Induction of TNFα by flavin adenine dinucleotide (FADH) protects neonatal C57Bl6 lungs from high oxygen induced lung injury

Abstract

Background: Bronchopulmonary dysplasia (BPD) is a serious lung disease caused by oxidative stress, predominately affecting premature infants that require prolonged oxygen support. The co-factor flavin adenine dinucleotide (FADH) facilitates glutathione reductase (GR) enzymatic activity and increases the bioavailability of the antioxidant glutathione (GSH). As such, we hypothesized that intranasal delivery of FADH can improve redox homeostasis and attenuate lung injury following chronic high oxygen supplementation (0.85% FiO2) by altering pro-inflammatory signal transduction pathways in a C57Bl6 newborn mouse model for BPD. Methods: We used a prolonged hyperoxia-induced lung injury rodent model to recapitulate the clinical and histological changes present in BPD. Newborn mice were housed in FiO2 85% (hyperoxic) or 21% O2 (normoxic) from day of birth until post-natal day (PN) 14. FADH (7 μM) or saline (control) treatments were administered daily via intranasal insufflation on PN 14-21 in a final volume of 1.5μL/g body weight. BALF and lung tissue samples were collected and evaluated for redox stress, lung injury/development, and inflammation using standard immunohistological techniques, morphometric analysis, and standard molecular assays. BALF cytokines were measured using a flow cytometric approach (BioLegend). Two-dimensional cell migration assays were tracked via microscopy daily until 100% confluence reached; the ½ maximal peak values were evaluated to compare rate of wound closure following very low (2.5 ng/mL) TNFα or IL12 treatment. Transepithelial resistance and potential differences were measured using an EVOM device (World Precision Instrument) across human small airway epithelial cells, and equivalent short circuit currents (Isc) calculated in accordance with Ohm’s Law, where V=IR. Single data comparisons were performed using paired Student’s t-tests. Multiple comparisons were performed using ANOVA followed by post-hoc testing in Sigma Plot. Results: FADH protected neonatal lungs from high oxygen induced oxidative stress: GSH/GSSG Eh (a measure of oxidative stress) improved from -168.77 mV ± 3.64 mV to -179.10 mV ± 1.85 mV (n=5 BALF measurements). FADH also improved lung injury scores from 0.187±0.038 to 0.03±0.014 (p=0.005), decreased neutrophil migration (p<0.001), and increased macrophages (p<0.001) when compared to age-matched untreated pups. FADH-mediated increase in TNFα (and not IL12) significantly increased the rate of lung epithelial cell wound closure from [2.27±0.07 to 1.97±0.1 average days for ½ complete wound closure, n=6, p=0.01] and increased Isc from 6.5±.21 to 9.2±1.0 μA/cm2, n=3, p=0.03. Conclusions: Our findings indicate that FADH protects the preterm lung from hyperoxic injury by 1) increasing the bioavailability of GSH and 2) via TNFα signaling to increase the rate of wound closure and repair of epithelial cell function. Significances: The mechanisms identified through this study could be targeted as a potential adjunct therapy for BPD patients to attenuate high oxygen induced lung injury. Funding: Supported by R01HL137033 (MH). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.