Distribution of growth hormone-responsive cells in the mouse brain

Furigo, Isadora C.; Metzger, Martin; Teixeira, Pryscila D.S.; Soares, Carlos R.J.; Donato, José

doi:10.1007/s00429-016-1221-1

Cited by 72 publications

(91 citation statements)

References 57 publications

(108 reference statements)

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“…This suggests that central GH signaling might be involved in energy expenditure and glucose homeostasis through a central mechanism [10]. GH overexpression in the CNS results in hyperphagia-induced obesity, insulin resistance, and increased circulating GH levels [17].…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies also indicate that leptin can modulate GH secretion and the GH response to GHRH [22]. LepRb neurons are widely distributed within the hypothalamic ARH, VMH, DMH, LHA, and some additional sites that also express GHR [10], [23]. Recent transcriptome analysis of LepRb expressing neurons revealed that the Ghr gene is strongly enriched in LepRb neurons [24].…”

Section: Introductionmentioning

confidence: 98%

“…In both human and mouse brain, GH and the GH receptor (GHR) are present in regions known to participate in the regulation of feeding behavior, energy balance, and glucose metabolism such as the hypothalamus, hippocampus, and amygdala [6], [7], [8], [9], [10]. Upon GHR activation, the signal transducer and activator of transcription 5 (Stat5) is recruited and regulates the transcription of genes directly controlled by GH [11], [12].…”

Section: Introductionmentioning

confidence: 99%

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Hypothalamic growth hormone receptor (GHR) controls hepatic glucose production in nutrient-sensing leptin receptor (LepRb) expressing neurons

Cady

Landeryou

Garratt

et al. 2017

Molecular Metabolism

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ObjectiveThe GH/IGF-1 axis has important roles in growth and metabolism. GH and GH receptor (GHR) are active in the central nervous system (CNS) and are crucial in regulating several aspects of metabolism. In the hypothalamus, there is a high abundance of GH-responsive cells, but the role of GH signaling in hypothalamic neurons is unknown. Previous work has demonstrated that the Ghr gene is highly expressed in LepRb neurons. Given that leptin is a key regulator of energy balance by acting on leptin receptor (LepRb)-expressing neurons, we tested the hypothesis that LepRb neurons represent an important site for GHR signaling to control body homeostasis.MethodsTo determine the importance of GHR signaling in LepRb neurons, we utilized Cre/loxP technology to ablate GHR expression in LepRb neurons (LeprEYFPΔGHR). The mice were generated by crossing the Leprcre on the cre-inducible ROSA26-EYFP mice to GHRL/L mice. Parameters of body composition and glucose homeostasis were evaluated.ResultsOur results demonstrate that the sites with GHR and LepRb co-expression include ARH, DMH, and LHA neurons. Leptin action was not altered in LeprEYFPΔGHR mice; however, GH-induced pStat5-IR in LepRb neurons was significantly reduced in these mice. Serum IGF-1 and GH levels were unaltered, and we found no evidence that GHR signaling regulates food intake and body weight in LepRb neurons. In contrast, diminished GHR signaling in LepRb neurons impaired hepatic insulin sensitivity and peripheral lipid metabolism. This was paralleled with a failure to suppress expression of the gluconeogenic genes and impaired hepatic insulin signaling in LeprEYFPΔGHR mice.ConclusionThese findings suggest the existence of GHR-leptin neurocircuitry that plays an important role in the GHR-mediated regulation of glucose metabolism irrespective of feeding.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Hypothalamic growth hormone receptor (GHR) controls hepatic glucose production in nutrient-sensing leptin receptor (LepRb) expressing neurons

Cady

Landeryou

Garratt

et al. 2017

Molecular Metabolism

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“…Thus, pSTAT5 immunoreactivity observed in this group reveals signalling exclusively through the PRLR-l. Still, GH (Furigo et al 2016) or leptin could contribute to the pSTAT5-ir observed in pregnant females, although the high levels of PLs likely account for most (if not all) of the pSTAT5 immunolabelling observed. Regarding leptin, STAT3 is the main STAT member associated with the leptin receptor (Ladyman et al 2012), whereas STAT5 phosphorylation associated with leptin signalling has been reported only in the arcuate nucleus (Gong et al 2007;Mütze et al 2007) and has not been replicated in all studies (Vaisse et al 1996).…”

Section: Immunohistochemical Detection Of Pstat5 As a Measure Of Centmentioning

confidence: 94%

“…Regarding leptin, STAT3 is the main STAT member associated with the leptin receptor (Ladyman et al 2012), whereas STAT5 phosphorylation associated with leptin signalling has been reported only in the arcuate nucleus (Gong et al 2007;Mütze et al 2007) and has not been replicated in all studies (Vaisse et al 1996). As for GH, regions of the brain showing high levels of expression of GH receptors and responsiveness to GH (detected by pSTAT5-ir; Furigo et al 2016), such as the hippocampus and dentate gyrus (Burton et al 1992) or layers 2, 3, and 5, and especially, layer 6 of the cerebral cortex (Lobie et al 1993), show no pSTAT5 labelling in any of our mice, neither in virgin nor in pregnant or lactating females. This suggests that GH signalling in the brain is taking place through alternative pathways, e.g., those involving Src kinases (Waters 2015).…”

Section: Immunohistochemical Detection Of Pstat5 As a Measure Of Centmentioning

confidence: 99%

Tuning the brain for motherhood: prolactin-like central signalling in virgin, pregnant, and lactating female mice

et al. 2016

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Prolactin is fundamental for the expression of maternal behaviour. In virgin female rats, prolactin administered upon steroid hormone priming accelerates the onset of maternal care. By contrast, the role of prolactin in mice maternal behaviour remains unclear. This study aims at characterizing central prolactin activity patterns in female mice and their variation through pregnancy and lactation. This was revealed by immunoreactivity of phosphorylated (active) signal transducer and activator of transcription 5 (pSTAT5-ir), a key molecule in the signalling cascade of prolactin receptors. We also evaluated non-hypophyseal lactogenic activity during pregnancy by administering bromocriptine, which suppresses hypophyseal prolactin release. Late-pregnant and lactating females showed significantly increased pSTAT5-ir resulting in a widespread pattern of immunostaining with minor variations between pregnant and lactating animals, which comprises nuclei of the sociosexual and maternal brain, including telencephalic (septum, nucleus of the stria terminalis, and amygdala), hypothalamic (preoptic, paraventricular, supraoptic, and ventromedial), and midbrain (periaqueductal grey) regions. During late pregnancy, this pattern was not affected by the administration of bromocriptine, suggesting it to be elicited mostly by non-hypophyseal lactogenic agents, likely placental lactogens. Virgin females displayed, instead, a variable pattern of pSTAT5-ir restricted to a subset of the brain nuclei labelled in pregnant and lactating mice. A hormonal substitution experiment confirmed that estradiol and progesterone contribute to the variability found in virgin females. Our results reflect how the shaping of the maternal brain takes place prior to parturition and suggest that lactogenic agents are important candidates in the development of maternal behaviours already during pregnancy.

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Neurochemical phenotype of growth hormone‐responsive cells in the mouse paraventricular nucleus of the hypothalamus

Quaresma

Santos

Wasinski

et al. 2020

J of Comparative Neurology

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Multiple neuroendocrine, autonomic and behavioral responses are regulated by the paraventricular nucleus of the hypothalamus (PVH). Previous studies have shown that PVH neurons express the growth hormone (GH) receptor (GHR), although the role of GH signaling on PVH neurons is still unknown. Given the great heterogeneity of cell types located in the PVH, we performed a detailed analysis of the neurochemical identity of GH‐responsive cells to understand the possible physiological importance of GH action on PVH neurons. GH‐responsive cells were detected via the phosphorylated form of the signal transducer and activator of transcription‐5 (pSTAT5) in adult male mice that received an intraperitoneal GH injection. Approximately 51% of GH‐responsive cells in the PVH co‐localized with the vesicular glutamate transporter 2. Rare co‐localizations between pSTAT5 and vesicular GABA transporter or vasopressin were observed, whereas approximately 20% and 38% of oxytocin and tyrosine hydroxylase (TH) cells, respectively, were responsive to GH in the PVH. Approximately 55%, 35% and 63% of somatostatin, thyrotropin‐releasing hormone (TRH) and corticotropin‐releasing hormone (CRH) neurons expressed GH‐induced pSTAT5, respectively. Additionally, 8%, 49% and 75% of neuroendocrine TH, TRH and CRH neurons, and 67%, 32% and 74% of nonneuroendocrine TH, TRH and CRH neurons were responsive to GH in the PVH of Fluoro‐Gold‐injected mice. Our findings suggest that GH action on PVH neurons is involved in the regulation of the thyroid, somatotropic and adrenal endocrine axes, possibly influencing homeostatic and stress responses.

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Distribution of growth hormone-responsive cells in the mouse brain

Cited by 72 publications

References 57 publications

Hypothalamic growth hormone receptor (GHR) controls hepatic glucose production in nutrient-sensing leptin receptor (LepRb) expressing neurons

Hypothalamic growth hormone receptor (GHR) controls hepatic glucose production in nutrient-sensing leptin receptor (LepRb) expressing neurons

Tuning the brain for motherhood: prolactin-like central signalling in virgin, pregnant, and lactating female mice

Neurochemical phenotype of growth hormone‐responsive cells in the mouse paraventricular nucleus of the hypothalamus

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