Molecular and behavioral profiling of Dbx1-derived neurons in the arcuate, lateral and ventromedial hypothalamic nuclei.

IF 4 3区 生物学 Q1 DEVELOPMENTAL BIOLOGY
Katie Sokolowski, Tuyen Tran, Shigeyuki Esumi, Yasmin Kamal, Livio Oboti, Julieta Lischinsky, Meredith Goodrich, Andrew Lam, Margaret Carter, Yasushi Nakagawa, Joshua G Corbin
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引用次数: 0

Abstract

Background: Neurons in the hypothalamus function to regulate the state of the animal during both learned and innate behaviors, and alterations in hypothalamic development may contribute to pathological conditions such as anxiety, depression or obesity. Despite many studies of hypothalamic development and function, the link between embryonic development and innate behaviors remains unexplored. Here, focusing on the embryonically expressed homeodomain-containing gene Developing Brain Homeobox 1 (Dbx1), we explored the relationship between embryonic lineage, post-natal neuronal identity and lineage-specific responses to innate cues. We found that Dbx1 is widely expressed across multiple developing hypothalamic subdomains. Using standard and inducible fate-mapping to trace the Dbx1-derived neurons, we identified their contribution to specific neuronal subtypes across hypothalamic nuclei and further mapped their activation patterns in response to a series of well-defined innate behaviors.

Results: Dbx1-derived neurons occupy multiple postnatal hypothalamic nuclei including the lateral hypothalamus (LH), arcuate nucleus (Arc) and the ventral medial hypothalamus (VMH). Within these nuclei, Dbx1 (+) progenitors generate a large proportion of the Pmch-, Nesfatin-, Cart-, Hcrt-, Agrp- and ERα-expressing neuronal populations, and to a lesser extent the Pomc-, TH- and Aromatase-expressing populations. Inducible fate-mapping reveals distinct temporal windows for development of the Dbx1-derived LH and Arc populations, with Agrp(+) and Cart(+) populations in the Arc arising early (E7.5-E9.5), while Pmch(+) and Hcrt(+) populations in the LH derived from progenitors expressing Dbx1 later (E9.5-E11.5). Moreover, as revealed by c-Fos labeling, Dbx1-derived cells in male and female LH, Arc and VMH are responsive during mating and aggression. In contrast, Dbx1-lineage cells in the Arc and LH have a broader behavioral tuning, which includes responding to fasting and predator odor cues.

Conclusion: We define a novel fate map of the hypothalamus with respect to Dbx1 expression in hypothalamic progenitor zones. We demonstrate that in a temporally regulated manner, Dbx1-derived neurons contribute to molecularly distinct neuronal populations in the LH, Arc and VMH that have been implicated in a variety of hypothalamic-driven behaviors. Consistent with this, Dbx1-derived neurons in the LH, Arc and VMH are activated during stress and other innate behavioral responses, implicating their involvement in these diverse behaviors.

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下丘脑弓状核、外侧核和腹内侧核中 Dbx1 衍生神经元的分子和行为特征分析
背景:下丘脑中的神经元具有调节动物学习行为和先天行为状态的功能,下丘脑发育的改变可能导致焦虑、抑郁或肥胖等病理状况。尽管对下丘脑的发育和功能进行了许多研究,但胚胎发育与先天行为之间的联系仍有待探索。在此,我们以胚胎表达的含同源染色体的基因发育脑同源染色体 1(Dbx1)为研究对象,探讨了胚胎系、出生后神经元特征和系特异性先天性线索反应之间的关系。我们发现,Dbx1 在多个发育中的下丘脑亚域中广泛表达。利用标准和诱导性命运图谱追踪 Dbx1 衍生神经元,我们确定了它们对下丘脑核特定神经元亚型的贡献,并进一步绘制了它们对一系列明确定义的先天性行为的激活模式:结果:Dbx1衍生神经元占据了多个出生后下丘脑核,包括下丘脑外侧(LH)、弓状核(Arc)和下丘脑腹内侧(VMH)。在这些细胞核中,Dbx1(+)祖细胞产生了很大比例的Pmch-、Nesfatin-、Cart-、Hcrt-、Agrp-和ERα表达的神经元群,其次是Pomc-、TH-和Aromatase-表达的神经元群。诱导命运图谱显示,Dbx1衍生的LH和Arc群体的发育具有不同的时间窗口,Arc中的Agrp(+)和Cart(+)群体出现较早(E7.5-E9.5),而LH中的Pmch(+)和Hcrt(+)群体则来自表达Dbx1的祖细胞,出现较晚(E9.5-E11.5)。此外,c-Fos标记显示,雄性和雌性LH、Arc和VMH中的Dbx1衍生细胞在交配和攻击过程中反应灵敏。相比之下,Arc和LH中的Dbx1系细胞具有更广泛的行为调谐,包括对禁食和捕食者气味线索的反应:结论:我们根据下丘脑祖细胞区中 Dbx1 的表达确定了下丘脑的新命运图谱。我们证明,Dbx1 衍生的神经元以时间调控的方式为 LH、Arc 和 VMH 分子上不同的神经元群做出了贡献,这些神经元群与下丘脑驱动的各种行为有关。与此相一致的是,LH、Arc 和 VMH 中的 Dbx1 衍生神经元在压力和其他先天性行为反应期间被激活,这表明它们参与了这些不同的行为。
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来源期刊
Neural Development
Neural Development 生物-发育生物学
CiteScore
6.60
自引率
0.00%
发文量
11
审稿时长
>12 weeks
期刊介绍: Neural Development is a peer-reviewed open access, online journal, which features studies that use molecular, cellular, physiological or behavioral methods to provide novel insights into the mechanisms that underlie the formation of the nervous system. Neural Development aims to discover how the nervous system arises and acquires the abilities to sense the world and control adaptive motor output. The field includes analysis of how progenitor cells form a nervous system during embryogenesis, and how the initially formed neural circuits are shaped by experience during early postnatal life. Some studies use well-established, genetically accessible model systems, but valuable insights are also obtained from less traditional models that provide behavioral or evolutionary insights.
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