Obesity arises from disrupted energy balance and is caused by chronically higher energy intake compared to expenditure via basal metabolic rate, exercise, and thermogenesis. The brown adipose tissue (BAT), the primary thermogenic organ, has received considerable attention as a potential therapeutic target due to its ability to burn lipids in the production of heat. Pituitary adenylate cyclase-activating polypeptide (PACAP) has been identified as a key regulator of the physiological stress response both centrally and peripherally. While PACAP has been shown to increase thermogenesis by acting at the hypothalamus to increase sympathetic output to BAT, a peripheral role for PACAP-activated thermogenesis has not been studied. We identified PACAP receptor (PAC1, VPAC1/2) expression for the first time in murine BAT and confirmed their expression in white adipose tissues. PAC1 receptor expression was significantly altered in all three adipose tissues studied in response to 3.5-week cold acclimation, with expression patterns differing by depot type. In primary cell culture, VPAC1 was increased in differentiated compared to non-differentiated brown adipocytes, and the same trend was observed for the PACAP-specific receptor PAC1 in gonadal white fat primary cultures. The primary PAC1R mRNA splice variant in interscapular BAT was determined as isoform 2 by RNA-Seq. These results show that PACAP receptors are present in adipose tissues and may have important functional roles in adipocyte differentiation, lipid metabolism, or adipose sensitization to sympathetic signaling in response to thermogenic stimuli.
Pituitary adenylate cyclase activating polypeptide (PACAP) is a neuropeptide critical to the regulation of the stress response, including a role in energy homeostasis. Mice lacking PACAP are cold sensitive and have impaired adrenergic-induced thermogenesis. Interestingly, Pacap null mice can survive cold housing if acclimated slowly, similar to observations in UCP1 deficient mice. We hypothesized that Pacap null mice employ alternate thermogenic pathways to compensate for impaired adaptive thermogenesis in male and female, Pacap-/- and Pacap+/+ mice acclimated to cold. Observations of behaviour and assessment of fibre type in skeletal muscles did not show evidence of prolonged burst shivering or changes in oxidative metabolism in male or female Pacap-/- mice during cold acclimation compared to Pacap+/+ mice. Despite previous work that has established impaired capacity for adaptive thermogenesis in Pacap null mice, adaptive thermogenesis can be induced in mice lacking PACAP to support survival with cold housing. Interestingly, sex-specific morphological and molecular differences in adipose tissue remodelling were observed in Pacap null mice compared to controls. Thus, sexual dimorphisms are highlighted in adipose tissue remodelling and thermogenesis with cold acclimation in the absence of PACAP.
Pituitary Adenylate Cyclase Activating Polypetptide (PACAP) is a peptide hormone known to regulate energy homeostasis1. Mice lacking PACAP are cold sensitive and have impaired adrenergic-induced thermogenesis2-4. Interestingly, Pacap null mice can survive cold housing if acclimated slowly, similar to what was observed in UCP1 deficient mice4,5. We hypothesized that Pacap-/- mice employ alternate thermogenic pathways to compensate for impaired adaptive thermogenesis and assessed shivering thermogenesis and UCP1-dependent and UCP1-independent adaptive thermogenesis in male and female Pacap-/- and Pacap+/+ with cold acclimation (4°C). Assessment of oxidative fibres in skeletal muscles and behavioural observations did not show evidence of prolonged shivering in male or female Pacap-/- mice during cold acclimation compared to Pacap+/+ mice. We did however observe morphological and molecular differences in adipose tissues of Pacap-/- mice compared to Pacap+/+ mice that were distinct in males and females. Cold-acclimated, female Pacap-/- mice had decreased induction of UCP1 protein in intrascapular brown fat (iBAT), yet had a significantly higher beiging and UCP1 immunoreactivity (ir) in gonadal white fat (gWAT) compared to female Pacap+/+ mice. Furthermore, beiging was observed in inguinal white fat (ingWAT) and gWAT of female Pacap-/- mice housed at thermoneutrality (30°C), a finding not observed in Pacap+/+ control mice. Unlike female mice, we did not observe impaired UCP1 induction in iBAT of male Pacap-/- mice compared to Pacap+/+ mice, and this was associated with negligible UCP1-ir in male gWAT similar to wildtype controls. Despite previous work that has established impaired adaptive thermogenesis in Pacap-/- mice4, we show here that UCP1 protein can be induced in adipose tissues of Pacap-/- mice during cold acclimation, although to a lesser degree or in a different pattern compared to Pacap+/+ control mice. Taken together, this work suggests that while PACAP is clearly involved in regulating thermoregulation, it is not required for cold-induced UCP1 expression. In addition, this work highlights sexual dimorphism in adipose tissue remodeling and induction of thermogenesis with cold acclimation. References: (1) Rudecki AP, et al. Trends Endocrinol Metab. 2016;27(9), 620–632. (2) Gray SL, et al. J Mol Endocrinol. 2001;15(10), 1739–1747. (3) Gray SL, et al. J Endocrinol. 2002;143(10), 3946–3954. (4) Diané A, et al. J Endocrinol. 2014;222, 327–339. (5) Golozoubova V, et al. FASEB J. 2001;15, 2048–2050.
Impaired adipose tissue function in obesity, including reduced thermogenic potential, has detrimental consequences for metabolic health. Hormonal regulation of adaptive thermogenesis is being explored as a potential therapeutic target for human obesity. Pituitary adenylate cyclase-activating polypeptide (PACAP) is a neuropeptide expressed in nuclei of the hypothalamus known to regulate energy expenditure, and functional studies reveal a role for PACAP in the central regulation of thermogenesis, although mechanisms are not well understood. We hypothesized that PACAP acts upstream of the melanocortin system to regulate sympathetic nerve activity to stimulate thermogenesis. To assess this, female PACAP −/− and PACAP +/+ mice were given daily peripheral injections of a melanocortin receptor agonist, melanotan II (MTII), for 3 weeks during cold acclimation, and the effect of MTII on thermogenic capacity and adipose tissue remodelling was examined by physiological and histological analyses. MTII partially rescued the impaired thermogenic capacity in PACAP −/− mice as compared to PACAP +/+ mice as determined by measuring noradrenaline-induced metabolic rate. In addition, MTII treatment during cold acclimation corrected the previously identified deficit in lipid utilization in response to adrenergic stimulation in PACAP −/− null mice, suggesting impaired lipid mobilization may contribute to the impaired thermogenic capacity of PACAP −/− mice. Results presented here provide physiological evidence to suggest that PACAP acts upstream of melanocortin receptors to facilitate sympathetically induced mechanisms of adaptive thermogenesis in response to cold acclimation.
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