Multi-Modal Regulation of Circadian Physiology by Interactive Features of Biological Clocks

Since the formation and settlement of our solar system roughly 4.5 billion years ago, the Earth has been rotating on its axis and revolving around the Sun, bringing about continuous light and dark cycles on this planet. In accordance with these cycles, nearly all living unicellular and multicellular organisms have evolved rhythmic life processes controlled by the circadian clock (from the Latin phrase circa diem meaning “about a day”), which have about 24 h periods and constantly predict and adapt to daily environmental changes [1]. This internal timing system is believed to help organisms survive by increasing their ability to timely anticipate the cyclic changes of light and food availability as well as predation risk. At the unicellular level, the timely compartmentalization of the organism’s biochemical, metabolic, and redox processes, coordinated by the intrinsic clockwork, ensures the temporal fitness of cell physiology and functions across species [2]. In lower eukaryotic species, biological timers may help single-celled organisms escape the DNA-damaging effects of ionizing radiation from sunlight as well as oxidative stress during cell division [3]. In higher, complex organisms, including humans, common cellular oscillators constitute the brain and peripheral tissue clocks that interconnect to form a circadian network at the whole-body level. Interestingly, human or cross-species studies reveal differences in behavioral chronotype not only between species but also within and between different individuals of each species, suggesting the extent of intra- and inter-subject variability of circadian timing systems [4,5,6,7,8]. With periodic anticipation and synchronization to day–night cycles, these internal timing systems, in concert, coordinate rhythmic physiology and behaviors such as the sleep–wake cycle, body temperature, blood pressure, hormone production, neural and immune system processes, and cell proliferation [9,10].

In contrast to the adaptive benefits of circadian rhythms, modern lifestyles result in misalignment of the working, eating, and sleeping cycles, relative to natural 24 h light/dark cycles, that historically defined human existence. Such misalignment has been found to increase our susceptibility to the onset and development of cardiometabolic, digestive, immune, and neuropsychiatric disorders, as well as cancers [11,12,13,14]. Several studies in animal models containing genetic mutations of clock genes or those exposed to forced circadian desynchrony regimens have also reinforced the causal relationship between circadian disturbances and disease pathologies [15,16,17,18,19,20]. Furthermore, increasing numbers of studies in cellular and animal models have reported that cellular and bodily rhythms are highly influenced by physiological and metabolic stimuli, such as diet, exercise, metabolites, ions, and gaseous molecules [21,22,23]. In this review, we will describe recent advances in chronobiology as well as the roles of central and peripheral clocks in physiology and diseases, with a particular focus on the dynamic interactions between biological timing systems and metabolic factors.

The basic circadian rhythm mechanism, conserved across living species on earth, is typically characterized by a cell-autonomous autoregulatory feedback loop [3,24]. In eukaryotes, a subset of dedicated positive and negative clock regulators forms the interlocked transcriptional translational feedback loop (TTFL), which constitutes a cell-intrinsic oscillator that drives the rhythmic expression of output genes involved in metabolic, biosynthetic, and signal transduction pathways [9]. In mammals, the BMAL1 and CLOCK transcriptional activator complex cyclically drives the transcription of its own repressors, period (PER) and cryptochrome (CRY). The core oscillator is complemented by a second loop in which periodic expression of BMAL1 is maintained by the REV-ERBα/β repressor and RORα/β activator proteins [25] (Figure 1).

Besides the core regulatory loops, multiple levels of epigenetic, posttranscriptional, and posttranslational regulation involving various kinases and phosphatases, ubiquitin–proteasome pathway components, nuclear–cytoplasmic transporters, non-coding RNAs, and chromatin remodelers contribute to the molecular clockwork, thus coordinating temporal programs via multiple clock–output genes involved in cellular physiology and metabolism [26,27,28,29,30,31,32,33]. Notably, recent large-scale genomic studies reveal that ~50% of mammalian genes exhibit circadian regulation in at least one tissue, although the identity of genes expressed rhythmically varies from tissue to tissue [34,35,36]. In addition, multi-scale omics studies demonstrated circadian regulation of the epigenome, the metabolome, the proteome/phosphoproteome, and the microbiome [34,35,37,38,39,40,41,42,43,44,45]. These studies reveal that proteins or metabolites display different patterns of oscillations relative to transcript rhythms in a given tissue (e.g., hippocampus, liver), and oscillations at all levels can be reprogramed by circadian disturbances, such as sleep deprivation, jet lag, high-fat diet, and aging.

In mammalian species, the circadian clock machinery is shared across the brain and peripheral organ systems, constituting a body-wide circadian network (Figure 2).

The intracellular oscillators, in approximately 20,000 neurons, comprise the hypothalamic suprachiasmatic nucleus (SCN), a central clock in the rodent brain. The SCN in humans has been found to contain a total number of neurons close to 100,000, though these numbers decline with age [46,47,48]. The SCN consists of different subtypes of neurons that express the neurotransmitter c-aminobutyric acid (GABA), an inhibitory neurotransmitter in the brain, alongside a range of neuropeptides such as vasoactive intestinal peptide (VIP), arginine vasopressin (AVP), and their cognate receptors (VPAC2 and AVPR1A/B) [49,50,51,52]. These GABAergic/peptidergic SCN neurons interact among themselves or with the other neurons in extra-SCN brain regions, constituting the main output pathway of the clock. Notably, a recent study has demonstrated that the VIP-VPAC2 neuropeptidergic axis plays a central role in mediating the endogenous pacemaking function of the SCN circadian circuit [53]. In line with this, the suprachiasmatic VIP neurons (SCN^VIP) have been shown to be required for normal circadian behaviors via functional connectivity between SCN^VIP neurons and dorsomedial hypothalamic neurons [54]. Interestingly, recent single-cell RNA sequencing (scRNASeq) studies with mouse SCN slice revealed novel neuronal phenotypes and interaction networks involved in the central clock, including the identification of five SCN neuronal subtypes, with cluster-specific marker genes of VIP, AVP, gastrin-releasing peptide (GRP), cholecystokinin (CCK), and the cell adhesion regulator C1ql3 [55,56]. Additional scRNASeq study has also identified a subgroup of cells expressing Prokineticin2 (Prok2) and its cognate receptor (ProkR2) found to be topologically and functionally distinct pacemaking element of the central clock [57]. Thus, these studies highlight diverse cellular sub-populations within the neuropeptidergic topology of the SCN, which may differently contribute to the central pacemaker function. Notably, recent studies have shown that astrocytes harbor distinct rhythmic properties, such as anti-phasic Ca²⁺ rhythms, that direct the circadian rhythmicity of SCN neurons and behavior [58,59,60]. This work suggests the importance of bipartite intercellular communication between astrocytes and neurons in modulating SCN pacemaker functions, beyond neuronal regulation of the central clock.

Along with endogenous circadian pacemaking activity, the SCN central clock also mediates the periodic synchronization of internal body rhythms with external day and night cycles by communicating retinal light information received from the retinohypothalamic tract (RHT) to peripheral clock systems [26]. In a hierarchical organization model, the SCN master clock coordinates the circadian phases of individual subordinate clocks in other brain regions via rhythmic release of neurotransmitters and neuropeptides as well as in peripheral tissues via systemic hormonal secretion and neural innervations, thus generating rhythmic output physiology and behaviors that are in keeping with the daily changes in environment and needs [61,62,63,64]. For example, the SCN coordinates the rhythmic anti-phasic secretion of the night sleep hormone melatonin in the pineal gland and the morning stress hormone glucocorticoid in the adrenal glands via the sympathetic nervous system, ensuring daily rhythms in sleep/wake, as well as neural, metabolic, and immune functions [65,66,67]. In addition, the brain master clock controls peripheral clock functions in the heart, kidney, pancreas, lung, intestine, and thyroid glands by circadian regulation of the autonomic nervous system [68,69,70,71,72,73].

Besides SCN-driven clock entrainment, a growing number of studies have reported that non-SCN brain regions and peripheral tissues possess their own autonomous, entrainable oscillators that influence not only circadian functions in the SCN and neighboring local clocks, but also whole body rhythms via neural, hormonal, and metabolic feedback mechanisms [13,74,75,76,77,78,79,80]. The SCN receives a myriad of nonphotic input, arousal, feeding behavior, locomotor activity, immune function, blood pressure, and melatonin, which are all able to adjust and synchronize the SCN [81,82,83,84]. The SCN can receive this feedback through its large array of reciprocal neuronal connections with different hypothalamic regions, such as the arcuate nucleus (ARC), intergeniculate leaflet (IGL), nucleus tractus solitarius (NTS), dorsal raphe, and dorsomedial hypothalamus, allowing these nuclei to convey nonphotic feedback to the SCN and thus adjusting circadian rhythmicity [85,86,87,88,89].

Beyond photic entrainment, multiple physiological and environmental cues (e.g., food intake, gut microbial products, redox cofactors, metal ions, metabolic gases) control non-SCN and peripheral clock functions, which, in turn, impact the entire host clock system via neural and immune–metabolic circuits [12,22,72,90,91,92,93,94,95]. These findings suggest that systemic circadian rhythms are achieved through multi-modal regulation of tightly coupled body clocks according to daily changes that occur in the internal and external environments.

The growing knowledge of cellular and tissue clock coupling mechanisms has increased our understanding of how rhythm disturbances of the SCN or locally distributed clocks within other tissues, caused by multiple physiological and environmental factors, impact circadian physiology and diseases at the whole-body level. Indeed, numerous animal studies have demonstrated pathological impacts of experimental circadian disruptions, such as surgical ablation of the SCN specific clock, whole-body knockout of core clock genes (i.e., Bmal1, Per1/2, Cry1/2, Rev-erbα/β), and experimental jet lag (chronic phase shift by altered light schedules). These studies provide ample evidence for the increased risk of sleep, mood, cardiometabolic, immune, endocrine, digestive, reproductive, premature aging, neurodegenerative, and neoplastic disorders [13,69,71,96,97,98,99,100,101,102]. Accordingly, several human health and translational studies have reported similar adverse health consequences as a result of circadian clock gene polymorphisms, sleep deprivation, night shift work, and artificial light at night (LAN) exposure [103,104,105,106].

The recent development of a tissue-specific genetic disruption tool has provided further insights into the specific roles of the SCN and its surrounding brain regions in circadian rhythm regulation. Studies of mice with genetic ablation of Bmal1 in SCN neurons showed that peripheral clocks, as well as locomotor activity, were lost or compromised in constant darkness but remained rhythmic and synchronized to light–dark (LD) conditions [107,108]. This suggests that previously observed loss of circadian rhythms, even under LD cycles, in animals with surgical ablation of the SCN resulted from the elimination of SCN afferents [109,110,111]. In a similar study, forebrain/SCN-specific deletion of Bmal1 in mice resulted in the immediate loss of circadian behavior as well as desynchronized and dampened circadian rhythms in peripheral tissues under conditions of constant darkness [112]. However, the loss of behavior and peripheral synchrony was rescued by LD cycles and was partially rescued by restricted feeding [112]. Moreover, targeted deletion of Bmal1 in neurons and glia was found to exacerbate neurodegenerative pathologies and behaviors, despite the retention of intact circadian behavioral and sleep–wake rhythms under LD conditions [101]. In line with these findings, a recent study showed that the nuclear receptors Rev-erbα/β in the GABAergic (γ-aminobutyric acid-producing) in neurons of the SCN (SCN^GABA neurons) control the diurnal rhythm of insulin-mediated suppression of hepatic glucose production in mice, without affecting diurnal eating or locomotor behaviors during regular light–dark cycles [113]. These results suggest that the SCN central clock plays an important role in maintaining the internal synchrony of robust circadian programs in some peripheral clocks, while other peripheral clocks can be differentially modulated by light and feeding, regardless of the presence of a functional SCN central oscillator in the brain.

Beyond the SCN’s clock-modulatory functions, accumulating evidence has revealed a critical role for SCN-independent clock entrainment in circadian rhythms and disorders. Recent studies have shown that several brain regions outside the SCN (e.g., extra-SCN hypothalamic nuclei, hippocampus, lateral habenula, choroid plexus) express SCN-independent or semi-autonomous intrinsic circadian rhythms that are sensitive to fluctuations in nutrients, behavioral arousal, and hormonal signals, particularly driven by daily food intake [75,79,80]. Through ablation or genetic perturbation, these studies revealed the important roles of non-SCN clock functions in modulating downstream body activities including metabolic rate, thermogenesis, food consumption, thirst, mood, and sleep [75,79,80].

Notably, SCN-independent clocks can modulate the activity of the SCN oscillator itself. With the combined approaches of pharmacological inhibition and electrophysiological stimulation of the substantia innominata (SI) in the basal forebrain, a recent study has argued that the cholinergic basal forebrain is both a necessary and sufficient arousal input to the circadian pacemaker, mediating arousal-induced clock resetting [114]. These results may also explain why, in the absence of a functional SCN clock in the brain, behavioral rhythms, and peripheral clocks are still entrained when mice are kept under LD cycle conditions [112,115]. The SCN circuitry is thus capable of conveying rhythmicity secondarily to other oscillators. Consistent with these findings, another recent study using an in vitro tissue co-culture model revealed that the autonomous clock in the choroid plexus (CP), the brain region responsible for cerebrospinal fluid (CSF) secretion, exceeds even the SCN clock in terms of robustness, perhaps determining the circadian period of behavioral locomotor activities by speeding up the SCN clock via the circulation of CSF [75]. In a parallel study, this CP oscillator was shown to be modulated by estrogens via a hormone receptor-dependent mechanism [116]. Together, these results indicate the physiological importance of non-SCN brain oscillator functions in mediating systemic regulation and environmental entrainment of biological clock function.

In addition to the brain network of cellular oscillators, growing evidence suggests that self-driving clocks in peripheral tissues are critical for the systemic homeostasis of circadian physiology. An approach that has been applied extensively in this context is tissue-specific disruption of a core clock component, for instance, the bmal1 locus, paired with assessment of physiological and endocrinological functions of that tissue. Table 1 lists some examples of studies in which this approach has yielded novel insights into the function of peripheral clocks in physiology and endocrinology.

For example, in a prevailing model, the robust daily rhythm of glucocorticoid (GC; corticosterone (CS) in rodents and cortisol in primates) has generally been attributed to SCN-mediated modulation of the hypothalamic–pituitary–adrenal (HPA) stress response axis and sympathetic innervation of the GC secretory adrenal gland for the light entrainment of other peripheral clock systems [65,66,129]. On the other hand, Kim and colleagues have shown that the adrenal gland has its own autonomous clock that functions independently of the SCN, and that adrenal-specific disruption of Bmal1 dampens the circadian CS rhythm, impairing behavioral rhythmicity and gene expression cycling in several peripheral organs [76,118]. These findings correspond with another study showing that the adrenal-intrinsic oscillator controls a gating mechanism involved in circadian sensitivity to adrenocorticotropin (ACTH) produced by the pituitary gland [119,130].

In another peripheral clock study, liver-specific Bmal1 deletion was shown to increase glucose clearance and hypoglycemia restricted to the fasting phase as a result of arrhythmic gene expression of glucose-related genes [120]. The systemic impact of the liver clock was further demonstrated in additional studies showing that dual Rev-erbα/β knockout specifically in the liver leads to increased circulating glucose and triglyceride levels, a reduction in free fatty acids (FFAs), as well as altered transcriptional, metabolic, and behavioral rhythms, compared with controls [131,132,133]. Notably, a more recent study revealed that circadian oscillations persist in the livers of mice devoid of an SCN or oscillators in cells other than hepatocytes, corroborating the independent nature of the liver clock [78].

Similar to liver cells, adipocytes harbor their own circadian clock. Disruption of this clock via adipocyte-specific deletion of Bmal1 results in obesity in mice, with a shift in the diurnal rhythm of food intake and energy expenditure, suggesting a central role for adipose tissue as an integrator of organismal energy balance [117]. In support of this idea, a recent study using an adiponectin (ADIPOQ)-deficient mouse model showed that this adipokine, which is produced primarily in adipose tissue to modulate glucose levels as well as fatty acid breakdown, regulates diurnal feeding rhythms through clocks in energy regulatory centers (e.g., arcuate nucleus (ARC)) of the mediobasal hypothalamus (MBH) [134]. The physiological implications of these mechanistic studies in animals are further underscored by previous human studies showing that in obese patients, ADIPOQ blood levels decline and the diurnal rhythms of ADIPOQ release are dampened [135,136]. On the other hand, another endocrine study showed that ablation of the pancreatic β cell-autonomous clock in adult mice caused severe glucose intolerance along with altered insulin secretion [121]. Interestingly, the O’Neill group recently provided evidence of the role of insulin as a systemic timing cue to entrain circadian rhythms throughout the body by selective induction of the period clock proteins, with further demonstration of the circadian disruption recapitulated by mistimed insulin in cell and animal models [137].

Importantly, growing evidence suggests an independent physiological role for the skeletal muscle clock. Recently, Ehlen et al. reported that muscle-specific Bmal1 disruption and restoration in Bmal1-KO mice led to sleep disturbances and recovery, respectively; however, brain-specific restoration of BMAL1 expression did not rescue BMAL1-dependent sleep phenotypes, indicating that the skeletal muscle clock is both necessary and sufficient for normal sleep regulation [122]. In line with these findings, a subsequent study indicated that muscle-specific loss of BMAL1 is associated with metabolic inefficiency, impaired muscle triglyceride biosynthesis, and the accumulation of bioactive lipids and amino acids [123]. More recently, skeletal muscle was also shown to exhibit diurnal variations in muscle growth and metabolism, independent of locomotor activity [138]. Thus, it can be speculated that rhythmic metabolic signals from the skeletal muscle clock impact systemic energy homeostasis, thus regulating brain activity and sleep function.

Notably, emerging transcriptomic and metabolomic studies have reported that lung adenocarcinoma as well as pulmonary inflammation (e.g., asthma) can reprogram the circadian homeostasis of local and systemic physiology, leading to metabolic and sleep disturbances [139,140]. In line with the idea that local organ disease impacts circadian rhythms, a recent study using a chronic kidney disease (CKD) mouse model reported that kidney-specific clock disruption by CKD leads to unstable circadian behavioral rhythms, which may explain the sleep disturbances that are known to be associated with kidney failure [77]. It is assumed that the rhythmic readjustment of fluid homeostasis by the kidney affects the SCN clock, thereby altering circadian rhythms at the behavioral level [77]. Overall, the current evidence suggests that brain clocks as well as multiple regulatory feedback networks in the periphery contribute to circadian physiology and pathophysiology (Figure 2).

Besides the systemic impact of local clock dysfunction, growing evidence has emphasized the chrono-physiological importance of non-photic regulation of the body clock network. Several early studies showed that timed food administration affects peripheral clocks without altering the SCN [141,142]. However, recent comprehensive metabolomics studies demonstrated that nutritional challenges, such as a high-fat diet, metabolically reprogram the circadian rhythmicity of distinct brain areas, including the SCN, and peripheral clocks, thus altering the system-wide synchrony of the internal body clocks [38,143,144]. In addition to an unbalanced diet, short-term feeding at the wrong time is reported to be sufficient to desynchronize peripheral clocks and induce obesity along with hyperphagia, physical inactivity, and metabolic disorders in mice [145]. These observations from animal models are resonant with several human studies, reporting that food intake during the circadian evening and/or night is associated with increased body fat and obesity and reduced effectiveness of weight loss therapy in both adults and children [146,147,148,149]. Besides the metabolic impact, mistimed feeding was also shown to result in dramatic deficits in hippocampus-dependent learning and memory by reducing cyclic AMP response element binding protein (CREB)-mediated long-term potentiation in the hippocampus [150]. Moreover, a recent population-based case–control study reported that mistimed eating patterns increase the risk of breast and prostate cancer [151].

Notably, an increasing number of studies has revealed that the intestinal microbiota in both mice and humans exhibit diurnal oscillations in composition and activity, and that these rhythms are impaired by the ablation of host molecular clock components or the induction of jet lag, leading to gut dysbiosis and altered feeding rhythms [37,152,153,154]. The potential systemic impact of a dysregulated microbiome was further shown in a subsequent study indicating that the diurnal rhythmicity of the microbiota drives the global programming of host circadian transcriptional, epigenetic, and metabolite oscillations [90]. Interestingly, Chambon and colleagues from the analysis of large intestine showed that depletion of microbiota profoundly disrupts circadian clock in intestinal epithelial cells (IECs), leading to altering corticosteroids levels and consequent metabolic disorders [155]. This suggests a reciprocal influence between the gut epithelium of the host and the microbiota for each other’s physiology that contributes to additional system-wide cyclic homeostasis. In line with these studies, Kuang et al. recently reported that cyclically induced expression of histone deacetylase 3 (HDAC3) in gut epithelial cells mediates the diurnal programming of the host’s metabolism by the intestinal microbiota, the lack of which leads to diet-induced obesity [156]. Given the systemic modulation of both brain and peripheral clock functions by gut microbiome metabolites [157], it is plausible that the above pathological impact of mistimed feeding is associated, in part, with dysregulated gut-microbiome products. Together, these findings underscore the physiological and pathological significance of peripheral entrainment of host circadian systems in response to multiple internal and external cues.

Emerging studies suggest that multiple metabolic or nutritional components, such as redox cofactors, gases, and ions, are not only circadian-regulated components, but can also act as timing cues to regulate circadian physiology via reciprocal feedback mechanisms (Figure 1). Descriptions of some of these factors and their roles in circadian rhythms and disorders are detailed below.

In recent decades, extensive chronobiological research has expanded our understanding of the functional roles and mechanisms of the circadian clockwork in human health and diseases. Thus, research trends in chronobiology have undergone a paradigm shift in many ways, particularly changing from hierarchical models to more integrated ones for understanding the circadian clock mechanism. In this regard, the overall evidence points to bidirectional crosstalk between transcriptional and metabolic rhythms, neuronal and glial clocks, SCN and non-SCN clocks, as well as brain and peripheral clocks (Figure 1, Figure 2). Our growing knowledge of the interactive nature of clock regulatory systems is expected to not only diversify our understanding of circadian physiology and pathophysiology but also increase our capacity to harness chronobiological knowledge to improve the prevention and treatment of multiple circadian-related disorders.