Dual signal transduction pathways activated by TSH receptors in rat primary 1 tanycyte cultures

Bolborea, M., Helfer, Gisela, Ebling, F.J.P., Barrett, P.

15 April 2015

yes / Tanycytes play multiple roles in hypothalamic functions, including sensing peripheral nutrients and metabolic hormones, regulating neurosecretion and mediating seasonal cycles of reproduction and metabolic physiology. This last function reflects the expression of TSH receptors in tanycytes, which detect photoperiod-regulated changes in TSH secretion from the neighbouring pars tuberalis. The present overall aim was to determine the signal transduction pathway by which TSH signals in tanycytes. Expression of the TSH receptor in tanycytes of 10-day-old Sprague Dawley rats was observed by in situ hybridisation. Primary ependymal cell cultures prepared from 10-day-old rats were found by immunohistochemistry to express vimentin but not GFAP and by PCR to express mRNA for Dio2, Gpr50, Darpp-32 and Tsh receptors that are characteristic of tanycytes. Treatment of primary tanycyte/ependymal cultures with TSH (100 IU/l) increased cAMP as assessed by ELISA and induced a cAMP-independent increase in the phosphorylation of ERK1/2 as assessed by western blot analysis. Furthermore, TSH (100 IU/l) stimulated a 2.17-fold increase in Dio2 mRNA expression. We conclude that TSH signal transduction in cultured tanycytes signals via Gαs to increase cAMP and via an alternative G protein to increase phosphorylation of ERK1/2.

Rôle de la signalisation hypothalamique TSH/T3 dans la reproduction saisonnière chez les hamsters Djungariens (Phodopus sungorus) et Syriens (Mesocricetus auratus) / Implication of the TSH/T3 dependent hypothalamic pathway in the seasonal reproduction of Djungarian (Phodopus sungorus) and Syrian (Mesocricetus auratus) hamsters

Milesi, Sébastien

03 May 2018

Chez les hamsters, les jours longs activent la reproduction. Cette activation photopériodique (AP) impliquerait la mélatonine, l’hormone thyroïdienne (HT) et les RFamides hypothalamiques. Si les jours courts inhibiteurs sont maintenus au-delà de 20 semaines, une réactivation photoréfractaire (RP) de l’axe hypothalamo pituitaire gonadotrope (HPG) est déclenchée. Les mécanismes de cette RP sont inconnus. Notre analyse de la cinétique des changements moléculaires induits par l’AP et la RP montre dans les deux cas une inhibition précoce de l’expression de la Désiodinase 3 (Dio3), l’enzyme catabolisant les HT, dans les tanycytes. Associée à une inhibition tardive du transporteur MCT8 des HT, la diminution de Dio3 pourrait créer un pic d’HT dans l’hypothalamus. Dans les 2 activations, Kisspeptine et RFRP3 augmentent plusieurs semaines après l’inhibition de Dio3 et l’activation de l’HPG. Aussi, une inhibition d’RFRP3 lors de l’AP n’affecte pas l’HPG, mettant en cause le rôle du RFRP3. Nous avons donc découvert une inhibition précoce de Dio3 pouvant induire l’activation saisonnière de l’HPG. Le régulateur saisonnier précoce de Dio3 reste à découvrir. / In hamsters, reproduction is activated by long days. This photoactivation (PA) supposedly involves melatonin, hypothalamic thyroid hormones (TH) and RFamide peptides. Maintaining inhibitory short days for over 20 weeks triggers a photorefractory reactivation of the hypothalamo pituito gonadotropic axis (HPG) The mechanisms of this PR are so far unknown. Our cinetic analysis of the dynamic molecular changes in PA and PR revealed a conserved early inhibition of tanycytic deiodinase 3 (Dio3), which catabolizes TH, in both activation mechanisms. Associated with a late decrease of the TH transporter MCT8, the inhibition of Dio3 could generate an early peak of hypothalamic TH. In both activations, RFamide upregulation occurs several weeks after the initial Dio3 inhibition. Also, pharmacological inhibition of RFRP3 during PA does not influence the HPG activity, questioning the role of RFRP3 in HPG activation. We have thus uncovered a so far unreported early Dio3 inhibition that could be sufficient to seasonally reactivate the gonadotropic axis. The seasonal regulator of Dio3 remains to be discovered.

Saisonnalité

TSH

Hormones thyroïdiennes

Pars tuberalis

Tanycytes

Déiodinase 3

Hamsters

Photoréfractaire

Seasonality

TSH

Thyroid hormones

Pars tuberalis

Tanycytes

Déiodinase 3

Hamsters

Photorefractoriness

571.7

612.02

Rôle de la programmation maternelle et du rythme circannuel sur le contrôle neuroendocrine de la physiologie saisonnière / The role of photoperiodic history and internal long‐term timing in seasonal neuroendocrinology

Saenz De Miera Patin, Cristina

25 November 2014

La régulation endogène de la physiologie saisonnière, comme les rythmes circannuels et l’histoire photopériodique vécue pendant la gestation, permet aux individus d’anticiper à l’arrivée des saisons. L’objectif de cette thèse a été l’étude de l’effet de ces deux phénomènes à long terme sur les voies neuroendocrines contrôlant la physiologie saisonnière. Ces études montrent que les rythmes circannuels sont initiés au niveau de l’expression de la thyréostimuline dans la pars tuberalis et celle-ci est transmisse à l’hypothalamus où elle contrôle les niveaux d’hormone thyroïdienne et de neuropeptides. De façon similaire, la photopériode vécue pendant la gestation semble programmer l’expression des déiodinases dans l’hypothalamus des rongeurs adultes. Dans l’ensemble, ces résultats montrent la conservation du rôle de la pars tuberalis en tant que site central pour l’intégration des signaux impliqués dans le contrôle de la physiologie saisonnière. / Internal long-term timing strategies, like circannual rhythms and photoperiodic history, allow changes in physiology in anticipation to the seasons. In this project I investigated the effects of both types of history dependent timing on the neuro endocrine pathways for regulation of seasonal physiology. My work revealed that internal circannual timing is initiated through the control of thyroid stimulating hormone at the pars tuberalis and is integrated into the regulation of hypothalamic thyroid hormone levels and neuropeptides.Similarly, history-dependent expression in hypothalamic deiodinases was observed in adult rodents based on their gestational photoperiodic experience. Overall, my results highlight the pars tuberalis as a conserved central site in mammals for the integration of multiple seasonal cues, which via differential control of thyroid hormone levels in the hypothalamus dictates the timing in seasonal physiology.

Saisonnalité

Circannuel

Programmation maternelle

Déiodinases

Pars tuberalis

RF-amides

Seasonality

Circannual

Maternal programming

Deiodinases

Pars tuberalis

RF-amides

571.8

573.8

612.02

Melatonin mediated transcriptional mechanisms in the ovine pars tuberalis

West, Alexander

January 2013

In seasonal mammals the duration of nocturnal melatonin secretion accurately reflects the environmental photoperiod. The endocrine rhythm is decoded by a specialised portion of the pituitary gland (the pars tuberalis, PT) which then relays this information to the pars distalis and hypothalamus, precipitating huge annual changes in physiology and behaviour. However how the PT decodes the melatonin signal is currently unknown. Melatonin influences gene transcription in the ovine PT at its onset and offset, and the phase relationship of these two groups is believed to form the underlying mechanism by which the PT integrates seasonal time. The transcripts induced at melatonin offset are understood to be under the control of a seasonally gated cAMP mechanism. Conversely processes involved in melatonin-mediated gene induction are currently not understood.The work in this thesis ultimately aims to reveal how the seasonal melatonin signal is decoded by the PT. To this end melatonin-mediated gene induction has been characterised through RNAseq, the highly displaced cohorts submitted to bioinformatic promoter analysis and the paradigm tested though in vitro modelling techniques.In this study a 1.5 h infusion with melatonin acutely regulated 219 transcripts in the ovine PT (115 induced, 104 repressed, >1.5 fold change), confirming previous association of several genes (including Cry1, MT1, Gadd45g, Nampt and Npas4) to rapid melatonin control. Gross promoter analysis of these groups indicated that the induced gene cohort was significantly enriched for GC content and CpG islands suggesting the involvement of epigenetic mechanisms of transcriptional control. Further bioinformatic analysis specifically implicated the importance of transcription factors ZFP161 and PAX5 in melatonin-mediated gene induction in the PT. Several immortalised cell lines were screened for the presence of a functional melatonin receptor. Two strains (MCF7 oMT1 and NES2Y) exhibited significant attenuation of forskolin-mediated cAMP accumulation when co-treated with melatonin, a hallmark of melatonin Gαi-coupled protein receptor signalling. These lines were subsequently evaluated as models of melatonin-mediated gene induction of the sheep PT through ovine promoter reporter assays of Cry1, Nampt, NeuroD1 and Npas4. However, treatment with melatonin failed to evoke a reporter response suggesting that the cell line models were inadequately equipped to reflect PT biology. Subsequently a protocol was established to culture ovine PT explants culture which faithfully recapitulated melatonin mediated transcriptional dynamics in vitro, providing a possible tool for the future investigation of the PT. Lastly, previous work has shown the transcriptional profile of Npas4 to peak highly and transiently, pre-empting the expression of other melatonin-induced genes. Using a COS7 cell line model, heterologously-expressed NPAS4 was shown to form functional heterodimeric partnerships with ARNT and ARNTL and transactivate both Cry1 and Nampt promoter reporters through novel binding sites. Collectively these data indicated NPAS4 to act as an immediate activator of melatonin regulated circuits

612.4

A unifying hypothesis for control of body weight and reproduction in seasonally breeding mammals

Helfer, Gisela, Barrett, P., Morgan, P.J.

26 December 2018

Yes / Animals have evolved diverse seasonal variations in physiology and reproduction to accommodate yearly changes in environmental and climatic conditions. These changes in physiology are initiated by changes in photoperiod (daylength) and are mediated through melatonin, which relays photoperiodic information to the pars tuberalis of the pituitary gland. Melatonin drives thyroid‐stimulating hormone transcription and synthesis in the pars tuberalis, which, in turn, regulates thyroid hormone and retinoic acid synthesis in the tanycytes lining the third ventricle of the hypothalamus. Seasonal variation in central thyroid hormone signalling is conserved among photoperiodic animals. Despite this, different species adopt divergent phenotypes to cope with the same seasonal changes. A common response amongst different species is increased hypothalamic cell proliferation/neurogenesis in short photoperiod. That cell proliferation/neurogenesis may be important for seasonal timing is based on (i) the neurogenic potential of tanycytes; (ii) the fact that they are the locus of striking seasonal morphological changes; and (iii) the similarities to mechanisms involved in de novo neurogenesis of energy balance neurones. We propose that a decrease in hypothalamic thyroid hormone and retinoic acid signalling initiates localised neurodegeneration and apoptosis, which leads to a reduction in appetite and body weight. Neurodegeneration induces compensatory cell proliferation from the neurogenic niche in tanycytes and new cells are born under short photoperiod. Because these cells have the potential to differentiate into a number of different neuronal phenotypes, this could provide a mechanistic basis to explain the seasonal regulation of energy balance, as well as reproduction. This cycle can be achieved without changes in thyroid hormone/retinoic acid and explains recent data obtained from seasonal animals held in natural conditions. However, thyroid/retinoic acid signalling is required to synchronise the cycles of apoptosis, proliferation and differentiation. Thus, hypothalamic neurogenesis provides a framework to explain diverse photoperiodic responses. / MRC. Grant Number: MR/P012205/1 - Scottish Government - BBSRC. Grant Number: BB/K001043/1 - Physiological Society

Melatonin

Neuroendocrinology

Neurogenesis

Pars tuberalis

Photoperiod

Retinoic acid

Season

Tanycyte

Thyroid hormone