Hedgehog Signaling in Development and Metabolism

发育和代谢中的刺猬信号传导

• 批准号: 10472508
• 负责人: Jianhang Jia
• 金额: $ 38.25万
• 依托单位: UNIVERSITY OF KENTUCKY
• 依托单位国家: 美国
• 财政年份: 2019
• 资助国家: 美国
• 起止时间: 2019-09-01 至 2024-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10472508
• 关键词: Adipose tissue; Basal cell carcinoma; Biochemical; Biological; Blood Circulation; Cell membrane; Cell surface; Cholesterol; Development; Drosophila genus; Drug resistance; Embryonic Development; Endocytosis; Erinaceidae; Event; Fat Body; Foundations; G-Protein-Coupled Receptors; Genes; Genetic; Genetic Transcription; Goals; Human; Insecta; Integral Membrane Protein; Investigation; Knowledge; Lipids; Lipolysis; Malignant Neoplasms; Mammals; Metabolic Control; Metabolic Diseases; Metabolism; Modeling; Mutation; Na(+)-K(+)-Exchanging ATPase; Obesity; Outcome; Pathway interactions; Pattern; Pattern Formation; Phosphorylation; Phosphotransferases; Play; Process; Protein Family; Proteins; Publishing; Regulation; Research; Role; Signal Pathway; Signal Transduction; Sumoylation Pathway; System; Ubiquitination; cancer type; cell growth; cholesterol biosynthesis; developmental disease; diagnostic tool; hedgehog signal transduction; human disease; insight; lipid biosynthesis; lipid metabolism; medulloblastoma; novel; novel therapeutic intervention; patched protein; programs; protein activation; protein expression; public health relevance; response; smoothened signaling pathway; tool

Abstract: Hedgehog (Hh) signaling plays critical roles in pattern formation and cell growth control and is also involved in metabolic control. Further, aberrant Hh signaling causes diverse types of cancers. Transduction of the Hh signal requires the G protein-coupled receptor (GPCR) family protein Smoothened (Smo) in both insects and mammals. While many components in the Hh pathway have been identified, how the Hh signal is transduced through the 12-span transmembrane protein Patched (Ptc) to Smo is still unclear. This team has discovered 1) that Smo undergoes phosphorylation by multiple kinases, which leads to Smo cell surface accumulation and signaling activity; 2) that sumoylation induced by Hh promotes Smo activation; and 3) that ubiquitination downregulates Smo cell surface accumulation by promoting Smo endocytosis. Results from these studies suggest that, in response to Hh stimulation, multiple steps occur in Smo regulation. However, despite significant progress, key questions persist regarding the mechanism controlling Smo protein expression and activation: 1) How is Smo transcription specifically regulated? 2) Whether and how does Hh regulate lipolysis? 3) How does cholesterol activate Smo? and 4) Whether and how is the sodium pump involved in Ptc and Smo regulation? Recent discoveries by this group that Smo transcription is specifically regulated in adipose tissue, that an alternative cholesterol biosynthesis pathway regulates Smo accumulation and activation, and that the sodium pump plays a positive role in activating Smo, likely by regulating cholesterol on the plasma membrane are critical foundations to answering those questions. The overarching goal of this research program is to understand how Hh signals are sensed and transmitted to control downstream biological events that ultimately govern cell growth and patterning. Drosophila fat body and oenocyte have emerged as attractive models to study lipid metabolism and circulation. Published and preliminary findings in these models have indicated that lipid accumulation is regulated by highly conserved signaling pathways, and that Hh signaling controls not only lipogenesis but also lipolysis by regulating specific genes. These studies provide new tools and hypotheses for investigating the mechanisms of Smo signaling and the role of Hh/Smo signaling in regulating lipid metabolism, which particular relevance to such cancers as basal cell carcinoma and medulloblastoma. The proposed five- year program of studies uses a combination of genetic and biochemical approaches to build on prior contributions and to transition to newly emergent avenues of inquiry. The knowledge gained from this study will provide novel insights into mechanisms surrounding Smo suppression by Ptc and activation by cholesterol. In addition, expected outcomes will provide novel insights into human developmental disorders and promote development of diagnostic tools and novel therapeutic approaches to oppose Smo drug resistance using metabolism as a platform to transform current concepts of Hh signaling in cancer, obesity, and metabolic diseases.

摘要： Hedgehog（Hh）信号传导在模式形成和细胞生长控制中起关键作用，并且还参与 代谢控制此外，异常的Hh信号传导导致不同类型的癌症。Hh的转导 信号需要昆虫和哺乳动物中的G蛋白偶联受体（GPCR）家族蛋白Smoothened（Smo） 哺乳动物虽然Hh通路中的许多组分已被鉴定，但Hh信号如何转导 通过12跨膜蛋白Patched（Ptc）到Smo的作用尚不清楚。该团队发现1） Smo通过多种激酶进行磷酸化，这导致Smo细胞表面积累， 信号活性; 2）由Hh诱导的sumo化促进Smo活化; 3）泛素化 通过促进Smo内吞作用下调Smo细胞表面积累。这些研究的结果 提示，在响应Hh刺激时，Smo调节中发生多个步骤。但尽管 虽然取得了重大进展，但关于控制Smo蛋白表达的机制仍存在关键问题， 激活：1）Smo转录是如何特异性调节的？2)Hh是否以及如何调节脂解？ 3)胆固醇如何激活Smo？钠泵是否及如何参与Ptc和Smo 监管？该小组最近发现Smo转录在脂肪组织中受到特异性调节， 胆固醇生物合成途径调节Smo的积累和激活， 钠泵在激活Smo中起积极作用，可能是通过调节质膜上的胆固醇 是回答这些问题的重要基础。这项研究计划的首要目标是 了解Hh信号是如何被感知和传递的，以控制下游生物事件， 控制着细胞的生长和模式。果蝇的脂肪体和卵母细胞已经成为研究 研究脂质代谢和循环。在这些模型中发表的和初步的研究结果表明， 脂质的积累是由高度保守的信号通路调节的，Hh信号通路不仅控制着脂质的积累， 脂肪生成以及通过调节特定基因的脂解作用。这些研究提供了新的工具和假设， 研究Smo信号转导机制和Hh/Smo信号转导在调节脂质代谢中的作用， 这与基底细胞癌和髓母细胞瘤等癌症特别相关。建议的五个- 一个为期一年的研究计划使用遗传和生物化学方法的组合，以建立在以前的基础上， 贡献和过渡到新出现的调查途径。从这项研究中获得的知识将 提供了新的见解Smo抑制Ptc和激活胆固醇周围的机制。在 此外，预期结果将为人类发育障碍提供新的见解，并促进 开发诊断工具和新的治疗方法，以对抗Smo耐药性， 代谢作为一个平台，以改变目前的概念Hh信号在癌症，肥胖和代谢 疾病