333-OR: Hypoimmune Islet Cells Mediate Insulin Independence after Allogeneic Transplantation in a Fully Immunocompetent Nonhuman Primate without Immunosuppression
XIAOMENG HU, KATHY WHITE, CHI YOUNG, ARI G. OLROYD, PAUL KIEVIT, ANDREW CONNOLLY, TOBIAS DEUSE, SONJA SCHREPFER
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引用次数: 0
Abstract
Treatment of type 1 diabetes mellitus (T1DM) via allogeneic donor transplant has limited success due to morbidities from immunosuppression (IS) and a gradual loss of engrafted pancreatic islet function. We report that allogeneic transplantation of engineered, primary, hypoimmune, pseudo-islets (HIP p-islets) engraft into a fully immunocompetent, diabetic non-human primate (NHP), provide stable endocrine function, and enable insulin independence without inducing any detectable immune response in the absence of IS. NHP cadaveric islet cells were engineered to disrupt function of MHC class I and II and overexpress CD47 thus rendering them hypoimmune (HIP). Diabetes was induced in the NHP with streptozotocin and daily insulin injections started to re-establish glucose control. After 78 days, NHP underwent transplantation of HIP p-islets by intramuscular injection resulting in insulin independence. As early as one week after the transplantation, the NHP’s serum c-peptide level had normalized and remained stable throughout the follow-up period of 6 months. The NHP showed tightly controlled blood glucose levels for 6 months, was completely insulin-independent, and continuously healthy. Up to 6 months after HIP p-islet transplantation, PBMCs and serum were obtained for immune analyses. HIP PI showed no T cell recognition, no graft-specific antibodies, and were protected from NK cell and macrophage killing. To prove that the monkey’s insulin-independence was fully dependent on the HIP p-islets graft and there was no regeneration of his endogenous islet cell population, we triggered the destruction of the HIP p-islet transplant using a CD47-targeting strategy resulting in loss of glycemic control and return to exogenous insulin dependence. These data demonstrate evidence for immune evasion of HIP p-islets, graft mediated insulin-independence of the diabetic NHP, and a potential safety strategy. Disclosure X. Hu: Employee; Sana Biotechnology. Stock/Shareholder; Sana Biotechnology. K. White: None. C. Young: Employee; Sana biotechnology. Stock/Shareholder; Sana biotechnology. A.G. Olroyd: Employee; Sana Biotechnology. Stock/Shareholder; Sana Biotechnology. P. Kievit: Consultant; Alnylam Pharmaceuticals, Inc., Embark Bio. Research Support; Sana Biotechnology, Novo Nordisk A/S. A. Connolly: None. T. Deuse: Stock/Shareholder; Sana Biotechnology, Shinobi Therapeutics. S. Schrepfer: Stock/Shareholder; Sana Biotechnology. Employee; Sana Biotechnology.
通过异体供体移植治疗 1 型糖尿病(T1DM)的成功率有限,原因是免疫抑制(IS)和移植胰岛功能逐渐丧失造成的发病率。我们报告说,异体移植工程化、原发性、低免疫、假性胰岛细胞(HIP p-islets)可接种到完全免疫功能健全的糖尿病非人灵长类动物(NHP)体内,提供稳定的内分泌功能,并在无 IS 的情况下实现胰岛素独立,而不会诱发任何可检测到的免疫反应。对非人灵长类尸体胰岛细胞进行了改造,以破坏 MHC I 类和 II 类的功能,并过度表达 CD47,从而使其免疫力低下(HIP)。用链脲佐菌素诱导 NHP 患上糖尿病,并开始每天注射胰岛素以重建血糖控制。78 天后,通过肌肉注射移植 HIP p-islets 使 NHP 不再依赖胰岛素。早在移植后一周,NHP 的血清 c 肽水平就已恢复正常,并在 6 个月的随访期间保持稳定。在长达 6 个月的时间里,NHP 的血糖水平得到严格控制,完全不依赖胰岛素,身体持续健康。HIP p-islet移植6个月后,采集了PBMCs和血清进行免疫分析。HIP PI 没有出现 T 细胞识别,没有移植物特异性抗体,并且不会被 NK 细胞和巨噬细胞杀死。为了证明猴子的胰岛素依赖性完全依赖于 HIP p 型胰岛移植,其内源性胰岛细胞群没有再生,我们使用 CD47 靶向策略触发了对 HIP p 型胰岛移植的破坏,导致血糖失控,恢复了外源性胰岛素依赖性。这些数据证明了 HIP p-islet 的免疫逃避、糖尿病 NHP 移植介导的胰岛素依赖性以及潜在的安全策略。披露信息 X. Hu:员工;萨纳生物技术公司。萨纳生物技术公司股票/股东。K. White:无。C. Young:萨纳生物技术公司员工。萨纳生物技术公司股票/股东。A.G. Olroyd:员工;萨纳生物技术公司。萨纳生物技术公司股票/股东。P. Kievit:顾问; Alnylam Pharmaceuticals, Inc.研究支持;萨纳生物技术公司、诺和诺德公司。A. Connolly:无。T. Deuse:股票/股东;Sana 生物技术公司、Shinobi Therapeutics。S. Schrepfer:股票/股东;萨纳生物技术公司。萨纳生物技术公司员工。
期刊介绍:
Diabetes is a scientific journal that publishes original research exploring the physiological and pathophysiological aspects of diabetes mellitus. We encourage submissions of manuscripts pertaining to laboratory, animal, or human research, covering a wide range of topics. Our primary focus is on investigative reports investigating various aspects such as the development and progression of diabetes, along with its associated complications. We also welcome studies delving into normal and pathological pancreatic islet function and intermediary metabolism, as well as exploring the mechanisms of drug and hormone action from a pharmacological perspective. Additionally, we encourage submissions that delve into the biochemical and molecular aspects of both normal and abnormal biological processes.
However, it is important to note that we do not publish studies relating to diabetes education or the application of accepted therapeutic and diagnostic approaches to patients with diabetes mellitus. Our aim is to provide a platform for research that contributes to advancing our understanding of the underlying mechanisms and processes of diabetes.