Imaging the Granzyme Mediated Host Immune Response to Viral and Bacterial Pathogens In Vivo Using Positron Emission Tomography

IF 4 2区医学 Q2 CHEMISTRY, MEDICINAL ACS Infectious Diseases Pub Date : 2024-05-31 DOI:10.1021/acsinfecdis.4c00114

Apurva Pandey, Shalini Chopra, Simon J. Cleary, Marina López-Álvarez, Fiona M. Quimby, Aryn A.A. Alanizi, Sasank Sakhamuri, Ningjing Zhang, Mark R. Looney, Charles S. Craik, David M. Wilson* and Michael J. Evans*,

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Abstract

Understanding how the host immune system engages complex pathogens is essential to developing therapeutic strategies to overcome their virulence. While granzymes are well understood to trigger apoptosis in infected host cells or bacteria, less is known about how the immune system mobilizes individual granzyme species in vivo to combat diverse pathogens. Toward the goal of studying individual granzyme function directly in vivo, we previously developed a new class of radiopharmaceuticals termed “restricted interaction peptides (RIPs)” that detect biochemically active endoproteases using positron emission tomography (PET). In this study, we showed that secreted granzyme B proteolysis in response to diverse viral and bacterial pathogens could be imaged with [⁶⁴Cu]Cu-GRIP B, a RIP that specifically targets granzyme B. Wild-type or germline granzyme B knockout mice were instilled intranasally with the A/PR/8/34 H1N1 influenza A strain to generate pneumonia, and granzyme B production within the lungs was measured using [⁶⁴Cu]Cu-GRIP B PET/CT. Murine myositis models of acute bacterial (E. coli, P. aeruginosa, K. pneumoniae, and L. monocytogenes) infection were also developed and imaged using [⁶⁴Cu]Cu-GRIP B. In all cases, the mice were studied in vivo using mPET/CT and ex vivo via tissue-harvesting, gamma counting, and immunohistochemistry. [⁶⁴Cu]Cu-GRIP B uptake was significantly higher in the lungs of wild-type mice that received A/PR/8/34 H1N1 influenza A strain compared to mice that received sham or granzyme B knockout mice that received either treatment. In wild-type mice, [⁶⁴Cu]Cu-GRIP B uptake was significantly higher in the infected triceps muscle versus normal muscle and the contralateral triceps inoculated with heat killed bacteria. In granzyme B knockout mice, [⁶⁴Cu]Cu-GRIP B uptake above the background was not observed in the infected triceps muscle. Interestingly, live L. monocytogenes did not induce detectable granzyme B on PET, despite prior in vitro data, suggesting a role for granzyme B in suppressing their pathogenicity. In summary, these data show that the granzyme response elicited by diverse human pathogens can be imaged using PET. These results and data generated via additional RIPs specific for other granzyme proteases will allow for a deeper mechanistic study analysis of their complex in vivo biology.

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利用正电子发射断层扫描成像格兰氏酶介导的宿主对病毒和细菌病原体的体内免疫反应。

了解宿主免疫系统如何与复杂的病原体打交道，对于制定克服病原体毒性的治疗策略至关重要。虽然人们对颗粒酶触发受感染宿主细胞或细菌凋亡的作用有了充分了解，但对免疫系统如何在体内调动单个颗粒酶种类来对抗各种病原体却知之甚少。为了实现在体内直接研究单个颗粒酶功能的目标，我们之前开发了一类新的放射性药物，称为 "受限相互作用肽（RIPs）"，它能利用正电子发射断层扫描（PET）检测生化活性内切蛋白酶。我们在这项研究中发现，用[64Cu]Cu-GRIP B（一种特异性靶向颗粒酶 B 的 RIP）可以对颗粒酶 B 在多种病毒和细菌病原体作用下分泌的蛋白水解进行成像。用 A/PR/8/34 H1N1 甲型流感病毒株向野生型或基因型颗粒酶 B 基因敲除的小鼠鼻腔内灌注病毒以产生肺炎，然后用[64Cu]Cu-GRIP B PET/CT 测量肺内颗粒酶 B 的产生情况。此外，还开发了急性细菌（大肠杆菌、绿脓杆菌、肺炎双球菌和单核细胞增生性酵母菌）感染的小鼠肌炎模型，并使用[64Cu]Cu-GRIP B 进行成像。与接受假治疗或接受颗粒酶 B 基因敲除治疗的小鼠相比，接受 A/PR/8/34 H1N1 甲型流感病毒株治疗的野生型小鼠肺部的[64Cu]Cu-GRIP B 摄取量明显更高。在野生型小鼠中，受感染的肱三头肌对正常肌肉和接种了热致死细菌的对侧肱三头肌的[64Cu]Cu-GRIP B摄取量明显较高。在粒酶 B 基因敲除小鼠中，受感染的肱三头肌中未观察到高于背景的[64Cu]Cu-GRIP B 摄取。有趣的是，尽管之前有体外数据，但活的单核细胞增生梭状芽孢杆菌并未在 PET 上诱导出可检测到的颗粒酶 B，这表明颗粒酶 B 在抑制其致病性方面发挥了作用。总之，这些数据表明，各种人类病原体引起的颗粒酶反应可以用 PET 进行成像。这些结果以及通过其他颗粒酶蛋白酶特异性 RIPs 生成的数据将有助于对它们复杂的体内生物学进行更深入的机理研究分析。

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来源期刊

ACS Infectious Diseases CHEMISTRY, MEDICINALINFECTIOUS DISEASES&nb-INFECTIOUS DISEASES

CiteScore

9.70

自引率

3.80%

发文量

213

期刊介绍： ACS Infectious Diseases will be the first journal to highlight chemistry and its role in this multidisciplinary and collaborative research area. The journal will cover a diverse array of topics including, but not limited to: * Discovery and development of new antimicrobial agents — identified through target- or phenotypic-based approaches as well as compounds that induce synergy with antimicrobials. * Characterization and validation of drug target or pathways — use of single target and genome-wide knockdown and knockouts, biochemical studies, structural biology, new technologies to facilitate characterization and prioritization of potential drug targets. * Mechanism of drug resistance — fundamental research that advances our understanding of resistance; strategies to prevent resistance. * Mechanisms of action — use of genetic, metabolomic, and activity- and affinity-based protein profiling to elucidate the mechanism of action of clinical and experimental antimicrobial agents. * Host-pathogen interactions — tools for studying host-pathogen interactions, cellular biochemistry of hosts and pathogens, and molecular interactions of pathogens with host microbiota. * Small molecule vaccine adjuvants for infectious disease. * Viral and bacterial biochemistry and molecular biology.