从干细胞中生成人类食欲调节神经元和澹细胞

bioRxiv Pub Date : 2024-07-16 DOI:10.1101/2024.07.11.603039
Zehra Abay-Nørgaard, Anika K Müller, Erno Hänninen, Dylan Rausch, Louise Piilgaard, Jens Bager Christensen, Sofie Peeters, Alrik L. Schörling, Alison Salvador, Viktoriia Nikulina, Yuan Li, Janko Kajtez, T. Pers, A. Kirkeby
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引用次数: 0

摘要

能量摄入和消耗之间的平衡由下丘脑控制,下丘脑是一个很小的脑区,其特点是神经元高度多样化。具体来说,弓状核(ARC)和腹内侧下丘脑(VMH)是下丘脑的关键核团,通过对循环体液信号的行为反应来控制食欲。然而,尽管它们具有重要的生理意义,但由于缺乏人体模型,人们主要在动物身上研究这一高度专业化神经区域的细胞和功能特征。在这里,我们微调了人类多能干细胞向ARC和VMH下丘脑核的分化,并确定了这些亚区域的关键亚型特异性祖细胞标记。我们证明,骨形态发生蛋白(BMP)信号的启动和终止时间对于控制结节下丘脑祖细胞沿前后轴的亚区域分化、平衡VMH与ARC命运至关重要。研究发现,SHH-/NKX2.1+/FGF10high/RAXhigh/TBX3high后结节祖细胞是产生ARC相关激动相关肽(AGRP)神经元和澹细胞的来源,而前结节SHH+/NKX2.1+/FGF10low/RAXlow/TBX3low祖细胞则产生包括NR5A1神经元在内的VMH表型。在体外和异种移植中成熟后,ARC模式的祖细胞产生了关键的食欲调节细胞类型,包括产生AGRP、前皮质素(PNOC)、生长激素释放激素(GHRH)、促甲状腺激素释放激素(TRH)和前表皮促皮质素(POMC)的细胞,以及澹细胞胶质细胞。分化的 ARC 培养物显示出与人类 ARC 高度相似的转录组,并通过 AGRP 分泌以及对瘦素和成纤维细胞生长因子 1(FGF1)的反应显示出功能性。总之,我们的工作深入揭示了下丘脑亚区域规范的发育谱系,使我们能够获得高度表征的人类 ARC 和 VMH 培养物,这将为研究肥胖相关基因变异和体重调节刺激引发的细胞和分子途径提供新的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Generation of human appetite-regulating neurons and tanycytes from stem cells
The balance between energy intake and expenditure is controlled by the hypothalamus, a small brain region characterised by high neuronal diversity. Specifically, the arcuate nucleus (ARC) and ventromedial hypothalamus (VMH) are key hypothalamic nuclei controlling appetite through behavioural response to circulating humoral signals. Yet, despite their physiological importance, the cellular and functional characteristics of this highly specialised neural region has been studied mainly in animals due to a lack of human models. Here, we fine-tuned the differentiation of human pluripotent stem cells toward the ARC and VMH hypothalamic nuclei and identified key subtype-specific progenitor markers of these subregions. We demonstrate that the timing for initiation and termination of bone morphogenetic protein (BMP) signalling is essential for controlling subregional specification of tuberal hypothalamic progenitors along the anterior-posterior axis, balancing VMH versus ARC fates. A particular population of SHH-/NKX2.1+/FGF10high/RAXhigh/TBX3high posterior tuberal progenitors was identified as the source for generation of ARC-associated agouti-related peptide (AGRP) neurons and tanycytes whilst anterior tuberal SHH+/NKX2.1+/FGF10low/RAXlow/TBX3low progenitors generated VMH phenotypes including NR5A1 neurons. Upon maturation in vitro and in xenografts, ARC-patterned progenitors gave rise to key appetite-regulating cell types including those producing AGRP, prepronociceptin (PNOC), growth hormone-releasing hormone (GHRH), thyrotropin-releasing hormone (TRH) and pro-opiomelanocortin (POMC), as well as tanycyte glial cells. Differentiated ARC cultures showed high transcriptomic similarity to the human ARC and displayed evidence of functionality by AGRP secretion and responsiveness to leptin and fibroblast growth factor 1 (FGF1). In summary, our work provides insights into the developmental lineages underlying hypothalamic subregional specification and enables access to highly characterised human ARC and VMH cultures, which will provide novel opportunities for investigating the cellular and molecular pathways triggered by obesity-associated genetic variants and weight-regulating stimuli.
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