STRUCTURE/FUNCTION OF CARBOXYPEPTIDASE D

羧肽酶 D 的结构/功能

• 批准号: 6381275
• 负责人: LLOYD D FRICKER
• 金额: $ 22.75万
• 依托单位: ALBERT EINSTEIN COLLEGE OF MEDICINE
• 依托单位国家: 美国
• 财政年份: 1996
• 资助国家: 美国
• 起止时间: 1996-05-15 至 2003-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6381275
• 关键词: antisense nucleic acid; carboxypeptidase; cell line; chemical cleavage; enzyme activity; enzyme biosynthesis; enzyme mechanism; enzyme substrate; isozymes; laboratory rabbit; mass spectrometry; neurohormones; neuropeptides; peptide hormone biosynthesis; posttranslational modifications; proinsulin; protease inhibitor; protein purification; protein sequence; protein structure function; protein transport; secretory protein; western blottings

Many neuroendocrine peptides and proteins are produced from precursors by a series of endopeptidase and carboxypeptidase reactions. Carboxypeptidase E (CPE) was initially thought to be the only carboxypeptidase required for the generation of most neuroendocrine peptides. Recently we found that fat/fat mice lack CPE activity due to a point mutation in the coding region of the gene. These mice are overweight, and males are hyperglycemic. Although peptide processing by the carboxypeptidase step is reduced in these mice, it is not eliminated despite the complete absence of functional CPE. In a search for novel enzymes with CPE-like properties, we recently discovered carboxypeptidase D (CPD). Based on our studies over the past three years, we hypothesize that CPD contributes to the processing of neuroendocrine peptides as well as proteins that transit the secretory pathway. In the present application, we will continue to test this hypothesis, as well as to explore the possibility that CPD performs additional functions in the cell. In Specific Aim 1, we will compare the enzymatic properties of the three carboxypeptidase-like domains of CPD. Since the third carboxypeptidase- like domain of CPD does not appear to be enzymatically active, we will explore other potential functions for this domain. In Aim 2, we will examine the molecular basis for the forms of CPD found in the cell, and in various tissues. Previously, we have found evidence for multiple forms of CPD. In Aim 3, we will address the physiological function(s) of CPD by overexpressing this enzyme in cell lines that are deficient in CPE, and then testing whether elevated CPD can further compensate for the deficiency of CPE. In addition, we will use various strategies to reduce levels of CPD (inhibitors, antisense RNA) in cultured cells and then examine the effect on peptide/protein processing and sorting. Together, this concerted approach will provide important information regarding the role of CPD in the production of neuroendocrine peptides.

许多神经内分泌肽和蛋白质由前体通过一系列内肽酶和羧肽酶反应产生。羧肽酶E（CPE）最初被认为是产生大多数神经内分泌肽所需的唯一羧肽酶。 最近，我们发现，脂肪/脂肪小鼠缺乏CPE活动，由于在该基因的编码区的点突变。 这些小鼠超重，雄性高血糖。 尽管在这些小鼠中通过羧肽酶步骤的肽加工减少，但尽管完全不存在功能性CPE，但其并未被消除。 在寻找具有CPE样性质的新型酶的过程中，我们最近发现了羧肽酶D（CPD）。 基于我们过去三年的研究，我们假设CPD有助于神经内分泌肽以及转运分泌途径的蛋白质的加工。 在本申请中，我们将继续测试该假设，以及探索CPD在细胞中执行额外功能的可能性。在具体目标1中，我们将比较CPD的三个羧肽酶样结构域的酶性质。由于CPD的第三个羧肽酶样结构域似乎没有酶活性，我们将探索该结构域的其他潜在功能。 在目标2中，我们将研究在细胞和各种组织中发现的CPD形式的分子基础。在目标3中，我们将通过在CPE缺陷的细胞系中过表达这种酶来解决CPD的生理功能，然后测试CPD升高是否可以进一步弥补CPE的缺陷。 此外，我们将使用各种策略来降低培养细胞中CPD（抑制剂，反义RNA）的水平，然后检查对肽/蛋白质加工和分选的影响。总之，这种协调一致的方法将提供有关CPD在神经内分泌肽生产中的作用的重要信息。