PURPOSE: Melatonin synthesis in mammalian retinal photoreceptors is under photic and circadian control and regulated by changes in the activity of arylalkylamine N-acetyltransferase (AANAT). Recent studies have suggested that retinal dopaminergic neurons contain a circadian pacemaker, and dopamine is the neurotransmitter that drives circadian rhythmicity in the mammalian retina. METHODS: To investigate the role of inner retinal neurons, including dopamine neurons, in generating the rhythm of melatonin synthesis, rat retinas were lesioned with kainic acid (KA), which was shown previously to induce degeneration of neurons in the inner nuclear layer and to eliminate rhythmicity in the dopaminergic system. Aanat, rhodopsin, medium wavelength (mwl) opsin, short wavelength (swl) opsin, and period1 (Per1), and period2 (Per2) mRNA levels were measured using real-time quantitative RT-PCR in KA injected and control eyes. RESULTS: Our data show that intraocular injections of KA did not abolish the daily and circadian rhythms of Aanat mRNA in the photoreceptors, but it did shift the phase of the Aanat transcript rhythm in constant darkness. Surprisingly, KA injections reduced the levels and eliminated daily rhythms of mwl and swl opsin transcripts, but not of rhodopsin mRNA. Per1 and Per2 mRNA levels were rhythmic in saline injected and in KA-treated retinas, and Per2 mRNA levels were significantly reduced (20-50%) in KA-treated retinas. CONCLUSIONS: These findings demonstrate that the circadian clock generating melatonin rhythmicity is largely KA insensitive and likely to be located in the rod photoreceptors, although KA-sensitive neurons do influence its timing. More important, our data demonstrate that dopamine rhythmicity is not necessary for generating the circadian rhythm of Aanat mRNA in the photoreceptors. Our data also indicate that Per1 and Per2 are rhythmically transcribed in the rat retina and KA treatment has a dramatic effect on the overall levels of Per2 mRNA.
PURPOSE:Melatonin synthesis in mammalian retinal photoreceptors is under photic and circadian control and regulated by changes in the activity of arylalkylamine N-acetyltransferase (AANAT). Recent studies have suggested that retinal dopaminergic neurons contain a circadian pacemaker, and dopamine is the neurotransmitter that drives circadian rhythmicity in the mammalian retina. METHODS: To investigate the role of inner retinal neurons, including dopamine neurons, in generating the rhythm of melatonin synthesis, rat retinas were lesioned with kainic acid (KA), which was shown previously to induce degeneration of neurons in the inner nuclear layer and to eliminate rhythmicity in the dopaminergic system. Aanat, rhodopsin, medium wavelength (mwl) opsin, short wavelength (swl) opsin, and period1 (Per1), and period2 (Per2) mRNA levels were measured using real-time quantitative RT-PCR in KA injected and control eyes. RESULTS: Our data show that intraocular injections of KA did not abolish the daily and circadian rhythms of Aanat mRNA in the photoreceptors, but it did shift the phase of the Aanat transcript rhythm in constant darkness. Surprisingly, KA injections reduced the levels and eliminated daily rhythms of mwl and swl opsin transcripts, but not of rhodopsin mRNA. Per1 and Per2 mRNA levels were rhythmic in saline injected and in KA-treated retinas, and Per2 mRNA levels were significantly reduced (20-50%) in KA-treated retinas. CONCLUSIONS: These findings demonstrate that the circadian clock generating melatonin rhythmicity is largely KA insensitive and likely to be located in the rod photoreceptors, although KA-sensitive neurons do influence its timing. More important, our data demonstrate that dopamine rhythmicity is not necessary for generating the circadian rhythm of Aanat mRNA in the photoreceptors. Our data also indicate that Per1 and Per2 are rhythmically transcribed in the rat retina and KA treatment has a dramatic effect on the overall levels of Per2 mRNA.
Authors: Guo-Xiang Ruan; Dao-Qi Zhang; Tongrong Zhou; Shin Yamazaki; Douglas G McMahon Journal: Proc Natl Acad Sci U S A Date: 2006-06-09 Impact factor: 11.205