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Repression via Facultative Heterochomatin.

通过兼性异染色质进行抑制。

基本信息

批准号：
8044357
负责人：
DANNY REINBERG
金额：
$ 33.03万
依托单位：
NEW YORK UNIVERSITY SCHOOL OF MEDICINE
依托单位国家：
美国
项目类别：
财政年份：
2002
资助国家：
美国
起止时间：
2002-01-01 至 2014-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8044357
关键词：
Accounting Affect Antibodies Architecture Binding Biochemical Catalysis Cell Cycle Cell Cycle Progression Cell Cycle Proteins Cell Differentiation process Cell Lineage Cell Nucleus Cell division Cell physiology Cells Chromatin Chromatin Structure Cleaved cell Complex DLEC1 gene DNA Binding DNA Damage DNA Sequence DNA biosynthesis Degradation Pathway Detection Deubiquitinating Enzyme Development Disease EZH2 gene Electron Microscopy Enzymes Epigenetic Process Family Family member Fluorescence Microscopy Functional RNA Gene Expression Gene Targeting Genes Genetic Transcription Genome Goals Heterochromatin Histone H3 Histones Homologous Gene In Vitro Label Ligase Link Lysine Maintenance Malignant Neoplasms Malignant neoplasm of prostate Mass Spectrum Analysis Methylation Methyltransferase Mitochondria Modification Molecular Mus Nuclear Nucleosomes Organ Organism Pattern Phase Phosphorylation Phosphorylation Site Polycomb Polyubiquitin Post-Translational Protein Processing Post-Translational Regulation Process Property Proteasome Inhibitor Protein Family Proteins Quantum Dots Reader Regulation Reporting Repression Resolution Role Signal Transduction Sister Site Specificity Spermatogenesis Staging Stress Structure System Tail Testing Testis Tissues cancer cell cancer cell differentiation cell type embryonic stem cell fascinate gel mobility shift assay gene repression histone methyltransferase in vivo indexing innovation member metaplastic cell transformation mouse model novel particle protein complex protein degradation reconstitution response sperm cell tumor progression ubiquitin-protein ligase

项目摘要

DESCRIPTION (provided by applicant): The complexity of multi-cellular organisms characterized by cell specialization and sophisticated tissue and organ architecture is possible because of an efficient indexing system that keeps track of which sections of the genome are active or repressed, according to cell type and developmental phase. This "epigenetic" information (independent of DNA sequence) not only needs to be accurately established, but must also be transmitted to the cell's progeny. This must be achieved through a number of molecular mechanisms, many of which impact the structure of chromatin, particularly histones. Key to cell identity is the establishment and maintenance of "facultative heterochromatin", i.e. the silencing of specific genes in certain cell lineages through the formation of chromatin structure(s) repressive to transcription. The goal of this proposal is to expand our previous studies on the molecular mechanisms underlying facultative heterochromatin. How is selectivity achieved? What chromatin structures contain epigenetic information? How is this information transmitted through cell division? We will answer these and other questions through traditional and innovative biochemical approaches. In aim 1, we will expand our studies on PRC2, a central chromatin regulator on which we have accumulated much molecular information in the last years. We will study further: the function of EZH1, an EZH2 homolog with less pronounced methyltransferase activity; the effects of optional PRC2 complex subunits in cell differentiation and cancer; and the role of two novel EZH2 phosphorylation sites on PRC2 activity, chromatin localization, and interaction with non-coding RNAs (ncRNAs). In aim 2, we will employ TIRF microscopy and state-of-the-art mass spectrometry to determine whether sister histones within the same nucleosome carry any symmetrical post-translational modification, which would be strong candidates for "true" epigenetic marks as they may be equally segregated upon DNA replication. In aim 3, we will expand our studies on MBT proteins, an understudied family of chromatin binders; in particular we will investigate the biochemical and cellular function of SFMBTs and SCMH1/L2, which contain MBT repeats and were genetically classified as Polycomb group genes. The role of Pr-SET7 in preserving chromatin structure, protecting from or signaling DNA damage, its interaction with PCNA and its interaction with the cognate histone reader, L3MBTL1, will be investigated in aim 4, as well as the potential for this interaction to transmit epigenetic information. In aim 5, we will continue and expand our studies on SirT3, a fascinating Sirtuin with a dual role in mitochondrial function and regulation of nuclear transcription. We will explore this connection, as well as post-translational modifications and interactors of SirT3. PUBLIC HEALTH RELEVANCE: A key to development of multi-cellular organisms is the maintenance of distinct cell identities resulting from different patterns of gene expression; cells keep track of these by assembling unused parts of the genome in a repressive structure called "heterochromatin". When this process is compromised, cells can acquire a new identity, often transforming into cancer cells. The aim of this proposal is to better understand the molecular mechanisms involved in this process, and their role in disease such as cancer.

描述（由申请人提供）：由于有效的索引系统可以根据细胞类型和发育阶段跟踪基因组的哪些部分是活跃的或受抑制的，因此以细胞特化和复杂的组织和器官结构为特征的多细胞生物体的复杂性是可能的。这种“表观遗传”信息（独立于DNA序列）不仅需要准确地建立，而且还必须传递给细胞的后代。这必须通过许多分子机制来实现，其中许多机制影响染色质的结构，特别是组蛋白。细胞身份的关键是建立和维持“兼性异染色质”，即通过形成抑制转录的染色质结构来沉默某些细胞谱系中的特定基因。这个建议的目的是扩大我们以前的研究基础的分子机制兼性异染色质。如何实现选择性？哪些染色质结构包含表观遗传信息？这些信息是如何通过细胞分裂传递的？我们将通过传统的和创新的生物化学方法来回答这些和其他问题。在目标1中，我们将扩大我们对PRC 2的研究，PRC 2是一个中心染色质调节因子，我们在过去几年中积累了大量的分子信息。我们将进一步研究：EZH 1的功能，EZH 2同源物具有不太明显的甲基转移酶活性;可选的PRC 2复合亚基在细胞分化和癌症中的作用;以及两个新的EZH 2磷酸化位点对PRC 2活性，染色质定位和与非编码RNA（ncRNA）相互作用的作用。在目标2中，我们将采用TIRF显微镜和最先进的质谱法来确定同一核小体内的姐妹组蛋白是否携带任何对称的翻译后修饰，这将是“真正的”表观遗传标记的强有力的候选者，因为它们在DNA复制时可能是平等分离的。在目标3中，我们将扩大我们对MBT蛋白的研究，这是一个研究不足的染色质结合剂家族;特别是我们将研究SFMBTs和SCMH 1/L2的生化和细胞功能，它们含有MBT重复序列，在遗传上被归类为Polycomb组基因。Pr-SET 7在保留染色质结构、保护免受DNA损伤或发出DNA损伤信号、其与PCNA的相互作用及其与同源组蛋白阅读器L3 MBTL 1的相互作用中的作用将在目的4中研究，以及这种相互作用传递表观遗传信息的潜力。在目标5中，我们将继续并扩大我们对SirT 3的研究，这是一种迷人的Sirtuin，在线粒体功能和核转录调控中具有双重作用。我们将探讨这种联系，以及SirT 3的翻译后修饰和相互作用。公共卫生相关性：多细胞生物体发育的一个关键是维持不同的细胞身份，这是由不同的基因表达模式造成的;细胞通过将基因组中未使用的部分组装成一种称为“异染色质”的抑制性结构来跟踪这些特征。当这个过程受到损害时，细胞可以获得新的身份，通常转化为癌细胞。该提案的目的是更好地了解参与这一过程的分子机制，以及它们在癌症等疾病中的作用。