Visual sensitivity and interphotoreceptor retinoid binding protein in the mouse: regulation by vitamin A.

Interphotoreceptor retinoid binding protein (IRBP) is a retinoid and fatty acid binding glycoprotein secreted by rod and cone photoreceptors in all vertebrates. IRBP is believed to serve as a carrier for retinoids in the bleaching and regeneration cycle of rhodopsin. IRBP protein has been found to be decreased in vitamin A-deprived rats; it is rapidly recovered after retinol repletion. To understand the mechanism for this recovery, we determined whether vitamin A affects transcription and translation of the IRBP gene. Wild-type and transgenic mice harboring the IRBP promoter-CAT reporter fusion gene were maintained on a retinol-deficient diet supplemented with retinoic acid (-A) or on a control diet (+A) for up to 60 wk postweaning. Some of the -A mice were given retinol repletion for 7 days (-A+A). Electroretinography analysis revealed alterations in waveform and a 2 log unit decrease in b-wave sensitivity in the -A mice over a broad range of stimulus wavelengths. Retinol repletion effected a full recovery. Immunochemistry showed a significant decrease in the immunogold-labeled IRBP between the retinal pigment epithelium and the outer segments of the -A mice compared with +A and -A+A mice. Northern blots showed no differences in the amounts of IRBP or CAT mRNA between these three treatment groups. These results suggest that the regulation of IRBP by retinol is not transcriptional.

Dietary carnitine supplements slow disease progression in a putative mouse model for hereditary ceroid-lipofuscinosis.

The childhood ceroid-lipofuscinoses are a group of autosomal recessively inherited disorders characterized by massive accumulation of autofluorescent lysosomal storage bodies in neurons as well as other cell types. The storage body accumulation is accompanied by severe degeneration of the central nervous system that results in blindness, cognitive and psychomotor degeneration, and premature death. On the basis of pathologic and biochemical criteria, a hereditary disease in the mnd mouse strain has been proposed as a model for certain types of human ceroid-lipofuscinosis. Experimental evidence suggests that the storage body accumulation in humans with juvenile and late-infantile ceroid-lipofuscinosis is linked to altered carnitine biosynthesis. On the basis of the latter observation, a study was performed to determine whether dietary carnitine supplements could slow the disease progression in the mnd mouse model. Carnitine supplementation begun at 4 weeks of age did not slow the retinal degeneration that is characteristic of this disease. It did, however, significantly elevate brain carnitine levels, slow the accumulation of autofluorescent storage bodies in brain neurons, and prolong the lifespans of the treated animals. These findings suggest that there is a link between carnitine biosynthesis and the disease pathology and indicate that carnitine supplementation may be beneficial in slowing the disease progression in humans with certain types of hereditary ceroid-lipofuscinosis.