CDC2-RELATED KINASES AND THE CONTROL OF CELL CYCLE

CDC2 相关激酶和细胞周期的控制

• 批准号: 2186135
• 负责人: EDWARD E HARLOW
• 金额: $ 25.78万
• 依托单位: MASSACHUSETTS GENERAL HOSPITAL
• 依托单位国家: 美国
• 财政年份: 1992
• 资助国家: 美国
• 起止时间: 1992-09-30 至 1996-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/2186135
• 关键词: cell cycle; enzyme activity; enzyme substrate; gene expression; immunochemistry; molecular cloning; monoclonal antibody; phosphorylation; polymerase chain reaction; protein kinase; protein purification; protein structure function; reagent /indicator

A cell's decision to divide ultimately rests on its ability to respond correctly to environmental cues. Extracellular signals are interpreted by the cell through a complex system of positive and negative signalling pathways that connect to the machinery that controls cell division. When these regulatory pathways behave correctly, normal controlled cell division is possible. However, when these systems fail as they do in human cancer, uncontrolled division can lead to disastrous results. Cell division is controlled by a carefully orchestrated cycle of events. Perhaps the most intriguing finding of cell cycle research is that all eukaryotic cells appear to use a similar mechanism to regulate progression through important control points of the cell cycle. This is most evident when comparing the transition of cells from the G2 phase into mitosis. Cells regulate this transition by activating a kinase complex, composed of a catalytic subunit, cdc2, and regulatory subunit, cyclin B. The properties of this enzyme complex now form the paradigm of cell cycle regulation. All eukaryotic cells that have been studied contain homologs for cdc2 and cyclin B, and they regulate entry into mitosis in similar ways. It is now clear that other key regulatory points in cell cycle progression are controlled by interesting variations of this pattern. For example, in yeast the transition from G1 into S phase is controlled by the same catalytic subunit but in association with other cyclins known as CLN's. In mammalian cells this pattern is even more complicated, as eight different cyclins have now been discovered. In general, little is known about their correct catalytic partners or about their regulation. Recently, we have identified eight novel human kinases, six of which show greater than 50% amino acid identity with cdc2. Although the analysis of these kinases is at an early stage, it is already clear that some of these kinases have the hallmarks of cell-cycle-regulating kinases; they associate with cyclins and display temporally regulated kinase activity. This grant proposes to investigate the function of these new kinases in the control of mammalian cell cycle progression. Our first goal will be to complete the initial characterization of these kinases. This work is currently underway and encompasses the physical and immunochemical properties of the kinase polypeptides, the timing of their kinase activation, and their patterns of expression. Initial studies show that some of these kinases are closely related to the cdc2 kinase, and these proteins will be come the focus of more detailed cell cycle studies. We will determine whether these kinases are essential for cell cycle progression, how their kinase activities are regulated, what substrates they phosphorylate, and the structural features that distinguish their functional differences from cdc2. The kinases that are more distantly related to cdc2 are the focus of our last goal. Here we will examine the significance of these different properties, paying particular attention to features that are not characteristic of cdc2 or its closely related family members.

细胞分裂的决定最终取决于它的反应能力 对环境线索的反应 细胞外信号由 细胞通过一个复杂的正负信号系统 连接到控制细胞分裂的机制的通路。 当 这些调节途径正确地运作，正常控制细胞分裂， 是可能. 然而，当这些系统像在人类癌症中一样失效时， 不受控制的分裂会导致灾难性的后果。 细胞分裂是由一个精心安排的事件循环控制的。 也许细胞周期研究中最有趣的发现是， 真核细胞似乎使用类似的机制来调节进展， 通过细胞周期的重要控制点。 最明显的例子 当比较细胞从G2期到有丝分裂的转变时。 细胞通过激活激酶复合物来调节这种转变， 一个催化亚基cdc 2和一个调节亚基cyclin B。 的 这种酶复合物的性质现在形成了细胞周期的范例 调控 所有研究过的真核细胞都含有同源物 对于cdc 2和细胞周期蛋白B，它们以类似的方式调节进入有丝分裂。 的方式 现在很清楚，细胞周期中的其他关键调控点 进展是由这种模式的有趣变化控制的。 为 例如，在酵母中，从G1期到S期的转变是由 相同的催化亚基，但与其他细胞周期蛋白， CLN的。 在哺乳动物细胞中，这种模式甚至更复杂， 现在已经发现了不同的细胞周期蛋白。 总的来说， 关于它们正确的催化伙伴或它们的调节。 最近，我们发现了八种新的人类激酶，其中六种显示出 与CDC 2具有大于50%的氨基酸同一性。 虽然分析 这些激酶处于早期阶段，已经很清楚，其中一些激酶 激酶具有细胞周期调节激酶的特征;它们与 与细胞周期蛋白和显示时间调节激酶活性。 这项资助计划研究这些新激酶在细胞中的功能， 控制哺乳动物细胞周期进程。 我们的第一个目标是 完成这些激酶的初步鉴定。 这项工作是 目前正在进行中，包括物理和免疫化学 激酶多肽的性质、它们的激酶 激活及其表达模式。 初步研究表明， 这些激酶中的一些与CDC 2激酶密切相关，并且这些 蛋白质将成为更详细的细胞周期研究的焦点。 我们 将确定这些激酶是否对细胞周期至关重要 进展，它们的激酶活性是如何调节的， 它们磷酸化，以及区分它们的结构特征， 与CDC 2的功能差异。 距离较远的激酶 与cdc 2相关的是我们最后一个目标的重点。 在这里，我们将检查 这些不同属性的重要性，特别注意 不是CDC 2或其密切相关家族特征的特征 成员