TGF-ß1 Suppresses the Type I IFN Response and Induces Mitochondrial Dysfunction in Alveolar Macrophages.

TGF-ß1 is a pleiotropic cytokine with an established role in fibrosis; however, the immunosuppressive effects of TGF-ß1 are less characterized. Elevated levels of TGF-ß1 are found in patients with acute and chronic lung diseases, and the underlying disease processes are exacerbated by respiratory viral infections. The alveolar macrophage is the first line of cellular defense against respiratory viral infections, and its response to infections is dependent on environmental cues. Using the mouse alveolar macrophage line, MH-S, and human CD14+ monocyte-derived macrophages, we examined the effects of TGF-ß1 on the type I IFN antiviral response, macrophage polarization, and mitochondrial bioenergetics following a challenge with human respiratory syncytial virus (RSV). Our results showed that TGF-ß1 treatment of macrophages decreased the antiviral and proinflammatory response, and suppressed basal, maximal, spare mitochondrial respiration, and mitochondrial ATP production. Challenge with RSV following TGF-ß1 treatment further exacerbated mitochondrial dysfunction. The TGF-ß1 and TGF-ß1+RSV-treated macrophages had a higher frequency of apoptosis and diminished phagocytic capacity, potentially through mitochondrial stress. Disruption of TGF-ß1 signaling or rescue of mitochondrial respiration may be novel therapeutically targetable pathways to improve macrophage function and prevent secondary bacterial infections that complicate viral respiratory infections.

Impaired defenses of neonatal mouse alveolar macrophage with cftr deletion are modulated by glutathione and TGFß1.

Our understanding of the intrinsic effects of cystic fibrosis (CF) transmembrane conductance regulator (cftr) deletion on resident neonatal alveolar macrophage (AM) remains limited. We previously demonstrated that diminished glutathione (GSH) or excessive AM transforming growth factor beta one (TGFß1) contributes to AM dysfunction in a variety of disease states. In this study, using a gut-corrected cftr neonatal knockout (KO) mouse model and a siRNA-manipulated macrophage-like cell line (THP-1 cell), we hypothesized (1) that cftr mutation alone increases neonatal AM oxidant stress and cellular TGFß1 signaling via altered GSH, thereby impairing cellular function, and (2) that exogenous GSH attenuates AM alterations and dysfunction in the KO AM In neonatal KO mice, the baseline bronchoalveolar lavage fluid demonstrated a near doubling in mixed disulfides (P ≤ 0.05) and oxidized GSSG (P ≤ 0.05) without concurrent inflammation compared to WT littermates. KO AM demonstrated diminished AM thiols (P ≤ 0.05), increased AM mitochondrial ROS (P ≤ 0.05), increased AM TGFß1 (P ≤ 0.05) with increased TGFß1 signaling (P ≤ 0.05), and impaired phagocytosis (P ≤ 0.05). KO AM mitochondrial ROS was modulated by exogenous GSH (P ≤ 0.05). Conversely, TGFß1 was reduced (P ≤ 0.05) and impaired phagocytosis was rescued (P ≤ 0.05) by exogenous GSH in the KO AM These results suggest that an altered neonatal AM phenotype may contribute to the initiation of lung inflammation/infection in the CF lung. Modulation of the AM in the neonatal CF lung may potentially alter progression of disease.

In utero alcohol effects on foetal, neonatal and childhood lung disease.

Maternal alcohol use during pregnancy exposes both premature and term newborns to the toxicity of alcohol and its metabolites. Foetal alcohol exposure adversely effects the lung. In contrast to the adult "alcoholic lung" phenotype, an inability to identify the newborn exposed to alcohol in utero has limited our understanding of its effect on adverse pulmonary outcomes. This paper will review advances in biomarker development of in utero alcohol exposure. We will highlight the current understanding of in utero alcohol's toxicity to the developing lung and immune defense. Finally, we will present recent clinical evidence describing foetal alcohol's association with adverse pulmonary outcomes including bronchopulmonary dysplasia, viral infections such as respiratory syncytial virus and allergic asthma/atopy. With research to define alcohol's effect on the lung and translational studies accurately identifying the exposed offspring, the full extent of alcohol's effects on clinical respiratory outcomes of the newborn or child can be determined.

Maternal Alcohol Use During Pregnancy and Associated Morbidities in Very Low Birth Weight Newborns.

BACKGROUND: We hypothesized that maternal alcohol use occurs in pregnancies that end prematurely and that in utero alcohol exposure is associated with an increased risk of morbidities of premature newborns. METHODS: In an observational study of mothers who delivered very low birth weight newborns (VLBW) ≤1,500 g, maternal alcohol use was determined via a standardized administered questionnaire. We compared the effect of maternal drinking on the odds of developing late-onset sepsis (LOS), bronchopulmonary dysplasia (BPD), death, BPD or death, days on oxygen or any morbidity (either LOS, BPD or death). The effect of drinking amounts (light versus heavy) was also evaluated. RESULTS: A total of 129 subjects who delivered 143 VLBW newborns were enrolled. Approximately 1 in 3 (34%) subjects reported drinking alcohol during the first trimester ("exposed"). Within the exposed group, 15% reported drinking ≥7drinks/week ("heavy") and 85% of the subjects reported drinking <7drinks/week ("light"). When controlling for maternal age, drug or tobacco use during pregnancy and neonatal gestational age, any drinking increased the odds of BPD or death and any morbidity. Furthermore, light or heavy drinking increased the odds of BPD or death and any morbidity, whereas heavy drinking increased the odds of LOS. CONCLUSIONS: In utero alcohol exposure during the first trimester occurred in 34% of VLBW newborns. Maternal drinking in the first trimester was associated with significantly increased odds of neonatal morbidity. Further studies are warranted to determine the full effect of in utero alcohol exposure on the adverse outcomes of VLBW premature newborns.

Comparison of Glutathione, Cysteine, and Their Redox Potentials in the Plasma of Critically Ill and Healthy Children.

BACKGROUND: Oxidative stress is known to play a role in critical illness due to an imbalance in reactive oxygen species and reactive nitrogen species, and the body's ability to detoxify pro-oxidants using small molecule anti-oxidants and anti-oxidant enzymes. OBJECTIVE: To compare the concentrations of plasma redox metabolites and redox potentials for the Cys/CySS and GSH/GSSG thiol/disulfide pairs in critically ill children with healthy control children. METHODS: We performed a prospective clinical observational study of children ages ≤18 years and weight ≥6 kg, who were hospitalized between January 2010 and April 2012 in a 30-bed multidisciplinary medical-surgical pediatric intensive care unit (PICU). We measured the plasma concentrations of Cys, CySS, GSH, and GSSG within the first 24 h of PICU arrival, and we calculated the redox potential for the Cys/CySS (Eh Cys/CySS) and GSH/GSSG (Eh GSH/GSSG) thiol/disulfide pairs in the plasma of 61 critically ill children and 16 healthy control children. RESULTS: Critically ill children have less Cys (p = 0.009), less CySS (p = 0.011), less Total Cys ([Cys] + 2[CySS], p = 0.01), more GSSG (p < 0.001), and more oxidized Eh GSH/GSSG (p < 0.001) compared to healthy children. CONCLUSION: Our results demonstrate that in the presence of pediatric critical illness, the Total Cys/CySS thiol pool decreases while GSH is likely one component of the cellular redox system that reduces CySS back to Cys, thus maintaining Eh Cys/CySS. The Total Cys pool is more abundant than the Total GSH pool in the plasma of children. Further investigation is needed to elucidate the differences in redox potentials in subgroups of critically ill children, and to determine whether differences in redox metabolite concentrations and redox potentials correlate with severity of critical illness and clinical outcomes.

Placental Fatty Acid ethyl esters are elevated with maternal alcohol use in pregnancies complicated by prematurity.

The accumulation of fatty acid ethyl esters (FAEEs) in meconium of term newborns has been described as one potential biomarker of maternal alcohol use during pregnancy. FAEEs accumulate in multiple alcohol-exposed fetal tissues and in the placenta. Limited research has focused on the identification of the premature newborn exposed to alcohol in utero. We hypothesized that maternal alcohol use occurs in a significant proportion of premature deliveries and that this exposure can be detected as elevated placental FAEEs. The goals of this study were to 1) determine the prevalence of maternal alcohol use in the premature newborn and 2) investigate whether placental FAEEs could identify those newborns with fetal alcohol exposure. This prospective observational study evaluated 80 placentas from 80 women after premature delivery. Subjects were interviewed for alcohol intake and placental FAEEs were quantified via GC/MS. Receiver Operator Characteristic (ROC) Curves were generated to evaluate the ability of placental FAEEs to predict maternal drinking during pregnancy. Adjusted ROC curves were generated to adjust for gestational age, maternal smoking, and illicit drug use. 30% of the subjects admitted to drinking alcohol during pregnancy and approximately 14% answered questions indicative of problem drinking (designated AUDIT+). The specific FAEEs ethyl stearate and linoleate, as well as combinations of oleate + linoleate + linolenate (OLL) and of OLL + stearate, were significantly (p<0.05) elevated in placentas from AUDIT+ pregnancies. Adjusted ROC Curves generated areas under the curve ranging from 88-93% with negative predictive values of 97% for AUDIT+ pregnancies. We conclude that nearly one third of premature pregnancies were alcohol-exposed, and that elevated placental FAEEs hold great promise to accurately determine maternal alcohol use, particularly heavy use, in pregnancies complicated by premature delivery.

Exhaled breath condensate in intubated neonates--a window into the lung's glutathione status.

BACKGROUND: Analysis of exhaled breath condensates (EBC) is a non-invasive technique to evaluate biomarkers such as antioxidants in the pediatric population, but limited data exists of its use in intubated patients, particularly newborns. Currently, tracheal aspirate (TA) serves as the gold standard collection modality in critically ill newborns, but this method remains invasive. We tested the hypothesis that glutathione status would positively correlate between EBC and TA collections in intubated newborns in the Newborn Intensive Care Unit (NICU). We also hypothesized that these measurements would be associated with alveolar macrophage (AM) glutathione status in the newborn lung. METHODS: Reduced glutathione (rGSH), glutathione disulfide (GSSG), and total GSH (rGSH + (2 X GSSG)) were measured in sequential EBC and TA samples from 26 intubated newborns via high performance liquid chromatography (HPLC). Additionally, AM glutathione was evaluated via immunofluorescence. Pearson's correlation coefficient and associated 95% confidence intervals were used to quantify the associations between raw and urea-corrected concentrations in EBC and TA samples and AM staining. Statistical significance was defined as p ≤ 0.05 using two-tailed tests. The sample size was projected to allow for a correlation coefficient of 0.5, with 0.8 power and alpha of 0.05. RESULTS: EBC was obtainable from intubated newborns without adverse clinical events. EBC samples demonstrated moderate to strong positive correlations with TA samples in terms of rGSH, GSSG and total GSH. Positive correlations between the two sampling sites were observed in both raw and urea-corrected concentrations of rGSH, GSSG and total GSH. AM glutathione staining moderately correlated with GSSG and total GSH status in both the TA and EBC. CONCLUSIONS: GSH status in EBC samples of intubated newborns significantly correlated with the GSH status of the TA sample and was reflective of cellular GSH status in this cohort of neonatal patients. Non-invasive EBC sampling of intubated newborns holds promise for monitoring antioxidant status such as GSH in the premature lung. Further studies are necessary to evaluate the potential relationships between EBC biomarkers in the intubated premature newborn and respiratory morbidities.

In utero nicotine exposure promotes M2 activation in neonatal mouse alveolar macrophages.

BACKGROUND: Maternal smoking in utero has been associated with adverse health outcomes including lower respiratory tract infections in infants and children, but the mechanisms underlying these associations continue to be investigated. We hypothesized that nicotine plays a significant role in mediating the effects of maternal tobacco smoke on the function of the neonatal alveolar macrophage (AM), the resident immune cell in the neonatal lung. METHODS: Primary AMs were isolated at postnatal day 7 from a murine model of in utero nicotine exposure. The murine AM cell line MH-S was used for additional in vitro studies. RESULTS: In utero nicotine increased interleukin-13 and transforming growth factor-ß1 (TGFß1) in the neonatal lung. Nicotine-exposed AMs demonstrated increased TGFß1 and increased markers of alternative activation with diminished phagocytic function. However, AMs from mice deficient in the α7 nicotinic acetylcholine receptor (α7 nAChR) had less TGFß1, reduced alternative activation, and improved phagocytic functioning despite similar in utero nicotine exposure. CONCLUSION: In utero nicotine exposure, mediated in part via the α7 nAChR, may increase the risk of lower respiratory tract infections in neonates by changing the resting state of AM toward alternative activation. These findings have important implications for immune responses in the nicotine-exposed neonatal lung.

Delayed neonatal lung macrophage differentiation in a mouse model of in utero ethanol exposure.

We have previously demonstrated that fetal ethanol exposure deranges the function and viability of the neonatal alveolar macrophage. Although altered differentiation of the alveolar macrophage contributes to pulmonary disease states within the adult lung, the effects of fetal ethanol exposure on the normal differentiation of interstitial to alveolar macrophage in the newborn lung are unknown. In the current study, using a mouse model of fetal ethanol exposure, we hypothesized that altered terminal differentiation of the neonatal interstitial to alveolar macrophage contributes to the observed cellular dysfunction in the ethanol-exposed newborn mouse. Control alveolar macrophage differentiation was characterized by increased expression of CD32/CD11b (P < or = 0.05) and increased in vitro phagocytosis of Staphylococcus aureus (P < or = 0.05) compared with interstitial macrophage. After in utero ethanol exposure, both alveolar and interstitial macrophage lacked the acquisition of CD32/CD11b (P < or = 0.05) and displayed impaired in vitro phagocytosis (P < or = 0.05). Ethanol significantly increased transforming growth factor-beta(1) (TGF-beta(1)) in the bronchoalveolar lavage fluid (P < or = 0.05), as well as in both interstitial and alveolar macrophages (P < or = 0.05). Oxidant stress contributed to the ethanol-induced changes on the interstitial and alveolar cells, since maternal supplementation with the glutathione precursor S-adenosylmethionine during ethanol ingestion normalized CD32/CD11b (P < or = 0.05), phagocytosis (P < or = 0.05), and TGF-beta(1) in the bronchoalveolar lavage fluid and macrophages (P < or = 0.05). Contrary to our hypothesis, fetal ethanol exposure did not solely impair interstitial to alveolar macrophage differentiation. Rather, fetal ethanol exposure impaired both neonatal interstitial and alveolar macrophage phagocytic function and differentiation. Increased oxidant stress and elevated TGF-beta(1) contributed to the impaired differentiation of both interstitial and alveolar macrophage.

Maternal alcohol use during pregnancy causes systemic oxidation of the glutathione redox system.

BACKGROUND: Increased systemic oxidant stress contributes to a variety of maternal complications of pregnancy. Although the antioxidant glutathione (GSH) and its oxidized component glutathione disulfide (GSSG) have been demonstrated to be significantly altered in the adult alcoholic, the effects of maternal alcohol use during pregnancy on oxidant stress in the postpartum female remain under investigation. We hypothesized that maternal alcohol use would increase systemic oxidant stress in the pregnant female, evidenced by an oxidized systemic GSH redox potential. METHODS: As a subset analysis of a larger maternal language study, we evaluated the effects of alcohol consumption during pregnancy on the systemic GSH redox status of the postpartum female. Using an extensive maternal questionnaire, postpartum women where queried regarding their alcohol consumption during pregnancy. Any drinking, the occurrence of drinking >3 drinks/occasion, and heavy drinking of >5 drinks/occasion during pregnancy were noted. Using HPLC, maternal plasma samples were analyzed for GSH, oxidized GSSG and the redox potential of the GSH/GSSG antioxidant pair calculated. RESULTS: Maternal alcohol use occurred in 25% (83/321) of our study sample. Two in ten women reported consuming >3 drinks/occasion during pregnancy, while 1 in 10 women reported consuming alcohol at >5 drinks/occasion. Any alcohol use during pregnancy significantly decreased plasma GSH (p < 0.05), while alcohol at >3 drinks/occasion or >5 drinks/occasion significantly decreased plasma GSH concentration (p < 0.05), increased the percent of oxidized GSSG (p < 0.05), and substantially oxidized the plasma GSH redox potential (p < 0.05). CONCLUSIONS: Alcohol use during pregnancy, particularly at levels >3 drinks/occasion, caused significant oxidation of the systemic GSH system in the postpartum women. The clinical ramifications of the observed alcohol-induced oxidation of the GSH redox system on high risk pregnancies or on the exposed offspring require more accurate identification and further investigation.

Impaired terminal differentiation of pulmonary macrophages in a Guinea pig model of chronic ethanol ingestion.

BACKGROUND: Alcoholic patients have an increased risk of respiratory infections, which is partially due to an impaired immune response of alveolar macrophages. The mechanisms by which alcohol impairs alveolar macrophage function are poorly understood. In this study, we demonstrated in a guinea pig model that chronic ethanol ingestion significantly impaired alveolar macrophage differentiation and function. METHODS: Isolated alveolar macrophages were separated into 4 different subpopulations with varying densities and levels of maturation. RESULTS: Compared to control values, chronic ethanol ingestion decreased the percentage of alveolar macrophages in the mature fractions by approximately 60%. Alveolar macrophage function in each subpopulation was determined by measuring phagocytosis of fluorescein isothiocyanate-labeled Staphylococcus aureus. Alveolar macrophages from ethanol-fed animals had approximately 80% decrease in the phagocytic index. Western blot and immunohistochemical analysis of the differential markers granulocyte/macrophage colony-stimulating factor (GM-CSF) receptor alpha (GM-CSFR-alpha), PU.1, CD11c, and CD11b verified that alcoholic macrophages displayed impaired terminal differentiation. While oral supplementation with the glutathione precursor S-adenosyl-methionine (SAM) did not alter the maturational status of control animals, SAM supplementation shifted the distribution of macrophages to more mature fractions, normalized the phagocytic index; as well as normalized expression of CD11c, CD11b, PU.1, and GM-CSFR-alpha. Chronic ethanol ingestion also impaired the differentiation status of interstitial macrophages which was normalized by SAM supplementation. CONCLUSION: This improvement in the maturational status suggested that ethanol-induced oxidant stress is a central feature in impaired terminal differentiation of macrophages in the interstitial and alveolar space. Therefore, strategies targeting pulmonary oxidant stress may restore macrophage differentiation and function even after chronic ethanol ingestion.

N-acetylcysteine improves group B streptococcus clearance in a rat model of chronic ethanol ingestion.

BACKGROUND: Sepsis is the most common risk factor associated with acute respiratory distress syndrome (ARDS) and results in a 40-60% mortality rate due to respiratory failure. Furthermore, recent epidemiological studies have demonstrated that a history of alcohol abuse increases the risk of ARDS by 3.6-fold. More recently, group B streptococcus (GBS) infections in nonpregnant adults have been increasing, particularly in alcoholics where there is an increased risk of lobular invasion and mortality. We have shown in an established rat model that chronic ethanol ingestion impaired macrophage internalization of inactivated infectious particles in vitro and enhanced bidirectional protein flux across the alveolar epithelial-endothelial barriers, both of which were attenuated when glutathione precursors were added to the diet. We hypothesized that chronic ethanol ingestion would increase the risk of infection even though GBS is less pathogenic but that dietary N-acetylcysteine (NAC), a glutathione precursor, would improve in vivo clearance of infectious particles and reduce systemic infection. METHODS: After 6 weeks of ethanol feeding, rats were given GBS intratracheally and sacrificed 24 hours later. GBS colony-forming units were counted in the lung, liver, spleen, and bronchoalveolar lavage fluid. Acute lung injury in response to GBS was also assessed. RESULTS: Chronic ethanol exposure decreased GBS clearance from the lung indicating an active lung infection. In addition, increased colonies formed within the liver and spleen indicated that ethanol increased the risk of systemic infection. Ethanol also exacerbated the acute lung injury induced by GBS. NAC supplementation normalized GBS clearance by the lung, prevented the appearance of GBS systemically, and attenuated acute lung injury. CONCLUSIONS: These data suggested that chronic alcohol ingestion increased the susceptibility of the lung to bacterial infections from GBS as well as systemic infections. Furthermore, dietary NAC improved in vivo clearance of GBS particles, attenuated acute lung injury, and disseminated infection.

In utero ethanol exposure impairs defenses against experimental group B streptococcus in the term Guinea pig lung.

BACKGROUND: The effects of fetal alcohol exposure on the risks of neonatal lung injury and infection remain under investigation. The resident alveolar macrophage (AM) is the first line of immune defense against pulmonary infections. In utero ethanol (ETOH) exposure deranges the function of both premature and term guinea pig AM. We hypothesized that fetal ETOH exposure would increase the risk of pulmonary infection in vivo. METHODS: We developed a novel in vivo model of group B Streptococcus (GBS) pneumonia using our established guinea pig model of fetal ETOH exposure. Timed-pregnant guinea pigs were pair fed +/-ETOH and some were supplemented with the glutathione (GSH) precursor S-adenosyl-methionine (SAM-e). Term pups were given GBS intratracheally while some were pretreated with inhaled GSH prior to the experimental GBS. Neonatal lung and whole blood were evaluated for GBS while isolated AM were evaluated using fluorescent microscopy for GBS phagocytosis. RESULTS: Ethanol-exposed pups demonstrated increased lung infection and sepsis while AM phagocytosis of GBS was deficient compared with control. When SAM-e was added to the maternal diet containing ETOH, neonatal lung and systemic infection from GBS was attenuated and AM phagocytosis was improved. Inhaled GSH therapy prior to GBS similarly protected the ETOH-exposed pup from lung and systemic infection. CONCLUSIONS: In utero ETOH exposure impaired the neonatal lung's defense against experimental GBS, while maintaining GSH availability protected the ETOH-exposed lung. This study suggested that fetal alcohol exposure deranges the neonatal lung's defense against bacterial infection, and support further investigations into the potential therapeutic role for exogenous GSH to augment neonatal AM function.

Highlight Commentary on "Influence of lung oxidant and antioxidant status on alveolarization: Role of light-exposed total parenteral nutrition".

Bronchopulmonary dysplasia (BPD) is a frequent complication of premature newborns, particularly very low birth-weight babies (<1500 g). Undoubtedly multiple mechanisms contribute to the adverse outcomes associated with BPD but oxidative stress is one causative factor. In this issue of Free Radical Biology and Medicine, Lavoie et al. describe the increased peroxide generation when the multivitamin solution used for nutritional support, total parenteral nutrition (TPN), is exposed to ambient light. Because the premature newborn has limited antioxidant capacity, this increased oxidative burden from the TPN becomes increasingly significant. Infusion of this light-exposed solution in a newborn guinea pig decreased lung tissue vitamin C but not vitamin E. When the multivitamin and lipid solutions were mixed and then exposed to light, alveolarization of the developing lung was decreased. This study by Lavoie et al. highlights simple measures that can potentially decrease the oxidant burden delivered to this vulnerable population and improve alveolarization.

Highlight Commentary on "Influence of lung oxidant and antioxidant status on alveolarization: role of light-exposed total parenteral nutrition"

Bronchopulmonary dysplasia (BPD) is a frequent complication of premature newborns, particularly very low birth-weight babies (< 1500 g). Undoubtedly multiple mechanisms contribute to the adverse outcomes associated with BPD but oxidative stress is one causative factor. In this issue of Free Radical Biology & Medicine, Lavoie et al describe the increased peroxide generation when the multivitamin solution used for nutritional support, total perenteral nutrition (TPN), is exposed to ambient light. Since the premature newborn has limited antioxidant capacity, this increased oxidative burden from the TPN becomes increasingly significant. Infusion of this light-exposed solution in a newborn guinea pig decreased lung tissue vitamin C but vitamin E. When the multivitamin and lipid solutions were mixed and then exposed to light, alveolarization of the developing lung was decreased. This study by Lavoie et al highlights simple measures that may potentially decrease the oxidant burden delivered to this vulnerable population and improve alveolarization.

In vivo dysfunction of the term alveolar macrophage after in utero ethanol exposure.

BACKGROUND: The effects of in utero alcohol exposure on the immune function of the newborn remain under investigation. Fetal ethanol (ETOH) exposure increases oxidative stress in the developing lung, in part due to decreased availability of the antioxidant glutathione (GSH). We have previously shown that in utero ETOH impairs alveolar macrophage phagocytosis and viability in the premature pup, while maintaining GSH availability with maternal supplementation of S-adenosyl-methionine (SAM) during ETOH ingestion improves macrophage function and viability. We hypothesized that dysfunction of the neonatal alveolar macrophage exposed to ETOH in utero would persist at term gestation. METHODS: Using a guinea-pig model of fetal ETOH exposure, timed-pregnant guinea-pigs were pair-fed ETOH+/-the GSH precursor SAM and the diet continued until spontaneous delivery. Term alveolar macrophages were evaluated using fluorescent microscopy for phagocytosis and apoptosis after in vitro incubation with Staphalococcus aureus. Using an in vivo model of intranasal Staph. aureus inoculation, the in vivo function of the term alveolar macrophage was also investigated using confocal fluorescent analysis. RESULTS: In utero ETOH exposure increased oxidant stress in the alveolar macrophage and decreased phagocytosis and viability in vitro and in vivo. Confocal analysis of phagocytosis in vivo demonstrated a marked impairment of internalization of the bacteria by the ETOH-exposed alveolar macrophage. The addition of SAM during maternal ETOH ingestion prevented loss of alveolar macrophage function and viability in vitro and in vivo. CONCLUSIONS: In utero ETOH exposure impairs alveolar macrophage function and viability in vitro and in vivo even at term gestation. The ETOH-induced changes in macrophage function and viability can be ablated with maternal SAM supplementation. Further investigations are required to identify the mechanisms of ETOH-induced derangement of phagocytosis in the neonatal alveolar macrophage and the clinical ramifications of altered immune function after in utero alcohol exposure for the newborn.

Glutathione availability modulates alveolar macrophage function in the chronic ethanol-fed rat.

We have previously demonstrated that chronic alcohol exposure decreases glutathione in the alveolar space. Although alcohol use is associated with decreased alveolar macrophage function, the mechanism by which alcohol impairs macrophage phagocytosis is unknown. In the current study, we examined the possibility that ethanol-induced alveolar macrophage dysfunction was secondary to decreased glutathione and subsequent chronic oxidative stress in the alveolar space. After 6 wk of ethanol ingestion, oxidant stress in the alveolar macrophages was evidenced by a 30-mV oxidation of the GSH/GSSG redox potential (P

Maternal alcohol abuse and neonatal infection.

BACKGROUND: Since chronic alcohol use suppresses the adult immune system, we tested the hypothesis that maternal alcohol ingestion increases the risk of infection in term newborns. METHODS: Analysis of a large case-control study of birth weight for gestational age was performed focusing on maternal alcohol ingestion and the development of infection in term newborns > or =36 weeks gestation. After delivery, mothers were asked about alcohol and tobacco use in the 3 months prior to conception, the 1st, 2nd, and 3rd trimester of pregnancy. RESULTS: Eight hundred and seventy-two singleton newborns (872) > or = 36 weeks gestation were identified for analysis. A total of 51 (5.8%) had newborn infections. Gestational age, sex, and small for gestational age (SGA) were similar in the newborns with and without infection (p = NS). Infants whose mothers reported alcohol use, excessive drinking or smoking in pregnancy were more likely to have a newborn diagnosed with an infection than were mothers who reported abstaining from alcohol or cigarettes (p < 0.05). When controlling for race and smoking, SGA infants whose mothers used any alcohol had a 2.5-fold increase risk of infection, while excessive alcohol use increased the risk 3-4-fold. In a multivariable logistic regression analysis controlling for low maternal income, smoking, and SGA, excessive alcohol use during the 2 trimester increased the risk of newborn infection (OR 3.7 [1.1,12.8], p < 0.05). CONCLUSIONS: Excessive maternal alcohol use is associated with an increased risk of newborn infection in this patient sample. Increased awareness and further clinical investigations are warranted to address the detrimental effects of fetal alcohol exposure on the developing immune system.

Fetal alcohol exposure impairs alveolar macrophage function via decreased glutathione availability.

Immature function of the alveolar macrophage increases the risk of pulmonary infections in premature newborns. In utero alcohol increases fetal systemic oxidative stress. Because the premature lung is deficient in glutathione (GSH), we hypothesized that chronic in utero alcohol (ethanol) exposure exacerbates the oxidative stress within the developing lung, thereby impairing alveolar macrophage function. Additionally, we evaluated the effects of in vivo and in vitro GSH availability on ethanol-exposed macrophage function. Using a guinea pig model of chronic in utero ethanol exposure, fetal epithelial lining fluid (ELF) and alveolar macrophage GSH were decreased with increased markers of oxidative stress. Ethanol-exposed macrophage exhibited impaired phagocytosis and increased apoptosis compared with gestational control. When the GSH precursor S-adenosyl-methionine (SAM) was added to the maternal drinking water containing ethanol, fetal ELF and macrophage GSH were maintained and ELF oxidative stress diminished. In vivo maternal SAM therapy maintained macrophage phagocytosis and decreased apoptosis. In vitro GSH supplements also improved phagocytosis and viability in both premature and ethanol-exposed macrophage. This suggested that in utero ethanol impaired premature macrophage function and viability via decreased GSH availability. Furthermore, GSH supplementation during and after ethanol exposure improved fetal macrophage function and viability. These results add a new dimension to the detrimental effects of fetal alcohol exposure on the developing alveolar macrophage, raising the possibility of GSH therapy to augment premature alveolar macrophage function.

Chronic ethanol ingestion and the risk of acute lung injury: a role for glutathione availability?

Although pulmonary function is not altered, a history of alcohol abuse is an independent outcome variable in the development of acute respiratory distress syndrome. In the absence of cirrhosis, alcohol abuse decreased glutathione, the key antioxidant lining the alveolar space, by 80% and is associated with alveolar barrier leak. Neither the glutathione pool nor barrier leak was corrected by abstinence for 1 week. This aberrant glutathione homeostasis may contribute to enhanced alveolar permeability, thereby increasing susceptibility to the development of acute respiratory distress syndrome. In a rat model, chronic ingestion of ethanol decreased pulmonary glutathione concentration, increased alveolar barrier permeability, and increased the risk of acute lung injury. In alveolar type II cells, chronic ingestion of ethanol altered cellular functions such as decreased surfactant processing, decreased barrier integrity, and increased sensitivity to cytotoxin-induced apoptosis in vitro and in vivo. In alveolar macrophages, chronic ingestion of ethanol decreased phagocytosis of microorganisms and decreased cell viability, events that would increase the risk of pneumonia. A central role for glutathione availability was demonstrated by the normalization of cellular function and viability of type II cells and macrophages as well as decreased sensitivity to endotoxemia-induced acute lung injury when glutathione precursors were added to the ethanol diet. These results support the suggestion that chronic ingestion of ethanol increased the risk of acute lung injury not through ethanol per se but through the chronic oxidative stress that resulted from ethanol-induced glutathione depletion. Because chronic oxidative stress alters cellular functions and viability, the lung becomes more susceptible when a second hit such as sepsis occurs.