Department of Internal Medicine (Division of Gastroenterology), University of Michigan Health System, Ann Arbor, MI, USA.
Unit for Laboratory Animal Medicine, Department of Microbiology and Immunology, University of Michigan, Ann Arbor, MI, USA.
Helicobacter. 2020 Dec;25(6):e12763. doi: 10.1111/hel.12763. Epub 2020 Oct 6.
Helicobacter pylori infection leads to regulatory T-cell (Treg) induction in infected mice, which contributes to H. pylori immune escape. However, the mechanisms responsible for H. pylori induction of Treg and immune tolerance remain unclear. We hypothesized DC-produced TGF-β may be responsible for Treg induction and immune tolerance.
To test this hypothesis, we generated TGF-β mice (CD11c DC-specific TGF-β deletion) and assessed the impact of DC-specific TGF-β deletion on DC function during Helicobacter infection in vitro and in vivo. To examine the T cell-independent DC function, we crossed TGF-β mice onto Rag1KO background to generate TGF-β xRag1KO mice.
When stimulated with H. pylori, TGF-β BMDC/splenocyte cocultures showed increased levels of proinflammatory cytokines and decreased levels of anti-inflammatory cytokines compared to control, indicating a proinflammatory DC phenotype. Following 6 months of H. felis infection, TGF-β mice developed more severe gastritis and a trend toward more metaplasia compared to TGF-β with increased levels of inflammatory Th1 cytokine mRNA and lower gastric H. felis colonization compared to infected TGF-β mice. In a T cell-deficient background using TGF-β xRag1KO mice, H. felis colonization was significantly lower when DC-derived TGF-β was absent, revealing a direct, innate function of DC in controlling H. felis infection independent of Treg induction.
Our findings indicate that DC-derived TGF-β mediates Helicobacter-induced Treg response and attenuates the inflammatory Th1 response. We also demonstrated a previously unrecognized innate role of DC controlling Helicobacter colonization via a Treg-independent mechanism. DC TGF-β signaling may represent an important target in the management of H. pylori.
幽门螺杆菌(H. pylori)感染可诱导感染小鼠中的调节性 T 细胞(Treg),这有助于 H. pylori 免疫逃逸。然而,导致 H. pylori 诱导 Treg 和免疫耐受的机制仍不清楚。我们假设树突状细胞(DC)产生的 TGF-β可能是诱导 Treg 和免疫耐受的原因。
为了验证这一假设,我们生成了 TGF-β 小鼠(DC 特异性 TGF-β缺失),并评估了 DC 特异性 TGF-β缺失对 H. pylori 感染时 DC 功能的影响,包括体外和体内实验。为了研究 T 细胞非依赖性 DC 功能,我们将 TGF-β 小鼠与 Rag1KO 背景杂交,生成 TGF-β xRag1KO 小鼠。
与对照相比,用 H. pylori 刺激时,TGF-β BMDC/脾细胞共培养物显示促炎细胞因子水平升高,抗炎细胞因子水平降低,表明具有促炎表型的 DC。在感染 H. felis 6 个月后,与 TGF-β 小鼠相比,TGF-β 小鼠的胃炎更严重,且化生趋势更明显,炎性 Th1 细胞因子 mRNA 水平升高,胃内 H. felis 定植减少。在使用 TGF-β xRag1KO 小鼠的 T 细胞缺陷背景下,当 DC 来源的 TGF-β缺失时,H. felis 定植显著降低,这揭示了 DC 在控制 H. felis 感染方面的直接、先天功能,而不依赖于 Treg 诱导。
我们的研究结果表明,DC 衍生的 TGF-β介导了 H. pylori 诱导的 Treg 反应,并减弱了炎症性 Th1 反应。我们还证明了 DC 通过 Treg 非依赖机制控制 H. pylori 定植的先前未知的先天作用。DC TGF-β 信号可能是 H. pylori 管理的重要靶点。
