Development of adjunctive therapies directed at S. aureus amidases

针对金黄色葡萄球菌酰胺酶的辅助疗法的开发

• 批准号: 8800543
• 负责人: BLAISE R BOLES
• 金额: $ 18.43万
• 依托单位: UNIVERSITY OF IOWA
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-03-01 至 2016-02-29
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8800543
• 关键词: Address; Amidohydrolases; Animal Model; Antibiotic Resistance; Antibiotic Therapy; Antibiotics; Antimicrobial Resistance; Bacteria; Bacterial Infections; Biochemical; Biological Assay; Biology; Blood; Cell Wall; Cells; Chemicals; Cleaved cell; Communicable Diseases; Communities; Data; Development; Drug Formulations; Drug resistance; Endocarditis; Enzymes; Fluorescence Resonance Energy Transfer; Foundations; Frequencies; Funding; Fusidic Acid; Future; Generations; Genetic; Genomics; Genus staphylococcus; Goals; Gram-Positive Bacteria; Growth; Health; Health Care Costs; Human; Implant; In Vitro; Infection; Lead; Libraries; Life; Mediating; Medical Device; Michigan; Microbial Biofilms; Mission; Modeling; Morbidity - disease rate; Names; Organism; Osteomyelitis; Peptides; Peptidoglycan; Phase; Positioning Attribute; Prevalence; Research; Resistance; Resources; Staphylococcus aureus; Structure-Activity Relationship; Surface; Swimming; System; Testing; Therapeutic; Therapeutic Studies; Time; Tissues; Toxic effect; Translating; United States National Institutes of Health; Universities; Validation; Work; amidase; antimicrobial; chemotherapy; clinical application; crosslink; design; drug resistant bacteria; enzyme activity; experience; high throughput screening; improved; in vivo; in vivo Model; inhibitor/antagonist; member; methicillin resistant Staphylococcus aureus; mortality; mutant; novel; novel strategies; novel therapeutics; pathogen; prevent; screening; small molecule; therapeutic target

DESCRIPTION (provided by applicant): Resistance to antimicrobial chemotherapies is a major contributor to morbidity, mortality, and rising healthcare costs. The prevalence of drug-resistant pathogens against conventional antibiotics has been rising over the last several decades. Of great concern is methicillin-resistant Staphylococcus aureus (MRSA), which is rapidly diminishing the available treatment options for S. aureus infections. As drug resistances continue to emerge there is an urgent need to develop alternative therapeutic approaches such as the development of adjunctive therapies to potentiate the activity of existing antimicrobials. Recently we have discovered that amidase activity of cell wall modifying enzymes (named SsaA1 and SsaA2) mediates S. aureus biofilm resistance to the conventional antibiotic fusidic acid. That is, genetic inactivation of ssaA1 or ssaA2 results in sensitivity of biofilms to fusidic acid. This result suggests that small molecules capable of inhibiting SsaA amidase activity could be used as an adjunctive in conjunction with fusidic acid to effectively eliminate S. aureus biofilms. Mutants in ssaA1 also displayed reduced frequency of fusidic acid resistance emergence, suggesting that in addition to rendering biofilm bacteria sensitive to an antimicrobial, small molecule SsaA amidase inhibitors would also reduce the emergence of drug resistant bacteria. SsaA amidases are an ideal target for small molecule therapies because they are located on the outside of cells making them readily accessible and because humans lack peptidoglycan and the associated biosynthetic machinery (including SsaA amidase homologous). The primary goal of this R21 research is to identify chemical inhibitors of SsaA amidase activity and characterize these molecules for use as potential adjunctive therapeutics. To achieve the goal, we propose the following aims: (1) Identify chemical compounds that eliminate SsaA amidase activity via high throughput screening and (2) Elucidate the ability of SsaA chemical inhibitors to sensitize Staphylococcus biofilms to antimicrobial treatment in in vitro and in vivo models of biofilm development. During the next phase of research (R33), we plan on translating our basic findings for clinical applications by investigating chemical optimization of lead compounds, characterizing antimicrobial activity against other gram-positive pathogens, and developing formulation/delivery systems to be tested with in vivo animal models. The PI's experience in S. aureus biology and the strength of the University of Michigan's Center for Chemical Genomics uniquely position us to conduct this research and make profound discoveries.

描述（由申请人提供）：对抗菌化学疗法的抵抗是导致发病率，死亡率和医疗保健成本上升的主要因素。在过去的几十年中，针对常规抗生素的耐药病原体的流行一直在上升。值得关注的是金黄色葡萄球菌（MRSA），它正在迅速减少金黄色葡萄球菌感染的可用治疗选择。随着耐药性继续出现，迫切需要开发替代治疗方法，例如开发辅助疗法以增强现有抗菌剂的活性。最近，我们发现细胞壁修饰酶的酰胺酶活性（命名为SSAA1和SSAA2）介导了金黄色葡萄球菌生物膜耐药性，对常规的抗生素熔融酸。也就是说，SSAA1或SSAA2的遗传灭活会导致生物膜对熔融的敏感性 酸。该结果表明，能够抑制SSAA酰胺酶活性的小分子可以用作辅助性与梭酸一起有效消除金黄色葡萄球菌生物膜。 SSAA1中的突变体还显示出熔融酸耐药性的频率降低，这表明除了使对抗菌剂敏感的生物膜细菌外，小分子SSAA amidase抑制剂还将降低耐药细菌的出现。 SSAA酰胺酶是小分子疗法的理想靶标，因为它们位于细胞的外部，使其易于访问，并且因为人类缺乏肽聚糖和相关的生物合成机械（包括SSAA amidase酶同源物）。这项R21研究的主要目标是鉴定SSAA amidase活性的化学抑制剂，并将这些分子用作潜在的辅助治疗剂。为了实现目标，我们提出以下目的：（1）通过高吞吐量筛选来确定消除SSAA amidase活性的化学化合物，（2）阐明SSAA化学抑制剂敏感生物膜对葡萄球菌生物膜敏感的能力，可在体外和体内生物学模型中对抗伴侣治疗。在下一阶段的研究（R33）中，我们计划通过研究铅化合物的化学优化，表征针对其他革兰氏阳性病原体的抗菌活性，并开发用于体内动物模型测试的抗菌活性，并开发用于测试的配方/递送系统，从而转化临床应用的基本发现。 PI在金黄色葡萄球菌生物学方面的经验以及密歇根大学化学基因组学中心的力量独特地对我们进行了这项研究并进行了深刻的发现。