Project description:Effect of prenatal sulforaphane (SUL) on hyperoxia-induced lung injury in Nrf2+/+ and Nrf2-/- neonates

Project description:Background: Nrf2 is an essential cytoprotective transcription factor. However, association of Nrf2 in organ development and neonatal disease is rarely examined. Hyperoxia exposure to newborn rodents generates pulmonary phenotypes which resemble bronchopulmonary dysplasia (BPD) of prematurity. Methods: To investigate the role of Nrf2 in lung maturation and BPD pathogenesis, Nrf2-deficient (Nrf2-/-) and wild-type (Nrf2+/+) neonates were exposed to air or hyperoxia (O2). Transcriptome analysis determined Nrf2-directed mechanisms in premature lung. Lung injury was assessed by bronchoalveolar lavage analysis and histopathology. Results: In Nrf2-/- neonates, basal expression of cell cycle machinery, redox balance, and lipid/carbohydrate metabolism genes were suppressed while immunity genes were overexpressed compared to Nrf2+/+ pups. O2-induced mortality and pulmonary inflammation/injury were significantly higher in Nrf2-/- than in Nrf2+/+. Lung DNA lesion and oxidation were greater in Nrf2-/- than in Nrf2+/+, constitutively and after O2. Nrf2-dependent genes modulated cellular growth/proliferation, defense, immunity, and lipid metabolism against hyperoxia. Bioinformatic elucidation of Nrf2 binding motifs and augmented O2-induced inflammation in genetically deficient neonates validated Gpx2 and Marco as Nrf2 effectors. Conclusion: Overall, Nrf2 in underdeveloped lungs orchestrated cell cycle, morphogenesis, and immunity as well as cellular defense constitutively and under oxidant stress. Results provide putative molecular mechanisms of Nrf2-directed lung alveolarization and BPD of prematurity. PARALLEL study design with 42 samples comparing 14 groups of age (P1 to P4 corresponding to day 0 to day 3 animals), gene, and exposure: (4 groups Nrf+/+ wild type P1-P4 air exposure) (4 groups Nrf -/- knockout P1-P4 air exposure), (3 groups Nrf+/+ wild type P2-P4 with 100 percent O2 (hyperoxia exposure) and 3 groupsNrf -/- knockout P2-P4 with 100 percent O2 (hyperoxia exposure)) Biological replicates: 3 per group

Project description:Background: Nrf2 is an essential cytoprotective transcription factor. However, association of Nrf2 in organ development and neonatal disease is rarely examined. Hyperoxia exposure to newborn rodents generates pulmonary phenotypes which resemble bronchopulmonary dysplasia (BPD) of prematurity. Methods: To investigate the role of Nrf2 in lung maturation and BPD pathogenesis, Nrf2-deficient (Nrf2-/-) and wild-type (Nrf2+/+) neonates were exposed to air or hyperoxia (O2). Transcriptome analysis determined Nrf2-directed mechanisms in premature lung. Lung injury was assessed by bronchoalveolar lavage analysis and histopathology. Results: In Nrf2-/- neonates, basal expression of cell cycle machinery, redox balance, and lipid/carbohydrate metabolism genes were suppressed while immunity genes were overexpressed compared to Nrf2+/+ pups. O2-induced mortality and pulmonary inflammation/injury were significantly higher in Nrf2-/- than in Nrf2+/+. Lung DNA lesion and oxidation were greater in Nrf2-/- than in Nrf2+/+, constitutively and after O2. Nrf2-dependent genes modulated cellular growth/proliferation, defense, immunity, and lipid metabolism against hyperoxia. Bioinformatic elucidation of Nrf2 binding motifs and augmented O2-induced inflammation in genetically deficient neonates validated Gpx2 and Marco as Nrf2 effectors. Conclusion: Overall, Nrf2 in underdeveloped lungs orchestrated cell cycle, morphogenesis, and immunity as well as cellular defense constitutively and under oxidant stress. Results provide putative molecular mechanisms of Nrf2-directed lung alveolarization and BPD of prematurity.

Project description:Effect of prenatal sulforaphane (SUL) on Nrf2+/+ and Nrf2-/- placenta

Project description:Results: In Nrf2+/+ placenta, genes involved in estrogen receptor signaling and reproductive system development (e.f., Med subfamily, Igf1r, Ncor2), vasculature and embryonic development (e.g., Adamdec1, Pdgfrb, Col8a2, Sema3g, Krt5, Lce1a1), and inhibition of prenatal death and cell morbidity (e.g., Dnmt3a, Col4a2) were regulated by SFN. Multiple granzyme isozymes (Gzmd, Gzmg, Gzmf, Gzmc) and oxidoreduction genes (e.g., Gstt1, Gstt2, Prdx5, Hao3, Hsd17b10, Pecr) were suppressed in Nrf2+/+ placenta treated with SFN. SFN-altered transcriptome changes in Nrf2-/- placenta were predicted to inhibit prenatal death via regulation of genes including Igf2r, Tgfb2, Arid5b, and Il6st and to activate angiogenesis and cell growth by alteration of genes such as Timp3, Kdr, and Il6ra. Conclusion: Overall transcriptome changes indicated reduced cytotoxicity and activated feto-placenta barrier functions in both Nrf2+/+ and Nrf2-/- mice.

Project description:Background: NRF2 is an essential cytoprotective transcription factor inducing antioxidant response element (ARE)-bearing genes. However, association of NRF2 with lung development has not been examined. Human lungs are not fully developed until 2-3 years of and they are fully matured at about 8 years. Murine lungs at birth are immature (at saccular stage of lung development) and have been used to study developmental lung disorders. Methods: To investigate (1) the transcriptome changes during lung development and (2) the role of NRF2 in lung development and maturation in mice, lungs were harvested from Nrf2-deficient (Nrf2-/-) and wild-type (Nrf2+/+) mouse embryos, neonates and adults. Microarray and pathway analysis determined NRF2-directed mechanisms underlying lung development and maturation. Results: Nrf2 mRNA expression was peack at embryonic days E17.5-E18.5 (immediately before birth) probably to increase antioxidant apparatus to prepare against high O2 environment after birth. The pseudoglandular phase lungs (E13-E15) are undergoing vigorous cell proliferation under the control of high-fidelity DNA damage repair system. Fetal lungs (E13.5-E17.5) are lack in immune system, xenobiotic metabolism, and tissue damage genes. After birth at postnatal day 1 (PND1), lung cell division is quiescent but transporters and lipid metabolism are activated. When lung enters alveolar phase (PND4), cell proliferation is resumed. Mature lungs (PND14-P42) have heightened networks of host defense systems (immunity, antioxidants) and cellular injury and abnormality (e.g., glucose metabolism disorder). Nrf2 deletion in fetal lung (E13.5-E17.5) altered developmental, immunity, and metabolism genes, and it may have affected lung branching. Nrf2 deletion affected lung transcriptome changes the most at E17.5 when Nrf2 message level is maximum (E17.5-E18.5). Nrf2 deletion in newborn lung (PND0) decreased cell cycle progress and DNA damage repair. Nrf2 deletion in neonatal lung (PND1-4) enhanced tissue injury/cell death and inhibited developmental cell differentiation. Nrf2 deletion in matured mouse lung (PND42) affected not only antioxidant pathway but also immune responses and connective tissue cell migrations. Conclusion: Overall, NRF2 plays multiple roles in underdeveloped lungs and associated with lung morphogenesis, immunity, cell cycle progress, tissue differentiation and metabolism as well as cellular defense. Results provide putative molecular mechanisms of NRF2-directed lung morphogenesis and maturation.

Project description:Protective roles of Nrf2, a key transcription factor for antioxidant and defense genes, have been determined in oxidative lung injury, and health benefits of Nrf2 agonists including sulforaphane have been demonstrated. The current study was designed to investigate the effect of sulforaphane on model acute lung injury and sulforaphane-mediated transcriptome changes in mouse lungs. Adult mice genetically deficient in Nrf2 (Nrf2-/-) and wild-type controls (Nrf2+/+, ICR) received oral sulforaphane (9 mmol/daily) or vehicle before (-5, -3, -1 days) hyperoxia or air exposure (3 days), and lung injury and gene expression changes were assessed. Sulforaphane significantly reduced hyperoxia-induced airway injury, inflammation, and mucus hypersecretion in Nrf2+/+ mice while relatively marginal treatment effect was found in Nrf2-/- mice. Sulforaphane significantly altered expression of lung genes associated with oxidative phosphorylation and mitochondrial dysfunction (Atp2a2, Cox7a1, Ndufa1) basally and cell function/cycle and protein metabolism (Actr1a, Wasf2, Ccne1, Gtpbp4) after hyperoxia in Nrf2+/+ mice. Nrf2-dependently modulated lung genes by sulforaphane and hyperoxia were associated with tissue development and hereditary disorders (Slc25a3, Pccb, Psmc3ip). Results demonstrate preventive roles of sulforaphane against oxidant lung injury in mice, and reveal potential downstream mechanisms. Our observations also suggest Nrf2-independent mechanisms of sulforaphane in prevention of acute lung injury.

Project description:Nrf2 is a transcription factor that binds to antioxidant response elements of the regulatory region of a number of antioxidant genes. A mutation in the Nrf2 gene increases susceptibility to hyperoxic lung injury. This project examines expression differences between wild type and Nrf2 knock out mice with the hope of providing insight to the downstream effector genes regulated by Nrf2.

Project description:WGS and RNA-seq data for Nrf2 study

Project description:Multiple cancers regulate oxidative stress by activating the transcription factor NRF2 through mutation of its negative regulator KEAP1. NRF2 has been studied extensively in KEAP1-mutant cancers, however the role of this pathway in cancers with wildtype KEAP1 remains poorly understood. To answer this question, we induced NRF2 via pharmacological inactivation of KEAP1 in a panel of 50+ non-small cell lung cancer cell lines. Unexpectedly, marked decreases in viability were observed in >13% of the cell lines—an effect that was rescued by NRF2 ablation. Genome-wide and targeted CRISPR screens revealed that NRF2 induces NADH-reductive stress, through the upregulation of the NAD+-consuming enzyme ALDH3A1. Leveraging these findings, we show that cells treated with KEAP1 inhibitors or those with endogenous KEAP1 mutations are selectively vulnerable to Complex I inhibition, which impairs NADH oxidation capacity and potentiates reductive stress. Thus, we identify reductive stress as a metabolic vulnerability in NRF2-activated lung cancers.