Naoki Kusunose

The intrinsic microglial molecular clock controls synaptic strength via the circadian expression of cathepsin S

Microglia are thought to play important roles in the maintenance of neuronal circuitry and the regulation of behavior. We found that the cortical microglia contain an intrinsic molecular clock and exhibit a circadian expression of cathepsin S (CatS), a microglia-specific lysosomal cysteine protease in the brain. The genetic deletion of CatS causes mice to exhibit hyperlocomotor activity and removes diurnal variations in the synaptic activity and spine density of the cortical neurons, which are significantly higher during the dark (waking) phase than the light (sleeping) phase. Furthermore, incubation with recombinant CatS significantly reduced the synaptic activity of the cortical neurons. These results suggest that CatS secreted by microglia during the dark-phase decreases the spine density of the cortical neurons by modifying the perisynaptic environment, leading to downscaling of the synaptic strength during the subsequent light-phase. Disruption of CatS therefore induces hyperlocomotor activity due to failure to downscale the synaptic strength.

cAMP-response Element (CRE)-mediated transcription by Activating Transcription Factor-4 (ATF4) is essential for circadian expression of the Period2 gene

Activating transcription factor (ATF)/cAMP-response element (CRE)-binding (CREB) proteins induce the CRE-mediated gene transcription depending on the cAMP stimulation. cAMP-dependent signaling oscillates in a circadian manner, which in turn also sustains core oscillation machinery of the circadian clock. Here, we show that among the ATF/CREB family proteins, ATF4 is essential for the circadian expression of the Period2 (Per2) gene, a key component of the circadian clock. Transcription of the Atf4 gene was regulated by core components of the circadian clock, and its expression exhibited circadian oscillation in mouse tissues as well as embryonic fibroblasts. ATF4 bound to the CRE of the Per2 promoter in a circadian time-dependent manner and periodically activated the transcription of the Per2 gene. Consequently, the oscillation of the Per2 expression was attenuated in embryonic cells prepared from Atf4-null mice. Furthermore, the loss of ATF4 also disrupted the rhythms in the expression of other clock genes. These results suggest that ATF4 is a component responsible for sustaining circadian oscillation of CRE-mediated gene expression and also constitute a molecular link connecting cAMP-dependent signaling to the circadian clock.

Molecular basis for the dosing time-dependency of anti-allodynic effects of gabapentin in a mouse model of neuropathic pain

BackgroundNeuropathic pain is characterized by hypersensitivity to innocuous stimuli (tactile allodynia) that is nearly always resistant to NSAIDs or even opioids. Gabapentin, a GABA analogue, was originally developed to treat epilepsy. Accumulating clinical evidence supports the effectiveness of this drug for diverse neuropathic pain. In this study, we showed that the anti-allodynic effect of gabapentin was changed by the circadian oscillation in the expression of its target molecule, the calcium channel α2δ-1 subunit.ResultsMice were underwent partial sciatic nerve ligation (PSL) to create a model of neuropathic pain. The paw withdrawal threshold (PWT) in PSL mice significantly decreased and fluctuated with a period length about 24 h. The PWT in PSL mice was dose-dependently increased by intraperitoneal injection of gabapentin, but the anti-allodynic effects varied according to its dosing time. The protein levels of α2δ-1 subunit were up-regulated in the DRG of PSL mice, but the protein levels oscillated in a circadian time-dependent manner. The time-dependent oscillation of α2δ-1 subunit protein correlated with fluctuations in the maximal binding capacity of gabapentin. The anti-allodynic effect of gabapentin was attenuated at the times of the day when α2δ-1 subunit protein was abundant.ConclusionsThese findings suggest that the dosing time-dependent difference in the anti-allodynic effects of gabapentin is attributable to the circadian oscillation of α2δ-1 subunit expression in the DRG and indicate that the optimizing its dosing schedule helps to achieve rational pharmacotherapy for neuropathic pain.

Intestinal Expression of Mouse Abcg2/Breast Cancer Resistance Protein (BCRP) Gene Is under Control of Circadian Clock-activating Transcription Factor-4 Pathway

Background: Intestinal expression of Abcg2/breast cancer resistance protein (BCRP) exhibits circadian oscillation, but the mechanism is unknown. Results: ATF4, a molecular component of the circadian clock, induced circadian expression of Abcg2 in mouse small intestine. Conclusion: The circadian clock-ATF4 pathway causes the oscillation of BCRP function and induces the circadian change in intestinal drug absorption. Significance: ATF4 constitutes a novel molecular link connecting the circadian clock to xenobiotic detoxification. ABCG2, encoding breast cancer resistance protein (BCRP), is a member of the ATP-binding cassette transporter family and is often associated with cancer chemotherapeutic resistance. BCRP is also expressed in a variety of normal cells and acts as a xenobiotic efflux transporter. Because intestinal BCRP limits systemic exposure to xenobiotics, alterations in the function and expression of this transporter could account for part of the variation in oral drug absorption. In this study, we show that ATF4, a molecular component of the circadian clock, induces circadian expression of the Abcg2 gene in mouse small intestine. Three types of leader exons (termed exons 1A, 1B, and 1C) are identified in the 5′-untranslated region of mouse Abcg2 transcripts. The exon 1B-containing Abcg2 transcript was the only isoform detected in mouse small intestine, and its mRNA levels oscillated in a circadian time-dependent manner. ATF4 bound time-dependently to the cAMP response element within the exon 1B promoter region of the Abcg2 gene, thereby causing the oscillation of BCRP protein abundance and its efflux pump function. The circadian clock-ATF4 pathway appears to enhance the function of BCRP during a specific time window and to modulate intestinal drug absorption. Our findings suggest a mechanism underlying circadian change in xenobiotic detoxification.

Aryl hydrocarbon receptor-mediated Cyp1a1 expression is modulated in a CLOCK-dependent circadian manner

The expression of genes involved in xenobiotic detoxification is under the control of the circadian clock. The aryl hydrocarbon receptor (AhR) is one of the transcription factors responsible for the induction of detoxification enzymes in response to xenobiotic toxins, and the expression of AhR has been suggested to be regulated by a circadian oscillator. In this study, we investigated whether toxin-mediated activation of the AhR signaling pathway was modulated by CLOCK protein, a key component of the mammalian circadian clock. The expression of AhR and its DNA binding ability in the lungs of wild-type mice showed significant 24-h oscillation. Clock mutant (Clk/Clk) mice, producing CLOCK protein deficient in transcriptional activity, failed to show significant oscillation in the expression of AhR. The mRNA levels of AhR in the lungs of Clk/Clk mice were significantly lower than in wild-type mice. A single intraperitoneal injection of benzo[α]pyrene, a ligand of AhR, induced the expression of Cyp1a1 in the lungs of wild-type mice, but the induction varied depending on the benzo[α]pyrene injection time. The dosing time-dependency of benzo[α]pyrene-induced Cyp1a1 expression was also modulated by Clock gene mutation. These findings suggest that CLOCK protein affects the toxin-induced expression of detoxification enzymes through modulating the activity of AhR. Our present findings provide a molecular link between the circadian clock and xenobiotic detoxification.

Glucocorticoid regulation of ATP release from spinal astrocytes underlies diurnal exacerbation of neuropathic mechanical allodynia

Diurnal variations in pain hypersensitivity are common in chronic pain disorders, but the underlying mechanisms are enigmatic. Here, we report that mechanical pain hypersensitivity in sciatic nerve-injured mice shows pronounced diurnal alterations, which critically depend on diurnal variations in glucocorticoids from the adrenal glands. Diurnal enhancement of pain hypersensitivity is mediated by glucocorticoid-induced enhancement of the extracellular release of ATP in the spinal cord, which stimulates purinergic receptors on microglia in the dorsal horn. We identify serum- and glucocorticoid-inducible kinase-1 (SGK-1) as the key molecule responsible for the glucocorticoid-enhanced release of ATP from astrocytes. SGK-1 protein levels in spinal astrocytes are increased in response to glucocorticoid stimuli and enhanced ATP release by opening the pannexin-1 hemichannels. Our findings reveal an unappreciated circadian machinery affecting pain hypersensitivity caused by peripheral nerve injury, thus opening up novel approaches to the management of chronic pain.

Diurnal Spatial Rearrangement of Microglial Processes through the Rhythmic Expression of P2Y12 Receptors

Microglia plays important roles in synaptic reorganization during the postnatal developmental stage. Moreover, microglia continuously surveys the functional state of the synapse and change to improve the function. This phenomenon was attributed to the fine process of extension and retraction. However, the mechanism underlying the dynamics of microglial movement and function is still unclear. We herein report that cortical microglia exhibit clock gene-regulated diurnal morphological changes. Cortical microglia extended their processes during the dark phase and retracted them during the light phase. These diurnal changes were also observed in cortical microglia from animals housed under constant darkness, but not in cortical microglia from clock-mutant mice. The mean contact ratio of the microglia-synapse interactions was significantly larger during the dark phase than the light phase. These diurnal changes in microglial morphology and microglia-synaptic interactions were significantly inhibited by the systemic administration of clopidogrel, a P2Y12 receptor (P2Y12R) blocker. We further observed diurnal variation in the P2Y12R expression in cortical microglia. The reporter analyses further revealed that P2Y12R was regulated by a negative feedback loop of the clock system. These observations suggest that the microglial clock system drives the diurnal morphological changes of microglia and microglia-synapse interactions by controlling the P2Y12R expression.

Influence of intermittent hypoxia on the signal transduction pathways to inflammatory response and circadian clock regulation

AIMS Obstructive sleep apnea syndrome (OSAS), characterized by intermittent hypoxia/reoxygenation (IHR), is often associated with changing levels of circulating inflammatory cytokines and causes excessive daytime sleepiness, mood disturbances, and cardiovascular disease. An abnormal rhythm in the expression of circadian clock genes is observed in OSAS patients, and is also implicated in OSAS-related clinical symptoms. IHR-induced signal transduction is thought to underlie OSAS-associated complications. The aim of this study is to elucidate the influence of IHR on signal transduction pathways to inflammatory response and circadian clock regulation. MAIN METHODS To evaluate the direct action of IHR on intracellular signaling, we used a cell culture model to explore the underlying transcriptional events initiated by IHR. KEY FINDINGS Treatment of cultured human lung adenocarcinoma epithelial cells (A549) with IHR resulted in the elevation of mRNA levels of an inflammation cytokine interleukin-6 (IL-6), due to activation of the signaling pathway of nuclear factor-kappaB, a potent transcriptional activator of IL-6. On the other hand, the treatment of cells with IHR had little effect on clock gene response element-driven transcription. As a consequence, there was no significant change in mRNA levels of clock genes in IHR-treated cells. SIGNIFICANCE These results suggest that IHR can activate signal transduction to an inflammatory response, but not to circadian clock regulation. The abnormal rhythm in the expression of clock genes in OSAS patients is attributable to the changed levels of circulating factors that have the ability to modulate clock gene expression.

Bile acid-regulated peroxisome proliferator-activated receptor-α (PPARα) activity underlies circadian expression of intestinal peptide absorption transporter PepT1/Slc15a1

Background: Intestinal expression of peptide absorption transporter (PepT1)/Slc15a1 exhibits circadian oscillation, but the mechanism is unknown. Results: During the daily feeding cycle, bile acids accumulated in intestinal cells, thereby suppressing PPARα-mediated expression of PepT1/Slc15a1. Conclusion: Time-dependent suppression of PPARα activity by bile acids underlies circadian expression of PepT1/Slc15a1. Significance: Bile acids cause circadian change in the intestinal absorption of peptides. Digested proteins are mainly absorbed as small peptides composed of two or three amino acids. The intestinal absorption of small peptides is mediated via only one transport system: the proton-coupled peptide transporter-1 (PepT1) encoded from the soluble carrier protein Slc15a1. In mammals, intestinal expression of PepT1/Slc15a1 oscillates during the daily feeding cycle. Although the oscillation in the intestinal expression of PepT1/Slc15a1 is suggested to be controlled by molecular components of circadian clock, we demonstrated here that bile acids regulated the oscillation of PepT1/Slc15a1 expression through modulating the activity of peroxisome proliferator-activated receptor α (PPARα). Nocturnally active mice mainly consumed their food during the dark phase. PPARα activated the intestinal expression of Slc15a1 mRNA during the light period, and protein levels of PepT1 peaked before the start of the dark phase. After food intake, bile acids accumulated in intestinal epithelial cells. Intestinal accumulated bile acids interfered with recruitment of co-transcriptional activator CREB-binding protein/p300 on the promoter region of Slc15a1 gene, thereby suppressing PPARα-mediated transactivation of Slc15a1. The time-dependent suppression of PPARα-mediated transactivation by bile acids caused an oscillation in the intestinal expression of PepT1/Slc15a1 during the daily feeding cycle that led to circadian changes in the intestinal absorption of small peptides. These findings suggest a molecular clock-independent mechanism by which bile acid-regulated PPARα activity governs the circadian expression of intestinal peptide transporter.

Time-Dependent Interaction between Differentiated Embryo Chondrocyte-2 and CCAAT/Enhancer-Binding Protein α Underlies the Circadian Expression of CYP2D6 in Serum-Shocked HepG2 Cells

Differentiated embryo chondrocyte-2 (DEC2), also known as bHLHE41 or Sharp1, is a pleiotropic transcription repressor that controls the expression of genes involved in cellular differentiation, hypoxia responses, apoptosis, and circadian rhythm regulation. Although a previous study demonstrated that DEC2 participates in the circadian control of hepatic metabolism by regulating the expression of cytochrome P450, the molecular mechanism is not fully understood. We reported previously that brief exposure of HepG2 cells to 50% serum resulted in 24-h oscillation in the expression of CYP3A4 as well as circadian clock genes. In this study, we found that the expression of CYP2D6, a major drug-metabolizing enzyme in humans, also exhibited a significant oscillation in serum-shocked HepG2 cells. DEC2 interacted with CCAAT/enhancer-binding protein (C/EBPα), accompanied by formation of a complex with histone deacetylase-1, which suppressed the transcriptional activity of C/EBPα to induce the expression of CYP2D6. The oscillation in the protein levels of DEC2 in serum-shocked HepG2 cells was nearly antiphase to that in the mRNA levels of CYP2D6. Transfection of cells with small interfering RNA against DEC2 decreased the amplitude of CYP2D6 mRNA oscillation in serum-shocked cells. These results suggest that DEC2 periodically represses the promoter activity of CYP2D6, resulting in its circadian expression in serum-shocked cells. DEC2 seems to constitute a molecular link through which output components from the circadian clock are associated with the time-dependent expression of hepatic drug-metabolizing enzyme.