Ghrelin Restores the Disruption of the Circadian Clock in Steatotic Liver

Cells in vitro lose their rhythm and can be resynchronized by dexamethasone [20]. To determine whether isolated hepatocytes can be synchronized by dexamethasone, we treated the cultured hepatocytes with dexamethasone (100 nM) and analyzed the mRNA levels of circadian clock genes. As shown in Figure 1, the mRNA levels of the core circadian clock genes showed a robust rhythmic oscillation in cells treated with dexamethasone, whereas they demonstrated no obvious effect in control cells treated with methanol. We thus used 100 nM dexamethasone to synchronize hepatocytes in this study.

We next examined the effect of HFD on the expression rhythm of clock genes in hepatocytes and liver. As shown in Figure 2, the expression amplitude or rhythmicity of the core clock genes in hepatocytes (Figure 2A) or liver (Figure 2B) was severely impaired by HFD. The amplitude and oscillation of Bmal1 and Clock were significantly blunted, while Cry1, Per1, and Rev-erbα were increased in hepatocytes or liver of HFD mice relative to normal chaw diet (NCD) mice, resulting in attenuated diurnal variation in each of these transcripts.

Preliminary experimental results showed that ghrelin decreases in the circulation of HFD mice. To test whether the decline of ghrelin contributes to the attenuated circadian rhythm in steatotic liver, we administrated ghrelin in vitro and in vivo. As shown in Figure 3A, treatment of hepatocytes isolated from mice fed HFD for 12 weeks with 10⁻⁸ M ghrelin significantly restored both amplitude and rhythmicity of the diurnal expression of Clock and Per2. The circadian expression of Clock was phase-advanced of 8 h, and the peak–trough amplitude was augmented in cells treated with ghrelin. On the other hand, the expression of Per2 was phase-delayed for 12 h, and the peak of Cry1 was phase-delayed for 4 h.

Consistent with the alteration in the mRNA levels, the protein levels of Clock and Per2 also showed a significant change after ghrelin administration (Figure 3B). The circadian expression of Clock protein was phase-advanced of 12 h, while Per2 protein was phase-delayed for 12 h. This result indicates that ghrelin enhances the phase and amplitude rhythm of clock genes in steatotic hepatocytes.

To further explore the effect of exogenous ghrelin on the circadian rhythm in steatotic liver, we administrated synthetic ghrelin (11 nmol/kg/d, 2 weeks) to mice fed with HFD for 12 weeks. The administration of exogenous ghrelin significantly increased the circulating levels of ghrelin (Figure S1). As shown in Figure 4, ghrelin also significantly restored the derangement of core clock gene mRNA and protein levels. Upon treatment with ghrelin, the amplitude of Bmal1 and Rev-erbα mRNA was significantly increased, while both the amplitude and the rhythmicity of Clock and Per2 were enhanced. The peak–trough amplitude of Clock was delayed for 4 h, while that of Per2 was advanced of 8 h (Figure 4A). The protein levels of Clock and Per2 also displayed a robust diurnal variation after ghrelin administration. The peak of Clock was delayed for 4 h, while that of Per2 was advanced of 4 h (Figure 4B).

Collectively, these findings reveal that ghrelin markedly increases the expression amplitude of circadian clock genes, causing a peak shift to the dark period for Clock and a peak shift to the light period for Per2 in steatotic hepatocytes and liver.

We next examined the effect of endogenous ghrelin using GHSR1a-deficient mice. Cre adenovirus (Ad-cre) was injected through the tail vein into GHSR1a^flox/flox mice fed the HFD. The significant reduction of GHSR1a mRNA and protein in liver was validated by Western blotting and RT-qPCR three days after injection of Ad-cre (Figure 5A). GFP adenovirus (Ad-GFP) was used as a control. As shown in Figure 5B, deficiency of GHSR1a resulted in a significant decrease of the amplitude of Bmal1, Clock, Per2, Rev-erbα. Of note, GHSR1a deficiency led to an almost complete disruption of Clock and Per2 mRNA oscillation (Figure 5B) in steatotic hepatocytes. Consistently, the circadian oscillation of Clock and Per2 proteins demonstrated a significant attenuation in GHSR1a-deficient mice fed with the HFD (Figure 5C). Our result suggests that endogenous ghrelin regulates the rhythm of the hepatic clock.

In summary, these findings suggest that ghrelin restored the circadian rhythm in steatotic liver likely through a mechanism dependent on mTOR/S6 signaling.

Previous studies [21] have demonstrated that the diurnal rhythm of food intake is associated with the oscillation of mTOR activity, evidenced by increased pS6 levels during nighttime feeding. The diurnal rhythm of mTOR activity is significantly suppressed in mice fed a HFD. We thus tested whether ghrelin alters the diurnal rhythm of mTOR activity in C57BL/6J mice fed a HFD for 12 weeks. Ghrelin (11 nmol/kg/d) was administrated by a subcutaneous minipump for two weeks. Food intake was significantly increased by ghrelin treatment, especially in the dark period (Figure 6A). This change was associated with an increased oscillation in mTOR activity. Hepatic pS6 levels was significantly increased in the dark period in mice fed HFD or in cultured hepatocytes (Figure 6B,D). Conversely, deficiency of GHSR1a markedly attenuated the diurnal oscillation of mTOR activity (Figure 6C).

To determine whether mTOR mediates the effect of ghrelin on the improvement of the circadian rhythm in steatotic liver, we used rapamycin, an inhibitor of mTOR signaling. As shown in Figure 7, rapamycin significantly decreased the protein levels of Clock, Per2, and p-S6 in cultured hepatocytes. Further, rapamycin treatment markedly perturbed ghrelin-induced restoration of the circadian rhythm, evidenced by the attenuation of diurnal variation of Clock and Per2 protein levels.

The ghrelin peptide was purchased from Phoenix Pharmaceuticals, Inc. (Burlingame, CA, USA). Dexamethasone was purchased from Sigma-Aldrich (St. Louis, MO, USA). Mouse anti-β-actin and rabbit anti-S6 and anti-p-S6 were obtained from Cell Signaling Technology (Beverly, MA, USA). Rabbit anti-GHSR1a and rabbit anti-Clock were purchased from Santa Cruz Inc. (Santa Cruz, CA, USA). Rabbit anti-Per2 was from MBL Inc. (Medical & Biological Laboratories, Nagoya, Japan).

Male C57BL/6J mice were used in the present study. Four-week-old mice were assigned to receive a normal chow diet or a high-fat diet (60% fat, D12492; Research Diets, New Brunswick, NJ, USA) ad libitum for 12 weeks. Mice were handled in accordance with the Guide for the Care and Use of Laboratory Animals published by the US National Institutes of Health (NIH publication no. 85 revised 1996). All experimental protocols were approved by the Animal Care and Use Committee of Peking University (Permit Number: LA2012-60, 6 January 2012). All mice had free access to food and drinking water and were maintained under conditions of controlled temperature (24 °C) and humidity, with a 12 h light (lights on at 7:30 a.m.) and 12 h dark (lights off at 7:30 p.m.) cycle. For circadian studies, the animals were sacrificed every 4 h starting at 7:30 a.m. (ZT4) for 24 h (n = 7–8 at each time point).

Surgery and implantation of osmotic minipumps: Mice were anesthetized with 1% Nembutal (7 mL/g body weight). Through a 1 cm incision in the back skin, the mice were implanted subcutaneously with an Alzet osmotic minipump (model 1002) filled with vehicle or acyl-ghrelin (11 nmol/kg/d) for 14 days. Before implantation, the pumps were filled with the test agent and placed in a Petri dish with sterile 0.9% saline at 37 °C for at least 4 h to prime the minipumps.

Hepatocytes were isolated from mouse liver as previously described [26]. Briefly, male C57BL/6 mice fed with HFD were anesthetized with 1% Nembutal (7 mL/g body weight) and injected intraperitoneally with 1000 IU heparin. The liver was perfused with 20 mL pre-warmed 37 °C DHANKS buffer, followed by 15–20 mL of 3.3% collagenase IV (Sigma Aldrich Corp., St. Louis, MO, USA) at a flow rate of 4 mL/min. After perfusion, liver tissues were removed and washed with 15 mL high-glucose DMEM. The hepatocytes were centrifuged at 50 g for 3 min and washed thrice with DMEM medium to remove tissue dissociation enzymes, damaged cells, and non-parenchymal cells. Dexamethasone (100 nM) was applied for 1 h to synchronize the cells. After thorough washing, fresh culture media was added, and the cells were collected at the indicated times after dexamethasone removal.

Cells or liver tissue were homogenized with cell lysis buffer to obtain protein lysates. Proteins were separated by SDS-polyacrylamide gel electrophoresis and transferred to polyvinylidene fluoride membranes. The membranes were incubated for 1 h at room temperature with 5% fat-free milk in Tris-buffered saline containing Tween 20, followed by incubation overnight at 4 °C with primary antibodies. β-actin was used as an internal control.

Total RNA was isolated with RNATrip (Applied Gene, Beijing, China) from hepatocytes or liver tissues according to the manufacturer’s protocol and reverse-transcribed into cDNAs by reverse transcriptase PCR (Cat#3500, Promega, Fitchburg, WI, USA). The cDNA was detected by the Agilent AriaMx real-time PCR system (Agilent Technologies, Inc., Santa Clara, CA, USA).

Sequences of primers for circadian rhythm genes and β-actin are shown in Table 1.

Statistical analysis was performed using Graph Pad Prism Version 5.0 (GraphPad Software, Inc., San Diego, CA, USA). The differences between groups were assessed by an unpaired two-sample t-test, and multiple comparisons between more than two groups were analyzed by one-way ANOVA. The data represents means ± standard error of the mean (SEM). A p-value < 0.05 was considered significant.