The Clock and the Brain: Circadian Rhythm and Alzheimer’s Disease

The molecular structure of the circadian clock in mammals, SCN, consists of two interlocking Transcription/Translation Feedback Loops (TTFLs), which are directed by two activators [Circadian Locomotor Output Cycles Kaput (CLOCK) and basic helix-loop-helix ARNT like 1 (BMAL1)] and two repressors [Period (PER) and Cryptochrome (CRY)] [35]. Transcription of BMAL1 and CLOCK genes leads to the heterodimerization of the BMAL1:CLOCK complex in the cytoplasm. This complex is transferred to the nucleus and binds to canonical Enhancer Box (E-Box) sequences or noncanonical E-Boxes of clock-regulated genes. BMAL1 and CLOCK drive the expression of PER and CRY. PER and CRY proteins form a complex in the cytoplasm, and this complex is transferred to the nucleus. PER and CRY proteins inhibit the transcriptional activity of the BMAL1:CLOCK complex after their translation and nuclear accumulation. PER and CRY protein levels reduction decreases the suppression of BMAL1:CLOCK activity, and a new cycle begins [36]. Figure 1 illustrates the cellular and molecular mechanisms involved in the association of the circadian clock and AD.

Neuronal dysfunction has also been observed in the SCN of patients with AD [14,37]. Similarly, signs of degeneration, including increased glia/neuron ratio in the SCN tissue of postmortem AD patients, have been detected [38]. Moreover, in AD patients, melatonin levels are reduced [39]. These changes could potentially contribute to disruptions in circadian gene expression and hence CRDs.

It has been shown that rhythmic expression of clock genes was lost in both preclinical and clinical AD patients [40]. A study by Luo et al. demonstrated that sleep deprivation (SD) upregulated Cry2 in the hippocampus of AD mice by decreasing cytokine-inducible SH2-containing protein (CISH)-mediated transcription factor Signal Transducer and Activator of Transcription 1 (STAT1) phosphorylation, which resulted in synaptic dysfunction [41]. Oyegbami et al. showed a blunted effect of Cry1 and Cry2 gene expression in the medulla/pons of the AD mouse model [38]. In a study in the AD mouse model with disrupted circadian clock function via Bmal1 gene deletion, disruption of daily hippocampal Interstitial Fluid (ISF) Aβ oscillations, and increased amyloid plaque accumulation were observed [42].

A recent preclinical study has shown a close relationship between sleep–wake cycle parameters and circadian clock gene expression levels, especially within the SCN and hippocampus in 2-month-old (plaque-free stage) and 10-month-old (plaque-burdened stage) AD mouse models [43]. The result showed that CRDs preceded Aβ deposition.

Longitudinal studies can help to determine whether clock gene disruptions are a cause or consequence of AD pathology. By observing over time, researchers can follow the events leading to neurodegeneration. Assessing circadian gene expression along with Aβ and tau accumulation in animal models can help to find which one precedes the other.

Genetic factors have a significant role in both AD pathogenesis and circadian rhythm regulation. There is evidence of polymorphisms in several genes involved in circadian clock function that may influence AD progression and the manifestation of CRDs.

The clock genes encode a transcription factor central to circadian rhythm generation and contain several Single Nucleotide Polymorphisms (SNPs) associated with AD. Studies identified the higher prevalence of the C allele of the CLOCK gene for rs4580704 SNP [44] and also a higher prevalence of the rs1554483 G allele [45] in AD patients compared to controls in the Chinese population.

A significant association between the rs3027178 SNP of the PER1 gene and AD, where the G allele was protective against AD has been reported [46]. It was proposed that this polymorphism can influence the expression of genes that can be relevant for AD, including Vesicle-Associated Membrane Protein 2 (VAMP2) in the hypothalamus and CST Telomere Replication Complex Component 1 (CTC1) protein across several tissues. Xiang et al. showed an increased prevalence of five-repeat homozygotes of PER3 length in AD patients compared to controls [47].

BMAL genes contain variants that have been identified in AD patients. Chen et al. found a higher prevalence of TT genotypes ARNTL (BMAL1) gene rs2278749 SNP in AD patients compared to that in controls [48]. Qing-Xiu et al. also showed a significantly higher prevalence of C allele and CC genotypes of ARNTL2 (BMAL2) gene rs2306074 SNP in AD patients compared to that in controls [49].

Yang et al. reported that the prevalence of the C allele of the CLOCK gene 3111T/C SNP in AD patients was significantly higher than that in control subjects in the Chinese population [22]. A study in the Chinese population showed that the prevalence of the A allele of the CLOCK gene rs4864548 SNP in AD patients was significantly higher than that in control subjects [50].

In the Chinese population, a significant difference was detected in ARNTL (BMAL1) gene rs900147 SNP between AD and control subjects regarding the genotypic distribution [51]. This study also showed that G allele carriers have a significantly higher risk of developing AD and amnestic MCI than other carriers.

A study of the Mexican population reported that PER3 gene rs228697 SNP showed a nine-fold increased risk for CRDs in AD patients [52]. It was proposed that this variant may contribute to circadian disruption, leading to sleep disturbances in AD patients. This, in turn, exacerbates Aβ pathology and may accelerate neurodegeneration. The study also mentioned that the risk of CRDs may be higher in Apolipoprotein E4 (APOE ε4) carrier patients because of a potential interaction between PERIOD protein and APOE.

For CLOCK gene rs4580704 [44], rs1554483 [45], rs4864548 [50] SNPs, BMAL1 gene rs2278749 [48], and BMAL2 gene rs2306074 [49] SNPs, the authors argued that they might contribute to increasing AD risk through dysregulation of metabolic pathways, potentially overlapping with APOE ε4-associated mechanisms, and possibly exacerbating neurodegeneration via impaired glucose [53] and lipid [54] metabolisms, and an increase in metabolic syndrome risk [55].

These genetic associations provide insight into shared biological pathways between CRDs and AD pathogenesis, while suggesting that genotyping of clock-associated gene polymorphisms may help identify high-risk individuals and provide guidance for personalized chronotherapeutic interventions.

Table 1 summarizes some polymorphisms in circadian clock genes that affect AD.

Vasopressin is mostly synthesized in the supraoptic nucleus (SON) and paraventricular nucleus (PVN) of the hypothalamus. It acts as a hormone and neurotransmitter. Vasopressin plays a key role in the homeostasis of water and electrolytes in the body and is a vasoconstrictor [56]. It is also a modulator of the stress response and vital autonomic functions, including body temperature, behavior, and memory [57]. Neurotensin (NT) is a 13-amino-acid peptide that was originally isolated from bovine hypothalami in 1973 [58]. NT is found in the central nervous system and gastrointestinal tract [59]. The association between NT as a neuromodulator and dopamine in the nervous system has been well known [59]. A post-mortem study showed that patients with AD compared to controls exhibited a significant decrease in vasopressin and NT and a corresponding increase in the Glial Fibrillary Acidic Protein (GFAP)-stained astrocyte to Nissl-stained neuron ratio in the SCN [60]. Additionally, Kang et al. found that ISF Aβ levels significantly increase during acute SD and with orexin infusion, whereas Aβ levels decreased following administration of a dual orexin receptor antagonist [61].

It has been shown that Aβ administration in the SCN can cause CRDs [62]. Aβ accumulation has been shown to impair melatonin receptor signaling in the SCN and pineal gland [28]. A post-mortem study showed reduced melatonin receptors (MT1 and MT2) expression in the pineal gland and the occipital cortex of AD patients, which correlates with Aβ burden severity [63]. The downregulation of these receptors may contribute to the loss of melatonin’s chronobiotic effects in AD patients.

Pappolla et al. demonstrated that melatonin prevents Aβ aggregation rather than reversing the neuropathology in the clinical phases of AD [64]. They studied the effect of melatonin on the clearance of Aβ peptides through the lymphatic system. The study was performed on AD transgenic mouse models (Tg2576) treated with melatonin at the ages of 4 months and 15.5 months. Aβ (Aβ42, Aβ40) levels were measured in the lymph nodes, brain, plasma, and multiple tissues one week after the treatment in the treated and control groups. A remarkable reduction in Aβ42 and oligomeric Aβ40 levels in the brain and also a notable increase in soluble monomeric Aβ40 levels in the brain and cervical lymph nodes, which showed that melatonin increases Aβ lymphatic clearance system were seen. Regarding the anti-amyloid effects of melatonin, melatonin treatment initiation before the age of amyloid formation at the age of 4 months exhibited a greater response in comparison with 15.5 months [64]. The decreased melatonin levels may contribute further to compromising sleep quality and worsening circadian desynchronization.

A study investigating AD-related pathology and CRD in an Amyloid Precursor Protein with the Swedish mutation (APPSwe)-Tau (TAPP) mouse model, showed phase-delayed body temperature and locomotor activity with increases around the active-to-rest phase transition [65]. It was also shown that CRD and aggression coincide with hyperphosphorylated Tau (pTau) development in Lateral Parabrachial (LPB) neurons. These neurons, including those expressing dynorphin (LPB^dyn), project to circadian structures and are affected by pTau. The ablation of LPB^dyn partially recapitulated the hyperthermia in this mouse model [65]. Another study investigating the relationship between the sleep–wake cycle impairment and the CSF AD biomarkers and CSF orexin concentrations in mild to moderate AD patients showed a correlation between tau proteins and orexin CSF levels and the sleep–wake cycle dysregulation [66].

Using tau-specific Positron Emission Tomography (PET) imaging, Lucey et al. demonstrated that regions known to be involved with AD progression showed associations with reduced slow-wave activity of non-REM (NREM) sleep in orbitofrontal, entorhinal, lingual, parahippocampal, and inferior parietal areas [67]. These findings indicate a relationship between regional tau pathology and specific sleep architecture changes important for memory consolidation.

Oxidative stress, through hydrogen peroxide activity, has the potential to shift the phase of the circadian clock in the brain and other organs [68]. This phenomenon further depends on the time of the day and the dose of the oxidative stress produced. On the other hand, oxidative stress can regulate the expression of antioxidant genes by modulating nuclear factor-erythroid 2 related factor 2 (Nrf2), a transcription factor [69]. Nrf2 activation can further give rise to the upregulation of the repressor gene Cry2 and lead to CLOCK-BMAL1 transcriptional activation, which are critical components of the circadian clock [69].

Not only is the circadian clock disrupted in AD, but another study also showed a bidirectional relationship between oxidative stress and disruptions of the circadian clock, resulting in the progression of cognitive decline in AD [70]. This study showed that environmental stress following the CRDs is related to elevated levels of Nicotinamide Adenine Dinucleotide Hydrogen (NADH) and decreased levels of Glutathione (GSH), which lead to the progression of cognitive deficits in AD.

In addition, a recent study has highlighted the molecular mechanisms of CRD associated with cognitive decline via neuroinflammation [71]. This study indicated that microglial activation and the subsequent production of cytokines led to a loss of neurogenesis and a reduction in synaptic proteins in the hippocampus. Furthermore, neuroinflammation induced by CRD was prevented by removing microglia in the hippocampus. Another study by Fonken et al. indicated that neuroinflammation has a potential effect on the expression of core circadian clock genes in the SCN, including Bmal1, Per2, and Clock [72]. Moreover, in the setting of circadian disruptions, elevated levels of proinflammatory cytokines, including Interleukin-1 beta (IL-1β) and Tumor Necrosis Factor-alpha (TNF-α), were detected [72]. In a study on mice, TNF-α influenced the expression of the D site of albumin promoter binding protein (Dbp), a circadian clock gene, in the SCN, resulting in the prolongation of the rest period in the dark, i.e., the active phase for mice [73]. Additionally, TNF-α inhibits the activation of the E-Box, a DNA regulatory circadian gene expression element, through the CLOCK-BMAL1 complex. Increased IL-1β levels have been observed in macrophages lacking Bmal1, a crucial transcription factor that modulates the antioxidant transcription factor Nrf2 [74]. In the absence of Bmal1, Nrf2 activity is reduced, which leads to a decreased antioxidant response and subsequent rise in reactive oxygen species (ROS) (Figure 1). ROS further regulates Hypoxia-Inducible Factor 1-alpha (HIF-1α), a transcription factor that upregulates the production of IL-1β [74]. A study in an AD mouse model showed that neuroinflammation can accelerate Aβ deposition [75].

In another study on mice investigating the relationship between Interleukin-6 (IL-6) and circadian rhythms, it was found that mice lacking IL-6 showed altered expression of Cry1, Differentiated Embryo Chondrocyte 2 (Dec2), and Nuclear Receptor Subfamily 1 Group D Member 2 (Rev-erbβ) [76]. This study demonstrated the role of IL-6 in regulating ultradian activity (shorter cycles that occur several times throughout the day), rest rhythmicity, and clock gene expression, which may contribute to CRDs in some neurodegenerative diseases, including AD.

In a study of the effect of Interferon gamma (IFN-γ) on rat SCN cultures and its effect on the expression of clock genes, it was found that cells exposed to IFN-γ showed decreased average spiking frequency and exhibited a higher level of irregular firing pattern in addition to a lower expression amplitude of Per1 in SCN neurons [77]. This study demonstrates that IFN-γ may alter the circadian rhythms and sleep disturbances in the aging brain.

A study showed that exposure of different types of cells, including neurons, to Aβ and its fragments led to a slowing of the circadian rhythms through mitochondrial dysfunction [78]. In this study, different Aβ species, including Aβ1–42, Aβ1–40, Aβ1–28, Aβ34–42, Aβ15–25, and Aβ25–35, were used within the same concentration range. The results also showed that all Aβ species induce remarkable changes in circadian function similar to more neurotoxic Aβ1–42. Moreover, Aβ is linked to changes in circadian length compared to changes in amplitude. Additionally, Aβ induces mitochondrial Adenosine Triphosphate (ATP) depletion and reduced energy levels, elevated oxidative stress and ROS, and a decline in mitochondrial respiration, which results in the mitochondria’s inability to respond to elevated metabolic demand and subsequent CRDs.

It is worth mentioning that even though there are several studies [79,80,81] that have highlighted the important role of neuroinflammation and oxidative stress in CRD, further studies need to be conducted to understand the exact mechanisms behind this interaction due to its complexity. Some studies [70,82] have emphasized that this relationship is bidirectional. Hence, it is crucial to evaluate the causal direction of the link between CRD and neuroinflammation. These studies used animal models, including mice [73,76]. This could be a limitation. To evaluate this association, thus, future clinical trials need to be conducted to confirm it in clinical settings. The variation in therapeutic agents used to investigate these underlying pathways has led to a persistent knowledge gap regarding this relationship [83].

Chronotherapeutics is the science of considering the delivery of drugs and therapeutic methods based on the inherent activity of each disease over a specific period of time. The aim of chronotherapy is to synchronize treatment or intervention with the inherent timing of the disease [108].

In a study on an AD mouse model, Time-Restricted Feeding (TRF) resulted in increased production of β-Hydroxybutyrate and decreased levels of blood glucose [109]. According to this study, TRF enhanced total sleep and sleep-phase consolidation and decreased fragmentation and agitation.

The investigation of the natural compound Nobiletin (NOB), which directly activates circadian cellular oscillators, showed a reduction in sleep disturbances and an increase in oxygen consumption and CO₂ production in a female AD mouse model [110]. Additionally, this study indicated that the expression of multiple core clock genes in the cerebral cortex, such as Bmal1, Neuronal PAS Domain Protein 2 (Npas2), and RAR-related orphan receptor alpha (Rora) was altered following the administration of NOB.

Furthermore, in a randomized controlled trial, the effect of donepezil and galantamine at different time points during the day on sleep quality of AD patients was evaluated [111]. This study indicated that patients who took donepezil in the morning, compared to at night, experienced an improvement in sleep quality and decreased daytime drowsiness. These findings indicate that the administration of acetylcholinesterase inhibitors in the morning may enhance the sleep quality of patients with AD.