表达人T细胞消耗抗cd2单克隆抗体的转基因猪的特性。

IF 3.3 4区 医学 Q2 MEDICINE, RESEARCH & EXPERIMENTAL
Evelyn J Salvaris, Nella Fisicaro, Stephen McIlfatrick, Adwin Thomas, Erin Fuller, Andrew M Lew, Mark B Nottle, Wayne J Hawthorne, Peter J Cowan
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引用次数: 0

摘要

背景:猪胰岛异种移植是治疗1型糖尿病的一种潜在方法。我们已经证明,需要维持免疫抑制来保护转基因(GM)猪胰岛异种移植物免受T细胞介导的狒狒排斥反应。异种移植物局部表达一种消耗性抗cd2单克隆抗体(mAb)可能提供另一种解决方案。我们之前已经报道了在MHCI类启动子(MHCIP)下表达嵌合抗cd2单抗地利昔单抗的GGTA1敲入转基因猪的产生。在这项研究中,我们培育了GGTA1敲入猪,其中MHCIP被β细胞特异性猪胰岛素启动子(PIP)取代,并比较了两种品系中地利昔单抗的表达模式。方法:制备pip -地利昔单抗敲入构建体,并转染小鼠胰岛素瘤细胞。利用CRISPR技术将该构建体敲入野生型(WT)猪胎儿成纤维细胞的GGTA1中,并利用敲入细胞通过体细胞核移植(SCNT)产生猪。采用RT-qPCR、流式细胞术、ELISA和免疫组织化学检测mhcip -地利昔单抗和pip -地利昔单抗敲入猪的mRNA和蛋白表达。将mhcip -地利昔单抗和对照GGTA1 KO新生猪的胰岛移植到链脲佐菌素-糖尿病SCID小鼠的肾包膜下。结果:转染PIP-diliximab敲入构建体的NIT-1细胞稳定地将diliximab分泌到培养上清中,证实了单抗在β细胞中的正确表达和加工。pip -地利昔单抗敲入猪显示转基因在GGTA1内的精确整合。在mhcip -地利昔单抗猪的所有组织(脾、肾、心、肝、肺、胰腺)中均检测到地利昔单抗mRNA,但在pip -地利昔单抗猪中未检测到。mhcip -地利昔单抗猪血清中也存在地利昔单抗,平均浓度为1.8 μg/mL,而pip -地利昔单抗猪血清中未检测到地利昔单抗。免疫组织化学调查显示,mhcip -地利昔单抗猪的所有器官都有地利昔单抗染色,而pip -地利昔单抗猪没有。pip -地利昔单抗猪的全基因组测序(WGS)在地利昔单抗轻链编码区发现了一个错义突变。这种突变也被发现存在于用于产生pip -地利昔单抗猪的成纤维细胞敲入克隆中。新生儿mhcip -地利昔单抗猪胰岛异种移植恢复了糖尿病免疫缺陷小鼠的正常血糖,表明转基因对胰岛功能没有明显影响,并证实了地利昔单抗的原位表达。结论:地利昔单抗在mhcip -地利昔单抗猪中广泛表达,包括在胰岛中,与MHC i类内源性表达模式一致。mhcip -地利昔单抗猪胰岛中的表达水平是否足以预防T细胞介导的胰岛异种移植排斥反应,还需要进一步研究。pip -地利昔单抗猪的胰岛中出人意料地缺乏地利昔单抗表达,这可能是由于用于SCNT的敲入细胞生成过程中产生的转基因突变。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Characterisation of transgenic pigs expressing a human T cell-depleting anti-CD2 monoclonal antibody.

Background: Pig islet xenotransplantation is a potential treatment for type 1 diabetes. We have shown that maintenance immunosuppression is required to protect genetically modified (GM) porcine islet xenografts from T cell-mediated rejection in baboons. Local expression of a depleting anti-CD2 monoclonal antibody (mAb) by the xenograft may provide an alternative solution. We have previously reported the generation of GGTA1 knock-in transgenic pigs expressing the chimeric anti-CD2 mAb diliximab under an MHC class I promoter (MHCIP). In this study, we generated GGTA1 knock-in pigs in which MHCIP was replaced by the β-cell-specific porcine insulin promoter (PIP), and compared the pattern of diliximab expression in the two lines.

Methods: A PIP-diliximab knock-in construct was prepared and validated by transfection of NIT-1 mouse insulinoma cells. The construct was knocked into GGTA1 in wild type (WT) porcine fetal fibroblasts using CRISPR, and knock-in cells were used to generate pigs by somatic cell nuclear transfer (SCNT). Expression of the transgene in MHCIP-diliximab and PIP-diliximab knock-in pigs was characterised at the mRNA and protein levels using RT-qPCR, flow cytometry, ELISA and immunohistochemistry. Islets from MHCIP-diliximab and control GGTA1 KO neonatal pigs were transplanted under the kidney capsule of streptozotocin-diabetic SCID mice.

Results: NIT-1 cells stably transfected with the PIP-diliximab knock-in construct secreted diliximab into the culture supernatant, confirming correct expression and processing of the mAb in β cells. PIP-diliximab knock-in pigs showed a precise integration of the transgene within GGTA1. Diliximab mRNA was detected in all tissues tested (spleen, kidney, heart, liver, lung, pancreas) in MHCIP-diliximab pigs, but was not detectable in PIP-diliximab pigs. Likewise, diliximab was present in the serum of MHCIP-diliximab pigs, at a mean concentration of 1.8 μg/mL, but was not detected in PIP-diliximab pig serum. An immunohistochemical survey revealed staining for diliximab in all organs of MHCIP-diliximab pigs but not of PIP-diliximab pigs. Whole genome sequencing (WGS) of a PIP-diliximab pig identified a missense mutation in the coding region for the dixilimab light chain. This mutation was also found to be present in the fibroblast knock-in clone used to generate the PIP-diliximab pigs. Islet xenografts from neonatal MHCIP-diliximab pigs restored normoglycemia in diabetic immunodeficient mice, indicating no overt effect of the transgene on islet function, and demonstrated expression of diliximab in situ.

Conclusion: Diliximab was widely expressed in MHCIP-diliximab pigs, including in islets, consistent with the endogenous expression pattern of MHC class I. Further investigation is required to determine whether the level of expression in islets from the MHCIP-diliximab pigs is sufficient to prevent T cell-mediated islet xenograft rejection. The unexpected absence of diliximab expression in the islets of PIP-diliximab pigs was probably due to a mutation in the transgene arising during the generation of the knock-in cells used for SCNT.

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来源期刊
Xenotransplantation
Xenotransplantation 医学-医学:研究与实验
CiteScore
6.80
自引率
15.40%
发文量
58
审稿时长
>12 weeks
期刊介绍: Xenotransplantation provides its readership with rapid communication of new findings in the field of organ and tissue transplantation across species barriers.The journal is not only of interest to those whose primary area is xenotransplantation, but also to veterinarians, microbiologists and geneticists. It also investigates and reports on the controversial theological, ethical, legal and psychological implications of xenotransplantation.
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