JoVE Journal > Immunology and Infection
Summary
Abstract
Introduction
Protocol
Results
Discussion
Disclosures
Acknowledgements
Materials
References
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면역학 및 감염병학

慢性沙门氏菌感染诱发肠纤维化

Published: September 22, 2019
doi:
10.3791/60068
, , ,
1The Biomedical Research Centre,University of British Columbia

Summary

该协议描述了沙门氏菌驱动的肠道纤维化的小鼠模型,类似于克罗恩病的关键病理特征,包括跨体炎症和纤维化。该方法可用于评估使用维持在C57Bl/6遗传背景的突变小鼠改变纤维化结果的宿主因素。

Abstract

组织纤维化的特点是细胞外基质(如胶原蛋白)的病理积累是持续炎症和失调修复的结果。在炎症性肠病(IBD)中,纤维化导致复发性严格性形成,除了手术切除,没有其他有效的治疗方法。由于其发病较晚,驱动纤维化的过程较少研究,而且在很大程度上是未知的。因此,纤维化并发症是IBD的一大挑战。在本议定书中,描述了肠道纤维化的强健体内模型,其中对C57Bl/6小鼠进行链霉素预处理,然后口服带有疫苗级沙门氏菌的口角,即阿罗阿突变体导致持久性病原体殖民化和纤维化。准备S.解释用于接种、定量囊肿和脾脏中的病原体负荷以及评估肠道组织中胶原蛋白沉积的Typhimurium_AroA。这种实验性疾病模型可用于检查增强或加剧CD样肠道纤维化的宿主因素。

Introduction

溃疡性结肠炎(UC)和克罗恩病(CD)是IBD的两种主要形式,并被定性为胃肠道1、2的慢性和复发性炎症性疾病。这些疾病对患者的生活质量有重大影响。IBD的症状包括腹痛,腹泻,恶心,体重减轻,发烧和疲劳3。最近的研究已经确定了导致疾病发病机制的遗传和环境因素;据认为,这些危险因素导致上皮屏障的中断,导致发光抗原4的易位或过采样。因此,这启动一个异常的炎症反应,由肠道免疫细胞4介导的共体菌群。IBD相关并发症的特征可能延伸到胃肠道以外的部位,影响各种器官,包括关节、皮肤和肝脏1,2。UC的标记包括严重和弥漫性炎症,通常局部在结肠1。疾病病理学影响肠道的粘膜和亚粘膜,导致表面粘膜溃疡1。相反,CD可以影响胃肠道的任何部分,虽然疾病的证据常见于结肠和远端回肠2。此外,CD中的炎症是跨体,影响肠壁的所有层2。

已识别的几个IBD易感基因将表明上皮屏障或免疫调节失调是疾病进展5的关键贡献者。发现单核细胞表达的核苷酸寡聚域2(NOD2)中的突变与CD易感性增加有关;这突出了细菌成分的先天免疫检测与疾病6之间的联系。最近的全基因组关联研究(GWAS)揭示了其他可能参与IBD发病机制的通路,包括:STAT1、NKX2-3、IL2RA、IL23R依赖途径的遗传变异与适应性免疫、MUC1、MUC19和PTGER4在肠道屏障维护中,以及ATG16L介导自噬7,8,9。虽然这些基于人群的遗传学研究增强了我们对IBD的理解,但仅仅易感等位基因可能不足以引发和维持慢性疾病3。其他非遗传因素,包括肠道微生物群的改变和多样性的减少都与肠道炎症有关。然而,目前还不清楚肠道消化不良是先于或是否是免疫反应不良的后果3。虽然IBD的病因尚不明确,但通过10、11的实验性小鼠模型,我们加强了对疾病发病机制的了解。这些模型单独并不完全代表人类疾病的复杂性,但它们对于阐明与IBD相关的病理生理学途径和验证试探性治疗策略10具有价值。 11.这种小鼠模型通常依赖于通过化学诱导或感染、免疫细胞转移或基因操作引发炎症。此外,这些策略往往涉及上皮完整性的扰动或先天或适应性免疫的调制。

肠沙门氏菌是肠道病原体,可以感染人类和小鼠。摄入后,沙门氏菌可以通过直接侵入上皮细胞、M细胞或抗原呈现细胞12来殖民肠道。被S口头感染的老鼠。Typhimurium导致主要在系统位点的殖民化,如脾脏淋巴结,在GI区12中丰度相对较低。然而,对使用链霉素的小鼠进行预处理,通过减少正常微生物群13的宿主保护作用,提高了肠道沙门氏菌的殖民化效率。该模型的病理特征包括上皮屏障的中断或溃疡、粒细胞招募和严重水肿13。或者,感染S级疫苗。Typhimurium _AroA 突变体导致慢性殖民化的 cecum 和结肠,持续到感染14后的第 40 天。S.Typhimurium_AroA菌株在芳香氨基酸的生物合成中存在缺陷;这使得突变菌株具有阿维性,并可用作高效疫苗15。小鼠的口腔感染导致Th1-和Th17细胞因子相关的炎症反应、广泛的组织重塑和胶原蛋白沉积。组织病理学与亲纤维化因子(如TGF-β1、CTGF和IGF14)的升高有关。该模型中报告的跨壁画纤维化疤痕让人联想到IBD中经常观察到的严格性形成。沙门氏菌引起的纤维化需要由沙门氏菌致病性岛屿(SPI)-1和2 12编码的毒性。重要的是,这个S.Tymphimurium_AroA感染模型是研究在C57/Bl6背景下维持的突变小鼠纤维化反应的有用系统。C57/Bl6 应变对 S 极其敏感。由于基因编码自然抗药性相关巨噬平板蛋白(NRAMP)-116、17的功能丧失而感染。我们发现IL-17A和ROR®依赖性先天淋巴细胞是本模型18中发病机制的重要贡献者。

CD的一个主要并发症是细胞外基质(ECM)的调节失调和过度沉积,包括胶原蛋白2,19。虽然胃肠道具有相对较高的再生能力,纤维化疤痕可能会出现由于未解决的伤口愈合反应,与慢性和严重炎症20,21。在CD中,这导致对组织结构的有害影响,导致严重的器官损伤21,22。在CD中观察到的炎症的跨面性质最终先于肠壁的增厚与症状性狭窄或严格形成21相关。约三分之一的CD患者需要肠道切除这种并发症22。IBD没有有效的抗纤维化疗法,因为使用免疫抑制剂,如阿扎西普林或抗TNF®生物制剂没有影响,或只是适度减少手术干预的需求19,23.虽然纤维化被认为是慢性炎症的结果,但中质细胞(如成纤维细胞和围细胞)被认为是纤维化疤痕21、24中ECM的主要细胞来源。慢性S.Typhimurium _AroA 感染是肠道纤维化的一种强大的小鼠模型,可提供对 CD 样特征的发病机制的见解。

Protocol

所有动物协议都得到不列颠哥伦比亚大学动物护理委员会的批准。 1. 为小鼠口服腹腔培养沙门氏菌的制备[AroA培养物] 从S的冷冻甘油库存。Typhimrium _AroA,使用含有100μg/mL链霉素的LB琼脂剂制备条纹板,具有无菌接种回路。在37°C下孵育过夜。条纹板可在 4°C 下存储长达一周。 感染前一天,在2.5 mL水中溶解0.5克链霉素,制备抗生素。过滤灭菌链霉素?…

Representative Results

链霉素治疗后,口服感染S.Typhimurium _AroA 导致强健的肠道炎症和纤维化,特别是在 cecum 中(图 1)。典型的病原体负担为每1克1克1至109 CFU,每1克脾脏可获104 CFU,可从受感染动物中恢复(图2)。在皮罗西里乌斯红染色剖腹产的纤维化评估表明,感染后21天出现纤维化,而大部分病理在第42 pi(图3和<s…

Discussion

我们对IBD发病机制的理解已经大大增强了小鼠的肠道炎症模型。虽然这些个体模型并不概括复杂和多因素人类疾病的所有特征,但它们有助于确定疾病进展的关键特征。与IBD相关的纤维化严格仍然是一个主要未满足的临床需要,因为目前的治疗在逆转疾病发展方面是无效的。此外,由于目前动物模型的限制,肠纤维化在实验室环境中很难研究。BALB/c小鼠长期接触TNBS已被证明诱导由IL-13和TGF-B1<sup cl…

Disclosures

The authors have nothing to disclose.

Acknowledgements

我们感谢英格丽德·巴塔为公司学服务。

Materials

2 ml round bottom safe lock tubes Eppendorf 22363344
Stainless steel beads Qiagen 69989
PBS Gibco 10010031
Large-Orifice Pipet Tips Fisher 2707134
2 mL megablock plates Sarstedt 82.1972.002
Gavage needles FST 18061-22
Streptomycin sulfate Sigma S9137
Mixer mill Retsch MM
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References

  1. Danese, S., Fiocchi, C. Ulcerative colitis. New England Journal of Medicine. 365 (18), 1713-1725 (2011).
  2. Baumgart, D. C., Sandborn, W. J. Crohn’s disease. The Lancet. 380 (9853), 1590-1605 (2012).
  3. Knights, D., Lassen, K. G., Xavier, R. J. Advances in inflammatory bowel disease pathogenesis: linking host genetics and the microbiome. Gut. 62 (10), 1505-1510 (2013).
  4. Xavier, R. J., Podolsky, D. K. Unravelling the pathogenesis of inflammatory bowel disease. Nature. 448 (7152), 427-434 (2007).
  5. Cho, J. H. The genetics and immunopathogenesis of inflammatory bowel disease. Nature Reviews Immunology. 8 (6), 458-466 (2008).
  6. Ogura, Y., et al. A frameshift mutation in NOD2 associated with susceptibility to Crohn’s disease. Nature. 411 (6837), 603-606 (2001).
  7. Jostins, L., et al. Host-microbe interactions have shaped the genetic architecture of inflammatory bowel disease. Nature. 491 (7422), 119-124 (2012).
  8. Rivas, M. A., et al. Deep resequencing of GWAS loci identifies independent rare variants associated with inflammatory bowel disease. Nature Genetics. 43 (11), 1066-1073 (2011).
  9. Rioux, J. D., et al. Genome-wide association study identifies new susceptibility loci for Crohn disease and implicates autophagy in disease pathogenesis. Nature Genetics. 39 (5), 596-604 (2007).
  10. Uhlig, H. H., Powrie, F. Mouse models of intestinal inflammation as tools to understand the pathogenesis of inflammatory bowel disease. European Journal of Immunology. 39 (8), 2021-2026 (2009).
  11. Nell, S., Suerbaum, S., Josenhans, C. The impact of the microbiota on the pathogenesis of IBD: lessons from mouse infection models. Nature Reviews Microbiology. 8 (8), 564-577 (2010).
  12. Grassl, G. A., Finlay, B. B. Pathogenesis of enteric Salmonella infections. Current Opinion in Gastroenterology. 24 (1), 22-26 (2008).
  13. Barthel, M., et al. Pretreatment of mice with streptomycin provides a Salmonella enterica serovar Typhimurium colitis model that allows analysis of both pathogen and host. Infection and Immunity. 71 (5), 2839-2858 (2003).
  14. Grassl, G. A., Valdez, Y., Bergstrom, K., Vallance, B. A., Finlay, B. B. Chronic Enteric Salmonella Infection in Mice Leads to Severe and Persistent Intestinal Fibrosis. Gastroenterology. 134 (3), 768-780 (2008).
  15. Hoiseth, S. K., Stocker, B. A. Aromatic-dependent Salmonella typhimurium are non-virulent and effective as live vaccines. Nature. 291 (5812), 238-239 (1981).
  16. Valdez, Y., Ferreira, R. B., Finlay, B. B. Molecular mechanisms of Salmonella virulence and host resistance. Current Topics in Microbiology and Immunology. 337, 93-127 (2009).
  17. Valdez, Y., et al. Nramp1 drives an accelerated inflammatory response during Salmonella-induced colitis in mice. Cellular Microbiology. 11 (2), 351-362 (2009).
  18. Lo, B. C., et al. The orphan nuclear receptor RORalpha and group 3 innate lymphoid cells drive fibrosis in a mouse model of Crohn’s disease. Science Immunology. 1 (3), eaaf8864 (2016).
  19. Burke, J. P., et al. Fibrogenesis in Crohn’s disease. American Journal of Gastroenterology. 102 (2), 439-448 (2007).
  20. Hogan, B. L., et al. Repair and regeneration of the respiratory system: complexity, plasticity, and mechanisms of lung stem cell function. Cell Stem Cell. 15 (2), 123-138 (2014).
  21. Fiocchi, C., Lund, P. K. Themes in fibrosis and gastrointestinal inflammation. American Journal of Physiology-Gastrointestinal and Liver Physiology. 300 (5), G677-G683 (2011).
  22. Rieder, F., Fiocchi, C. Intestinal fibrosis in IBD—a dynamic, multifactorial process. Nature Reviews Gastroenterology & Hepatology. 6 (4), 228-235 (2009).
  23. Bouguen, G., Peyrin-Biroulet, L. Surgery for adult Crohn’s disease: what is the actual risk?. Gut. 60 (9), 1178-1181 (2011).
  24. Wynn, T. A. Cellular and molecular mechanisms of fibrosis. The Journal of Pathology. 214 (2), 199-210 (2008).
  25. Junqueira, L. C., Bignolas, G., Brentani, R. R. Picrosirius staining plus polarization microscopy, a specific method for collagen detection in tissue sections. Histochem J. 11 (4), 447-455 (1979).
  26. Lo, B. C., et al. IL-22 Preserves Gut Epithelial Integrity and Promotes Disease Remission during Chronic Salmonella Infection. Journal of Immunology. 202 (3), 956-965 (2019).
  27. Fichtner-Feigl, S., et al. Induction of IL-13 triggers TGF-beta1-dependent tissue fibrosis in chronic 2,4,6-trinitrobenzene sulfonic acid colitis. Journal of Immunology. 178 (9), 5859-5870 (2007).
  28. Fichtner-Feigl, S., et al. IL-13 signaling via IL-13R alpha2 induces major downstream fibrogenic factors mediating fibrosis in chronic TNBS colitis. Gastroenterology. 135 (6), e2001-e2007 (2013).
  29. Johnson, L. A., et al. Intestinal fibrosis is reduced by early elimination of inflammation in a mouse model of IBD: impact of a "Top-Down" approach to intestinal fibrosis in mice. Inflammatory Bowel Diseases. 18 (3), 460-471 (2012).
  30. Darfeuille-Michaud, A., et al. High prevalence of adherent-invasive Escherichia coli associated with ileal mucosa in Crohn’s disease. Gastroenterology. 127 (2), 412-421 (2004).
  31. Small, C. L., Reid-Yu, S. A., McPhee, J. B., Coombes, B. K. Persistent infection with Crohn’s disease-associated adherent-invasive Escherichia coli leads to chronic inflammation and intestinal fibrosis. Nature Communications. 4, 1957 (2013).
  32. Imai, J., et al. Flagellin-mediated activation of IL-33-ST2 signaling by a pathobiont promotes intestinal fibrosis. Mucosal Immunology. , (2019).

Tags

Intestinal FibrosisChronic InflammationCrohn’s DiseaseSalmonella InfectionMouse ModelOral GavageStreptomycinLB AgarLB BrothBacterial CultureSterile Technique

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Lo, B. C., Shin, S. B., Messing, M., McNagny, K. M. Chronic Salmonella Infection Induced Intestinal Fibrosis. J. Vis. Exp. (151), e60068, doi:10.3791/60068 (2019).
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