ABSTRACT
Pluripotent stem cell-derived islets (SC-islets) now emerge as a new source for beta-cell replacement therapy. While the function of human islet transplants is hampered by excessive cell death post-transplantation, contributing factors include inflammatory reactions, insufficient revascularization and islet amyloid formation, there is a gap in knowledge on the engraftment process of the SC-islets. In this experimental study, we investigated the engraftment capability of SC-islets at three months post-transplantation, and observed that the cell apoptosis rates were lower, but the vascular density was similar in SC-islets to that of human islets. While the human islet transplant vascular structures were a mixture of remnant donor endothelium and ingrowing blood vessels, the SC-islets contained ingrowing blood vessels only. The oxygenation of the SC-islet grafts was twice as high as in the corresponding grafts of human islets, suggesting better vascular functionality. Similar to the blood vessel ingrowth, also the reinnervation of the SC-islets was four- to five-fold higher than the human islets. Both SC-islets and the human islets contained amyloid at one and three months post-transplantation. We conclude that the vascular and neural engraftment of SC-islets is superior to human islets, but that grafts of both origins develop amyloid with potential long-term consequences.
ABSTRACT
BACKGROUND: Beta-cell replacement methods such as transplantation of isolated donor islets have been proposed as a curative treatment of type 1 diabetes, but widespread application is challenging due to shortages of donor tissue and the need for continuous immunosuppressive treatments. Stem-cell-derived islets have been suggested as an alternative source of beta cells, but face transplantation protocols optimization difficulties, mainly due to a lack of available methods and markers to directly monitor grafts survival, as well as their localization and function. Molecular imaging techniques and particularly positron emission tomography has been suggested as a tool for monitoring the fate of islets after clinical transplantation. The integral membrane protein DGCR2 has been demonstrated to be a potential pancreatic islet biomarker, with specific expression on insulin-positive human embryonic stem-cell-derived pancreatic progenitor cells. The candidate Affibody molecule ZDGCR2:AM106 was radiolabeled with fluorine-18 using a novel click chemistry-based approach. The resulting positron emission tomography tracer [18F]ZDGCR2:AM106 was evaluated for binding to recombinant human DGCR2 and cryosections of stem-cell-derived islets, as well as in vivo using an immune-deficient mouse model transplanted with stem-cell-derived islets. Biodistribution of the [18F]ZDGCR2:AM106 was also assessed in healthy rats and pigs. RESULTS: [18F]ZDGCR2:AM106 was successfully synthesized with high radiochemical purity and yield via a pretargeting approach. [18F]ZDGCR2:AM106 retained binding to recombinant human DCGR2 as well as to cryosectioned stem-cell-derived islets, but in vivo binding to native pancreatic tissue in both rat and pig was low. However, in vivo uptake of [18F]ZDGCR2:AM106 in stem-cell-derived islets transplanted in the immunodeficient mice was observed, albeit only within the early imaging frames after injection of the radiotracer. CONCLUSION: Targeting of DGCR2 is a promising approach for in vivo detection of stem-cell-derived islets grafts by molecular imaging. The synthesis of [18F]ZDGCR2:AM106 was successfully performed via a pretargeting method to label a site-specific covalently bonded fluorine-18 to the Affibody molecule. However, the rapid washout of [18F]ZDGCR2:AM106 from the stem-cell-derived islets graft indicates that dissociation kinetics can be improved. Further studies using alternative binders of similar classes with improved binding potential are warranted.
