Stability of small non-coding RNA reference gene expression in the rat retina during exposure to cyclic hyperoxia.

PURPOSE: Oxygen-induced retinopathy (OIR) is a robust animal model of human retinopathy of prematurity that readily allows changes in retinal gene and microRNA (miRNA) expression in response to fluctuations in oxygen levels to be studied. We sought to identify small non-coding RNA (ncRNA) genes that showed stable expression upon exposure to varying levels of oxygen, with different developmental stages and in different rat strains, to act as reference genes for normalizing miRNA expression in a rat model of OIR. METHODS: Expression of five small ncRNAs (U6 snRNA, miR-16, U87, 4.5S RNA (H) "Variant 1", and 5S ribosomal RNA [rRNA]) were tested on a standard RNA pool and representative retinal samples from P5, P6, P9, and P14 from room air- and cyclic hyperoxia-exposed rats using reverse transcription (RT)-qPCR, to assess the effect of developmental stage and exposure to fluctuations in oxygen levels, respectively. Two strains of inbred albino rats, Fischer 344 (F344, resistant to OIR) and Sprague-Dawley rats (SD, susceptible to OIR), were used to assess the effect of rat strain on the stability of the small ncRNAs. RESULTS: In this rat model of OIR, 5S rRNA expression was variable with strain, fluctuations in oxygen levels, and developmental stage. U6 snRNA was stably expressed with changes in oxygen levels, and minimal variation was observed with strain and developmental stage. MiR-16 showed less stable expression with changes in oxygen levels and between strains compared to U6 snRNA. Some variation in expression in response to developmental stage was also observed. The PCR amplification efficiencies of the U6 snRNA and miR-16 TaqMan assays were 56% and 78%, respectively. U87 and 4.5S RNA (H) "Variant 1" expression varied with strain, exposure to cyclic hyperoxia, and in particular developmental stage, and was at low levels in the neonatal rat retina. CONCLUSIONS: We conclude that U6 snRNA and miR-16 are the most suitable reference RNAs for normalizing miRNA expression, as they are relatively stable with strain, exposure to cyclic hyperoxia, and developmental stage in a rat model of OIR.

Exposure to cyclic oxygen sufficient for development of oxygen-induced retinopathy does not induce bronchopulmonary dysplasia in rats.

Bronchopulmonary dysplasia and retinopathy of prematurity affect premature infants exposed to supplemental oxygen. Susceptibility to oxygen-induced retinopathy in the rat is heritable, with inbred Dark Agouti (DA) rats being more susceptible than Fischer 344 (F344) rats. To establish if hyperoxic exposure sufficient to induce florid retinopathy would induce strain-specific lung changes, newborn DA and F344 rats were exposed to cyclic hyperoxia or room air for up to 18 days. Lung function was assessed at 18 days, and standardized morphometry and immunohistochemistry were performed at intervals. No differences in arterial blood gases or protein concentration of bronchoalveolar lavage fluid were observed amongst groups at 18 days, although lung wet-to-dry weights were significantly lower for F344 than for DA rats. Pulmonary vascularity increased in all oxygen-exposed animals compared with room air-exposed controls, but there was no significant difference between strains. The lung surface area of oxygen-exposed F344 rats was significantly increased at day 10 compared with F344 controls and oxygen-treated DA rats, but at 14 and 17 days the oxygen-exposed DA rats showed increased lung surface area compared with oxygen-exposed F344 rats. The minor morphological differences found in the lung did not affect pulmonary function, suggesting that mechanisms inducing oxygen-induced retinopathy and bronchopulmonary dysplasia are fundamentally different, and that susceptibility to bronchopulmonary dysplasia is not heritable in the rat.

Stability of housekeeping gene expression in the rat retina during exposure to cyclic hyperoxia.

Recent evidence suggests a genetic component to oxygen-induced retinopathy (OIR), a robust experimental model of human retinopathy of prematurity. OIR lends itself well to quantitative analysis of gene expression in rodents with well-defined genetic backgrounds. Such analysis by real-time reverse transcription polymerase chain reaction (RT-PCR) requires the use of reference genes as internal standards for purposes of normalization. We sought to identify housekeeping genes showing stable retinal expression across different rat strains and developmental stages, that were not regulated by oxygen tension. Real-time RT-PCR was used to examine in normal (control) neonatal rat retina the expression of five candidate reference genes: acidic ribosomal phosphoprotein (ARBP), cyclophilin A (CYCA), gamma 2 actin (ACTG2), hypoxanthine guanine phosphoribosyltransferase (HPRT), and RNA polymerase 2 (RNAP2). ACTG2 was poorly expressed, whereas quantification of CYCA was confounded by putative amplification of pseudogenes. Expression of ARBP, HPRT, and RNAP2 was then quantified in dissected retinas from neonatal rats of three inbred strains (Fischer 344, Sprague Dawley, and Dark Agouti) under two different conditions of exposure to inspired oxygen (exposure to room air for 14 days from birth; exposure to cyclic hyperoxia for 14 days from birth). The average variation in relative expression between each pair of these three genes within each of the six cDNA test samples was used to assess stability of gene expression, relative to a standard retinal cDNA pool. The relative expression values for ARBP and HPRT were more closely correlated (r2=0.80) than were those for either gene with RNAP2 (ARBP and RNAP2: r2=0.31; HPRT and RNAP2: r2=0.25). There was little variation among the six experimental groups for the normalized expression of ARBP or HPRT (p>0.05). In contrast, the normalized expression of RNAP2 varied significantly amongst experimental groups: Within each strain, expression was higher in the oxygen-exposed group than in the room air-exposed group (p<0.05). We conclude that ARBP and HPRT exhibit expression that is sufficiently stable under conditions of varying oxygen tension, to permit their use as housekeeping genes in at least one model of OIR in the neonatal rat.