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使用移植后环磷酰胺治疗构建耐受平台以预防液体和实体器官同种异体移植排斥反应。

Use of Post-transplant Cyclophosphamide Treatment to Build a Tolerance Platform to Prevent Liquid and Solid Organ Allograft Rejection.

作者信息

Lightbourn Casey O, Wolf Dietlinde, Copsel Sabrina N, Wang Ying, Pfeiffer Brent J, Barreras Henry, Bader Cameron S, Komanduri Krishna V, Perez Victor L, Levy Robert B

机构信息

Department of Microbiology and Immunology, Miller School of Medicine, University of Miami, Miami, FL, United States.

Sylvester Comprehensive Cancer Center, Miller School of Medicine, University of Miami, Miami, FL, United States.

出版信息

Front Immunol. 2021 Mar 2;12:636789. doi: 10.3389/fimmu.2021.636789. eCollection 2021.

DOI:10.3389/fimmu.2021.636789
PMID:33737937
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7962410/
Abstract

Corneal transplantation (CT) is the most frequent type of solid organ transplant (SOT) performed worldwide. Unfortunately, immunological rejection is the primary cause of graft failure for CT and therefore advances in immune regulation to induce tolerance remains an unmet medical need. Recently, our work and others in pre-clinical studies found that cyclophosphamide (Cy) administered after ("post-transplant," PTCy) hematopoietic stem cell transplantation (HSCT), i.e., liquid transplants is effective for graft vs. host disease prophylaxis and enhances overall survival. Importantly, within the past 10 years, PTCy has been widely adopted for clinical HSCT and the results at many centers have been extremely encouraging. The present studies found that Cy can be effectively employed to prolong the survival of SOT, specifically mouse corneal allografts. The results demonstrated that the timing of PTCy administration is critical for these CT and distinct from the kinetics employed following allogeneic HSCT. PTCy was observed to interfere with neovascularization, a process critically associated with immune rejection of corneal tissue that ensues following the loss of ocular "immune privilege." PTCy has the potential to delete or directly suppress allo-reactive T cells and treatment here was shown to diminish T cell rejection responses. These PTCy doses were observed to spare significant levels of CD4 FoxP3 (Tregs) which were found to be functional and could readily receive stimulating signals leading to their expansion TNFRSF25 and CD25 agonists. In total, we posit future studies can take advantage of Cy based platforms to generate combinatorial strategies for long-term tolerance induction.

摘要

角膜移植(CT)是全球范围内最常见的实体器官移植(SOT)类型。不幸的是,免疫排斥是CT移植失败的主要原因,因此诱导免疫耐受的免疫调节进展仍然是未满足的医学需求。最近,我们的研究以及其他临床前研究发现,在造血干细胞移植(HSCT)后(“移植后”,PTCy)给予环磷酰胺(Cy),即液体移植,对预防移植物抗宿主病有效,并提高了总体生存率。重要的是,在过去10年中,PTCy已被广泛应用于临床HSCT,许多中心的结果都非常令人鼓舞。目前的研究发现,Cy可有效用于延长SOT的存活时间,特别是小鼠角膜同种异体移植。结果表明,PTCy给药的时机对这些CT至关重要,且与同种异体HSCT后的动力学不同。观察到PTCy会干扰新生血管形成,这一过程与眼部“免疫豁免”丧失后随之而来的角膜组织免疫排斥密切相关。PTCy有可能删除或直接抑制同种反应性T细胞,此处的治疗显示可减少T细胞排斥反应。观察到这些PTCy剂量可保留大量功能性CD4 FoxP3(调节性T细胞),它们能够轻易接收刺激信号并导致其扩增,如TNFRSF25和CD25激动剂。总的来说,我们认为未来的研究可以利用基于Cy的平台来生成长期诱导耐受的联合策略。

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