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Eat by the clock: How meal timing tunes your liver’s circadian rhythm

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Eat by the clock: How meal timing tunes your liver’s circadian rhythm

The circadian clock is key to healthy metabolism and is set by a central pacemaker within the brain. Peripheral clocks are present in just about all organs and are set to the central clock by various signals.

A brand new study published in Nature Communications reports on one pathway that synchronizes the liver clock to the central clock and the observable entraining of the liver physiology at different levels.

Study: Multi-omics profiling reveals rhythmic liver function shaped by meal timing. Image Credit: Billion Photos / Shutterstock.com

Introduction

Each light exposure and food intake determine the circadian rhythms of the body. The central pacemaker within the brain is situated within the suprachiasmatic nuclei (SCN) of the hypothalamus and responds to the light-dark exposure cycle.

Peripheral clocks follow the identical rhythms through neuroendocrine and metabolic signaling pathways conscious of the central pacemaker. This includes the liver clock, which immediately responds to changes in meal timing or the fast-feed cycle.

Food intake and fasting are linked to the body rhythms through post-translational modifications (PTM), which include phosphorylation and ubiquitylation of proteins resembling the circadian repressor gene PERIOD2 or the corresponding kinase genes CSNK1D/E (which encode CK1δ/ε). CK1 phosphorylates PERIOD1 and PERIOD2 at various sites, resembling the Ser971 residue of PERIOD2 (PER2-Ser971).

If feeding is proscribed to a particular time window through the day, known as day/sleep time-restricted feeding (DRF), the liver cycle shifts towards this era inside one week. This affects each the liver clock and transcriptional process, whereas metabolic pathways in mice don’t look like affected.

Earlier research has established that diurnal rhythms are present in about 5% of liver proteins. About 40% of phospho-proteins exhibit circadian rhythmicity.

Diurnal rhythms within the ubiquitylation of liver proteins influence the metabolism of fatty acid, glucose, and growth aspects. Amino acids, fatty acids, and energy pathways are regulated by acetylation, which responds to nighttime/wake time-restricted feeding (NRF), during which eating is permitted only during a specified window of time at night.  

It stays unclear whether PTM rhythmicity in response to meal timings is reflected at non-transcriptional levels.

The present study utilized a multi-omics approach to explore every day rhythms in liver proteins, in addition to 4 PTMs and the lipid cycle. This approach involved using a customized lipidomics technique to measure diurnal rhythmicity in lipid levels in mice on time-restricted feeding (TRF).

What does the study show?

Liver protein phosphorylation exhibits the best rhythmicity as in comparison with other PTMs. Just about all phosphorylation rhythms peaked within the sleep phase within the DRF group and within the second half of the sleep phase within the NRF group.

Nutrient availability was found to activate PER2-pSer971. Thus, phosphorylation was most conscious of nutrient intake, whereas succinylation showed the smallest change in response to food consumption.

For many rhythmic pathways, the phase was shifted by 4 to 5 hours, and none for greater than eight hours. Nevertheless, the lipid metabolic pathways showed a worldwide increase and shifted phase by eight hours. Lipid metabolism is an impressive feature of the liver’s diurnal rhythm in protein ubiquitylation that responds to the timing of feeds.

Integrated analyses indicated that fatty acid metabolism is regulated by proteins closely related to the circadian-associated PER2-pSer971. Thus, the diurnal rhythm of fat metabolism is a vital feature of the liver’s response to meal timing, as demonstrated by the rhythm of PER2-pSer971 formation within the liver under DRF conditions.  

The entrainment of fatty acid metabolism by DRF is supported by the lipidomics findings, which show strong diurnal rhythms in 155 lipids from 33 classes. This outnumbered the lipids in livers obtained from NRF mice by thrice.  

Transcripts were produced in rhythms matching those of unmodified or phosphorylated proteins. Conversely, rhythms observed in unmodified proteins were matched with those in messenger ribonucleic acid (mRNA), phosphorylated, or ubiquitylated proteins.

These findings reflect the presence of an intricate network that contributes to diurnal rhythms within the liver, that are controlled by N-glycosylation and phosphorylation, the primary under NRF and the second under DRF conditions.

What are the implications?

This dataset represents a comprehensive resource detailing the proteomic and lipidomic responses by the liver to alterations in meal timing.”

Understanding how time-restricted feeding (TRF) affects liver physiology and metabolism is very important to discover its potential health advantages. Previous studies have reported that the liver clock and liver transcriptomes respond rapidly to DRF; nevertheless, this entrainment will not be present within the liver metabolome. The present study examined this further using five PTMs with the associated proteomics.

Over 40% of phospho- and ubiquityl-proteins were rhythmic, along with over 30% of all proteins. About one in seven N-glycosylated proteins were also rhythmic, whereas only just a few succinyl-proteins exhibited this behavior.

Protein phosphorylation readily responds to the circadian liver clock. That is comparable to protein succinylation, which belies the circadian regulation of mitochondrial processes and responds to the circadian liver clock the least.

Each PTMs and the lipidome may contribute to the association between meal timing and diurnal liver rhythms, with PERS2-pSer971 sensing the provision of free fatty acids and glucose.

Over 30% of lipids were also rhythmic and appeared to take care of the diurnal rhythms of behavior and metabolism. The circadian clock responds to TRF in setting the diurnal rhythm of fatty acid metabolism, as shown by lipidomic and gene-level connectivity mapping.  

The study findings provide vital insights into how the circadian clock regulates body processes in normal and pathological conditions. Nevertheless, additional research is required to know the consequences of other PTMs and rule out the confounding effects of strong diurnal rhythms of other cell populations not intrinsic to the liver, resembling white cells.

Journal reference:

  • Huang, R., Chen, J., Zhou, M., et al. (2023). Multi-omics profiling reveals rhythmic liver function shaped by meal timing. Nature Communications. doi:10.1038/s41467-023-41759-9.

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