Subcutaneous nanotherapy repurposes the immunosuppressive mechanism of rapamycin to enhance allogeneic islet graft viability

Standard oral rapamycin (that is, Rapamune) administration is plagued by poor bioavailability and broad biodistribution. Thus, this pleotropic mammalian target of rapamycin (mTOR) inhibitor has a narrow therapeutic window and numerous side effects and provides inadequate protection to transplanted c...

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Bibliographic Details
Published in:	Nature nanotechnology Vol. 17; no. 3; pp. 319 - 330
Main Authors:	Burke, Jacqueline A., Zhang, Xiaomin, Bobbala, Sharan, Frey, Molly A., Bohorquez Fuentes, Carolina, Freire Haddad, Helena, Allen, Sean D., Richardson, Reese A. K., Ameer, Guillermo A., Scott, Evan A.
Format:	Journal Article
Language:	English
Published:	London Nature Publishing Group UK 01-03-2022 Nature Publishing Group
Subjects:	631/61/350/354 631/61/54/152 Antigen-presenting cells Antigens Bioavailability Biodistribution Cell proliferation Chemistry and Materials Science Diabetes mellitus (insulin dependent) Graft rejection Hematopoietic Stem Cell Transplantation Hydrophobicity Immune system Immunological tolerance Immunosuppression Immunosuppressive agents Immunosuppressive Agents - pharmacology Inflammation Islet cells Islets of Langerhans Transplantation Lymphocytes Lymphocytes T Major histocompatibility complex Materials Science Nanotechnology Nanotechnology and Microengineering Pancreatic islet transplantation Polyethylene glycol Propylene Rapamycin Science & Technology - Other Topics Side effects Sirolimus - pharmacology Tissue Distribution TOR protein Transplantation
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Summary:	Standard oral rapamycin (that is, Rapamune) administration is plagued by poor bioavailability and broad biodistribution. Thus, this pleotropic mammalian target of rapamycin (mTOR) inhibitor has a narrow therapeutic window and numerous side effects and provides inadequate protection to transplanted cells and tissues. Furthermore, the hydrophobicity of rapamycin limits its use in parenteral formulations. Here, we demonstrate that subcutaneous delivery via poly(ethylene glycol)-b-poly(propylene sulfide) polymersome nanocarriers significantly alters rapamycin’s cellular biodistribution to repurpose its mechanism of action for tolerance, instead of immunosuppression, and minimize side effects. While oral rapamycin inhibits T cell proliferation directly, subcutaneously administered rapamycin-loaded polymersomes modulate antigen presenting cells in lieu of T cells, significantly improving maintenance of normoglycemia in a clinically relevant, major histocompatibility complex-mismatched, allogeneic, intraportal (liver) islet transplantation model. These results demonstrate the ability of a rationally designed nanocarrier to re-engineer the immunosuppressive mechanism of a drug by controlling cellular biodistribution. Orally delivered rapamycin is an immunosuppressant that inhibits islet graft rejection in patients treated for type 1 diabetes, but it suffers from poor bioavailability, inconsistent cellular distribution and adverse reactions. Here the authors show that subcutaneous delivery of rapamycin using a polymersome platform allows for control of the drug’s biodistribution and activity on specific immune cells, which changes its mechanism of action from immunosuppression to tolerance, reduces side effects and enhances anti-inflammatory efficacy.
Bibliography:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 AC02-06CH11357 USDOE J.A.B. analyzed the data and composed the manuscript. J.A.B., X.Z., S.B., M.A.F., C.B., and H.F. performed the experiments. R.A.K.R. performed computational analysis on the RNA sequencing data. E.A.S. and G.A.A. supervised the study. J.A.B. designed the experiments with the assistance of S.D.A.. Author Contributions
ISSN:	1748-3387 1748-3395
DOI:	10.1038/s41565-021-01048-2