PURPOSE OF REVIEW: There is great hope that cellular therapy with regulatory T cells (Tregs) will be an effective way to induce alloantigen specific tolerance, ultimately allowing for reduction or elimination of nonspecific immunosuppression. In the past, considerable effort was focused on defining the optimal ways to isolate and expand Tregs from peripheral or cord blood. Now that expansion of therapeutically relevant numbers of Tregs is feasible, we need to consider what is going to happen to the cells when they are transferred in vivo. RECENT FINDINGS: For optimal function, Tregs must be able to traffic to the correct location(s) and, despite the presence of immunosuppressive therapy, live long enough to transfer their regulatory function to recipient T cells. Within the Treg pool, there are also functionally specialized subsets, identified by chemokine receptor expression and/or cytokine production, which control their trafficking and relative ability to suppress different types of T helper cells, respectively. Recent findings imply that the plasticity of appropriately obtained populations of Tregs may not be of as great concern as previously suggested. Experimental data have also provided evidence as to how one might design adjunctive treatment that best supports the viability and function of Tregs after transfer. SUMMARY: Knowledge of how Tregs work in transplantation comes from studies that do not recapitulate how these cells will be used in humans. There is a need to develop better preclinical models to study how the in-vivo function of human Tregs can be optimized to ensure they can meet the challenge of inducing transplantation tolerance.
PURPOSE OF REVIEW: There is great hope that cellular therapy with regulatory T cells (Tregs) will be an effective way to induce alloantigen specific tolerance, ultimately allowing for reduction or elimination of nonspecific immunosuppression. In the past, considerable effort was focused on defining the optimal ways to isolate and expand Tregs from peripheral or cord blood. Now that expansion of therapeutically relevant numbers of Tregs is feasible, we need to consider what is going to happen to the cells when they are transferred in vivo. RECENT FINDINGS: For optimal function, Tregs must be able to traffic to the correct location(s) and, despite the presence of immunosuppressive therapy, live long enough to transfer their regulatory function to recipient T cells. Within the Treg pool, there are also functionally specialized subsets, identified by chemokine receptor expression and/or cytokine production, which control their trafficking and relative ability to suppress different types of T helper cells, respectively. Recent findings imply that the plasticity of appropriately obtained populations of Tregs may not be of as great concern as previously suggested. Experimental data have also provided evidence as to how one might design adjunctive treatment that best supports the viability and function of Tregs after transfer. SUMMARY: Knowledge of how Tregs work in transplantation comes from studies that do not recapitulate how these cells will be used in humans. There is a need to develop better preclinical models to study how the in-vivo function of human Tregs can be optimized to ensure they can meet the challenge of inducing transplantation tolerance.
Authors: Paula Alonso-Guallart; Jonah S Zitsman; Jeffrey Stern; Sigal B Kofman; David Woodland; Siu-Hong Ho; Hugo P Sondermeijer; Leo Bühler; Adam Griesemer; Megan Sykes; Raimon Duran-Struuck Journal: Am J Transplant Date: 2019-03-29 Impact factor: 8.086
Authors: Scott J Patterson; Anne M Pesenacker; Adele Y Wang; Jana Gillies; Majid Mojibian; Kim Morishita; Rusung Tan; Timothy J Kieffer; C Bruce Verchere; Constadina Panagiotopoulos; Megan K Levings Journal: J Clin Invest Date: 2016-02-08 Impact factor: 14.808
Authors: M B Ezzelarab; H Zhang; H Guo; L Lu; A F Zahorchak; R W Wiseman; M A Nalesnik; J K Bhama; D K C Cooper; A W Thomson Journal: Am J Transplant Date: 2016-03-17 Impact factor: 8.086
Authors: Eirini Nikolouli; Matthias Hardtke-Wolenski; Martin Hapke; Michael Beckstette; Robert Geffers; Stefan Floess; Elmar Jaeckel; Jochen Huehn Journal: Front Immunol Date: 2017-06-28 Impact factor: 7.561
Authors: Maya M Lapp; Guang Lin; Alexander Komin; Leah Andrews; Mei Knudson; Lauren Mossman; Giorgio Raimondi; Julia C Arciero Journal: Transpl Int Date: 2022-04-11 Impact factor: 3.842