Leber congenital amaurosis (LCA), a severe and early-onset form of retinal dystrophy, has been linked to mutations in several distinct genes, including RDH12.1–5 The RDH12 gene encodes a microsomal retinol dehydrogenase that is expressed in photoreceptor cells in retina.6–9 RDH11, the most closely related sequence, shares 73% identity with RDH12 in humans6 and 67% identity with RDH12 in mice. RDH11 is a microsomal retinol dehydrogenase expressed in many tissues in mice including liver, testis, and retina.10 RDH11 has not been linked to any human disease. The physiological role of these enzymes has been investigated in vivo using knockout mice. As retinol dehydrogenases, these enzymes were expected to be important in the retinoid cycle for the recycling of the visual chromophore 11-cis retinal, allowing the regeneration of photosensitive rhodopsin pigment after bleaching.11 However, a decrease in the regeneration of 11-cis retinal has not been found in Rdh11 or Rdh12 knockout mice.8,9,12,13 These knockout mice, however, exhibit a significant delay in dark adaptation after bleaching.8,12,13 This phenotype cannot be explained by a delay of 11-cis retinal recycling, leaving the molecular mechanism for the delay in dark adaptation unknown. It was hypothesized that RDH12 catalyzes the reduction of all-trans retinal in photoreceptor inner segments, indirectly participating to the clearance of all-trans retinal in the outer segments. A delayed clearance in the knockout would then block the regeneration of photosensitive rhodopsin.8 Interestingly, clinical observations in patients with LCA caused by mutations of the RDH12 gene revealed that almost all patients had a defect in dark adaptation during the first years of life, followed by progressive rod-cone dystrophy.1,4,5,14 Although Rdh11 knockout mice have not been tested for sensitivity to light damage, Rdh12 knockout mice have a greater sensitivity to light-induced photoreceptor apoptosis.8 When exposed to constant bright light for 48 hours, photoreceptor cell loss was induced in the pigmented Rdh12 knockout mice but not in the wild-type mice.8 The molecular mechanism leading to this murine phenotype is unknown. It was hypothesized that the accumulation of all-trans retinal in photoreceptor inner segments of the knockout mice could be a sensitizer for light damage far beyond what is observed in the wild-type mice.8 LCA patients with mutated RDH12 have progressive photoreceptor degeneration affecting rods and cones. Onset of symptoms begins in early childhood (2–4 years) and progression to legal blindness begins in early adulthood, but it is unknown whether exposure to light or oxidative stress plays a role in this pathogenesis.1,2,4,5 The substrate specificity and catalytic activities of RDH11 and RDH12 have been characterized in vitro by using purified enzymes and microsomal fractions of transfected cells.6,7,10 These studies have shown that RDH11 and RDH12 are able to catalyze the reduction of two distinct groups of aldehydic substrates: the retinaldehydes and the short-chain (hydroxy)aldehydes.7,10 Because of their activity toward retinaldehydes, these enzymes were named retinol dehydrogenases and the idea that they could play a direct part in the visual cycle was proposed.3,6,7,15 Their activity toward the short-chain (hydroxy)aldehydes suggests that they may have additional or alternative roles.7,10 Short-chain (hydroxy)aldehydes are toxic end products of the lipid peroxidation of membrane polyunsaturated fatty acids. This nonenzymatic, auto-amplified degradation of lipids is induced by reactive oxygen species generated in excess during oxidative stress.16 Short-chain (hydroxy)aldehydes are thought to mediate, at least in part, the apoptotic response induced by oxidative stress in cells.17–19 Because RDH11 and RDH12 catalyze the reduction of these toxic aldehydes to less toxic alcohols, they may protect photoreceptor cells against the toxicity and apoptosis induced by oxidative stress. The similarities between RDH11 and RDH12 (sequence, activity, substrate specificity, and the common phenotype of delayed dark adaptation in knockout mice) suggest that the two enzymes may have overlapping physiological roles. In this study, we describe the expression levels and regulation of RDH11 and RDH12 enzymes during development and during exposure to oxidative stress. We found a significantly higher expression level of RDH12 than RDH11 in the mouse retina at all times after postnatal day (P) 7. We also found that exposure to oxidative stress greatly affects RDH12 levels but not RDH11 levels. We concluded that the two enzymes differ in their expression during development and in their regulation by light-induced oxidative stress.