Use of a Perfused Rat Heart Model to Investigate Anthrax Lethal and Edema Toxins

使用灌注大鼠心脏模型研究炭疽致死毒素和水肿毒素

• 批准号: 8952898
• 负责人: Peter Eichacker
• 金额: --
• 依托单位: CLINICAL CENTER
• 依托单位国家: 美国
• 资助国家: 美国
• 起止时间: 至
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/8952898
• 关键词: Adenylate Cyclase; Animals; Anthrax disease; Antigens; Apoptosis; Blood Pressure; Blood Vessels; Blood gas; Canis familiaris; Cardiac; Cardiac Myosins; Cardiopulmonary; Creatinine; Cyclic AMP; Data; Depressed mood; Disease Outbreaks; Edema; Excision; Future; Genes; Health; Heart; Heart Contractilities; Heart Injuries; Heart Rate; Host Defense; Infection; Injury; Lead; Manuscripts; Measures; Methods; Mitochondria; Mitogen-Activated Protein Kinase Kinases; Modeling; Myocardial; Myosin Light Chains; Nitric Oxide; Pathogenesis; Pathway interactions; Patients; Peptide Hydrolases; Perfusion; Phosphotransferases; Preparation; Procedures; Production; Pump; Rattus; Reaction; Shock; Signal Pathway; Stress; Structure; System; Toxin; Troponin I; United States; anthrax lethal factor; cytokine; design; edema factor; in vivo; research study; response; time interval; uptake

Both LeTx and ETx toxins, contribute to shock with anthrax. Common to each toxin is a component called protective antigen (PA), which is necessary for cellular uptake of the toxic components; lethal factor (LF) for LeTx and edema factor (EF) for ETx. Both factors are capable of disrupting key steps in essential but very different intracellular signaling pathways. Lethal factor is a protease, which inhibits stress kinase pathways and has been shown to inhibit host defense and other responses necessary for the survival of the host. Emerging data also suggests that LF may have a direct depressant effect on mitochondrial function. Edema factor has adenyl cyclase activity and increases intracellular cAMP levels to very high levels. While edema factor is capable of depressing host defense, it may also have direct effects on myocardial and vascular function via its adenyl cyclase activity. Findings from studies we have now conducted in toxin challenged rat and canine models have raised several questions regarding the effects of LeTx and ETx. First, does LeTx decrease heart rate or the strength with which the heart pumps. Second, does LeTx initiate reactions that lead to later reductions in heart strength despite cessation of toxin administration? Third, does ETx increase heart rate directly? Fourth, does ETx produce reductions in the strength of the heart that the canine model was insensitive to detecting? The present study is designed to further investigate the effects of LeTx and ETx on myocardial function employing a re-circulating Langendorff perfused rat heart model. This model directly measures myocardial function in excised hearts that are allowed to continue to beat in an ex vivo system. The present study is being conducted in three parts. In the initial part procedures were developed to establish and determine the stability of the perfused rat heart model. The second part has assessed the direct effects of LeTx and ETx added alone or together to the perfusion circuit on the heart rate and contractility of hearts taken from normal animals. In the third part, now underway, we are assessing the heart rates and contractility of hearts taken from animals previously challenged with either LeTx or ETx alone or together. In this final part, prior to removal of hearts for perfusion, animals are undergoing in vivo cardiopulmonary measures performed including blood pressure, heart rate, cardiac echo and arterial blood gas measures. During perfused heart studies, in addition to cardiac functional measures, perfusate is collected at timed intervals to measure markers of cardiac injury (creatinine phosphokinase, myocardial troponin I, cardiac myosin light chain-1), nitric oxide, and cytokines. At the completion of perfusion, in some studies, hearts are fixed with gluteraldehyde for EM studies including assessment of mitochondrial number and structure or they are prepared for mitochondrial, MAPKK, cAMP, gene microarray, quantitative PCR, and apoptosis analysis. Experiments have been completed for this part and a manuscript is in preparation for submission.

LeTx和ETx毒素都能引起炭疽热休克。每种毒素都有一种称为保护性抗原（PA）的成分，这是细胞吸收有毒成分所必需的；LeTx为致死因子（LF）， ETx为水肿因子（EF）。这两种因素都能够破坏基本但非常不同的细胞内信号通路的关键步骤。致死因子是一种蛋白酶，它抑制应激激酶途径，并已被证明可以抑制宿主防御和宿主生存所必需的其他反应。新出现的数据也表明，LF可能对线粒体功能有直接的抑制作用。水肿因子具有腺苷环化酶活性，使细胞内cAMP水平升高到非常高的水平。水肿因子除了能够抑制宿主防御外，还可能通过其腺苷环化酶活性对心肌和血管功能产生直接影响。