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1. Deletion of the testosterone-sensitive TRPM8 Ca++ channel disrupts measures of anxiety and depression in mice: Implications for dopamine

   Shepler, B; Erdmier, A; Palmisano, H; Asuthkar, S; Koeltzow, TE (April 2024, Bradley University)

   Testosterone exerts high affinity for the Transient Receptor Potential Melastatin 8 (TRPM8) Ca2+ channel. TRPM8 -/- male mice exhibit disrupted sexual behavior (e.g., indiscriminate approach, delayed satiety), possibly due to decreased ventral tegmental area dopamine neuron activity. It is hypothesized that TRPM8 null mutant mice (Jackson Laboratories) will exhibit disruptions across a range of motivationally-relevant behaviors, including spontaneous locomotor activation, detection of novel stimuli, sucrose preference, and sensitivity to the psychomotor stimulant amphetamine. Initial findings indicate that male TRPM8 mutant mice (n=6) exhibit decreased nocturnal locomotor activity (F(1,12)=23.41, p<0.001), increased behavioral anxiety in the light/dark task (t(10)=2.44, p<0.05; d=1.4), and behavioral despair in the forced swim task (t(10)=3.70, p<0.005; d=2.1). In contrast, these mice tended to prefer a low concentration (0.1%) of sucrose compared to wildtype males (n=6; t(10)=1.35, p=0.09; d=0.83). Tests for sensitivity to amphetamine are in progress. These data suggest a pivotal role for TRPM8 in motivated behavior. 

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2. Gut microbiota depletion minimally affects the daily voluntary wheel running activity and food anticipatory activity in female and male C57BL/6J mice

   https://doi.org/10.3389/fphys.2023.1299474  

   Ehichioya, David E.; Taufique, S. K.; Magaña, Isabel; Farah, Sofia; Obata, Yuuki; Yamazaki, Shin (December 2023, Frontiers in Physiology)

   Emerging evidence has highlighted that the gut microbiota plays a critical role in the regulation of various aspects of mammalian physiology and behavior, including circadian rhythms. Circadian rhythms are fundamental behavioral and physiological processes that are governed by circadian pacemakers in the brain. Since mice are nocturnal, voluntary wheel running activity mostly occurs at night. This nocturnal wheel-running activity is driven by the primary circadian pacemaker located in the suprachiasmatic nucleus (SCN). Food anticipatory activity (FAA) is the increased bout of locomotor activity that precedes the scheduled short duration of a daily meal. FAA is controlled by the food-entrainable oscillator (FEO) located outside of the SCN. Several studies have shown that germ-free mice and mice with gut microbiota depletion altered those circadian behavioral rhythms. Therefore, this study was designed to test if the gut microbiota is involved in voluntary wheel running activity and FAA expression. To deplete gut microbiota, C57BL/6J wildtype mice were administered an antibiotic cocktail via their drinking water throughout the experiment. The effect of antibiotic cocktail treatment on wheel running activity rhythm in both female and male mice was not detectable with the sample size in our current study. Then mice were exposed to timed restricted feeding during the day. Both female and male mice treated with antibiotics exhibited normal FAA which was comparable with the FAA observed in the control group. Those results suggest that gut microbiota depletion has minimum effect on both circadian behavioral rhythms controlled by the SCN and FEO respectively. Our result contradicts recently published studies that reported significantly higher FAA levels in germ-free mice compared to their control counterparts and gut microbiota depletion significantly reduced voluntary activity by 50%. 

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3. Novelty detection in early olfactory processing of the honey bee, Apis mellifera

   https://doi.org/10.1371/journal.pone.0265009  

   Lei, Hong; Haney, Seth; Jernigan, Christopher M.; Guo, Xiaojiao; Cook, Chelsea N.; Bazhenov, Maxim; Smith, Brian H. (March 2022, PLOS ONE)

   Skoulakis, Efthimios M. (Ed.)

   Animals are constantly bombarded with stimuli, which presents a fundamental problem of sorting among pervasive uninformative stimuli and novel, possibly meaningful stimuli. We evaluated novelty detection behaviorally in honey bees as they position their antennae differentially in an air stream carrying familiar or novel odors. We then characterized neuronal responses to familiar and novel odors in the first synaptic integration center in the brain–the antennal lobes. We found that the neurons that exhibited stronger initial responses to the odor that was to be familiarized are the same units that later distinguish familiar and novel odors, independently of chemical identities. These units, including both tentative projection neurons and local neurons, showed a decreased response to the familiar odor but an increased response to the novel odor. Our results suggest that the antennal lobe may represent familiarity or novelty to an odor stimulus in addition to its chemical identity code. Therefore, the mechanisms for novelty detection may be present in early sensory processing, either as a result of local synaptic interaction or via feedback from higher brain centers. 

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4. Sex differences in head‐fixed voluntary running behavior in C57BL/6J mice

   https://doi.org/10.1111/ejn.14654  

   Warner, Emily J.; Padmanabhan, Krishnan (December 2019, European Journal of Neuroscience)

   Abstract Sex differences in running behaviors between female and male mice occur naturally in the wild. Recent experiments using head‐fixed mice on a voluntary running wheel have exploited analogous locomotor activity to gain insight into the neural underpinnings of a number of behaviors ranging from spatial navigation to decision‐making. It is however largely unknown if sex differences exist between females and males in a head‐fixed experimental paradigm. To address this, we characterized locomotor activity in head‐fixed female and male C57BL/6J mice on a voluntary running wheel. First, we found that over the initial 7‐day period, on average, animals increased both the velocity and the time spent running. Furthermore, we found that female mice habituated to running forward over the initial 2 days of encountering the wheel, while male mice took up to 4 days to habituate to running forward. Taken together, we characterized features of a sexually divergent behavior in head‐fixed running that should be considered in experiments employing female and male mice. 

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5. Chronic environmental circadian disruption increases atherosclerosis and dyslipidemia in female, but not male, ApolipoproteinE-deficient mice

   https://doi.org/10.3389/fphys.2023.1167858  

   Chalfant, Jeffrey M.; Howatt, Deborah A.; Johnson, Victoria B.; Tannock, Lisa R.; Daugherty, Alan; Pendergast, Julie S. (March 2023, Frontiers in Physiology)

   Shift work chronically disrupts circadian rhythms and increases the risk of developing cardiovascular disease. However, the mechanisms linking shift work and cardiovascular disease are largely unknown. The goal of this study was to investigate the effects of chronically shifting the light-dark (LD) cycle, which models the disordered exposure to light that may occur during shift work, on atherosclerosis. Atherosclerosis is the progressive accumulation of lipid-filled lesions within the artery wall and is the leading cause of cardiovascular disease. We studied ApolipoproteinE -deficient ( ApoE −/− ) mice that are a well-established model of atherosclerosis. Male and female ApoE −/− mice were housed in control 12L:12D or chronic LD shift conditions for 12 weeks and fed low-fat diet. In the chronic LD shift condition, the light-dark cycle was advanced by 6 h every week. We found that chronic LD shifts exacerbated atherosclerosis in female, but not male, ApoE −/− mice. In females, chronic LD shifts increased total serum cholesterol concentrations with increased atherogenic VLDL/LDL particles. Chronic LD shifts did not affect food intake, activity, or body weight in male or female ApoE −/− mice. We also examined eating behavior in female ApoE −/− mice since aberrant meal timing has been linked to atherosclerosis. The phases of eating behavior rhythms, like locomotor activity rhythms, gradually shifted to the new LD cycle each week in the chronic LD shift group, but there was no effect of the LD shift on the amplitudes of the eating rhythms. Moreover, the duration of fasting intervals was not different in control 12L:12D compared to chronic LD shift conditions. Together these data demonstrate that female ApoE −/− mice have increased atherosclerosis when exposed to chronic LD shifts due to increased VLDL/LDL cholesterol, independent of changes in energy balance or feeding-fasting cycles. 

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