Differential susceptibility of BALB/c, C57BL/6N, and CF1 mice to photoperiod changes

Impacts of circadian disruptions on behavioral rhythms in mice

Circadian rhythms are fundamental biological processes that recur approximately every 24 h, with the sleep-wake cycle or circadian behavior being a well-known example. In the field of chronobiology, mice serve as valuable model animals for studying mammalian circadian rhythms due to their genetic similarity to humans and the availability of various genetic tools for manipulation. Monitoring locomotor activity in mice provides valuable insights into the impact of various conditions or disturbances on circadian behavior. In this review, we summarized the effects of disturbance of biological rhythms on circadian behavior in mice. External factors, especially light exert a significant impact on circadian behavior. Additionally, feeding timing, food composition, ambient temperature, and physical exercise contribute to variations in the behavior of the mouse. Internal factors, including gender, age, genetic background, and clock gene mutation or deletion, are effective as well. Understanding the effects of circadian disturbances on murine behavior is essential for gaining insights into the underlying mechanisms of circadian regulation and developing potential therapeutic interventions for circadian-related disorders in humans.

Adaptive Differences in Cellular and Behavioral Responses to Circadian Disruption between C57BL/6 and BALB/c Strains

The regulation of the mammalian circadian clock is largely dependent on heredity. In model animals for circadian rhythm studies, C57BL/6 and BALB/c mice exhibit considerable differences in their adaptation to circadian disruption, yet deeper comparisons remain unexplored. Here, we have established embryonic fibroblast cells derived from C57BL/6 mice (MEF) and BALB/c (BALB/3T3) mice, which have been transfected with the Bmal1 promoter-driven luciferase (Bmal1-Luc) reporter gene. Next, dexamethasone was applied for various cyclic stimulations, which revealed that Bmal1 bioluminescence of MEF cells was entrained to 24 to 26 h cycles, whereas BALB/3T3 cells have a wider range (22 to 28 h) with lower amplitudes. Behaviorally, BALB/c mice swiftly adapted to a 6-h advance light/dark cycle, unlike C57BL/6 mice. Furthermore, we found the expression of the circadian rhythm gene Npas2 in BALB/c mice is significantly lower than that in C57BL/6 mice. This observation is consistent with the differentially expressed genes (DEGs) in the intestine and lung tissues of C57BL/6 and BALB/c mice, based on the RNA-seq datasets downloaded from the Gene Expression Omnibus (GEO). In summary, our study uncovers that BALB/c mice possess greater resilience in circadian rhythm than C57BL/6 mice, both cellular and behaviorally, identifying potential genes underlying this difference.

Glucocorticoid receptor-mediated Nr1d1 chromatin circadian misalignment in stress-induced irritable bowel syndrome

Stress-elevated glucocorticoids cause circadian disturbances and gut-brain axis (GBA) disorders, including irritable bowel syndrome (IBS). We hypothesized that the glucocorticoid receptor (GR/NR3C1) might cause chromatin circadian misalignment in the colon epithelium. We observed significantly decreased core circadian gene Nr1d1 in water avoidance stressed (WAS) BALB/c colon epithelium, like in IBS patients. WAS decreased GR binding at the Nr1d1 promoter E-box (enhancer box), and GR could suppress Nr1d1 via this site. Stress also altered GR binding at the E-box sites along the Ikzf3-Nr1d1 chromatin and remodeled circadian chromatin 3D structures, including Ikzf3-Nr1d1 super-enhancer, Dbp, and Npas2. Intestinal deletion of Nr3c1 specifically abolished these stress-induced transcriptional alternations relevant to IBS phenotypes in BALB/c mice. GR mediated Ikzf3-Nr1d1 chromatin disease related circadian misalignment in stress-induced IBS animal model. This animal model dataset suggests that regulatory SNPs of human IKZF3-NR1D1 transcription through conserved chromatin looping have translational potential based on the GR-mediated circadian-stress crosstalk.

The disruptive relationship among circadian rhythms, pain, and opioids

Pain behavior and the systems that mediate opioid analgesia and opioid reward processing display circadian rhythms. Moreover, the pain system and opioid processing systems, including the mesolimbic reward circuitry, reciprocally interact with the circadian system. Recent work has demonstrated the disruptive relationship among these three systems. Disruption of circadian rhythms can exacerbate pain behavior and modulate opioid processing, and pain and opioids can influence circadian rhythms. This review highlights evidence demonstrating the relationship among the circadian, pain, and opioid systems. Evidence of how disruption of one of these systems can lead to reciprocal disruptions of the other is then reviewed. Finally, we discuss the interconnected nature of these systems to emphasize the importance of their interactions in therapeutic contexts.

Obesity in male volcano mice Neotomodon alstoni affects the daily rhythm of metabolism and thermoregulation

The mouse N. alstoni spontaneously develops the condition of obesity in captivity when fed regular chow. We aim to study the differences in metabolic performance and thermoregulation between adult lean and obese male mice. The experimental approach included indirect calorimetry using metabolic cages for VO2 intake and VCO2 production. In contrast, the body temperature was measured and analyzed using intraperitoneal data loggers. It was correlated with the relative presence of UCP1 protein and its gene expression from interscapular adipose tissue (iBAT). We also explored in this tissue the relative presence of Tyrosine Hydroxylase (TH) protein, the rate-limiting enzyme for catecholamine biosynthesis present in iBAT. Results indicate that obese mice show a daily rhythm persists in estimated parameters but with differences in amplitude and profile. Obese mice presented lower body temperature, and a low caloric expenditure, together with lower VO2 intake and VCO2 than lean mice. Also, obese mice present a reduced thermoregulatory response after a cold pulse. Results are correlated with a low relative presence of TH and UCP1 protein. However, qPCR analysis of Ucp1 presents an increase in gene expression in iBAT. Histology showed a reduced amount of brown adipocytes in BAT. The aforementioned indicates that the daily rhythm in aerobic metabolism, thermoregulation, and body temperature control have reduced amplitude in obese mice Neotomodon alstoni.

Strain and Age Dependent Entrainable Range of Circadian Behavior in C57BL/6 and BALB/c Mice

The mammalian circadian system has a plasticity in a certain range, rather than a strict 24-hour cycle, with considerable variations among species, strains, and ages. As the most widely used mouse strains in circadian research, C57BL/6 and BALB/c mice were well known to have different internal periods and responses to various non-24-hour light-dark cycles. However, their entrainable range of circadian behavior was not specifically studied, neither was the effect of aging. Besides, it is not well known if mice with appeared behavioral adaptation are really healthy. In the current study, we exposed C57BL/6 and BALB/c mice at 3 months and 18 months old to a series of short (T cycles < 24 h) and long (T cycles > 24 h) light-dark cycles. Wheel running activities were monitored continuously for calculation of the entrainable range and glucose homeostasis was investigated to reflect their health status. Our results showed that the range in both young and old C57BL/6 mice is between T23 and T26. By contrast, due to the strong adaptability to extreme LD cycles, the entrainable range on a circadian scale in both young and old BALB/c mice cannot be well determined. Despite the adaptation appeared at the behavioral level, glucose homeostasis revealed by glucose tolerance test and insulin tolerance test was impaired in mice upon T cycle treatment. In summary, our study explored the entrainment range in two popular mouse strains and suggested that behavioral adaptation may not well reflect their health status.

Mapping the living mouse brain neural architecture: strain-specific patterns of brain structural and functional connectivity

Mapping brain structural and functional connectivity (FC) became an essential approach in neuroscience as network properties can underlie behavioral phenotypes. In mouse models, revealing strain-related patterns of brain wiring is crucial, since these animals are used to answer questions related to neurological or neuropsychiatric disorders. C57BL/6 and BALB/cJ strains are two of the primary "genetic backgrounds" for modeling brain disease and testing therapeutic approaches. However, extensive literature describes basal differences in the behavioral, neuroanatomical and neurochemical profiles of the two strains, which raises questions on whether the observed effects are pathology specific or depend on the genetic background of each strain. Here, we performed a systematic comparative exploration of brain structure and function of C57BL/6 and BALB/cJ mice using Magnetic Resonance Imaging (MRI). We combined deformation-based morphometry (DBM), diffusion MRI and high-resolution fiber mapping (hrFM) along with resting-state functional MRI (rs-fMRI) and demonstrated brain-wide differences in the morphology and "connectome" features of the two strains. Essential inter-strain differences were depicted regarding the size and the fiber density (FD) within frontal cortices, along cortico-striatal, thalamic and midbrain pathways as well as genu and splenium of corpus callosum. Structural dissimilarities were accompanied by specific FC patterns, emphasizing strain differences in frontal and basal forebrain functional networks as well as hubness characteristics. Rs-fMRI data further indicated differences of reward-aversion circuitry and default mode network (DMN) patterns. The inter-hemispherical FC showed flexibility and strain-specific adjustment of their patterns in agreement with the structural characteristics.

Individual responses of rodents in modelling of affective disorders and in their treatment: prospective review

IntroductionLack of good animal models for affective disorders, including major depression and bipolar disorder, is noted as a major bottleneck in attempts to study these disorders and develop better treatments. We suggest that an important approach that can help in the development and use of better models is attention to variability between model animals. RESULTS: Differences between mice strains were studied for some decades now, and sex differences get more attention than in the past. It is suggested that one factor that is mostly neglected, individual variability within groups, should get much more attention. The importance of individual differences in behavioral biology and ecology was repeatedly mentioned but its application to models of affective illness or to the study of drug response was not heavily studied. The standard approach is to overcome variability by standardization and by increasing the number of animals per group. CONCLUSIONS: Possibly, the individuality of specific animals and their unique responses to a variety of stimuli and drugs, can be helpful in deciphering the underlying biology of affective behaviors as well as offer better prediction of drug responses in patients.

Regulation of amyloid-β dynamics and pathology by the circadian clock

Nighttime restlessness and daytime drowsiness are common and early symptoms of Alzheimer's Disease (AD). This symptomology implicates dysfunctional biological timing, yet the role of the circadian system in AD pathogenesis is unknown. To evaluate the role of the circadian clock in amyloid-β (Aβ) dynamics and pathology, we used a mouse model of β-amyloidosis and disrupted circadian clock function either globally or locally in the brain via targeted deletion of the core clock gene Bmal1 Our results demonstrate that loss of central circadian rhythms leads to disruption of daily hippocampal interstitial fluid Aβ oscillations and accelerates amyloid plaque accumulation, whereas loss of peripheral Bmal1 in the brain parenchyma increases expression of Apoe and promotes fibrillar plaque deposition. These results provide evidence that both central circadian rhythms and local clock function influence Aβ dynamics and plaque formation and demonstrate mechanisms by which poor circadian hygiene may directly influence AD pathogenesis.

Defining Conditions for Optimal Inhibition of Food Intake in Rats by a Grape-Seed Derived Proanthocyanidin Extract

Food intake depends on homeostatic and non-homeostatic factors. In order to use grape seed proanthocyanidins (GSPE) as food intake limiting agents, it is important to define the key characteristics of their bioactivity within this complex function. We treated rats with acute and chronic treatments of GSPE at different doses to identify the importance of eating patterns and GSPE dose and the mechanistic aspects of GSPE. GSPE-induced food intake inhibition must be reproduced under non-stressful conditions and with a stable and synchronized feeding pattern. A minimum dose of around 350 mg GSPE/kg body weight (BW) is needed. GSPE components act by activating the Glucagon-like peptide-1 (GLP-1) receptor because their effect is blocked by Exendin 9-39. GSPE in turn acts on the hypothalamic center of food intake control probably because of increased GLP-1 production in the intestine. To conclude, GSPE inhibits food intake through GLP-1 signaling, but it needs to be dosed under optimal conditions to exert this effect.