The long-term health effects of wildfire smoke exposure in pediatric populations are not known. The objectives of this study were to determine if early life exposure to wildfire smoke can affect parameters of immunity and airway physiology that are detectable with maturity. We studied a mixed-sex cohort of rhesus macaque monkeys that were exposed as infants to ambient wood smoke from a series of Northern California wildfires in the summer of 2008. Peripheral blood mononuclear cells (PBMCs) and pulmonary function measures were obtained when animals were approximately 3 years of age. PBMCs were cultured with either LPS or flagellin, followed by measurement of secreted IL-8 and IL-6 protein. PBMCs from a subset of female animals were also evaluated by Toll-like receptor (TLR) pathway mRNA analysis. Induction of IL-8 protein synthesis with either LPS or flagellin was significantly reduced in PBMC cultures from wildfire smoke-exposed female monkeys. In contrast, LPS- or flagellin-induced IL-6 protein synthesis was significantly reduced in PBMC cultures from wildfire smoke-exposed male monkeys. Baseline and TLR ligand-induced expression of the transcription factor, RelB, was globally modulated in PBMCs from wildfire smoke-exposed monkeys, with additional TLR pathway genes affected in a ligand-dependent manner. Wildfire smoke-exposed monkeys displayed significantly reduced inspiratory capacity, residual volume, vital capacity, functional residual capacity, and total lung capacity per unit of body weight relative to control animals. Our findings suggest that ambient wildfire smoke exposure during infancy results in sex-dependent attenuation of systemic TLR responses and reduced lung volume in adolescence.
These data demonstrate the development of immunological responses following chronic inhalation of a common environmental allergen during postnatal maturation in the non-human primate.
Rats were intratracheally instilled with bleomycin or with silica (quartz) dust to induce lung fibrosis. Several weeks later, purified collagen chains (or collagen digests) were isolated from the lungs of these animals and from age-matched controls instilled intratracheally with saline solution, and the ratios of hydroxylysine to lysine and of the dysfunctional cross-links DHLNL to HLNL were quantified. Collagen from fibrotic lungs had significantly higher ratios of DHLNL:HLNL than did control lungs, 15.5 +/- 4.8 and 17.1 +/- 4.8 vs. 2.3 +/- 0.5 for the silica-instilled and the bleomycin-instilled animals, respectively. The hydroxylysine:lysine ratio was significantly increased for the alpha 1(I) chain, to a value 170% of that of lung collagen from control animals, and for several of its constituent CNBr peptides. Lung tissue was exhaustively digested with collagenase and specific cross-linked peptides were isolated and characterized. The cross-linked alpha 1(I) x alpha 1(I) peptide linked by the residues 87 x 16C, with a ratio of DHLNL:HLNL of 17:1, demonstrated that the increased hydroxylation of the dysfunctional cross-links in fibrotic lung collagen could be accounted for in part by increased hydroxylation of the lysine residue at position 16C of the C-terminal telopeptide of the collagen alpha 1(I) chain. It proved impossible to locate the corresponding N-terminal cross-linked fragment from alpha 1(I) x alpha 1(I) chains, 9N x 930, possibly due to further reactions of this material to form the material referred to as poly(CB6). Isolated poly (CB6) accounted for more than half of the total alpha 1(I)CB6 peptide expected in lung collagen, and had a hydroxylysine:lysine content 2.8 times greater in bleomycin-treated animals than in their age-matched controls. Evidence was also found for a cross-linked alpha 1(III) x alpha 1(I) peptide linking residue 87 from the alpha 1(III) chain with residue 16C from the alpha 1(I) chain; it also had an increased ratio of DHLNL:HLNL. We conclude that the increased hydroxylation of lysine observed in two different animal models of lung fibrosis occurs preferentially at the N- and C-terminal nonhelical extension peptides of the alpha 1(I) collagen chains, and that this apparent specificity of overhydroxylation of fibrotic collagen may have important structural and pathological consequences.
The epidemiologic link between air pollutant exposure and asthma has been supported by experimental findings, but the mechanisms are not understood. In this study, we evaluated the impact of combined ozone and house dust mite (HDM) exposure on the immunophenotype of peripheral blood and airway lymphocytes from rhesus macaque monkeys during the postnatal period of development. Starting at 30 days of age, monkeys were exposed to 11 cycles of filtered air, ozone, HDM aerosol, or ozone + HDM aerosol. Each cycle consisted of ozone delivered at 0.5 ppm for 5 days (8h/day), followed by 9 days of filtered air; animals received HDM aerosol during the last 3 days of each ozone exposure period. Between 2-3 months of age, animals co-exposed to ozone + HDM exhibited a decline in total circulating leukocyte numbers and increased total circulating lymphocyte frequency. At 3 months of age, blood CD4+/CD25+ lymphocytes were increased with ozone + HDM. At 6 months of age, CD4+/CD25+ and CD8+/CD25+ lymphocyte populations increased in both blood and lavage of ozone + HDM animals. Overall volume of CD25+ cells within airway mucosa increased with HDM exposure. Ozone did not have an additive effect on volume of mucosal CD25+ cells in HDM-exposed animals, but did alter the anatomical distribution of this cell type throughout the proximal and distal airways. We conclude that a window of postnatal development is sensitive to air pollutant and allergen exposure, resulting in immunomodulation of peripheral blood and airway lymphocyte frequency and trafficking.
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