Differentiating external zeitgeber impact on peripheral circadian clock resetting

To disentangle different zeitgeber inputs into the circadian system, mice were exposed to a zeitgeber desynchrony (ZD) paradigm combining a 28-hour light-dark (LD) cycle (14 h light: 14 h dark; LD-14) with a 24-hour time-restricted feeding paradigm (12 h food: 12 h no food; RF-12; Fig. 1a). Another cohort of mice were exposed to 24-hour light-dark (12 h light: 12 h dark, LD-12) combined with a 28-hour time-restricted feeding paradigm (14 h food: 14 h no food; RF-14; Fig. S6), defined as the inversed zeitgeber desynchrony paradigm (iZD). During both protocols every 6^th experimental day animals experienced conditions when food access coincided with the dark phase. These days were defined as in-phase days since under ad-libitum conditions nocturnal mice also consume most their food during the dark phase¹⁷. Accordingly, days at which mice had food access almost exclusively in the light phase – thus being exposed to conflicting zeitgeber input – were defined as anti-phase days (Figs. 1a and S6). Mice exposed to the ZD protocol displayed a range of activity rhythms (Figs. 1b–e and S1). Roughly 13% of all mice (8 of 61) showed 28-hour activity rhythms phase-locked to the LD cycle (Figs. 1b and S1, top left). All other animals showed compound rhythms with median periods of 25.6 h falling between the 24- and 28-hour zeitgeber rhythms (Fig. 1c). χ² periodogram analysis revealed up to four distinct period peaks (at 22–23 h, 24 h, 25–26 h, and 28 h) with a characteristic long period-short period sequence (Figs. 1d,e and S1). When determining the phase angle between activity onsets and the two zeitgeber rhythms, it became clear that activity regulation was a function of zeitgeber phase angle. The smallest phase difference between activity and feeding time was observed just prior to in-phase and largest on anti-phase days (Fig. 1f,g). These data suggest that behavioural rhythms are lengthened when phase differences between the zeitgebers become larger, but activity rhythms snap back (i.e. show short periods) when zeitgeber phases re-converge during the second part of the ZD cycle. In the iZD paradigm, locomotor activity adapted to the 12h-light:12h-dark cycles with very little activity in the light phase. Some animals showed increased activity in the light phase when it coincided with the end of the fasting phase (Figs. S6 and S7). Only two animals showed a dominant 28-hour adapted activity period under iZD conditions. Here, periodogram analysis revealed additional 24-hour activity periods for both animals (Fig. S6). Three animals of the 42 mice analysed showed additional free-running periods between the 24- and 28-hour zeitgeber rhythms in the iZD paradigm.

Similar to standard LD conditions, running-wheel activity peaked in the beginning of the feeding/dark phase on in-phase days, though with a marked increase in activity towards the end of the light/fasting phase. On anti-phase days animals showed increased relative activity in the first half of the fasting/dark phase (Fig. 2a,b). The fasting/feeding phase distribution of activity patterns was almost inverted between in-phase (41 ± 3% fasting phase activity) and anti-phase days (63 ± 3% fasting phase activity, Fig. 2b). Overall, mice showed reduced total activity on anti-phase days (747 ± 41 vs. 1,031 ± 47 revolutions per day; Fig. 2c). Relative to the LD-14 cycle, running-wheel activity peaked in the beginning of the dark phase at 193° at both in-phase and anti-phase days (Fig. S2a,b).

In the SCN, mRNA expression profiles of two clock genes, Bmal1 and Per2, were determined by ³⁵S-UTP in situ hybridisation. In line with running-wheel activity rhythms, clock gene mRNA profiles in the SCN were phase-shifted relative to feeding time on anti-phase days compared to in-phase days (Fig. 3a,b). In addition, Bmal1 expression patterns were dampened with overall high levels on anti-phase days (Fig. 3a, upper panel). Mean phase shifts between in-phase and anti-phase days were 64 ± 28° for Bmal1 and 75 ± 12° for Per2 (Fig. 3b).

We next determined ZD clock gene (Bmal1, Per2, Dbp) mRNA expression profiles in three peripheral tissues (liver, epididymal white adipose tissue (eWAT), adrenal gland) by qPCR. Unlike the SCN, in peripheral tissues, clock gene expression profiles were similarly phased relative to feeding time – and, thus not to light phase – between in-phase and anti-phase conditions (Figs. 4a and S3–S4). In liver, phase differences were 28 ± 4°, 7 ± 3°, and 25 ± 8° for Bmal1, Per2 and Dbp, respectively (Fig. 4b, left panel, Table S2). In eWAT, in-phase/anti-phase angles were slightly more pronounced at 33 ± 5°, 20 ± 8° and 31 ± 19° for Bmal1, Per2 and Dbp, respectively (Fig. 4a,b, middle, Table S2). The largest clock gene expression phase shifts between in-phase and anti-phase days were seen in adrenals with 51 ± 13° (Bmal1), 53 ± 8° (Per2) and 49 ± 13° (Dbp) (Fig. 4a,b, right, Table S2). Variations between the different genes were small. Therefore, only one anti-phase profile was investigated under iZD conditions. Phase shifts were averaged over three genes for each tissue. Phase shifts were 10 ± 25° (liver), 55 ± 15° (eWAT) and 34 ± 12° (adrenal) between in-phase and anti-phase days (Fig. S8).

Finally, serum corticosterone and leptin level profiles were determined using radioimmunoassay (RIA) and enzyme-linked immunosorbent assay (ELISA), respectively (Figs. 5a,b and S5). The effect of ZD on the overall excretion for corticosterone and leptin was similar with mean phase shifts between in-phase and anti-phase days of 112 ± 37° and −125 ± 15°, respectively (Fig. 5c, Table S2).

Our data so far revealed a tissue-specific adaptation of molecular clocks to ZD conditions with highest phase disruption on days of largest zeitgeber divergence. Such chronodisruption is also a hallmark of shift work and has been suggested to contribute to the increased risk of shift workers for metabolic disorders¹⁸. In line with this, under ZD conditions mice were also forced to consume food during the light phase (Fig. 1). To determine to which extent divergent zeitgeber input may affect metabolic homeostasis, we analysed food intake and body weight regulation under ZD conditions. Similar to what we had observed for running-wheel activity, animals showed cyclic changes in food intake and body weight regulation under ZD conditions (Fig. 6a,b). Food intake was highest around in-phase days whereas it declined and was lowest around anti-phase days. Mice consumed significantly more food on in-phase (18.8 ± 0.3% relative to body weight) than on anti-phase days (16.3 ± 0.2%; Fig. 6c). Body weight followed food intake. Animals lost weight on anti-phase days (−0.6 ± 0.2%) whereas they gained weight on in-phase days (1.9 ± 0.3%; Fig. 6d) resulting in markedly higher energy conversion rates (7.2 ± 1.5% vs. −3.7 ± 1.3%; Fig. 6e). Under iZD conditions animals showed cyclic changes in food intake and body weight regulation. Interestingly, the relations of food intake and body weight gain were inversed between in-phase and anti-phase days compared to the ZD paradigm. Under prolonged feeding-fasting cycles mice gained weight (0.8 ± 0.2% vs. −0.8 ± 0.3%) and consumed more food (23.4 ± 0.5% vs. 18.3 ± 0.6%) on anti-phase days compared to in-phase days, respectively. In contrast to the ZD-paradigm, food conversion was more effective on in-phase days under iZD conditions (−6 ± 1.5% vs. 3.1 ± 0.9%; Fig. S7b–e). Under ZD conditions blood glucose levels were higher at fifteen minutes after glucose injection on in-phase days but declined rapidly back to baseline levels (Fig. 6f, left). Animals showed improved glucose tolerance on anti-phase days under ZD conditions (Fig. 6f, right). Glucose tolerance was similar between in-phase and anti-phase days under iZD conditions (Fig. S7f). Body composition was comparable between the paradigms and between in- and anti-phase days of the same paradigm. Mice in the iZD-paradigm showed marginal increased fat mass (22.7% and 22.9% under iZD conditions vs. 20.9% and 20.5% under ZD conditions) and decreased lean mass (72.9% and 73.5% under iZD conditions vs. 75.6% and 74.2% under ZD conditions) compared to the animals of the ZD-paradigm, but the differences were not significant (Fig. S10).

In order to differentially quantify zeitgeber input into specific molecular and behavioural rhythms we compared in-phase/anti-phase day phase shifts across tissues/outputs (Table S1). For easier comparison, external time (equaling feeding time) was used as reference frame and phase shifts for each tissue were averaged across genes (Fig. 7a). From this perspective, a phase shift of 0 h would mean that the rhythm stays aligned with the feeding/fasting cycle (RF-12) while a phase shift of ±12 h would signify a rhythm phase-locked to the light-dark cycle (LD-14). With the exception of leptin showing a phase advance of circa 8 hours on anti-phase days, all rhythms studied aligned between the two zeitgebers with peripheral tissues aligning more closely with food (Fig. 7a). As would be expected, SCN clock gene expression and rest/activity cycles showed very comparable phase shifts which were significantly different from, both, light and food rhythms. On average, corticosterone rhythms were closest to the light-dark cycle. These data reveal a marked tissue/rhythm specificity of the two zeitgebers and allow a comparison of zeitgeber resetting capacity across different biological functions. Under inversed zeitgeber rhythms (LD-12,RF-14; iZD), peripheral tissue clocks show little phase shifts – but higher variance between the genes investigated – between in-phase days and anti-phase days (Figs. S8 and S9). Peripheral tissue clocks stayed aligned to the LD cycle under iZD conditions. Activity phase shifts were different from, both, light and food rhythms (Fig. S9). However, those phase shifts were much smaller under iZD compared to ZD conditions (Figs. 7a and S9). Thus, normal light-dark cycles are more potent to entrain behavioural rhythms and may stabilise peripheral tissue clocks at a 24-hour period when feeding-fasting cycles are out of the range of entrainment. In consequence, the strong impact of the entrained SCN on peripheral tissue clocks in the iZD paradigm does not allow the investigation of differential zeitgeber impact on various tissue clock resetting.

Young adult male C57BL/6J mice were maintained in the animal facility of the University of Lübeck. All experiments were in accordance with the German Law for Animal Protection and the FELASA guidelines for animal research. They were ethically assessed and legally approved by the MELUR Schleswig-Holstein, Germany. Prior to experiments mice were kept under 12-hour light: 12-hour darkness conditions (LD-12) with 300 lux illumination during the light phase and access to chow food (Altromin #1314) and water ad libitum.

Mice were singly housed in running-wheel cages. Animal age ranged from 11–17 weeks at the start of the ZD paradigm and one experiment lasted between 4–8 weeks. After 1 week of acclimatisation, mice were put under 14-hour light: 14-hour darkness (LD-14) conditions with 300 lux illumination at light phases while food access was given at 12-hour food access: 12-hour fasting (RF-12) intervals (Fig. 1a). On the first day of the experiment food was removed 1 h after “lights on” and accessible again 1 h before “lights off”. Each day mice and food were weighed prior to food access.

In an inverse experiment (iZD), another cohort of mice (n = 48) were kept under 12-hour light:12-hour darkness (LD-12) conditions with 300 lux illumination at light phases while food access was provided at 14-hour food access:14-hour fasting (RF-14) intervals. On the first day, food was removed from the hopper 1 h before “lights on” and accessible again 1 hour after “lights off”. Each day food and mice were weighed prior to food access.

Running-wheel usage of singly-housed mice was recorded and analysed using the ClockLab system and software (6.0.34, Actimetrics, Evanston, USA). Activity recordings started during acclimatisation to ensure that mice were adapted to the light-dark cycle and to the running-wheels. Mice were accustomed to handling for several days before the start of the experiment. During the experiment mice were weighed before the access to food and consumed food was measured.

On in-phase or anti-phase days animals were sacrificed at specified times (zeitgeber times (ZT) 2, 8, 14, and 20, and 2 again (not included in analysis) relative to food access; “food in” = ZT12; n = 2–5 per time point). Note that under iZD conditions animals were sacrificed at comparable time points along the fasting-feeding cycle (e.g. “ZT2” = 2.3 h after food out). Mice were sacrificed by cervical dislocation followed by immediate decapitation. In the dark phase sacrificing was performed under dim red light and eyes were removed before turning on the lights for tissue dissection. Trunk blood was collected and kept at room temperature for 30 min for clotting and then centrifuged for 30 min at 664 × g and 4 °C. Serum was stored at −20 °C. Whole brains were isolated and fixed in 4% paraformaldehyde (PFA) in phosphate buffered saline (PBS) for 12–18 h before dehydration in ascending ethanol series and subsequent embedding in paraffin. Liver, eWAT and adrenals were stored in RNAlater (ThermoFisher, Waltham, USA) at −20 °C before RNA isolation.

Tissues were homogenised using a bench homogenizer (Biolab, Bebensee, Germany) and total RNA was extracted with TRIzol reagent (ThermoFisher). cDNA was obtained from isolated RNA using random-hexamer primers and High-capacity cDNA Reverse Transcription Kit (Applied Biosystems, Foster City, USA) following the manufacturer’s protocol. cDNAs were diluted 1:10–1:20 and stored at −20 °C. qPCR was done using Go-Taq qPCR Master Mix (Promega, Madison, USA) on a Bio-Rad CFX96 thermocycler (Bio-Rad, Hercules, USA). The following primers were used: Eef1a forward 5′-TGCCCCAGGACACAGAGACTTCA-3′; EeF1a reverse 5′-AATTCACCAACACCAGCAGCAA-3′; Bmal1 forward 5′CCTAATTCTCAGGGCAGCAGAT-3′; Bmal1 reverse 5′-TCCAGTCTTGGCATCAATGAGT-3′; Per2 forward 5′- GCCAAGTTTGTGGAGATTCCTG-3′; Per2 reverse 5′-CTTGCACCTTGACCAGGTAGG-3′; Dbp forward 5′-AATGACCTTTGAACCTTGATCCCGCT-3′; Dbp reverse 5′-GCTCCAGTACTTCTCATCCTTCTGT-3′.

Paraffin embedded brains were cut at 8 µm on a microtome (ThermoFisher). In situ hybridisation with ³⁵S-UTP labelled antisense RNA probes was performed as described⁴⁷. S³⁵-UTP was purchased from PE (Perkin Elmer, Waltham, USA). Bmal1 and Per2 riboprobes were synthesized with T7 and T3 RNA polymerases, respectively^48,49. Hybridisation was performed overnight at 50 °C. Quantification was determined by densitometric analysis of autoradiography films (Amersham Hyperfilm MP, GE Healthcare, Chicago, USA). Films were developed using an automatic developing machine (Kodak, Rochester, USA). Developed films were scanned in a high-resolution scanner (Bio-Rad) and grey-scale images were quantified using the Quantity One software (Bio-Rad) for expression levels. Regions of interest were normalized to background.

Serum leptin was measured by ELISA (#EZML-82K, Millipore, Burlington, USA) following the manufacturer’s protocol. Serum corticosterone levels were determined using ImmuChem Double Antibody Coticosterone ¹²⁵I RIA Kit (#07120102, MP Biomedicals, Eschwege, Germany) according to the manufacturer’s protocol.

GTTs were conducted in the third cycle of ZD or iZD on in-phase or anti-phase days. Animals were only used once. Mice were fasted for 12 h prior to GTT. A total of six animals was used for each GTT. Blood glucose was measured before the start of GTT using a glucometer (ACCU-CHECK Aviva, Roche, Basel, Switzerland). Intraperitoneal injection of 1.5 g glucose in 0.9% NaCl/kg body weight was was followed by blood glucose determination at 15, 30, 60, 90 and 120 minutes after injection.

Body composition was analysed using nuclear magnetic resonance (minispec LF110, Bruker, Billerica, USA) after the end of glucose tolerance test in the fasted mice. Free body fluid, fat and lean mass were measured. Fat and lean mass were normalized to individuals’ body weight (n = 6 for each condition).

χ² periodogramm analysis of activity recordings (n = 61 (ZD) or 42 (iZD)) was conducted excluding the first 3 experimental days. Peaks above p < 0.05 were considered as statistically significant. 30-min bin size running-wheel rotations were extracted for analysis using ClockLab version 6.0.34 (Actimetrics). Total running-wheel activity was averaged over 4–6 in-phase and anti-phase days, respectively, for 28 h (relative to light) or 24 h (relative to food). Activity was individually normalized to total activity for each in-phase and anti-phase day. Normalized activity of 4–6 in-phase and anti-phase days were averaged and displayed as relative activity, respectively. Feeding/fasting and light/dark phase distributions were calculated from relative activity profiles. In the relative activity profiles time is presented in degrees for LD and RF whereas 0° is “lights on”/“food out” and 180° is “lights off”/“food in”, respectively. Activity profiles were smoothed using a 3-neighbour running-average in GraphPad Prism 7 (GraphPad, San Diego, USA). Light and dark activity sections of anti-phase days were inverted for easier comparison of phase angles.

Daily activity onsets were determined by three independent investigators on long-term, double plotted actograms. Investigators were unaware of the phase relation of the ZD cycle. In case of disagreements, two additional investigators were asked to determine activity onset. The activity onset times of at least two investigators had to match for usability in further analysis.

Daily food intake was normalized to the fasted body weight of the animal. Body weight was normalized to the body weight of the previous day. Food conversion rate was determined by division of the body weight change by food intake of the same experimental day.

Gene expression was normalized to eukaryotic elongation factor-1 α (Eef1a). Relative expression ratios (using the ΔΔCT method) were calculated⁵⁰ and normalized to the mean ratio of the corresponding in-phase profile. Likewise, hormone levels were normalized to the mean ratio of in-phase profiles. Overall hormone excretion and individual gene expression between in-phase and anti-phase conditions were tested for significant differences using unpaired, two-tailed t tests. Three independent anti-phase profiles (ZD paradigm) or one anti-phase profile (iZD) were used for subsequent phase shift analysis using the centre of gravity (COG) as reference. The mean expression curves were analysed using CircWave 1.4⁵¹ and COGs were determined. Phase shifts of analysed genes (3 for peripheral tissues and 2 for the SCN) of each anti-phase profile were averaged to estimate tissue clock overall phase shifts. Differences of hormonal COGs between in-phase and anti-phase profiles were calculated. For activity phase shifts 3–5 in-phase to anti-phase transitions of individual activity onsets were averaged.

Two-way ANOVA was used to test for significant differences in activity distribution. Differences in activity peak of in-phase to anti-phase conditions relative to light or food phase were analysed using two-tailed, paired t tests, respectively. Food intake differences and body weight changes between in-phase and anti-phase days were analysed using two-tailed, paired t tests. For GTT analysis, two-way ANOVA was used to test for significant differences between conditions and Sidak’s multiple comparisons tests were performed to evaluate differences between conditions at specific time points. Areas under the curve for GTTs were analysed using two-tailed, paired t-tests. Statistical differences of body composition were analysed by one-way ANOVA (testing between paradigms) or two-tailed, unpaired t tests (between in-phase and anti-phase day of the same paradigm). Statistical differences of phase shifts between in-phase and anti-phase conditions were analysed in one-sample t tests against hypothetical values of minimal (0 h) and maximal (12 h) phase shifts. Rhythmicity of diurnal profiles was assessed using CircWave (s.a.). p-values below 0.05 were considered significant.

The datasets generated and analysed during the current study are available from the corresponding author on reasonable request.