Costimulation blockade and Tregs in solid organ transplantation

Muckenhuber, Moritz; Wekerle, Thomas; Schwarz, Christoph

doi:10.3389/fimmu.2022.969633

Cited by 7 publications

(4 citation statements)

References 104 publications

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“…Surprisingly, the immune checkpoint-related gene (CTLA4) in T cells with rejection was stably expressed in T cells with rejection, and there was no statistical difference compared with the isograft group and the DSA trapper group. Thus, these findings supported that the alloimmune microenvironment upregulated the antibody-dependent cell-mediated cytotoxicity (ADCC) effect, promoted antigen presentation, and immune cell homing activities, thus leading to the transplantation rejection and the graft loss . The gene set enrichment analysis (GSEA) confirmed the changes that using DSA trappers significantly downregulated the cytotoxicity-related genes in CD8 + T cells and the Th1-polarized genes in CD4 + T helper cells, while the expression set of immunoregulatory genes was increased compared to the allograft, as shown in Figure G.…”

Section: Resultssupporting

confidence: 59%

“…Thus, these findings supported that the alloimmune microenvironment upregulated the antibody-dependent cell-mediated cytotoxicity (ADCC) effect, promoted antigen presentation, and immune cell homing activities, thus leading to the transplantation rejection and the graft loss. 49 The gene set enrichment analysis (GSEA) confirmed the changes that using DSA trappers significantly downregulated the cytotoxicityrelated genes in CD8 + T cells and the Th1-polarized genes in CD4 + T helper cells, while the expression set of immunoregulatory genes was increased compared to the allograft, as shown in Figure 5G. Furthermore, it was supported that the DSA trappers reversed the highly biased cytotoxicity and promoted the proliferative profiles of Treg in alloimmunity, directly providing an obligate immune-tolerant niche for single-cell heterogeneity restoration (Figure 5H,I).…”

Section: Dsa Trappers Orchestrate Adaptive Endothelialmentioning

confidence: 99%

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Single-Cell Heterogeneity Restorative Chimeric Engineering Nanoparticles for Alleviating Antibody-Mediated Allograft Injury

Lin

et al. 2023

ACS Appl. Mater. Interfaces

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Disturbance of single-cell transcriptional heterogeneity is an inevitable consequence of persistent donor-specific antibody (DSA) production and allosensitization. However, identifying and efficiently clearing allospecific antibody repertoires to restore single-cell transcriptional profiles remain challenging. Here, inspired by the high affinity of natural bacterial proteins for antibodies, a genetic engineered membrane-coated nanoparticle termed as DSA trapper by the engineering chimeric gene of protein A/G with phosphatidylserine ligands for macrophage phagocytosis was reported. It has been shown that DSA trappers adsorbed alloreactive antibodies with high saturation and activated the heterophagic clearance of antibody complexes, alleviating IgG deposition and complement activation. Remarkably, DSA trappers increased the endothelial protective lineages by 8.39-fold, reversed the highly biased cytotoxicity, and promoted the proliferative profiles of Treg cells, directly providing an obligate immune tolerant niche for single-cell heterogeneity restoration. In the mice of allogeneic transplantation, the DSA trapper spared endothelial from inflammatory degenerative rosette, improved the glomerular filtration rate, and prolonged the survival of allogeneic mice from 23.6 to 78.3 days. In general, by identifying the lineage characteristics of rejection-related antibodies, the chimeric engineered DSA trapper realized immunoadsorption and further phagocytosis of alloantibody complexes to restore the single-cell genetic architecture of the allograft, offering a promising prospect for the treatment of alloantibody-mediated immune injury.

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Section: Resultssupporting

confidence: 59%

Section: Dsa Trappers Orchestrate Adaptive Endothelialmentioning

confidence: 99%

Single-Cell Heterogeneity Restorative Chimeric Engineering Nanoparticles for Alleviating Antibody-Mediated Allograft Injury

Lin

et al. 2023

ACS Appl. Mater. Interfaces

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“…In our model, IL-6 blockade resulted in only a modest increase in systemic Treg levels, which were already elevated after ATG induction. Nonetheless, we identified distinct phenotypical changes in Tregs of αIL-6 treated recipients that may correspond to a more suppressive Treg phenotype 78 .…”

Section: Discussionmentioning

confidence: 89%

IL-6 inhibition prevents costimulation blockade-resistant allograft rejection in T cell-depleted recipients by promoting intragraft immune regulation in mice

Muckenhuber,

Mengrelis,

Weijler

et al. 2024

Nat Commun

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The efficacy of costimulation blockade with CTLA4-Ig (belatacept) in transplantation is limited due to T cell-mediated rejection, which also persists after induction with anti-thymocyte globulin (ATG). Here, we investigate why ATG fails to prevent costimulation blockade-resistant rejection and how this barrier can be overcome. ATG did not prevent graft rejection in a murine heart transplant model of CTLA4-Ig therapy and induced a pro-inflammatory cytokine environment. While ATG improved the balance between regulatory T cells (Treg) and effector T cells in the spleen, it had no such effect within cardiac allografts. Neutralizing IL-6 alleviated graft inflammation, increased intragraft Treg frequencies, and enhanced intragraft IL-10 and Th2-cytokine expression. IL-6 blockade together with ATG allowed CTLA4-Ig therapy to achieve long-term, rejection-free heart allograft survival. This beneficial effect was abolished upon Treg depletion. Combining ATG with IL-6 blockade prevents costimulation blockade-resistant rejection, thereby eliminating a major impediment to clinical use of costimulation blockers in transplantation.

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“…Treg engineering may also overcome the negative effects of costimulatory blockade, which can be used in transplantation to dampen allograft rejection by abrogating T-cell stimulation and inducing anergy. 158,159 A commonly targeted pathway is the CD80/86-CD28 pathway, which is inhibited using therapies such as CTLA-4-Ig (e.g. Belatacept and Abatacept).…”

Section: Into the Clinicmentioning

confidence: 99%

Eras of designer Tregs: Harnessing synthetic biology for immune suppression

Tuomela

Salim

Levings

2023

Immunological Reviews

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SummarySince their discovery, CD4+CD25hiFOXP3hi regulatory T cells (Tregs) have been firmly established as a critical cell type for regulating immune homeostasis through a plethora of mechanisms. Due to their immunoregulatory power, delivery of polyclonal Tregs has been explored as a therapy to dampen inflammation in the settings of transplantation and autoimmunity. Evidence shows that Treg therapy is safe and well‐tolerated, but efficacy remains undefined and could be limited by poor persistence in vivo and lack of antigen specificity. With the advent of new genetic engineering tools, it is now possible to create bespoke “designer” Tregs that not only overcome possible limitations of polyclonal Tregs but also introduce new features. Here, we review the development of designer Tregs through the perspective of three ‘eras’: (1) the era of FOXP3 engineering, in which breakthroughs in the biological understanding of this transcription factor enabled the conversion of conventional T cells to Tregs; (2) the antigen‐specificity era, in which transgenic T‐cell receptors and chimeric antigen receptors were introduced to create more potent and directed Treg therapies; and (3) the current era, which is harnessing advanced genome‐editing techniques to introduce and refine existing and new engineering approaches. The year 2022 marked the entry of “designer” Tregs into the clinic, with exciting potential for application and efficacy in a wide variety of immune‐mediated diseases.

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Costimulation blockade and Tregs in solid organ transplantation

Cited by 7 publications

References 104 publications

Single-Cell Heterogeneity Restorative Chimeric Engineering Nanoparticles for Alleviating Antibody-Mediated Allograft Injury

Single-Cell Heterogeneity Restorative Chimeric Engineering Nanoparticles for Alleviating Antibody-Mediated Allograft Injury

IL-6 inhibition prevents costimulation blockade-resistant allograft rejection in T cell-depleted recipients by promoting intragraft immune regulation in mice

Eras of designer Tregs: Harnessing synthetic biology for immune suppression

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