Novel Roles of Pluripotency Regulators in the Early Mouse Embryo

多能性调节因子在早期小鼠胚胎中的新作用

• 批准号: 7936769
• 负责人: MYLENE W YAO
• 金额: $ 22.54万
• 依托单位: STANFORD UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-30 至 2011-02-28
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7936769
• 关键词: Address; Architecture; Boxing; Cell Cycle; Cell Lineage; Cells; Competence; Data; Development; Embryo; Embryonic Development; Ensure; Epigenetic Process; Family; Fertilization; Fetus; Figs - dietary; Gene Expression; Gene Expression Regulation; Gene Targeting; Genes; Genetic; Genetic Programming; Genome; Germ Cells; Goals; Human; In Vitro; Infertility; Inner Cell Mass; Lead; Malignant Neoplasms; Medicine; Modeling; Molecular Profiling; Morula; Mus; POU domain factors; Phenotype; Regulation; Regulator Genes; Reporting; Role; Signal Pathway; Signaling Molecule; Staging; Stem Cell Research; Stem cells; Testing; Transcript; Translations; Up-Regulation; Work; anticancer research; base; blastocyst; cyclin A2; embryo stage 2; embryonic stem cell; gene discovery; gene function; homeodomain; human embryonic stem cell; member; novel; nuclear reprogramming; pluripotency; programs; public health relevance; regenerative; self-renewal; somatic cell nuclear transfer; zygote

DESCRIPTION (provided by applicant): The gene regulatory network that controls pluripotency and differentiation in embryonic stem cells (ESCs) is widely studied and becoming well understood. However, the genetic parameters of successful somatic cell nuclear transfer and the genetic program that sets up the ESC gene network are not known. The answers to these key questions in ESC research lie in the gene regulation of the early embryo, which for our purpose here, encompasses developmental stages that occur after fertilization and prior to blastocyst formation. Just as the inner cell mass of the blastocyst must maintain pluripotency and the ability to self-renew in order to give rise to cell lineages that form the fetus, the blastomeres of the early embryo must establish totipotency and self-renewal abilities to form the blastocyst. However, we do not know how totipotency of blastomeres is achieved and how it relates to the waves of embryonic genome activation. Therefore, our overall goal is to address both the general architecture of this gene network and identify specific regulators that are critical and sufficient for establishing the correct genetic circuitry at the 1- to 2-cell stages, and that would ensure subsequent developmental competence. Further, the function of these regulators will be determined in order to understand mechanisms that are essential in early embryo development. We have established experimental strategies to interrogate the precise roles of transcriptional regulators during the maternal-embryonic transition of the early embryo, when both maternal and early embryonic transcripts may be present simultaneously. We discovered that Oct4, a homeodomain transcription factor of the POU family that is known for its critical functions in pluripotency in the inner cell mass, ESCs, and germ cells, has a novel role in early embryo development prior to the blastocyst stage and is required for progression beyond the multi-cell and morula stages. In addition, our data suggest that the pluripotency regulators, Sox2 and Sall4, may also have critical functions prior to blastocyst formation. We propose to fully investigate the novel roles of these and other pluripotency regulators and use them as "portals" to dissect gene regulation in the early embryo in the context of nuclear reprogramming and embryonic genome activation. Understanding the genetic requirements of the early embryo will have a direct and significant impact on regenerative and stem cell medicine, the treatment of infertility, and cancer research, as genes implicated in cancer are highly enriched in this genetic program. Public Health Relevance: The overall goal of this project is to investigate the novel roles of Oct4, Sall4, Sox2, and other pluripotency regulators in the early mouse embryo, with a focus on the 1- to 2-cell stages during the maternal-embryonic transition. Using these transcriptional regulators as "portals", we will dissect the gene regulatory network in the early embryo and identify specific regulators that are critical and sufficient for ensuring subsequent developmental competence. Understanding the genetic requirements of the early embryo will have a direct and significant impact on regenerative and stem cell medicine, the treatment of infertility, and cancer research.

描述（由申请人提供）：控制胚胎干细胞（ESC）多能性和分化的基因调控网络已被广泛研究并得到充分理解。然而，成功体细胞核移植的遗传参数以及建立ESC基因网络的遗传程序尚不清楚。 ESC 研究中这些关键问题的答案在于早期胚胎的基因调控，就我们的目的而言，它涵盖了受精后和囊胚形成之前发生的发育阶段。正如囊胚的内细胞团必须保持多能性和自我更新能力才能产生形成胎儿的细胞谱系一样，早期胚胎的卵裂球也必须建立全能性和自我更新能力才能形成囊胚。然而，我们不知道卵裂球的全能性是如何实现的，以及它与胚胎基因组激活波的关系。因此，我们的总体目标是解决该基因网络的一般架构，并确定对于在 1 至 2 细胞阶段建立正确的遗传电路至关重要且足够的特定调节因子，并且这将确保随后的发育能力。此外，将确定这些调节器的功能，以便了解早期胚胎发育中必需的机制。我们已经建立了实验策略来探究早期胚胎母体-胚胎转变过程中转录调节因子的精确作用，此时母体和早期胚胎转录可能同时存在。我们发现 Oct4 是 POU 家族的同源域转录因子，以其在内细胞团、ESC 和生殖细胞的多能性中发挥关键功能而闻名，它在囊胚阶段之前的早期胚胎发育中具有新的作用，并且是多细胞和桑椹胚阶段之后的进展所必需的。此外，我们的数据表明，多能性调节因子 Sox2 和 Sall4 在囊胚形成之前也可能具有关键功能。我们建议充分研究这些和其他多能性调节因子的新作用，并利用它们作为“门户”，在核重编程和胚胎基因组激活的背景下剖析早期胚胎中的基因调控。了解早期胚胎的遗传要求将对再生和干细胞医学、不孕症治疗和癌症研究产生直接而重大的影响，因为与癌症有关的基因在该遗传程序中高度丰富。 公共健康相关性：该项目的总体目标是研究 Oct4、Sall4、Sox2 和其他多能性调节因子在早期小鼠胚胎中的新作用，重点关注母体胚胎转变期间的 1 至 2 细胞阶段。使用这些转录调节因子作为“门户”，我们将剖析早期胚胎中的基因调节网络，并识别对于确保后续发育能力至关重要且足够的特定调节因子。了解早期胚胎的遗传要求将对再生和干细胞医学、不孕症治疗和癌症研究产生直接而重大的影响。