Impact of circadian time of dosing on cardiac-autonomous effects of glucocorticoids

Bioenergetic capacity is critical to adapt the high energy demand of the heart to circadian oscillations and diseased states. Glucocorticoids regulate the circadian cycle of energy metabolism, but little is known about how circadian timing of exogenous glucocorticoid dosing directly regulates cardiac bioenergetics through the primary receptor of these drugs, the glucocorticoid receptor (GR). While chronic once-daily intake of glucocorticoids promotes metabolic stress and heart failure, we recently discovered that intermittent once-weekly dosing of exogenous glucocorticoids promoted muscle metabolism and heart function in dystrophic mice. However, the effects of glucocorticoid intermittence on heart failure beyond muscular dystrophy remain unknown. Here we investigated the extent to which circadian time of dosing regulates the cardiac-autonomous effects of the glucocorticoid prednisone in conditions of single pulse or chronic intermittent dosing. In WT mice, we found that prednisone improved cardiac content of NAD+ and ATP with light-phase dosing (ZT0), while the effects were blocked by dark-phase dosing (ZT12). The effects on mitochondrial function were cardiomyocyte-autonomous, as shown by inducible cardiomyocyte-restricted GR ablation, and depended on an intact activating clock complex, as shown by hearts from BMAL1-KO mice. Conjugating time-of-dosing with chronic intermittence, we found that once-weekly light-phase prednisone improved metabolism and function in heart after myocardial injury. Our study identifies cardiac-autonomous mechanisms through which circadian time and chronic intermittence reconvert glucocorticoid drugs to bioenergetic boosters for the heart.

Susceptibility rhythm to bacterial endotoxin in myeloid clock-knockout mice

Local circadian clocks are active in most cells of our body. However, their impact on circadian physiology is still under debate. Mortality by endotoxic (LPS) shock is highly time-of-day dependent and local circadian immune function such as the cytokine burst after LPS challenge has been assumed to be causal for the large differences in survival. Here, we investigate the roles of light and myeloid clocks on mortality by endotoxic shock. Strikingly, mice in constant darkness (DD) show a three-fold increased susceptibility to LPS as compared to mice in light-dark conditions. Mortality by endotoxic shock as a function of circadian time is independent of light-dark cycles as well as myeloid CLOCK or BMAL1 as demonstrated in conditional knockout mice. Unexpectedly, despite the lack of a myeloid clock these mice still show rhythmic patterns of pro- and anti-inflammatory cytokines such as TNF,α MCP-1, IL-18 and IL-10 in peripheral blood as well as time-of-day and site dependent traffc of myeloid cells. We speculate that systemic time-cues are sufficient to orchestrate innate immune response to LPS by driving immune functions such as cell traffcking and cytokine expression.

P049 Sleep Regularity is Associated with Stability of Daily Light Exposure in Adolescents During School and Vacation

Study Objectives Light is the main time cue for the human circadian system. Irregular sleep/wake patterns are associated with poor health outcomes, which could be mediated by irregular patterns of light exposure. The relationship between sleep and light regularity has not been directly explored. We investigated the relationship between sleep and light regularity in adolescents, across school-term and vacation, using novel metrics for measuring light regularity. Methods Daily sleep and light patterns were measured via wrist actigraphy in 104 adolescents (54% male, age M±SD = 17.17±0.80 years) over two weeks of school-term and a subsequent two-week vacation. The Sleep Regularity Index (SRI) was computed for each two-week block. Stability of daily light exposure was assessed using variation of mean daily light timing (MLiT), variation in daily photoperiod, and the Light Regularity Index. Associations between SRI and each light regularity metric were examined, and within-individual changes in metrics were examined between school and vacation. Results More regular sleep was significantly associated with more regular scores for each light variability metric, during school and vacation. Between school and vacation sleep regularity decreased and nuanced changes in light patterns were observed. Variability measured by the MLiT variable increased, whereas variability measured by the LRI and photoperiod variable decreased. Conclusions Adolescents with irregular sleep also have irregular patterns of light exposure. These findings suggest sleep regularity may be a useful proxy for variability in the main circadian time cue, meaning that irregular light exposure may carry implications for the developing adolescent circadian system.

Pharmacological Rescue with SR8278, A Circadian Nuclear Receptor REV-ERBα Antagonist as a Therapy for Mood Disorders in Parkinson’s Disease

Background: Parkinson’s disease is a neurodegenerative disease characterized by progressive dopaminergic (DAergic) neuronal loss. Motor deficits experienced by patients with Parkinson’s disease are well documented, but non-motor symptoms, including mood disorders associated with circadian disturbances, are also frequent features. One common phenomenon is “sundowning syndrome,” which is characterized by the occurrence of neuropsychiatric symptoms at a specific time (dusk), causing severe quality of life challenges. This study aimed to elucidate the underlying mechanisms of sundowning syndrome in Parkinson’s disease and their molecular links with the circadian clock.Methods: To induce the Parkinson’s disease mouse model, a single injection of 6-hydroxydopamine (6-OHDA) was administered into the left dorsal striatum. Five weeks post injection, mood-related behavioral tests were performed at the indicated time of day (circadian time 22-01 vs. 10-13). Local injection of a REV-ERBα antagonist, SR8278, into the ventral tegmental area, was performed 3 h before each behavioral test. To determine the molecular mechanism of behavioral deficits, fluorescent in situ hybridization, chromatin immunoprecipitation assay, western blot analysis, and ATAC-sequencing were performed.Results: Our study demonstrated that 6-OHDA-lesioned mice exhibited increased depression- and anxiety-like behaviors only at dawn. SR8278 treatment exerted antidepressant and anxiolytic effects in a circadian time-dependent manner in 6-OHDA-lesioned mice, restoring the circadian rhythm of mood-related behaviors. 6-OHDA-lesion altered DAergic-specific Rev-erbα and Nurr1 transcription, and atypical binding activities of REV-ERBα and NURR1, which are upstream nuclear receptors for the discrete tyrosine hydroxylase promoter region SR8278, restored the binding activities of REV-ERBα and NURR1 to the tyrosine hydroxylase promoter and the induction of enrichment of the R/N motif, recognized by REV-ERBα and NURR1 only at dawn, as revealed by ATAC-sequencing; therefore, tyrosine hydroxylase expression was elevated in the ventral tegmental area of 6-OHDA-injected mice, especially at dawn.Conclusions: These results indicate that REV-ERBα is a potential therapeutic target, and its antagonist, SR8278, is a potential drug for mood disorders related to circadian disturbances, namely sundowning syndrome, in Parkinson’s disease.

Abstract 102: Time-of-intake Regulates Glucocorticoid Pharmacology Of Cardiac Bioenergetics

Glucocorticoid steroids are circadian regulators of energy balance. However, the specific direct effects of glucocorticoids on heart metabolism remain unresolved. Moreover, the impact of circadian time-of-intake on glucocorticoid pharmacology is still unknown. Here, we investigated whether circadian time of exposure gates the effects of synthetic glucocorticoids on heart bioenergetics. We compared the effects of diurnal versus nocturnal glucocorticoids in heart tissue and mitochondria from wildtype mice, controlling the subjective circadian time of drug injection. To avoid interferences from other tissues, we developed an ex vivo system to interrogate the mitochondrial respiratory capacity rate (state III/state IV) in isolated hearts. We found that diurnal but not nocturnal pulse of the glucocorticoid prednisone increased the mitochondrial respiratory capacity rate in heart. This correlated with circadian-restricted effects on mitochondrial abundance. This was remarkable as it contrasts the circadian fluctuations of endogenous glucocorticoids. Using transgenic mice with inducible cardiac-specific gene knockout, we found that the bioenergetic effects of diurnal-restricted prednisone were dependent on the glucocorticoid receptor and its co-factor Kruppel-like factor 15. Considering the bioenergetic decline that hallmarks the aging heart, we asked whether these circadian-gated effects were applicable to aged mice. We therefore treated 24 months-old mice for 12 weeks with a diurnal-restricted regimen of prednisone. Compared to vehicle, diurnal prednisone increased mitochondrial respiration along with NAD + and ATP content in aged hearts. Moreover, lipidomic profiling of myocardial tissue showed that the vast majority of lipids were downregulated after treatment, including triacylglycerols, suggesting a functional coupling between lipid utilization and mitochondrial oxidation in treated hearts. We also found that diurnal-restricted prednisone rescued bioenergetics and improved function in diabetic hearts from db/db mice. In summary, our data indicate that glucocorticoids regulate cardiac bioenergetics according to circadian-time of intake, supporting a role for chrono-pharmacology in aged and diabetic hearts.

Interpreting machine learning models to investigate circadian regulation and facilitate exploration of clock function

The circadian clock is an important adaptation to life on Earth. Here, we use machine learning to predict complex, temporal, and circadian gene expression patterns in Arabidopsis. Most significantly, we classify circadian genes using DNA sequence features generated de novo from public, genomic resources, facilitating downstream application of our methods with no experimental work or prior knowledge needed. We use local model explanation that is transcript specific to rank DNA sequence features, providing a detailed profile of the potential circadian regulatory mechanisms for each transcript. Furthermore, we can discriminate the temporal phase of transcript expression using the local, explanation-derived, and ranked DNA sequence features, revealing hidden subclasses within the circadian class. Model interpretation/explanation provides the backbone of our methodological advances, giving insight into biological processes and experimental design. Next, we use model interpretation to optimize sampling strategies when we predict circadian transcripts using reduced numbers of transcriptomic timepoints. Finally, we predict the circadian time from a single, transcriptomic timepoint, deriving marker transcripts that are most impactful for accurate prediction; this could facilitate the identification of altered clock function from existing datasets.

Thermographic imaging of mouse across circadian time reveals body surface temperature elevation associated with non-locomotor body movements

Circadian clocks orchestrate multiple different physiological rhythms in a well-synchronized manner. However, how these separate rhythms are interconnected is not exactly understood. Here, we developed a method that allows for the real-time simultaneous measurement of locomotor activity and body temperature of mice using infrared video camera imaging. As expected from the literature, temporal profiles of body temperature and locomotor activity were positively correlated with each other. Basically, body temperatures were high when animals were in locomotion. However, interestingly, increases in body temperature were not always associated with the appearance of locomotor activity. Video imaging revealed that mice exhibit non-locomotor activities such as grooming and postural adjustments, which alone induce considerable elevation of body temperature. Noticeably, non-locomotor movements always preceded the initiation of locomotor activity. Nevertheless, non-locomotor movements were not always accompanied by locomotor movements, suggesting that non-locomotor movements provide a mechanism of thermoregulation independent of locomotor activity. In addition, in the current study, we also report the development of a machine learning-based recording method for the detection of circadian feeding and drinking behaviors of mice. Our data illustrate the potential utility of thermal video imaging in the investigation of different physiological rhythms.

Reversible modulation of circadian time with chronophotopharmacology

The circadian clock controls daily rhythms of physiological processes. The presence of the clock mechanism throughout the body is hampering its local regulation by small molecules. A photoresponsive clock modulator would enable precise and reversible regulation of circadian rhythms using light as a bio-orthogonal external stimulus. Here we show, through judicious molecular design and state-of-the-art photopharmacological tools, the development of a visible light-responsive inhibitor of casein kinase I (CKI) that controls the period and phase of cellular and tissue circadian rhythms in a reversible manner. The dark isomer of photoswitchable inhibitor 9 exhibits almost identical affinity towards the CKIα and CKIδ isoforms, while upon irradiation it becomes more selective towards CKIδ, revealing the higher importance of CKIδ in the period regulation. Our studies enable long-term regulation of CKI activity in cells for multiple days and show the reversible modulation of circadian rhythms with a several hour period and phase change through chronophotopharmacology.