Although mice lacking rod and cone photoreceptors are blind, they retain many eye-mediated responses to light, possibly through photosensitive retinal ganglion cells. These cells express melanopsin, a photopigment that confers this photosensitivity. Mice lacking melanopsin still retain nonvisual photoreception, suggesting that rods and cones could operate in this capacity. We observed that mice with both outer-retinal degeneration and a deficiency in melanopsin exhibited complete loss of photoentrainment of the circadian oscillator, pupillary light responses, photic suppression of arylalkylamine-N-acetyltransferase transcript, and acute suppression of locomotor activity by light. This indicates the importance of both nonvisual and classical visual photoreceptor systems for nonvisual photic responses in mammals.
Lecithin-retinol acyltransferase (LRAT), an enzyme present mainly in the retinal pigmented epithelial cells and liver, converts all-trans-retinol into all-trans-retinyl esters. In the retinal pigmented epithelium, LRAT plays a key role in the retinoid cycle, a two-cell recycling system that replenishes the 11-cis-retinal chromophore of rhodopsin and cone pigments. We disrupted mouse Lrat gene expression by targeted recombination and generated a homozygous Lrat knock-out (Lrat؊/؊) mouse. Despite the expression of LRAT in multiple tissues, the Lrat؊/؊ mouse develops normally. The histological analysis and electron microscopy of the retina for 6 -8-week-old Lrat؊/؊ mice revealed that the rod outer segments are ϳ35% shorter than those of Lrat؉/؉ mice, whereas other neuronal layers appear normal. Lrat؊/؊ mice have trace levels of all-trans-retinyl esters in the liver, lung, eye, and blood, whereas the circulating all-trans-retinol is reduced only slightly. Scotopic and photopic electroretinograms as well as pupillary constriction analyses revealed that rod and cone visual functions are severely attenuated at an early age. We conclude that Lrat؊/؊ mice may serve as an animal model with early onset severe retinal dystrophy and severe retinyl ester deprivation.Lecithin-retinol acyltransferase (LRAT) 1 converts all-transretinol (vitamin A) to all-trans-retinyl esters in several tissues, including the liver, lung, pancreas, intestine, testis, and the retinal pigmented epithelium (RPE) (1-5). LRAT activity in the RPE has been studied for more than 60 years (6), but the enzyme was only recently identified on the molecular level as a 25-kDa integral membrane protein (7). All-trans-retinyl esters are intermediate compounds in a metabolic pathway ("visual cycle" or "retinoid cycle") that recycles 11-cis-retinal, the chromophore of rhodopsin and cone pigments (for review, see Refs. 8 -10). In this cycle, all-trans-retinal dissociates from rhodopsin and cone pigments after photobleaching. In the photoreceptors, all-trans-retinal is reduced to all-trans-retinol and subsequently exported to the adjacent RPE. In the RPE, alltrans-retinol is esterified by LRAT and stored. All-trans-retinyl esters have been suggested to be the substrate for a putative isomerohydrolase in the RPE (11) and for a retinyl ester hydrolase that produces all-trans-retinol, a substrate for the putative isomerase (for review, see Ref. 12). Ultimately, 11-cisretinol is produced, oxidized to 11-cis-retinal, and exported to the photoreceptors. In the rod and cone photoreceptor outer segments, 11-cis-retinal recombines with opsins to form rhodopsin and cone pigments (for review, see Ref. 8).Human LRAT cDNA was cloned from a retinal-RPE cDNA library (7) and rodent Lrat cDNA from liver and other tissues (13-15). Lrat mRNA was shown to be a 5.0-kb species expressed in the RPE, and the multiple transcripts based on differential polyadenylation were detected in several other tissues known for the highest LRAT activity (13). The human LRAT polypeptide consisted of 230 ...
We measured daily gene expression in heads of control and period mutant Drosophila by using oligonucleotide microarrays. In control flies, 72 genes showed diurnal rhythms in light-dark cycles; 22 of these also oscillated in free-running conditions. The period gene significantly influenced the expression levels of over 600 nonoscillating transcripts. Expression levels of several hundred genes also differed significantly between control flies kept in light-dark versus constant darkness but differed minimally between per 01 flies kept in the same two conditions. Thus, the period-dependent circadian clock regulates only a limited set of rhythmically expressed transcripts. Unexpectedly, period regulates basal and light-regulated gene expression to a very broad extent.F orward genetic screens in Drosophila melanogaster have identified at least eight genes [period (per), timeless (tim), cycle (cyc), clock (Clk), vrille (vri), doubletime, cryptochrome (cry), and shaggy] necessary for the normal functioning of the circadian time-keeping system. Null mutations in most of these genes render flies behaviorally arrhythmic in constant conditions, but they otherwise have minimal morphologic phenotype (1). A model for the mechanism by which specific gene products give rise to a stable clock mechanism has been formulated over the past 10 years (2, 3). These clock genes appear to function in a time-delayed transcription-translation feedback loop. A rhythmically expressed subset of the core clock genes (per, tim, and Clk) and a nonrhythmically expressed core clock gene (cyc) are thought to function as the state variables of the oscillator mechanism (4). This model predicts that these core clock genes also should influence the rhythmic expression of ''output'' genes important in regulating physiologic and biologic processes controlled by the circadian clock (5).Previous screens for such clock-controlled output genes have yielded varying estimates of their abundance and character in different organisms. An insertional reporter screen in the photosynthetic prokaryote Synechococcus suggested that most genes in this organism are transcribed in circadian fashion (6). Using microarray analysis, Harmer et al. identified 453 genes undergoing rhythmic expression under constant conditions in the plant Arabidopsis thaliana (7), representing Ϸ6% of the expressed genome. In Drosophila, analysis of 280 expressed sequence tags from the fly head revealed 20 diurnally varying transcripts, the majority of which were extremely rare, long messages of unclear physiologic function (8). The full extent of circadian gene expression is not known in any organism. The recent availability of an oligonucleotide-based microarray containing probes for nearly all known and predicted Drosophila genes allows estimation of the number of clock-controlled genes in the fly. Here we describe results of measuring circadian gene expression in control and period mutant flies in both light-dark (LD) and freerunning conditions. While this article was in preparation, three ot...
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