Hypocretin System in Mice

Hypocretin System in Mice

NSC 19305 No. of Pages 10 1 November 2019 NEUROSCIENCE 1 RESEARCH ARTICLE K. Ventzke et al. / Neuroscience xxx (2018) xxx–xxx 3 2 Diurnal Regula...
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NSC 19305

No. of Pages 10

1 November 2019

NEUROSCIENCE 1

RESEARCH ARTICLE K. Ventzke et al. / Neuroscience xxx (2018) xxx–xxx

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Diurnal Regulation of the Orexin/Hypocretin System in Mice

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Kathrin Ventzke, ay Henrik Oster b and Olaf Jo¨hren a,c*

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a

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b

Institute of Neurobiology, University of Lu¨beck, Lu¨beck, Germany

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c

Center of Brain, Behavior and Metabolism, University of Lu¨beck, Lu¨beck, Germany

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Abstract—A prominent feature of the hypothalamic neuropeptides orexins/hypocretins is their role in the regulation of sleep-wake behavior. While there is strong evidence for a diurnal (i.e. 24-h) rhythmicity of the expression of prepro-orexin (PPO) and its cleavage products, orexin A and B, it is not known whether orexin receptors are also subject to diurnal regulation. Here we ask whether besides the regulation of PPO the expression of the orexin receptor subtypes OX1R and OX2R varies over 24 hours in the mouse brain. The mRNA levels of PPO, OX1R, and OX2R as well as of various clock genes were analyzed over 24 hours in the hypothalamus, cortex, and adrenal glands of male mice using qPCR. We found a significant diurnal regulation of the mRNA levels of PPO as well as both orexin receptor subtypes in the brain, while no regulation was observed in adrenal glands. While in the cortex the mRNA levels of both OX1R and OX2R showed a significant diurnal regulation, in the hypothalamus, only the OX2R mRNA expression was subject to a diurnal rhythm. The expression of both orexin receptor subtypes significantly correlated with that of clock genes. Remarkably, the expression pattern of OX2R showed a strong and highly significant correlation with that of the clock gene Bmal1 in the cortex and hypothalamus. These results suggest that the rhythmic expression of orexin receptors is linked to clock gene expression and that OX2R may potentially play a role in the timing of sleep-wake behavior. Ó 2019 IBRO. Published by Elsevier Ltd. All rights reserved.

Institute for Experimental and Clinical Pharmacology and Toxicology, University of Lu¨beck, Lu¨beck, Germany

Key words: orexin receptor subtypes, OX1R, OX2R, diurnal expression, hypothalamus.

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INTRODUCTION

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Orexins/hypocretins are released by proteolytic cleavage from the common precursor protein prepro-orexin (PPO)/ prepro-hypocretin, which is selectively expressed in neurons of the lateral hypothalamic area (de Lecea et al., 1998; Sakurai et al., 1998). Orexin-containing neurons project into numerous brain regions such as the cerebral cortex, the thalamus, the hypothalamus, the brainstem, and the spinal cord (Date et al., 1999; Peyron et al., 1998; van den Pol, 1999). In neurons, orexins mediate their actions via two G-protein coupled receptor subtypes (Sakurai et al., 1998), namely orexin type-1 (OX1R) and orexin type-2 (OX2R) receptors. Orexin receptors are highly expressed in the brain and the distribution of OX1R and OX2R mRNA largely corresponds to

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the projection sites of orexin-positive nerve fibers (Marcus et al., 2001; Trivedi et al., 1998). According to the broad projection of orexin neurons, orexins are involved in the regulation of a variety of physiological and behavioral mechanisms driving energy homeostasis, arousal, endocrine functions and reward processes (Li et al., 2014). After initial findings showed that PPO is up-regulated by fasting and that orexins stimulate food intake (Sakurai et al., 1998), it is now clear that orexins play an important role in the regulation of sleep-wake behavior (Mieda, 2017). Orexins depolarize histaminergic neurons (Eriksson et al., 2001) to increase alertness (Huang et al., 2001) and an increased activity of orexin neurons can cause insomnia (Prober et al., 2006). In turn, mutations in the OX2R gene (HCRTR2) in narcoleptic canines (Lin et al., 1999) or orexin deficiency in mice (Chemelli et al., 1999) cause narcolepsy-like symptoms and, in humans, narcolepsy is most likely caused by a loss of orexin producing neurons (Nishino et al., 2000; Peyron et al., 2000). More recently, several human genome-wide association studies (GWAS) have linked variants of the OX2R gene to chronotypes in addition to clock gene variants (Hu et al., 2016; Jones et al., 2019; Jones et al., 2016; Lane et al., 2016). Thus, the orexin system represents an important regulator of sleep behavior. Besides the homeostatic drive to sleep, sleep behav-

*Correspondence to: O. Jo¨hren, University of Lu¨beck, Center of Brain, Behavior and Metabolism, Ratzeburger Allee 160, 23562 Lu¨beck, Germany. E-mail address: [email protected] (O. Jo¨hren). y Present address: Department of Anesthesiology and Intensive Care, University of Lu¨beck, Lu¨beck, Germany. Abbreviations: DMH, dorsomedial hypothalamus; GWAS, genomewide association studies; OX1R, orexin type-1 receptor; OX2R, orexin type-2 receptor; PPO, prepro-orexin; PVN, paraventricular nucleus; qPCR, quantitative RT-PCR; SCN, suprachiasmatic nucleus; ZT, zeitgeber time. https://doi.org/10.1016/j.neuroscience.2019.10.002 0306-4522/Ó 2019 IBRO. Published by Elsevier Ltd. All rights reserved. 1

Please cite this article in press as: Ventzke K et al. Diurnal Regulation of the Orexin/Hypocretin System in Mice. Neuroscience (2019), https://doi.org/10.1016/j.neuroscience.2019.10.002

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K. Ventzke et al. / Neuroscience xxx (2019) xxx–xxx Table 1. Sequences of primers used for RT-PCR of mouse RNA (orientation 50 –30 ).

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Primer

Forward

Reverse

GAPDH OX1R OX2R PPO Bmal1 (ARNTL) Per2 NFIL-3 (E4BP4) DBP

ATGTGTCCGTCGTGGATCTGA TTGGTGCGGAACTGGAAAC TTCCCGGAACTTCTTCTGTGG TGTTCCTGCCGTCTCTACGAA TCAAATGTGGAACCCTAGGCC TTCTCCCATTCGATTCCGC TGGTCCCTCAAATCGGAACA TGCCCGAAGAACGTCATGA

TGAAGTCGCAGGAGACAACCT CCATCAGCATCTTAGCCGTCT TCAGCAGCAACAGCGCTAATC TGGTTACCGTTGGCCTGAA TAGTTGCTGGTCACCCCAAAG TGTGCCTCCCAATGATGAAAG TCGGAAACCTTATAGCCACCG CCCCAACATGCTAAGAGCACA

ior is controlled by the circadian system. In mammals, the circadian rhythm is determined and controlled by the suprachiasmatic nucleus (SCN) (Ibuka and Kawamura, 1975; Moore and Eichler, 1972; Ralph et al., 1990). The SCN itself is entrained to light signals from the environment (Moore and Klein, 1974). At the cellular level, clock genes ensure rhythmicity via interconnected feedback loops of transcription and translation (Balsalobre et al., 1998). Members of the core clock loop essential for the function of circadian rhythms in mammals are the period isoforms Per1 and Per2, the cryptochromes Cry1 and Cry2, and the PAS helix-loop-helix transcription factor coding genes Bmal1 and Clock (Takahashi, 2017). Orexin neurons in the lateral hypothalamus receive direct inputs from the SCN (Abrahamson et al., 2001) and SCN neurons, in turn, are innervated by orexin neurons and express orexin receptors (Belle et al., 2014). The activity of the orexin neurons is controlled by a circadian stimulus, is increased during waking phases, and correlates with motor activity in nocturnal rodents (Marston et al., 2008; Martinez et al., 2002). Moreover, orexin neurons are involved in resetting of the SCN clock by dark pulses (Marston et al., 2008). Orexin A immunoreactivity shows time-dependent changes in rat brain areas associated with awakening, sleep and diurnal rhythm (Taheri et al., 2000) while in extracts from whole mouse brains no effect of daily time was observed on orexins A or orexin B levels (Lin et al., 2002). Within the hypothalamus, prepro-orexin mRNA levels decrease during the light and increased during the dark (active) phase in rats and mice (Justinussen et al., 2015; Taheri et al., 2000). In freely moving rodents, extracellular orexin A levels decrease during the light (inactive) phase and increase during the dark (active) phase in the lateral hypothalamus (Fenzl et al., 2009; Yoshida et al., 2001). Also in the cerebrospinal fluid, orexin A levels increase in the active (dark) phase in rats (Fujiki et al., 2001) and light phase in diurnal squirrel monkeys (Zeitzer et al., 2003). Furthermore, the rhythm of orexin A concentrations in cerebrospinal fluid disappears upon lesion of the SCN (Deboer et al., 2004; Zhang et al., 2004). While these data clearly demonstrate a diurnal regulation of the expression and release of orexins, little is known about the diurnal regulation of orexin receptors. Therefore, we analyzed the expression of the orexin receptor subtypes OX1R and OX2R over 24 hours in addition to PPO and comparison to the expression of selected clock genes in the present study.

Fig. 1. Diurnal expression of PPO mRNA in the mouse hypothalamus during the 24-h light–dark phase (A) and average PPO mRNA levels during the first (ZT0-8) and second (ZT12-20) half of the 24-h day (B). Shown are the means ± SEM (n = 5–6 for each group) in A or the minimum, 25th percentile, median, 75th percentile and maximum in B. Data were fitted with a sine wave function after CircWave analysis, values at ZT24 were not considered. * – p < 0.05, ** – p < 0.01 and *** – p < 0.001 compared to the 0 h value in A or to the first half (ZT0-8) of the 24-h day in B.

EXPERIMENTAL PROCEDURES

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Tissue preparation and RNA extraction

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12 weeks old, male C57BL/6N mice were obtained from Charles River Laboratories (Sulzfeld, Germany) and housed in groups of six per cage at constant 12-h light/12-h dark (L/D) cycle conditions with lights on at 7:00 AM (zeitgeber time (ZT)0) at 20 °C with ad libitum access to food and drinking water. To compensate for a 1-h time difference in the L/D cycle compared to the breeder’s location, mice were allowed to adapt for 1 week to the new conditions. All mice were sacrificed within one 24-h period by decapitation in a room separate but next the housing room. At various time points of the L/D cycle (ZT0, ZT4, ZT8, ZT12, ZT16, ZT20, ZT24), corresponding mice were brought into this room and sacrificed immediately. The preparation took 15–20 min for each time. During the dark phase, only red light was present. Brains and adrenal glands were quickly removed, frozen in liquid nitrogen, and stored at 80 °C until dissection. Hypothalami and cerebral cortices were dissected as described earlier for rats (Jo¨hren et al., 2003). To prepare the hypothalamus, mouse brains were adapted to 10 °C in a cryostat. Coronal cuts were made manually with a

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Fig. 2. Diurnal hypothalamic mRNA expression of the orexin receptor subtypes OX1R, OX2R, and the clock genes Bmal1, Per2, NIFL-3, and DBP in male mice during the 24-h light–dark phase. Shown are the means ± SEM (n = 5–6 for each group). Data were fitted with a sine wave function after CircWave analysis. Values at ZT24 were not considered. * – p < 0.05; ** – p < 0.01; *** – p < 0.001 compared to the 0 h value.

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sterilized blade at 0.14 mm (just anterior to the optic chiasm) and 2.70 mm (just anterior of the mamillary nucleus) relative to Bregma based on the Paxinos mouse brain atlas (Paxinos and Franklin, 2004). After turning it on its posterior surface, the coronal slice was cut dorsally just ventral to the anterior commissure, placed on the dorsal surface, and cut laterally directly before the amygdala. The cortex including the visual and retrosplenial parts was dissected along the cingulate tract from the dorsal part of the slice. Brain parts were processed for RNA extraction immediately after dissection. Tissues were homogenized in lysis buffer, treated with proteinase K and total RNA was extracted from homogenates in 96-well RNA-purification trays using an ABI Prism 6100 Nucleic Acid Prepstation (Applied Biosystems) according to the manufacturer’s protocol.

Quantitative RT-PCR (qPCR)

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Reverse transcriptase qPCR was performed as described earlier (Brix et al., 2012). 9 ml of total RNA was reverse transcribed with a Cloned AMV first-strand cDNA synthesis kit (Invitrogen) using oligo-(dT)15 primers. qPCR was accomplished with Platinum SYBR Green qPCR SuperMix-UDG (Invitrogen) on an ABI Prism 7000 Sequence Detection System (Applied Biosystems). For detection of specific cDNA, oligonucleotide primers were designed to amplify cDNA of OX1R, OX2R, PPO, the clock genes Bmal1, Per2, NFIL3, DBP, and the housekeeping gene GAPDH. Primers were obtained from Invitrogen (Karlsruhe, Germany) as indicated (Table 1). Product purity was confirmed by dissociation curve analysis. Calculations of mRNA copy numbers were based on the cycle threshold method using serial dilutions of known amounts of specific cDNA fragments to generate standard curves (Jo¨hren et al., 2001). Expression values of OX1R, OX2R, PPO, Bmal1, Per2, NIFL-3, and DBP were corrected to the variations of mRNA levels of the housekeeping gene GAPDH. We did not observe significant changes in the mRNA levels of GAPDH over 24 hours in our brain and adrenal samples.

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Statistics

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Data analysis was carried out with GraphPad Prism software version 7 (GraphPad Software, La Jolla, CA, USA). One-way ANOVA analysis was used to test for significant differences between expression values at various time points. For the comparisons of expression values, means were compared by Dunnett’s multiple comparison posttests. The existence of a diurnal 24-h rhythm was analyzed using the CircWave v1.4 software as described earlier (Oster et al., 2006). For CircWave analysis, we included the ZT0, ZT4, ZT8, ZT12, ZT16, and ZT20 but not the ZT24 values as we sometimes observed differences between ZT0 and ZT24 values.

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RESULTS

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Diurnal rhythms of PPO and orexin receptor subtypes as well as selected clock genes were assessed by analyzing mRNA levels every 4 hours over 24 hours in cortex, hypothalamus, and adrenal glands of mice using qPCR. A subsequent CircWave analysis was used to examine

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Fig. 3. Average hypothalamic mRNA levels of OX1R, OX2R, Bmal1, Per2, NIFL-3, and DBP in male mice during the first (ZT0-8) and second (ZT12-20) half of the 24-h day. Shown are the minimum, 25th percentile, median, 75th percentile and maximum. *** – p < 0.001 compared to the first half (ZT0-8) of the 24-h day.

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the extent to which the expression of the respective genes has a significant 24 h-cycle. Within the hypothalamus, PPO mRNA expression was significantly regulated over 24 hours (Fig. 1A). CircWave analysis, however, did not reveal a significant 24 h-cycle of PPO mRNA levels. In average, the PPO mRNA expression was significantly higher during the second half of the 24-h day (ZT12-20) when compared to the first half (Fig. 1B). Of the hypothalamic orexin receptors, mRNA levels of OX1R was not altered over 24 hours, whereas OX2R mRNA levels were significantly down regulated at the end of the light phase (ZT12) and showed a significant 24 h-cycle by CircWave analysis (Fig. 2). In addition, the clock genes Bmal1, NFIL-2, and DBP, but not Per2 were significantly regulated over 24 hours in the hypothalamus with significant 24 h-cycles (Fig. 2). OX2R mRNA expression was in phase with that of Bmal1 and NFIL-2 and nearly anti-phasic to that of DBP. Hypothalamic OX2R and Bmal1 showed lower average mRNA expression levels in the second compared to the first half of the 24-h day while no differences between the first and second half of the 24-h day were observed for hypothalamic OX1R or Per2, NFIL-3, and DBP mRNA levels (Fig. 3). Within the cortex, OX1R and OX2R as well as Bmal1, Per2, NFIL-2, and DBP mRNA levels were significantly regulated over 24 hours (Fig. 4). Cortical OX1R, Bmal1, NFIL-2, and DBP mRNA levels also showed a significant 24 h-cycle by CircWave analysis. As in the

hypothalamus, cortical orexin receptor expression was in phase with Bmal1 expression and anti-phasic to DBP expression. In average, OX1R, OX2R, and Bmal1 expression was lower during the second half of the day while DBP mRNA was slightly increased (Fig. 5). The expression of orexin receptor mRNA was also analyzed over 24 hours in adrenal glands, as orexin receptor expression had previously been described in the adrenal cortex (Jo¨hren et al., 2001; Randeva et al., 2001). In contrast to the brain, no clear regulation of OX1R or OX2R mRNA expression was observed in adrenals (Fig. 6). The mRNA levels of adrenal Bmal1, Per2, NFIL-2, and DBP, however, were significantly regulated over 24 hours. In addition, all displayed a significant 24h rhythm (Fig. 6). Average adrenal Per2 and NFIL-3 expressions were significantly higher during the second half of the 24-h day compared to the first half (Fig. 7). Within the hypothalamus and cortex, the expression of both orexin receptor subtypes was positively correlated with the expression of Bmal1, Per1, and NFIL-3 (Table 2). Particularly the diurnal expression of OX2R closely reassembled that of Bmal1 in its course over 24 hours and showed a very strong and highly significant (p < 10-10) correlation with the expression of Bmal1. In adrenal glands, only a weak negative correlation was observed between OX2R and Bmal1 expression. No correlation was observed between hypothalamic mRNA expression of PPO and that of clock genes.

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DISCUSSION

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In this study, we confirm the diurnal expression of hypothalamic PPO and demonstrate a diurnal regulation of OX1 and OX2 receptor subtypes in the mouse cortex and hypothalamus. As expected for orexins, within the hypothalamus of mice we found higher expression of PPO mRNA during the second half of the day confirming the decrease of PPO mRNA levels during the light and its increase during the active phase of the day as shown by others in nocturnal rats and mice (Justinussen et al., 2015; Taheri et al., 2000). The 24-h course of PPO mRNA described in the present study is also comparable to that of orexin A levels in the hypothalamus and in cerebrospinal fluid of rats (Fujiki et al., 2001; Taheri et al., 2000). Zeitzer et al. found low concentrations of orexin A in the cerebrospinal fluid at the beginning of the light (active) phase in diurnal squirrel monkeys that increased to maximum levels at the end of the light phase (Zeitzer et al., 2003). Here, we also detected the highest level of PPO mRNA during the second half of the day within the active phase of the mice. In nocturnal and diurnal rodents, orexin neurons exhibit a diurnal oscillation of c-Fos expression that correlates rather with activity and arousal than with wakefulness per se (Espana et al., 2003; Estabrooke et al., 2001; Martinez et al., 2002; Nixon and Smale, 2004). Under constant light, which suppresses locomotor activity, the diurnal rhythmicity of cFos expression in orexin neurons persists in mice and c-Fos expression is enhanced by dark pulses, which results in phase advances of the subjective day indicating

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2004). Thus, the circadian orexin expression and activity of orexin neurons is downstream of the SCN and orexins apparently do not affect the SCN. Besides the increase of PPO mRNA levels during the second half of the day, we found a significant regulation of both orexin receptor subtypes in the mouse brain. In the cortex, mRNA levels of OX1R and OX2R were reduced during the second half of the day. Within the hypothalamus, only OX2R mRNA levels were reduced. The higher concentration and the diurnal rhythm of OX2R in the hypothalamus suggests that here the OX2R may play a prominent role in the diurnal regulation of orexin functions. Wang et al. recently addressed the diurnal mRNA expression of both orexin receptor subtypes in the perifornical area of the lateral hypothalamus in mice (Wang et al., 2017). However, Wang et al. could not detect a significant regulation of orexin receptor mRNA levels over 24 h, although they described a weak rhythmicity of OX1R but not of OX2R in ad libitum fed rats. In the SCN, mRNA levels of OX1R but not OX2R mRNA were increased at ZT12 relative to ZT0 in parallel to the increase of Per2 mRNA indicating a diurnal regulation of OX1R in the SCN and suggesting an interaction of the molecular clock with OX1R Fig. 4. Diurnal cortical mRNA expression of the orexin receptor subtypes OX1R, OX2R, and the (Belle et al., 2014). The differences cock genes Bmal1, Per2, NIFL-3, and DBP mRNA in male mice during the 24-h light–dark phase. between our data and the results of Shown are the means ± SEM (n = 5–6 for each group). Data were fitted with a sine wave function others (Belle et al., 2014; Wang after CircWave analysis. Values at 24 h were not considered. * – p < 0.05; ** – p < 0.01; *** – p < 0.001 compared to the 0 h value. et al., 2017) can be explained by the different hypothalamic areas analyzed and different methodological approaches used, e.g. using extracts a circadian control of orexin neurons by the SCN (Marston from the whole hypothalamus vs. hypothalamic punches. et al., 2008). The increased activity of orexin neurons was Our novel finding of a diurnal regulation of OX2R mRNA apparent already at ZT12 before the start of the main within the hypothalamus could be due to the high expresactivity of mice (Marston et al., 2008). Here, we also found sion of OX2R in hypothalamic areas such as the paravenincreased expression of PPO at ZT8 and ZT12. Increastricular nucleus (PVN) (Marcus et al., 2001), an area that ing levels of PPO mRNA and orexins during increased was not included in the analysis of the aforementioned activity are consistent with the stimulatory effect of orexstudies. ins on arousal-related behavior and may counteract the While PPO mRNA levels increased during the active increasing drive for sleep (Hagan et al., 1999; Zeitzer phase, the mRNA levels of orexin receptors in the et al., 2003). The increased activity of orexin neurons mouse brain decreased during the second half of the and the increased PPO expression before the onset of day. A negative receptor autoregulation may explain this activity, however, indicates that orexin upregulation predivergent regulation. However, it is important to note cedes the activity of mice during the dark phase and is that in the present study we measured mRNA levels not due to increased locomotor activity. Ablation of orexin and not the actual receptor protein. Changes of protein neurons affected food-anticipatory increases of activity in levels may not temporally correlate with that of mRNA food-restricted mice but did not alter the Per2 rhythmicity (Vogel and Marcotte, 2012). During the circadian rhythm in the SCN and the phase uncoupling of Per2 expression of the cell cycle, protein expression can be delayed by in extra-SCN brain areas by food restriction (Mieda et al.,

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Fig. 5. Average cortical mRNA levels of OX1R, OX2R, Bmal1, Per2, NIFL-3, and DBP in male mice during the first (ZT0-8) and second (ZT12-20) half of the 24-h day. Shown are the minimum, 25th percentile, median, 75th percentile and maximum. * – p < 0.05; ** – p < 0.01; *** – p < 0.001 compared to the first half (ZT0-8) of the 24h day.

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more than six hours and even may show an anti-phasic appearance compared to rhythmic expression of the corresponding mRNA (Robles et al., 2014). Thus, posttranslational factors and the half-life of OX2R protein must be considered and the current expression data on OX2R mRNA only allow conclusions about OX2R rhythmicity, but not the exact timing of its activity. A prominent finding of our study is the strong and highly significant correlation of the mRNA levels of Bmal1 and OX2R suggesting a similar transcriptional regulation. A promising molecular mechanism in this context is the regulation of both Bmal1 and OX2R by the sirtuin SIRT1 (Asher et al., 2008; Satoh et al., 2013). Interestingly, genetic variations of both OX2R and clock genes such as Bmal1 are linked to chronotypes (Hu et al., 2016; Jones et al., 2019; Jones et al., 2016; Lane et al., 2016). However, the particular cellular and molecular mechanisms that connect clock gene regulation with sleep are largely unknown (Deboer, 2018). As the activity of orexin neurons peaks in the active phase in both nocturnal and diurnal rodents (Kodama et al., 2005; Martinez et al., 2002) it would be interesting to determine whether the correlation between Bmal1 and OX2R expression is also observed in diurnal animals. In the SCN, clock gene expression depends mainly on the L/D cycle while in extra-SCN brain areas such as the

cortex a phase shift of clock gene expression has been described and may be a result of the integration of light cues and non-photic cues such as daily-restricted feeding (Wakamatsu et al., 2001). Food entrained oscillation of c-Fos activity as well as circadian clock gene expression were found within the hypothalamus in a variety of nuclei including the dorsomedial hypothalamus (DMH) and the PVN (Angeles-Castellanos et al., 2004; Verwey et al., 2007). The expression of clock genes in these extra-SCN hypothalamic nuclei is entrained differentially by various food restriction schemes, is not necessarily in phase with the clock in the SCN, and may even autonomously oscillate (De Araujo et al., 2016; Mieda et al., 2006; Minana-Solis et al., 2009). For instance, Bmal1 mRNA expression peaked at ZG16 in the rat SCN, but at ZG4 in the PVN and was lowest in the PVN at ZG12 (Girotti et al., 2009) notably at a time, we observed the lowest hypothalamic OX2R mRNA levels in our present study. Interestingly, Girotti et al. observed an increased expression of Bmal1 in the evening in food-restricted rats (Girotti et al., 2009) and hypothalamic OX2R expression was increased by food restriction in rats at onset of the dark cycle (Karteris et al., 2005). Thus, a similar regulation of Bmal1 and OX2R expression is also apparent from these studies. Besides their expression in the brain, the orexin receptor subtypes OX1R and, to a higher extent, OX2R are also expressed in the adrenal gland of humans and rats, where OX2R is thought to be involved in the steroidogenesis of glucocorticoids (Jo¨hren et al., 2001; Kagerer et al., 2011; Randeva et al., 2001; Wenzel et al., 2009). Here, we confirm the expression of orexin receptors in the adrenal of mice showing also about 10fold higher expression of OX2R. However, unlike in the mouse brain, the expression of orexin receptors was not rhythmically regulated although we found a prominent circadian regulation of clock genes as described earlier (Oster et al., 2006). Thus, interactions between clock genes and orexin receptors appear to be restricted to the brain and may represent a possible connection between the circadian system and sleep-wake behavior. Although we have found clear daily regulation in the expression of brain PPO and orexin receptor subtypes in the present study, our study has also some limitations. Here, we analyzed the diurnal course of RNA expression, which does not necessarily reflect to diurnal expression of the functional peptides/proteins. In fact, it can be expected that protein is significantly later expressed compared to corresponding mRNA (Robles et al., 2014). Thus, a diurnal regulation can be detected by our RNA data but we cannot conclude on the timing of the protein function especially for orexin receptors as discussed above. The use of the complete hypothalamus without further dissection of other hypothalamic nuclei such as the SCN or the lateral hypothalamic area represents another limitation of our study. Thus, desynchronized expression of clock genes in different hypothalamic nuclei would not be detectable in extracts of the complete hypothalamus. The absence of a diurnal regulation of Per2 in hypothalamic extracts in the present study could be explained by a desynchronization of Per2

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with the that of clock genes, particularly Bmal1, suggests an important role of orexins and particularly the OX2R for the diurnal control of sleep-wake behavior as orexins are responsible for alertness and suppress sleep during the active phase (John et al., 2000; Kantor et al., 2009; Weinhold et al., 2014; Zeitzer et al., 2003).

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AUTHOR CONTRIBUTIONS

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KV, HO and OJ designed research. HO performed CircWave analysis. KV and OJ performed experiments and analyzed data. KV and OJ wrote the paper.

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ACKNOWLEDGEMENTS

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We thank Christine Eichholz and Gudrun Viercke for their technical support. This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

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Fig. 7. Average adrenal mRNA levels of OX1R, OX2R, Bmal1, Per2, NIFL-3, and DBP in male mice during the first (ZT0-8) and second (ZT12-20) half of the 24-h day. Shown are the minimum, 25th percentile, median, 75th percentile and maximum. *** – p < 0.001 compared to the first half (ZT0-8) of the 24-h day.

Table 2. Pearson correlation analysis of clock gene expression and expression of components of the orexin system in mouse brain and adrenal glands. Bmal1

Per2

NFIL-3

DBP

Hypothalamus PPO 0.207 ns OX1R 0.504** OX2R 0.895###

0.090 ns 0.482** 0.638***

0.144 ns 0.265 ns 0.442**

0.113 ns 0.108 ns 0.317 ns

Cortex OX1R OX2R

0.596*** 0.837***

0.616*** 0.713***

0.152 0.164

0.150 ns 0.043 ns

0.087 ns 0.187 ns

0.022 ns 0.224 ns

0.831*** 0.878###

Adrenal glands OX1R 0.090 ns OX2R 0.349*

Shown are Pearson’s correlation coefficients (r). * – p < 0.05; ** – p < 0.01; *** – p < 0.001, ### – p < 1010, ns – not significant.

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(Received 2 July 2019, Accepted 1 October 2019) (Available online xxxx)

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