALI,providing new thoughts for clinical treatments. Key words: Aquaporins; Acute lung injury; Models animal

The molecular mechanism of acute lung injury caused by Pseudomonas aeruginosa: from bacterial pathogenesis to host response.

Pseudomonas aeruginosa is the most common gram-negative pathogen causing pneumonia in immunocompromised patients. Acute lung injury induced by bacterial exoproducts is associated with a poor outcome in P. aeruginosa pneumonia. The major pathogenic toxins among the exoproducts of P. aeruginosa and the mechanism by which they cause acute lung injury have been investigated: exoenzyme S and co-regulated toxins were found to contribute to acute lung injury. P. aeruginosa secretes these toxins through the recently defined type III secretion system (TTSS), by which gram-negative bacteria directly translocate toxins into the cytosol of target eukaryotic cells. TTSS comprises the secretion apparatus (termed the injectisome), translocators, secreted toxins, and regulatory components. In the P. aeruginosa genome, a pathogenic gene cluster, the exoenzyme S regulon, encodes genes underlying the regulation, secretion, and translocation of TTSS. Four type III secretory toxins, namely ExoS, ExoT, ExoU, and ExoY, have been identified in P. aeruginosa. ExoS is a 49-kDa form of exoenzyme S, a bifunctional toxin that exerts ADP-ribosyltransferase and GTPase-activating protein (GAP) activity to disrupt endocytosis, the actin cytoskeleton, and cell proliferation. ExoT, a 53-kDa form of exoenzyme S with 75% sequence homology to ExoS, also exerts GAP activity to interfere with cell morphology and motility. ExoY is a nucleotidal cyclase that increases the intracellular levels of cyclic adenosine and guanosine monophosphates, resulting in edema formation. ExoU, which exhibits phospholipase A2 activity activated by host cell ubiquitination after translocation, is a major pathogenic cytotoxin that causes alveolar epithelial injury and macrophage necrosis. Approximately 20% of clinical isolates also secrete ExoU, a gene encoded within an insertional pathogenic gene cluster named P. aeruginosa pathogenicity island-2. The ExoU secretory phenotype is associated with a poor clinical outcome in P. aeruginosa pneumonia. Blockade of translocation by TTSS or inhibition of the enzymatic activity of translocated toxins has the potential to decrease acute lung injury and improve clinical outcome.Electronic supplementary materialThe online version of this article (doi:10.1186/2052-0492-2-10) contains supplementary material, which is available to authorized users.

Dysregulated Renin-AngioteNsin System Contributes to acute Lung Injury Caused by Hind-limb Ischemia-Reperfusion in Mice

The mechanism of acute lung injury (ALI) following limb ischemia-reperfusion (LIR) is not yet clear. We speculate that the unbalanced expression of angiotensin-converting enzymes (ACE and ACE2) and angiotensins [Ang II and Ang-(1-7)] in the renin-angiotensin system (RAS) is a major cause of ALI. To prove this hypothesis, pathological changes, lung edema, and permeability of wild-type mice at different time points within 12 h of reperfusion after 2 h of hind-limb ischemia were first detected by morphological method, measurements of wet-to-dry weight ratio, and bronchoalveolar lavage fluid. Meanwhile, the changes of lung ACE/ACE2 mRNA and protein expression were surveyed by the methods of real-time reverse transcription-polymerase chain reaction, Western blotting, and immunohistochemistry. Angiotensin II/Ang-(1-7) levels in the blood serum and lung tissue were measured by enzyme-linked immunosorbent assay. Then the effects of ACE2 gene insertion and deletion on the previously mentioned parameters were investigated in the mice being exposed to hind-limb 2-h ischemia and 4-h reperfusion. The results revealed that lung injuries in the wild-type mice were gradually aggravated, and the expression of ACE in lung tissue was progressively increased, whereas that of ACE2 decreased within 12 h after LIR. Unexpectedly, both Ang II and Ang-(1-7) in the lung tissue were obviously increased after LIR, showing Ang-(1-7) higher than Ang II in the early stage of reperfusion but lower than Ang II at the late stage of reperfusion. Unlike local Ang II/Ang-(1-7) changes, circulating Ang-(1-7) became greatly descending, and Ang II was markedly ascending from the start of reperfusion, corresponding to local ACE/ACE2 unbalanced expression. ACE2 transgenosis improved the imbalance of ACE/ACE2 and Ang II/Ang-(1-7) expression and alleviated lung injuries, whereas ACE2 knockout further aggravated the imbalance of ACE/ACE2 and Ang II/Ang-(1-7) expression and made lung injuries more serious in the post-LIR mice. The results indicate that the dysregulation of local and circulating RAS with increased expression of ACE/Ang II and decreased expression of ACE2/Ang-(1-7) contribute to ALI caused by LIR in mice. Maintaining RAS homeostasis through upregulating ACE2 expression may lessen lung injury, which provides a new idea for the treatment of posttraumatic ALI.

P62 sequestosome 1/light chain 3b complex confers cytoprotection on lung epithelial cells after hyperoxia.

Lung epithelial cell death is a prominent feature of hyperoxic lung injury, and has been considered a very important underlying mechanism of acute lung injury (ALI) and acute respiratory distress syndrome (ARDS). Here we report on a novel mechanism involved in epithelial cytoprotection and homeostasis after oxidative stress. p62 (sequestosome 1; SQSTM1) is a ubiquitously expressed cellular protein. It interacts with ubiquitinated proteins and autophagic marker light chain 3b (LC3b), thus mediating the degradation of selective targets. In this study, we explored the role of p62 in mitochondria-mediated cell death after hyperoxia. Lung alveolar epithelial cells demonstrate abundant p62 expression, and p62 concentrations are up-regulated by oxidative stress at both the protein and mRNA levels. The p62/LC3b complex interacts with Fas and truncated BID (tBID) physically. These interactions abruptly diminish after hyperoxia. The deletion of p62 robustly increases tBID and cleaved caspase-3, implying an antiapoptotic effect. This antiapoptotic effect of p62 is further confirmed by measuring caspase activities, cleaved poly ADP ribose polymerase, and cell viability. The deletion of the p62 PBI domain or the ubiquitin-associated domain both lead to elevated tBID, cleaved caspase-3, and significantly more cell death after hyperoxia. Moreover, p62 traffics in an opposite direction with LC3b after hyperoxia, leading to the dissociation of the p62/Cav-1/LC3b/BID complex. Subsequently, the LC3b-mediated lysosomal degradation of tBID is eliminated. Taken together, our data suggest that the p62/LC3b complex regulates lung alveolar epithelial cell homeostasis and cytoprotection after hyperoxia.

Mechanisms of acute lung injury: Programmed Cell Death Receptor (PD)‐1 ligation as a regulator of Angiopoietin‐2 expression

PD‐1 is a co‐inhibitory protein on leukocytes and has been shown to negatively regulate T‐cell responses. PD‐1 ligand, PD‐L1, is expressed on immune and non‐immune cells including lung vascular endothelial cells (ECs). The basis for PD‐1's broad influence on immune response is unclear. Our laboratory has shown expression of PD‐1 contributes to mortality in our model of hemorrhage (Hem) priming followed by sepsis in the development of indirect acute lung injury (iALI). Initial data shows significant increase in PD‐L1 expression on ECs in the lungs and PD‐1 on Gr1+ cells in circulation following Hem. To the extent that this expression of PD‐1/PDL‐1 impacts lung EC dysfunction encountered during iALI, we assessed changes in EC growth factor Angiopoietin (Ang)‐2 in PD‐1−/− or PD‐L1−/−mice in our Hem/sepsis model for iALI. Ang‐2, released by activated ECs, is associated with vascular destabilization, inflammation and vascular permeability, and is significantly elevated in both patients and mouse models of iALI. Our data found that Ang‐2 was significantly reduced in both PD‐1−/− and PD‐L1−/− mice with iALI. However, MPO activity in lung tissue was significantly suppressed in PD‐1−/− mice, but not in PD‐L1 −/−. These data suggest PD‐1:PD‐L1 also play role(s) beyond the classic regulation of the leukocyte immune response; not only T‐cell mediation, but also in the innate response to inflammation as modeled in our iALI mice.

MicroRNA-127 Inhibits Lung Inflammation by Targeting IgG Fcγ Receptor I

The molecular mechanisms of acute lung injury are incompletely understood. MicroRNAs (miRNAs) are crucial biological regulators that act by suppressing their target genes and are involved in a variety of pathophysiologic processes. miR-127 appears to be downregulated during lung injury. We set out to investigate the role of miR-127 in lung injury and inflammation. Expression of miR-127 significantly reduced cytokine release by macrophages. Looking into the mechanisms of regulation of inflammation by miR-127, we found that IgG FcγRI (CD64) was a target of miR-127, as evidenced by reduced CD64 protein expression in macrophages overexpressing miR-127. Furthermore, miR-127 significantly reduced the luciferase activity with a reporter construct containing the native 3' untranslated region of CD64. Importantly, we demonstrated that miR-127 attenuated lung inflammation in an IgG immune complex model in vivo. Collectively, these data show that miR-127 targets macrophage CD64 expression and promotes the reduction of lung inflammation. Understanding how miRNAs regulate lung inflammation may represent an attractive way to control inflammation induced by infectious or noninfectious lung injury.

Models and mechanisms of acute lung injury caused by direct insults

Acute lung injury (ALI) and its more severe form acute respiratory distress syndrome (ARDS) are life-threatening diseases that are characterized by acute onset, pulmonary inflammation, oedema due to increased vascular permeability and severe hypoxemia. Clinically, ARDS can be divided into ARDS due to direct causes such as pneumonia, aspiration or injurious ventilation, and due to extrapulmonary indirect causes such as sepsis, severe burns or pancreatitis. In order to identify potential therapeutic targets, we asked here whether common molecular mechanisms can be identified that are relevant in different models of the direct form of ALI/ARDS. To this end, we reviewed three widely used models: (a) one based on a biological insult, i.e. instillation of bacterial endotoxins; (b) one based on a chemical insult, i.e. instillation of acid; and (c) one based on a mechanical insult, i.e. injurious ventilation. Studies were included only if the mediator or mechanism of interest was studied in at least two of the three animal models listed above. As endpoints, we selected neutrophil sequestration, permeability, hypoxemia (physiological dysfunction) and survival. Our analysis showed that most studies have focused on mechanisms of pulmonary neutrophil sequestration and models with moderate forms of oedema. The underlying mechanisms that involve canonical inflammatory pathways such as MAP kinases, CXCR2 chemokines, PAF, leukotrienes, adhesions molecules (CD18, ICAM-1) and elastase have been defined relatively well. Further mechanisms including TNF, DARC, HMGB1, PARP, GADD45 and collagenase are under investigation. Such mechanisms that are shared between the three ALI models may represent viable therapeutic targets. However, only few studies have linked these pathways to hypoxemia, the most important clinical aspect of ALI/ARDS. Since moderate oedema does not necessarily lead to hypoxemia, we suggest that the clinical relevance of experimental studies can be further improved by putting greater emphasis on gas exchange.

Mechanism of acute lung injury due to phosgene exposition and its protection by cafeic acid phenethyl ester in the rat

The mechanism of phosgene-induced acute lung injury (ALI) remains unclear and it is still lack of effective treatments. Previous study indicated that oxidative stress was involved in phosgene-induced ALI. Caffeic acid phenethyl ester (CAPE) has been proved to be an anti-inflammatory agent and a potent free radical scavenger. The purpose of this study was to investigate the protective effects of CAPE on phosgene-induced ALI and identify the mechanism, in which oxidative stress and inflammation were involved. The phosgene was used to induce ALI in rats. The results showed that after phosgene exposure, total protein content in BALF was not significantly changed. The increase of MDA level and SOD activity induced by phosgene was significantly reduced by CAPE administration, and the decrease of GSH level in BALF and lung were significantly reversed by CAPE. CAPE also partially blocked the translocation of NF-κB p65 to the nucleus, but it had little effect on the phosphorylation of p38 MAPK. In conclusion, CAPE showed protective effects on lung against phosgene-induced ALI, which may be related with a combination of the antioxidant and anti-inflammatory functions of CAPE.

Pathophysiological Mechanisms of Acute Lung Injury in Patients With Leptospirosis

PURPOSE: Acute lung injury (ALI) or acute respiratory distress syndrome (ARDS) is a serious clinical problem, we investigated the pathogenic mechanisms of ARDS caused by leptospirosis due to spirochetes infection.

VEGF, Bcl-2 and Bad regulated by angiopoietin-1 in oleic acid induced acute lung injury

Molecular mechanisms of acute lung injury (ALI) are poorly defined. Our previous study demonstrated that recombinant angiopoietin-1 (Ang1) can protect against oleic acid (OA) induced ALI at an early stage. The purpose of this study was to elucidate whether vascular endothelial growth factor (VEGF), Bcl-2, and Bad, phosphoinositide 3-kinase (PI3K)/protein kinase B (Akt) play any role in the protective mechanism of recombinant Ang1 in OA-induced ALI. All BALB/C mice were administered a single dose of OA to induce lung injury. Lungs, bronchoalveolar lavage fluid (BALF), and serum were harvested at certain time points. The expression of VEGF, Bcl-2, Bad, PI3K/Akt, and the histological changes in the lung, and the levels of VEGF, IL-6, and IL-10 in serum and BALF were examined. A second cohort of mice was followed for survival for 7days. We observed increased expression of VEGF in BALF and serum and reduced expression of VEGF in lung tissue. Recombinant Ang1 treatment, however, up-regulated VEGF expression and p-Akt/Akt in lung tissue but down-regulated VEGF expression in BALF and serum. OA led to a decrease of anti-apoptotic marker Bcl-2 and a marked increase of pro-apoptotic marker Bad. Compared with the ALI group, in the recombinant Ang1 treated group, Bcl-2 expression was restored, and Bad expression was clearly attenuated. In addition, recombinant Ang1 attenuated the lung pathological changes and improved the survival of mice. These findings suggest that recombinant Ang1 may be a promising potential treatment for ALI. It seems that VEGF is mediated by PI3K/Akt pathway which is required for Ang1-mediated protection of lung injury. Activation of Akt stimulates expression of Bcl-2 and inhibits the expression of Bad, thus inhibiting the execution of apoptosis.

Alveolar acid transiently permeabilizes the alveolar epithelium in mouse lungs

Acid aspiration causes acute lung injury (ALI). However, acid interactions with the alveolar epithelial (AE) membrane are not understood. To understand acid interactions with intact alveoli, we set up isolated, perfused mouse lungs held at pulmonary artery, left atrial and alveolar pressures of 10, 3 and 5 cmH2O, respectively. Then we imaged intact alveoli by real‐time fluorescence microscopy. To view the alveolar cytosol, we microinfused alveoli with BCECF‐AM, that intra‐cellularly converts to the membrane‐impermeable fluorophore, BCECF. Then we imaged pH‐independent fluorescence (440 nm excitation). Alveolar microinfusion of HCl (pH 1.5) decreased AE fluorescence by 48±7 % of initial in 5 min (mean±SE, n=3). However subsequently, despite continued HCl infusion for 15 min, the AE fluorescence held steady. Further, after reloading BCECF to initial levels of AE fluorescence, a second HCl infusion given 20 min after the first, failed to decrease AE fluorescence (p&lt;.05). We conclude, first contact with acid immediately permeabilized the AE membrane. However, the membrane spontaneously resealed and resisted further acid‐induced damage. We report a novel protective mechanism in ALI in which the cell spontaneously repairs chemically‐induced membrane damage. (Support: HL69514, 78645).

Acute lung injury: apoptosis in effector and target cells of the upper and lower airway compartment

Apoptotic cell death has been considered an underlying mechanism in acute lung injury. To evaluate the evidence of this process, apoptosis rate was determined in effector cells (alveolar macrophages, neutrophils) and target cells (tracheobronchial and alveolar epithelial cells) of the respiratory compartment upon exposure to hypoxia and endotoxin stimulation in vitro. Cells were exposed to 5% oxygen or incubated with lipopolysaccharide (LPS) for 4, 8 and 24 h, and activity of caspase-3, -8 and -9 was determined. Caspase-3 of alveolar macrophages was increased at all three time-points upon LPS stimulation, while hypoxia did not affect apoptosis rate at early time-points. In neutrophils, apoptosis was decreased in an early phase of hypoxia at 4 h. However, enhanced expression of caspase-3 activity was seen at 8 and 24 h. In the presence of LPS a decreased apoptosis rate was observed at 8 h compared to controls, while it was increased at 24 h. Tracheobronchial as well as alveolar epithelial cells experienced an enhanced caspase-3 activity upon LPS stimulation with no change of apoptosis rate under hypoxia. While increased apoptosis rate is triggered through an intrinsic and extrinsic pathway in alveolar macrophages, intrinsic signalling is activated in tracheobronchial epithelial cells. The exact pathway pattern in neutrophils and alveolar epithelial cells could not be determined. These data clearly demonstrate that upon injury each cell type experiences its own apoptosis pattern. Further experiments need to be performed to determine the functional role of these apoptotic processes in acute lung injury.

Acute Lung Injury in Preterm Newborn Infants: Mechanisms and Management

Respiratory morbidity and mortality remain common in preterm infants. The immature preterm lung is especially prone to injury. This process often starts in-utero due to maternal chorioamnionitis, priming the lung for further injury in response to post-natal ventilation, oxygen and nosocomial infection. Pulmonary inflammation has been strongly implicated in the pathway leading to lung injury in this population of infants. Several therapeutic approaches have been attempted to prevent acute lung injury or to limit its progress. The mechanisms of acute lung injury in preterm infants; their clinical correlates and available therapeutic approaches are reviewed here.

Activation of the stress protein response inhibits the STAT1 signalling pathway and iNOS function in alveolar macrophages: role of Hsp90 and Hsp70

Background and aimAlveolar fluid clearance is impaired by inducible nitric oxide synthase (iNOS)/nitric oxide (NO)-dependent mechanisms in acute lung injury (ALI)/acute respiratory distress syndrome (ARDS). The activation of the stress...

Effects of penehyclidine hydrochloride on apoptosis of lung tissues in rats with traumatic acute lung injury

Objective To investigate the effects of penehyclidine hydrochloride on apoptosis of lung tissue cells and its mechanism in acute lung injury following blunt chest trauma in rats. Methods Sprague Dawley (SD) rats ( n=54) weighing (250±25) g were divided equally and randomly into three groups: normal control group (C group, n=18), trauma model group (T group, n=18) and penehyclidine hydrochloride treatment group (P group, n=18). Each group was further divided into three subgroups according to the time points of 3, 12 and 24 hours after experiment (at each time point, n=6 for each subgroup). Rats of P group were intraperitoneally injected with penehyclidine hydrochloride for 2 mg/kg immediately after blunt chest trauma and rats in its 24 hours subgroup were once again injected with penehyclidine hydrochloride in the same dose 12 hours after injury. Lung tissue samples were collected at every time point and cell apoptosis in lung tissues were measured by TUNEL. Apoptotic index (AI) was calculated, expressions of bax and bcl-2 were detected by immunohistochemical staining of SABC, and lung tissue sections were taken for light and electron microscopic observation. Results As compared with C group, at every time point, AI and expressions of bax and bcl-2 in T group were higher ( P<0.05), and the ratio of bcl-2/bax markedly decreased ( P<0.05), especially in the 24 hours subgroup. The ratio in T group (0.468±0.007) was lower than that in C group (1.382±0.058, t=12.5, P<0.01). Lung tissue injuries were significant under a light microscope, and the number of apoptotic cells increased obviously under a transmission electron microscope. As compared with T group at the same phase, AI and expression of bax decreased in P group ( P<0.05 and P<0.01), while the expression of bcl-2 increased significantly ( P<0.01), and the ratio of bcl-2/bax markedly increased ( P<0.05), especially in the 24 hours subgroup. The ratio in P group (1.012±0.070) was much higher than that in T group (0.468±0.007, t =8.3, P<0.01). The injury of lung tissues was relieved, and apoptosis of cells decreased obviously under a transmission electron microscopic observation. Conclusions Apoptosis and expressions of bax and bcl-2 in lung tissues might be involved in the pathogenesis of lung injury induced by blunt chest trauma. Penehyclidine hydrochloride can alleviate lung injuries by inhibiting apoptosis of lung tissue cells, during which effects of penehyclidine hydrochloride on regulating expressions of bax and bcl-2 may play an important role.

Kidney ischemia-reperfusion injury induces caspase-dependent pulmonary apoptosis

Distant organ effects of acute kidney injury (AKI) are a leading cause of morbidity and mortality. While little is known about the underlying mechanisms, limited data suggest a role for inflammation and apoptosis. Utilizing a lung candidate gene discovery approach in a mouse model of ischemic AKI-induced lung dysfunction, we identified prominent lung activation of 66 apoptosis-related genes at 6 and/or 36 h following ischemia, of which 6 genes represent the tumor necrosis factor receptor (TNFR) superfamily, and another 23 genes are associated with the TNFR pathway. Given that pulmonary apoptosis is an important pathogenic mechanism of acute lung injury (ALI), we hypothesized that AKI leads to pulmonary proapoptotic pathways that facilitate lung injury and inflammation. Functional correlation with 1) terminal deoxynucleotidyl transferase-mediated dUTP nick end-labeling and 2) active caspase-3 (aC3) activity, immunoblotting, and immunohistochemistry (IHC) identified kidney IRI-induced pulmonary apoptosis at 24 h, and colocalization studies with CD34 identified predominantly endothelial apoptosis. Mice were treated with the caspase inhibitor Z-VAD-FMK (0.25 mg ip) or vehicle 1 h before and 8 h after sham or kidney IRI, and bronchoalveolar lavage fluid protein was measured at 36 h as a surrogate for lung leak. Caspase inhibition reduced lung microvascular changes after kidney IRI. The pulmonary apoptosis seen in wild-type control mice during AKI was absent in TNFR(-/-) mice. Using an initial genomic approach to discovery followed by a mechanistic approach to disease targeting, we demonstrate that pulmonary endothelial apoptosis is a direct mediator of the distant organ dysfunction during experimental AKI.