The proteomic landscape and temporal dynamics of mammalian gastruloid development

Riddhiman K Garge, Valerie Lynch, Rose Fields, Silvia Casadei, Sabrina Best, Jeremy Stone, Matthew Snyder, Chris D McGann, Jay Shendure, Lea M Starita, Nobuhiko Hamazaki, Devin K. Schweppe
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Abstract

Gastrulation is the highly coordinated process by which the early embryo breaks symmetry, establishes germ layers and a body plan, and sets the stage for organogenesis. As early mammalian development is challenging to study in vivo, stem cell-derived models have emerged as powerful surrogates, e.g. human and mouse gastruloids. However, although single cell RNA-seq (scRNA-seq) and high-resolution imaging have been extensively applied to characterize such in vitro embryo models, a paucity of measurements of protein dynamics and regulation leaves a major gap in our understanding. Here, we sought to address this by applying quantitative proteomics to human and mouse gastruloids at four key stages of their differentiation (naïve ESCs, primed ESCs, early gastruloids, late gastruloids). To the resulting data, we perform network analysis to map the dynamics of expression of macromolecular protein complexes and biochemical pathways, including identifying cooperative proteins that associate with them. With matched RNA-seq and phosphosite data from these same stages, we investigate pathway-, stage- and species-specific aspects of translational and post-translational regulation, e.g. finding peri-gastrulation stages of human and mice to be discordant with respect to the mitochondrial transcriptome vs. proteome, and nominating novel kinase-substrate relationships based on phosphosite dynamics. Finally, we leverage correlated dynamics to identify conserved protein networks centered around congenital disease genes. Altogether, our data (https://gastruloid.brotmanbaty.org/) and analyses showcase the potential of intersecting in vitro embryo models and proteomics to advance our understanding of early mammalian development in ways not possible through transcriptomics alone.
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哺乳动物胃肠发育的蛋白质组格局和时间动态
胚层形成是一个高度协调的过程,早期胚胎在此过程中打破对称性,建立胚层和身体计划,并为器官形成奠定基础。由于哺乳动物的早期发育难以在体内进行研究,干细胞衍生模型(如人类和小鼠的胃胚层)已成为强有力的替代物。然而,尽管单细胞RNA-seq(scRNA-seq)和高分辨率成像已被广泛应用于表征这类体外胚胎模型,但对蛋白质动态和调控的测量却很少,这给我们的理解留下了重大空白。为了解决这个问题,我们将定量蛋白质组学应用于人和小鼠胃小体的四个关键分化阶段(幼稚ESCs、primed ESCs、早期胃小体、晚期胃小体)。我们对所得数据进行网络分析,以绘制大分子蛋白复合物和生化通路的表达动态图,包括识别与之关联的合作蛋白。利用来自这些相同阶段的匹配 RNA-seq 和磷酸盐数据,我们研究了翻译和翻译后调控的通路、阶段和物种特异性方面,例如,我们发现人和小鼠的围胃期线粒体转录组与蛋白质组不一致,并根据磷酸盐动态发现了新的激酶-底物关系。最后,我们还利用相关动力学来识别以先天性疾病基因为中心的保守蛋白质网络。总之,我们的数据(https://gastruloid.brotmanbaty.org/)和分析展示了体外胚胎模型和蛋白质组学相互交叉的潜力,从而推动了我们对哺乳动物早期发育的了解,而这是仅仅通过转录组学无法实现的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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