Human Lung Project: Evaluating Variance of Gene Expression in the Human Lung

Gruber, Michael P.; Coldren, Christopher D.; Woolum, Malcolm D.; Cosgrove, Gregory P.; Zeng, Chan; Barón, Anna E.; Moore, Matthew; Cool, Carlyne D.; Worthen, G. Scott; Brown, Kevin K.; Geraci, Mark W.

doi:10.1165/rcmb.2004-0261oc

Cited by 32 publications

(34 citation statements)

References 52 publications

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“…The precision of our expression profiling is influenced by biological variability between individual donors, including smoking history, and is likely further affected by variables such as extent of hypoxemia prior to death, use of mechanical ventilation, time from death to cell isolation, duration of the isolation procedure, and cell purity. The variability in lung gene expression between individuals is recognized and was similar for our experiments (median coefficient of variation of 32%) and those with postmortem human lung tissue (34). All donor lungs in our study were from males, which may have a minor effect on our results; in a genderspecific microarray study of lung tissue, 11% of X-linked genes were expressed at Ͼ1.5-fold different level between genders (60).…”

Section: Does the Pattern Of Gene Expression In Dci-treated Fetal Episupporting

confidence: 82%

Regulated gene expression in cultured type II cells of adult human lung

Ballard¹,

Lee²,

Fang³

et al. 2010

American Journal of Physiology-Lung Cellular and Molecular Phys

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Alveolar type II cells have multiple functions, including surfactant production and fluid clearance, which are critical for lung function. Differentiation of type II cells occurs in cultured fetal lung epithelial cells treated with dexamethasone plus cAMP and isobutylmethylxanthine (DCI) and involves increased expression of 388 genes. In this study, type II cells of human adult lung were isolated at approximately 95% purity, and gene expression was determined (Affymetrix) before and after culturing 5 days on collagen-coated dishes with or without DCI for the final 3 days. In freshly isolated cells, highly expressed genes included SFTPA/B/C, SCGB1A, IL8, CXCL2, and SFN in addition to ubiquitously expressed genes. Transcript abundance was correlated between fetal and adult cells (r = 0.88), with a subset of 187 genes primarily related to inflammation and immunity that were expressed >10-fold higher in adult cells. During control culture, expression increased for 8.1% of expressed genes and decreased for approximately 4% including 118 immune response and 10 surfactant-related genes. DCI treatment promoted lamellar body production and increased expression of approximately 3% of probed genes by > or =1.5-fold; 40% of these were also induced in fetal cells. Highly induced genes (> or =10-fold) included PGC, ZBTB16, DUOX1, PLUNC, CIT, and CRTAC1. Twenty-five induced genes, including six genes related to surfactant (SFTPA/B/C, PGC, CEBPD, and ADFP), also had decreased expression during control culture and thus are candidates for hormonal regulation in vivo. Our results further define the adult human type II cell molecular phenotype and demonstrate that a subset of genes remains hormone responsive in cultured adult cells.

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Section: Does the Pattern Of Gene Expression In Dci-treated Fetal Episupporting

confidence: 82%

Regulated gene expression in cultured type II cells of adult human lung

Ballard¹,

Lee²,

Fang³

et al. 2010

American Journal of Physiology-Lung Cellular and Molecular Phys

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“…Recent studies validated changes in modulated genes similar in direction and magnitude when compared with semiquantitative RT-PCR (38,41,42). The new strategies developed to improve the validity of the analysis focus on the identification of sets of genes instead of individual genes by themselves (43,44). In this study, we used the same approach, assuming that a set of genes displaying coordinated expression level is involved in a functional pathway.…”

Section: Discussionmentioning

confidence: 99%

Gene Expression Profile of Human Airway Epithelium Induced by Hyperoxia In Vivo

Chambellan

Cruickshank²,

McKenzie³

et al. 2006

Am J Respir Cell Mol Biol

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Hyperoxia leads to oxidative modification and damage of macromolecules in the respiratory tract with loss of biological functions. Given the lack of antioxidant gene induction with acute exposure to 100% oxygen, we hypothesized that clearance pathways for oxidatively modified proteins may be induced and serve in the immediate cellular response to preserve the epithelial layer. To test this, airway epithelial cells were obtained from individuals under ambient oxygen conditions and after breathing 100% oxygen for 12 h. Gene expression profiling identified induction of genes in the chaperone and proteasome-ubiquitin-conjugation pathways that together comprise an integrated cellular response to manage and degrade damaged proteins. Analyses also revealed gene expression changes associated with oxidoreductase function, cell cycle regulation, and ATP synthesis. Increased HSP70, protein ubiquitination, and intracellular ATP were validated in cells exposed to hyperoxia in vitro. Inhibition of proteasomal degradation revealed the importance of accelerated protein catabolism for energy production of cells exposed to hyperoxia. Thus, the human airway early response to hyperoxia relies predominantly upon induction of cytoprotective chaperones and the ubiquitin-proteasome-dependent protein degradation system to maintain airway homeostatic integrity.Keywords: airways; gene expression; hyperoxia; proteasome; ubiquitin Oxygen, one of the most abundant elements in our world, is essential for the oxidation of organic compounds to generate the energy needed to sustain life. Under ambient conditions, reactive oxygen species (ROS) are generated at a low level in lung cells during aerobic metabolism. To minimize the oxidant injury that is a consequence of aerobic life, the human lung is endowed with an integrated antioxidant system, which detoxifies reactive products (1-4). However, excessive ROS may overwhelm the antioxidant system and result in damage to major cellular components, including membrane lipids, proteins, carbohydrates, and DNA (1,(5)(6)(7)(8). The pathophysiologic consequences of this injury may include cell death, and tissue inflammation and damage. This is particularly evident during conditions of increased oxygen exposure for medical therapy (4, 9, 10). The bronchial epithelium is particularly vulnerable to the effects of airborne oxidative stress as the moist mucosal surface of the airway is in direct contact with the environment (11). Hyperoxia leads to oxidant injury in the respiratory tract, which is manifest as acute tracheobronchitis with edema and decrease in mucocili-(Received in original form July 8, 2005 and in final form May 4, 2006 ) This study was supported by AI70649, HL60917, and M01 RR018390 from the National Center for Research Resources. A.C. was supported by grants from the Collège des Professeurs de Pneumologie.Correspondence and requests for reprints should be addressed to Serpil C. (12,13). Oxidative damage of proteins and loss of biological function is one defined end-point of hyperoxic inj...

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“…The use of inbred mice achieves several advantages such as isogenicity and genomewide homozygosity among individuals within a strain, which significantly reduces gene expression variability between individuals. This variability was confounding in the aging human study (18). Aging mouse models have been used, for example, to evaluate global gene expression changes in skeletal muscle (35).…”

mentioning

confidence: 99%

“…However, differential gene expression analyses have not been applied to the aging lung, a critical primary organ in the defense against environmental insults such as airborne pollutants. To date, only one study has documented global expression in healthy human lungs (18) as a function of age. Although this study did not actually achieve statistical significance in gene expression variation with age, modest global differences in gene expression between young and old subjects were observed.…”

mentioning

confidence: 99%

Global expression profiles from C57BL/6J and DBA/2J mouse lungs to determine aging-related genes

Misra

Lee

Singh

et al. 2007

Physiological Genomics

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This study identified gene expression profiles that provided evidence for genomic mechanisms underlying the pathophysiology of aging lung. Aging lungs from C57BL/6 (B6) and DBA/2 (D2) mouse strains differ in physiology and morphometry. Lungs were harvested from B6 mice at 2, 18, and 26 mo and from D2 mice at 2 and 18 mo of age. Purified RNA was subjected to oligonucleotide microarray analyses, and differential expression analyses were performed for comparison of various data sets. A significant majority of differentially expressed genes were upregulated with aging in both strains. Aging D2 lungs uniquely exhibited upregulation in stress-response genes including xenobiotic detoxification cascades. In contrast, aging B6 lungs showed downregulation of heat shock-response genes. Age-dependent downregulation of genes common to both B6 and D2 strains included several collagen genes (e.g., Col1a1 and Col3a1). There was a greater elastin gene (Eln) expression in D2 mice at 2 mo, and Eln was uniquely downregulated with age in this strain. The matrix metalloproteinase 14 gene (Mmp14), critical to alveolar structural integrity, was also downregulated with aging in D2 mice only. Several polymorphisms in the regulatory and untranslated regions of Mmp14 were identified between strains, suggesting that variation in Mmp14 gene regulation contributes to accelerated aging of lungs in D2 mice. In summary, lungs of B6 and D2 mice age with variable rates at the gene expression level, and these quantifiable genomic differences provide a template for understanding the variability in age-dependent changes in lung structure and function.Mmp14; lung elasticity; lung senescence; microarray; mouse single nucleotide polymorphisms GLOBAL GENE EXPRESSION PROFILING is a powerful tool to generate hypotheses for less understood processes and has been used to study aging-associated gene expression changes in a variety of mouse tissues (8,9,25,27,35,36). However, differential gene expression analyses have not been applied to the aging lung, a critical primary organ in the defense against environmental insults such as airborne pollutants. To date, only one study has documented global expression in healthy human lungs (18) as a function of age. Although this study did not actually achieve statistical significance in gene expression variation with age, modest global differences in gene expression between young and old subjects were observed.The present study offers certain alternatives relative to studies using clinical samples by employing inbred mouse strains. The use of inbred mice achieves several advantages such as isogenicity and genomewide homozygosity among individuals within a strain, which significantly reduces gene expression variability between individuals. This variability was confounding in the aging human study (18). Aging mouse models have been used, for example, to evaluate global gene expression changes in skeletal muscle (35). One of the primary findings with aged skeletal muscle suggested that stress-response genes, including heat...

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Human Lung Project: Evaluating Variance of Gene Expression in the Human Lung

Cited by 32 publications

References 52 publications

Regulated gene expression in cultured type II cells of adult human lung

Regulated gene expression in cultured type II cells of adult human lung

Gene Expression Profile of Human Airway Epithelium Induced by Hyperoxia In Vivo

Global expression profiles from C57BL/6J and DBA/2J mouse lungs to determine aging-related genes

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