The circadian rhythms in melatonin production in the chicken pineal gland and retina reflect changes in the activity of serotonin N‐acetyltransferase (arylalkylamine N‐acetyltransferase; AA‐NAT; EC 2.3.1.87). Here we determined that the chicken AA‐NAT mRNA is detectable in follicular pineal cells and retinal photoreceptors and that it exhibits a circadian rhythm, with peak levels at night. AA‐NAT mRNA was not detected in other tissues. The AA‐NAT mRNA rhythm in the pineal gland and retina persists in constant darkness (DD) and constant lighting (LL). The amplitude of the pineal mRNA rhythm is not decreased in LL. Light appears to influence the phase of the clock driving the rhythm in pineal AA‐NAT mRNA in two ways: The peak is delayed by ∼6 h in LL, and it is advanced by >4 h by a 6‐h light pulse late in subjective night in DD. Nocturnal AA‐NAT mRNA levels do not change during a 20‐min exposure to light, whereas this treatment dramatically decreases AA‐NAT activity. These observations suggest that the rhythmic changes in chicken pineal AA‐NAT activity reflect, at least in part, clock‐generated changes in mRNA levels. In contrast, changes in mRNA content are not involved in the rapid light‐induced decrease in AA‐NAT activity.
Melatonin production in the chick pineal gland is high at night and low during the day. This rhythm ref lects circadian changes in the activity of serotonin Nacetyltransferase (arylalkylamine N-acetyltransferase, AA-NAT; EC 2.3.1.87), the penultimate enzyme in melatonin synthesis. In contrast to the external regulation of pineal rhythms in mammals by the suprachiasmatic nucleus, rhythmic changes in AA-NAT activity in cultured chick pineal cells are controlled by an oscillator located in the pineal cells themselves. Here we present evidence that the chick pineal clock generates a rhythm in the abundance of AA-NAT mRNA in cultured cells that parallels the rhythm in AA-NAT activity. In contrast, elevating cAMP by forskolin treatment markedly increases AA-NAT activity without producing strong changes in AA-NAT mRNA levels, and lowering cAMP by norepinephrine treatment decreases enzyme activity without markedly decreasing mRNA. These results suggest that clock-controlled changes in AA-NAT activity occur primarily through changes at the mRNA level, whereas cAMP-controlled changes occur primarily through changes at the protein level. Related studies indicate that the clock-dependent nocturnal increase in AA-NAT mRNA requires gene expression but not de novo protein synthesis, and that AA-NAT mRNA levels are suppressed at all times of the day by a rapidly turning over protein. Further analysis of the regulation of chick pineal AA-NAT mRNA is likely to enhance our understanding of the molecular basis of vertebrate circadian rhythms.
The abundance of serotonin N-acetyltransferase (arylalkylamine N-acetyltransferase, AANAT) mRNA in the chicken pineal gland exhibits a circadian rhythm, which is translated into a circadian rhythm in melatonin production. Here we have started to elucidate the molecular basis of the circadian rhythm in chicken AANAT (cAANAT). The 5-flanking region of the cAANAT gene was isolated and found to contain an E box DNA element that confers strong luciferase reporter activity. In transfection experiments using chicken pineal cells, an E box mutation dramatically decreased reporter activity. Northern blot analysis indicated that several putative clock genes (bmal1, Clock, and MOP4) are co-expressed in the chicken pineal gland. bmal1 mRNA is expressed in a rhythmic manner in the chicken pineal gland, with peak levels at early subjective night, coincident with the increase in cAANAT expression. Co-transfection experiments in COS cells demonstrated that chicken BMAL1/ CLOCK and human BMAL1/MOP4 heterodimers bound the AANAT E box element and enhanced transcription. These observations suggest that binding of clock gene heterodimers to the cAANAT E box is a critical element in the expression of the cAANAT gene in vitro.
In the vertebrate retina and pineal gland, melatonin production displays diurnal variations with high levels at night. Hydroxyindole-O-methyltransferase (HIOMT, EC 2.1.1.4) catalyses the last step of melatonin biosynthesis. In the present study, a cDNA encoding chicken HIOMT was used to examine the effects of environmental lighting on HIOMT mRNA expression in the chicken retina. A day/night rhythm of HIOMT mRNA level was observed, with an average 5-fold increase during the night. Light strongly suppressed the night-time rise in HIOMT mRNA concentration while darkness prevented its daytime fall. An antibody directed against chicken HIOMT was used for immunocytochemical identification of retinal melatoninergic cells. HIOMT immunoreactivity could be observed in rods as well as in cones. However, the lowest levels of HIOMT immunoreactivity were always observed in the accessory cones of double cones. A few HIOMT-positive cell bodies could also be observed in the inner nuclear layer. Altogether, these data indicate that HIOMT gene expression in the retina is organized on a daily basis as a direct response to light, and that the different types of photoreceptors may not be equally involved in melatonin production.
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