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Notch signaling regulates pituitary gland organogenesis

Notch信号调节垂体器官发生

基本信息

批准号：
7176655
负责人：
LORI T RAETZMAN
金额：
$ 27.55万
依托单位：
UNIVERSITY OF ILLINOIS AT URBANA-CHAMPAIGN
依托单位国家：
美国
项目类别：
财政年份：
2007
资助国家：
美国
起止时间：
2007-02-01 至 2012-01-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7176655
关键词：
Address Affect Alagille Syndrome Alleles Animals Anterior Pituitary Gland CADASIL Cardiovascular system Cell Differentiation process Cell Nucleus Cell Proliferation Cells Clinical Complement Development Disease Dorsal Embryo Endocrine Enterobacteria phage P1 Cre recombinase Event Failure Family member Fertility Gene Activation Gene Expression Gene Targeting Genes Genetic Growth Health Hormones Human Knock-out Knockout Mice Lead Ligands Maintenance Metabolism Mus Mutant Strains Mice Mutation Notch Signaling Pathway Organ Organogenesis Pathway interactions Pattern Pituitary Gland Pituitary Hormones Pituitary Hypoplasia Play Proteins Research Personnel Reverse Transcriptase Polymerase Chain Reaction Role Screening procedure Sexual Maturation Signal Transduction Somatotropin Stem cells System Tissues Transcription Coactivator Transcription Repressor/Corepressor Transgenic Organisms Undifferentiated Vertebral column base cell type cofactor homeodomain hormone deficiency insight leukemia loris loss of function mRNA Expression member mutant notch protein notch-2 protein novel null mutation p27 Cell Cycle Protein p27 Enzyme Inhibitor precursor cell prenatal programs promoter receptor receptor expression transcription factor tumorigenesis

项目摘要

DESCRIPTION (provided by applicant): Formation of the pituitary gland relies on the expression of extrinsic factors produced by the surrounding tissue and transcription factors intrinsic to the pituitary. These factors dictate the specification and proliferation of the 5 hormone producing cell types of the anterior pituitary gland. Developmental failure of the pituitary gland has serious consequences for human health. Most significantly, the disease multiple pituitary hormone deficiency (MPHD), results in absence of growth hormone producing cells, with at least one other hormone being affected. The clinical manifestations of MPHD include growth insufficiency and delayed sexual maturation. Although most cases of MPHD are due to unknown causes, loss of function of the Prop1df gene is the most commonly identified cause of MPHD. Propl is a paired like homeodomain transcription factor expressed exclusively in the developing pituitary. A mutation in this gene also leads to a loss of three pituitary cell types, somatotropes, thyrotropes, and lactotropes, in the Ames dwarf mouse (Prop1 df). We demonstrated that the cell loss in Prop1 mutant mice correlates with alterations in pattern or level of Notch gene expression. Notch2 protein is absent in these mutants, indicating that Notch2 is an effecter of Prop1 and may be involved in the emergence of terminally differentiated cell types during pituitary development. The Notch signaling pathway is an evolutionary conserved mechanism that controls cellular proliferation and differentiation in a broad spectrum of developmental systems. In humans, null mutations in Notch receptors would likely lead to prenatal lethality. However, mutations in Notch family members that subtly reduce or enhance its activity can disrupt the development of the spine and circulatory system and cause diseases including leukemia, Alagille syndrome and CADASIL. My recent studies have demonstrated that Notch receptors, ligands (Delta and Jagged), and immediate downstream transcriptional targets (Hes) are present in the developing pituitary, but their function in this system is unknown. The proposed studies will determine if Notch signaling is necessary and sufficient for pituitary cell specification using transgenic and knock-out mice to modulate Notch receptor activity. In addition, the specific role of the Notch pathway gene Hes1, a transcriptional repressor, will be defined through gain and loss of function analysis. Finally, novel downstream targets of Notch activation in the pituitary will be defined by screening the candidates Mash1 and p27. These studies will provide a greater understanding of how the pituitary gland develops to produce hormones that affect growth, fertility and metabolism. They may also reveal genetic causes of congenital pituitary hormone deficiency and pituitary tumorigenesis and offer novel insight into the function of Notch signaling in endocrine cell differentiation.

描述（由申请人提供）：垂体的形成依赖于周围组织产生的外源性因子和垂体固有的转录因子的表达。这些因素决定了垂体前叶的5种激素产生细胞类型的特异性和增殖。脑下垂体的发育障碍对人类健康具有严重的后果。最重要的是，疾病多垂体激素缺乏症（MPHD），导致缺乏生长激素产生细胞，至少有一种其他激素受到影响。MPHD的临床表现包括生长不足和性成熟延迟。虽然大多数MPHD病例是由于未知的原因，但Prop1df基因的功能丧失是MPHD最常见的原因。Propl是一种成对的同源结构域转录因子，只在发育中的垂体中表达。该基因的突变也导致艾姆斯侏儒小鼠（Prop 1 df）中三种垂体细胞类型（促生长细胞、促甲状腺细胞和促乳细胞）的丢失。我们证明Prop1突变小鼠的细胞丢失与Notch基因表达模式或水平的改变相关。Notch2蛋白在这些突变体中不存在，表明Notch2是Prop 1的效应子，并且可能参与垂体发育期间终末分化细胞类型的出现。Notch信号通路是一种进化上保守的机制，在广泛的发育系统中控制细胞增殖和分化。在人类中，Notch受体的无效突变可能导致产前致死。然而，Notch家族成员的突变会微妙地降低或增强其活性，从而破坏脊柱和循环系统的发育，并导致包括白血病，Alagille综合征和CADASIL在内的疾病。我最近的研究表明，Notch受体，配体（Delta和Jagged）和直接下游转录靶点（Hes）存在于发育中的垂体中，但它们在该系统中的功能尚不清楚。拟议的研究将确定Notch信号传导是否是必要的和足够的垂体细胞规格使用转基因和敲除小鼠调节Notch受体活性。此外，Notch途径基因Hes1（一种转录抑制因子）的具体作用将通过功能分析的获得和丧失来确定。最后，将通过筛选候选Mash1和p27来定义垂体中Notch激活的新下游靶点。这些研究将提供一个更好的了解脑垂体如何发展产生激素，影响生长，生育和新陈代谢。它们还可能揭示先天性垂体激素缺乏症和垂体肿瘤发生的遗传原因，并为Notch信号在内分泌细胞分化中的功能提供新的见解。