Function and Inhibition of Plasmodium Lipid Decarboxylases

疟原虫脂质脱羧酶的功能和抑制

• 批准号: 8879955
• 负责人: CHOUKRI BEN MAMOUN
• 金额: $ 40.97万
• 依托单位: YALE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-07-01 至 2016-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8879955
• 关键词: 1,2-diacylglycerol; Affect; Amino Acids; Ammonium Compounds; Anabolism; Antimalarials; Applications Grants; Biochemical; Biochemical Genetics; Biological Assay; CDP ethanolamine; Carboxy-Lyases; Catabolism; Cells; Cessation of life; Codon Nucleotides; Complement; Complementary DNA; Data; Daughter; Decarboxylation; Development; Diglycerides; Disease; Drug Targeting; Enzyme Gene; Enzymes; Erythrocytes; Ethanolamines; Eukaryota; Fatty Acids; Fostering; Genes; Genetic; Genetic Screening; Genetic study; Genome; Genomics; Globin; Growth; Hemoglobin; Homologous Gene; Human; Inhibitory Concentration 50; Label; Lecithin; Libraries; Life Cycle Stages; Lipids; Malaria; Membrane; Metabolic; Names; Organism; Parasites; Pathway interactions; Phosphatidylethanolamine; Phosphatidylserines; Phospholipid Metabolism; Phospholipids; Phosphotransferases; Physiological; Plants; Plasmodium; Plasmodium falciparum; Plasmodium knowlesi; Play; Process; Production; Property; Proteins; Reaction; Research; Role; Serine; Signal Transduction; System; Work; Yeasts; cDNA Library; combat; design; drug sensitivity; enzyme activity; expression vector; genetic analysis; genetic approach; inhibitor/antagonist; insight; killings; lipid metabolism; macromolecule; metabolic abnormality assessment; mutant; novel; novel therapeutics; promoter; reverse genetics; small molecule libraries

DESCRIPTION (provided by applicant): During its life cycle within human erythrocytes, Plasmodium falciparum undergoes major developmental and metabolic changes and multiplies to produce up to 36 new daughter parasites. This rapid multiplication requires an active synthesis of structural and signaling lipids important for many essential parasite functions such as the production of new membranes following parasite multiplication, and the synthesis of diacylglycerol for activation of parasite kinases, to name only a few. The metabolic machineries that govern the synthesis of these macromolecules are fueled by precursors such as serine, ethanolamine and fatty acids scavenged from the host. These machineries have long been regarded as excellent targets for the development of novel antimalarial drugs. To date only a few of these machineries have been thoroughly characterized in Plasmodium parasites and pharmacological studies targeting some of them have successfully resulted in the production of highly potent antimalarial drugs. Serine obtained from the host serves as the primary precursor for the synthesis of the major phospholipids phosphatidylcholine and phosphatidylethanolamine. Serine is decarboxylated by a parasite specific serine decarboxylase (PfSD) to form ethanolamine, which is subsequently used as a precursor for the synthesis of both phosphatidylcholine and phosphatidylethanolamine. Serine is also incorporated into phosphatidylserine, which serves as an alternate precursor for the synthesis of phosphatidylethanolamine, via a reaction catalyzed by a parasite phosphatidylserine decarboxylase (PfPSD). Because of their predicted essential functions, PfSD and PfPSD are regarded as potential targets for the development of new antimalarial drugs. Moreover, human cells do not contain SD enzymes thereby making SD a species-specific vulnerability of the parasite. Using a Plasmodium cDNA library constructed in a yeast expression vector we have successfully complemented a yeast mutant lacking PSD activity and identified the malarial PSD gene. Available data suggest that the malarial PSD plays an essential role in the intraerythrocytic life cycle of the parasite and is an excellent target for the development of nove antimalarial drugs. The malarial SD gene, however, remains to be identified. The overall objectives of this grant application are to complete the biochemical and genetic characterization of the PfPSD gene in P. falciparum (Aim 1); to take advantage of the newly developed and successful functional complementation assay using yeast as a surrogate system to screen a library of antimalarial active compounds to search for inhibitors of PfPSD activity (Aim 2); and employ genetic and biochemical analyses to identify the malarial serine decarboxylase gene and characterize its importance in P. falciparum intraerythrocytic development and survival (Aim 3). These studies hold the potential for elucidating the importance of PfSD and PfPSD specifically, and phospholipid metabolism in general during P. falciparum development as well as fostering the design of specific inhibitors. This work will provide new therapeutic insights for combating a disease that affects 250 million people worldwide and causes 1 million deaths each year.

描述（由申请人提供）：恶性疟原虫在人类红细胞内的生命周期中，经历了主要的发育和代谢变化，并繁殖产生多达36个新的子代寄生虫。这种快速增殖需要结构脂和信号脂的活跃合成，这对寄生虫的许多基本功能至关重要，例如寄生虫增殖后新膜的产生，以及用于激活寄生虫激酶的二酰基甘油的合成，仅举几例。控制这些大分子合成的代谢机制是由从宿主清除的丝氨酸、乙醇胺和脂肪酸等前体提供燃料的。这些机制长期以来被认为是开发新型抗疟疾药物的良好靶点。迄今为止，这些机制中只有少数在疟原虫中得到了彻底的表征，针对其中一些的药理学研究已成功地产生了强效抗疟药物。从宿主获得的丝氨酸是合成主要磷脂磷脂酰胆碱和磷脂酰乙醇胺的主要前体。丝氨酸被寄生虫特异性丝氨酸脱羧酶（PfSD）脱羧，形成乙醇胺，乙醇胺随后被用作合成磷脂酰胆碱和磷脂酰乙醇胺的前体。丝氨酸也被纳入磷脂酰丝氨酸中，磷脂酰丝氨酸作为合成磷脂酰乙醇胺的替代前体，通过寄生虫磷脂酰丝氨酸脱羧酶（PfPSD）催化的反应。由于其预测的基本功能，PfSD和PfSD被认为是开发新的抗疟药物的潜在靶点。此外，人类细胞不含SD酶，因此使SD成为寄生虫的物种特异性易感性。利用在酵母表达载体上构建的疟原虫cDNA文库，我们成功地补充了缺乏PSD活性的酵母突变体，并鉴定了疟疾PSD基因。现有数据表明，疟原虫PSD在疟原虫的红细胞内生命周期中发挥着重要作用，是开发新型抗疟药物的良好靶点。然而，疟疾SD基因仍有待鉴定。这项拨款申请的总体目标是完成恶性疟原虫PfPSD基因的生化和遗传特征（目标1）；利用新开发和成功的功能互补试验，利用酵母作为替代系统筛选抗疟活性化合物库，寻找PfPSD活性抑制剂（Aim 2）；并采用遗传和生化分析鉴定疟疾丝氨酸脱羧酶基因，并表征其在恶性疟原虫红细胞发育和生存中的重要性（目的3）。这些研究有可能阐明PfSD和PfSD特异性的重要性，以及恶性疟原虫发展过程中磷脂代谢的总体重要性，并促进特异性抑制剂的设计。这项工作将提供新的治疗见解