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Endocrine Abstracts (2022) 84 OP04-19 | DOI: 10.1530/endoabs.84.OP-04-19

ETA2022 Oral Presentations Oral Session 4: Basic 1 (5 abstracts)

A thyroid hormone-independent role for transthyretin in neural stem cells of the postnatal mouse subventricular zone?

Pieter Vancamp 1 , Karine Le Blay 2 , Barbara Demeneix 3 & Sylvie Remaud 4


1Muséum National D’histoire Naturelle, Cnrs, Umr 7221, Paris, France; 2Muséum National D’histoire Naturelle, Muséum National D’histoire Naturelle, Adaptations du Vivant, Paris, France; 3Muséum National D’histoire Naturelle/Cnrs, Centre National de la Recherche Scientifique, Umr 7221 Evolution des Régulations Endocriniennes, Paris, France; 4Muséum National D’histoire Naturelle, Centre National de la Recherche Scientifique, Umr 7221 Evolution des Régulations Endocriniennes, Paris, France


Transthyretin (TTR) distributes thyroxine in the cerebrospinal fluid of mammals. Choroid plexus epithelial cells produce and secrete TTR, and were long recognized as the only CNS source of TTR. However, research over the last years has reported neuronal-specific expression as well, but without a clear function. Recently, we found Ttr transcripts in cells of the adult mouse subventricular zone (SVZ), the largest neural stem cell (NSC) region, but the protein was undetectable. We therefore investigated in more detail what role TTR might play in the SVZ, and when. We mapped temporal-spatial Ttr expression by re-analysing publicly available single-cell RNA-Seq data obtained from dissected mouse SVZs at E14-E17-P2-P7-P20-P61. We observed a peak in Ttr expression in NSCs, neural progenitors and differentiating cells at postnatal day 7 (P7). That is one week prior to when thyroxine serum levels peak and T3 activates SVZ-NSCs that start generating neurons and glia at a constant rate. RNAscope on P7 brain sections confirmed that few Ttr transcripts are present in a many SVZ-progenitors, oligodendrocyte precursors and neuroblasts. Unexpectedly though, no protein was detectable using commercially available antibodies, signal amplification and appropriate controls. This might suggest TTR is rapidly secreted to affect nearby cells. To test this hypothesis, we prepared neurospheres from dissected SVZ-progenitors at P7. After 7 days of proliferation, cells were dissociated, and allowed to differentiate for 1 or 5 days. In parallel with controls, we treated them once at day 0 of differentiation with a low (2.5 µg/ml) or a high dose (25 µg/ml) of human recombinant TTR, or with 5 nM T3. Low TTR doses reduced cell mitosis at day 1, as did T3. After 5 days, we counted a 30% lower proportion of differentiated neuroblasts with the highest TTR dose. That proportion had dropped 3-fold in the presence of T3. Proportions of oligodendroglia after 5 days of differentiation were only significantly higher in T3 conditions. As a result, the neuron/glia balance shifted in favour of oligodendrogenesis under T3, and borderline-significantly following high TTR doses. Altogether, the murine SVZ represents a novel region containing cells that express Ttr, with a peak at P7, despite seeming absence of the protein itself, precluding deducing its exact role. Single-cell RNA-Seq on treated neurospheres could reveal how exogenous TTR affects intracellular pathways, and whether its action is TH-dependent or not. This can help unravelling the pathophysiology of familial amyloid polyneuropathy, in which misfolded TTR proteins cause neurodegeneration.

Volume 84

44th Annual Meeting of the European Thyroid Association (ETA) 2022

Brussels, Belgium
10 Sep 2022 - 13 Sep 2022

European Thyroid Association 

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