20 research outputs found
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Combustion generated nickel species aerosols: Role of chemical and physical properties on lung injury
Homeobox, Wnt, and fibroblast growth factor signaling is augmented during alveogenesis in mice lacking superoxide dismutase 3, extracellular.
Superoxide dismutase 3, extracellular (SOD3) polymorphisms have been implicated in reduced pulmonary function development and altered risk for chronic obstructive pulmonary disease. We previously reported that gene-targeted Sod3−/− mice have impaired lung function and human SOD3 variants are associated with reduced pulmonary function in children. Reduced lung SOD3 levels were reported in mice with lower lung function with the greatest difference occurring during alveogenesis phase [postnatal (P) days 14–28]. Interactions between homeobox (HOX), wingless-type MMTV integration site member (WNT), and fibroblast growth factor (FGF) signaling govern complex developmental processes in several organs. A subset of HOX family members, HOXA5 and HOXB5, is expressed in the developing lung. Therefore, in this study we assessed the transcript expression of these family members and their downstream targets in Sod3−/− mice during alveogenesis (P14). In the lung of Sod3−/− mice, Hoxa5 and Hoxb5 increased. These transcription factors regulate WNT gene expression and were accompanied by increases in their downstream targets Wnt2 and Wnt5A, canonical and noncanonical WNT members, respectively. The WNT signaling target, lymphoid enhancer binding factor 1 (Lef1), also increased along with its downstream targets Fgf2, Fgf7, and Fgf10 in the lungs of Sod3−/− mice. Due to limited knowledge on the role of FGF2 in lung development, we further examined FGF2 protein and found increased levels in the bronchial and alveolar type II epithelial cells of Sod3−/− mice compared to age-matched controls. Thus, our findings suggest that deficient management of extracellular superoxide can lead to altered lung developmental signaling during alveogenesis in mice
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Pathogenomic mechanisms for particulate matter induction of acute lung injury and inflammation in mice.
Candidate genes controlling pulmonary function in mice: Transcript profiling and predicted protein structure.
Impaired development and reduced lung capacity are risk factors of asthma and chronic obstructive pulmonary disease. Previously, our genomewide linkage analysis of C3H/HeJ (C3H) and JF1/Msf (JF1) mouse strains identified quantitative trait loci (QTLs) associated with the complex traits of dead space volume (Vd), total lung capacity (TLC), lung compliance (CL), and diffusing capacity for CO (D(CO)). We assessed positional candidate genes by comparing C3H with JF1 lung transcript levels by microarray and by comparing C3H, BALB/cByJ, C57BL/6J, A/J, PWD/PhJ, and JF1 strains, using exon sequencing to predict protein structure. Microarray identified >900 transcripts differing in C3H and JF1 lungs related to lung development, function, and remodeling. Of these, three genes localized to QTLs associated with differences in lung function. C3H and JF1 strains differed in transcript and protein levels of superoxide dismutase 3, extracellular [SOD3; mouse chromosome (mCh) 5: VD] and transcript of trefoil factor 2 (TFF2; mCh 17: TLC and D(CO)), and ectonucleotide pyrophosphatase/phosphodiesterase 2 (ENPP2; mCh 15: TLC and CL). Nucleotide sequencing of Sod3, Tff2, and previously identified Relaxin 1 (Rln1; mCh 19: CL) uncovered polymorphisms that could lead to nonsynonymous amino acid changes and altered predicted protein structure. Gene-targeted Sod3(-/-) mice had increased conducting airway volume (Vd/TLC) compared with strain-matched control Sod3(+/+) mice, consistent with the QTL on mCh 5. Two novel genes (Tff2 and Enpp2) have been identified and two suspected genes (Sod3 and Rln1) have been supported as determinants of lung function in mice. Findings with gene-targeted mice suggest that SOD3 is a contributing factor defining the complex trait of conducting airway volume
Transcriptomic analysis comparing mouse strains with extreme total lung capacities identifies novel candidate genes for pulmonary function.
BACKGROUND: Failure to attain peak lung function by early adulthood is a risk factor for chronic lung diseases. Previously, we reported that C3H/HeJ mice have about twice total lung capacity (TLC) compared to JF1/MsJ mice. We identified seven lung function quantitative trait loci (QTL: Lfnq1-Lfnq7) in backcross/intercross mice derived from these inbred strains. We further demonstrated, superoxide dismutase 3, extracellular (Sod3), Kit oncogene (Kit) and secreted phosphoprotein 1 (Spp1) located on these Lfnqs as lung function determinants. Emanating from the concept of early origin of lung disease, we sought to identify novel candidate genes for pulmonary function by investigating lung transcriptome in C3H/HeJ and JF1/MsJ mice at the completion of embryonic development, bulk alveolar formation and maturity. METHODS: Design-based stereological analysis was performed to study lung structure in C3H/HeJ and JF1/MsJ mice. Microarray was used for lung transcriptomic analysis [embryonic day 18, postnatal days 28, 70]. Quantitative real time polymerase chain reaction (qRT-PCR), western blot and immunohistochemical analysis were used to confirm selected differences. RESULTS: Stereological analysis revealed decreased alveolar number density, elastin to collagen ratio and increased mean alveolar volume in C3H/HeJ mice compared to JF1/MsJ. Gene ontology term "extracellular region" was enriched among the decreased JF1/MsJ transcripts. Candidate genes identified using the expression-QTL strategy include: ATP-binding cassette, sub-family G (WHITE), member 1 (Abcg1), formyl peptide receptor 1 (Fpr1), gamma-aminobutyric acid (GABA) B receptor, 1 (Gabbr1); histocompatibility 2 genes: class II antigen E beta (H2-Eb1), D region locus 1 (H2-D1), and Q region locus 4 (H2-Q4); leucine rich repeat containing 6 (testis) (Lrrc6), radial spoke head 1 homolog (Rsph1), and surfactant associated 2 (Sfta2). Noteworthy genes selected as candidates for their consistent expression include: Wnt inhibitor factor 1 (Wif1), follistatin (Fst), chitinase-like 1 (Chil1), and Chil3. CONCLUSIONS: Comparison of late embryonic, adolescent and adult lung transcript profiles between mouse strains with extreme TLCs lead to the identification of candidate genes for pulmonary function that has not been reported earlier. Further mechanistic investigations are warranted to elucidate their mode of action in determining lung function
Secreted phosphoprotein 1 is a determinant of lung function development in mice.
Secreted phosphoprotein 1 (Spp1) is located within quantitative trait loci associated with lung function that was previously identified by contrasting C3H/HeJ and JF1/Msf mouse strains that have extremely divergent lung function. JF1/Msf mice with diminished lung function had reduced lung SPP1 transcript and protein during the peak stage of alveologenesis (postnatal day 14-28) as compared to C3H/HeJ mice. In addition to a previously identified genetic variant that altered runt related transcription factor 2 (RUNX2) binding in the Spp1 promoter, we identified another promoter variant in a putative RUNX2 binding site that increased the DNA protein binding. SPP1 induced dose dependent MLE-15 cell proliferation. Spp1((-/-)) mice have decreased specific total lung capacity/body weight, higher specific compliance, and increased mean airspace chord length (Lm) compared to Spp1((+/+)) mice. Microarray analysis revealed enriched gene ontogeny (GO) categories with numerous genes associated with lung development and/or respiratory disease. IGF1, HHIP, WNT5A, and NOTCH1 transcripts decreased in the lung of P14 Spp1((-/-)) mice as determined by qRT-PCR analysis. SPP1 promotes pneumocyte growth and mice lacking SPP1 have smaller, more compliant lungs with enlarged airspace (increased Lm). Microarray analysis suggests a dysregulation of key lung developmental transcripts in gene targeted Spp1((-/-)) mice particularly during the peak phase of alveologenesis. In addition to its known roles in lung disease, this study supports SPP1 as a determinant of lung development in mice