Control of In Vivo Collateral Damage Generated by T Cell Immunity

Thangavelu, Govindarajan; Gill, Ronald G.; Boon, Louis; Ellestad, Kristofor K.; Anderson, Colin C.

doi:10.4049/jimmunol.1203240

Cited by 17 publications

(21 citation statements)

References 30 publications

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“…In addition, the ability of TCRs to interact with tonic self‐peptide/MHC ligands opens the possibility that a co‐inhibitor blockade causes T cell effector activity to spill over onto nearby healthy cells or tumour cells that have down‐regulated tumour antigens. Increased collateral damage is indeed seen during immune responses where a co‐inhibitor is lacking . Altogether, the above concepts suggest that all T cells are temporarily activated, expressing co‐inhibitors such as CTLA‐4 that can then be targeted by anti‐CTLA‐4 antibodies.…”

Section: Anti‐ctla‐4 Antibody Blockade Induces An Uncontrolled T Cellmentioning

confidence: 99%

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Exploiting autoimmunity unleashed by low‐dose immune checkpoint blockade to treat advanced cancer

Bakács¹,

Moss²,

Kleef³

et al. 2019

Scand J Immunol

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As a result of the cancer immunotherapy revolution, more than 2000 immuno‐oncology agents are currently being tested or are in use to improve responses. Not unexpectedly, the 2018 Nobel Prize in Physiology or Medicine was awarded to James P. Allison and Tasuku Honjo for their development of cancer therapy by the blockade of co‐inhibitory signals. Unfortunately, manipulation of the co‐inhibitory receptors has also resulted in a safety issue: widespread iatrogenic immune‐related adverse events (irAEs). Autoimmunity is emerging as the nemesis of immunotherapy. Originally, it was assumed that CTLA‐4 blockade selectively targets T cells relevant to the antitumour immune response. However, an uncontrolled pan T cell activation was induced compromising tolerance to healthy self‐tissues. The irAEs are very similar to that of a chronic graft‐versus‐host‐disease (GVHD) reaction following allogeneic bone marrow transplantation (BMT). We hypothesized that ipilimumab induced a graft‐versus‐malignancy (GVM) effect, which eradicated metastatic melanoma in a minority of patients, but also involved an auto‐GVHD reaction that resulted in widespread autoimmunity in the majority. Therefore, we argued for a profound theoretical point against the consensus of experts. The task is not to desperately put the genie back in the bottle by immune‐suppressive treatments, but instead to harness the autoimmune forces. In this way, the same goal could be achieved by an antibody as by the adoptive transfer of alloreactive donor lymphocytes, but without severe GVHD. The proof‐of‐principle of a low‐dose‐combination immune checkpoint therapy, consisting only of approved drugs and treatments, was demonstrated in 111 stage IV cancer patients.

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Section: Anti‐ctla‐4 Antibody Blockade Induces An Uncontrolled T Cellmentioning

confidence: 99%

“…If this balance is perturbed, autoimmune reactions occur. To avoid collateral damage of normal tissues, natural inhibitory feedback loops, generated by co‐inhibitory signals, and also referred to as immune checkpoints, reduce inflammation following immune activation …”

Section: Introductionmentioning

confidence: 99%

Exploiting autoimmunity unleashed by low‐dose immune checkpoint blockade to treat advanced cancer

Bakács¹,

Moss²,

Kleef³

et al. 2019

Scand J Immunol

Self Cite

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show abstract

“…Another possibility, that includes naturally occurring T regs, is that these cells exist to limit “collateral damage” (Thangavelu, et al 2013) or ‘bystander effect (Anderson 2006)”. In this vein the original Danger model dealt with the generation of auto-reactive T cells in the context of an immune response to infection by suggesting that tissues, especially large and fast growing tissues could essentially “out run” the effects of auto-reactive T cells (Matzinger 1994), while small, slow growing tissues could not (Anderson, et al 2001).…”

Section: Introductionmentioning

confidence: 99%

To drive or be driven: the path of a mouse model of recurrent pregnancy loss

Bonney¹,

Brown²

2014

Reproduction

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“…During T cell response to infection, PD-1 functions to restrain collateral tissue damage [24]. Accordingly, therapeutic PD-1 blockade in the context of tumor immunotherapy is thought to work predominantly within the tumor microenvironment, where PD-1 is highly expressed on tumor-infiltrating lymphocytes [25,26] and both tumor cells and tumor infiltrating leukocytes often over express its ligands [27].…”

Section: Checkpoints and Their Tissues Of Actionmentioning

confidence: 99%

Progress and opportunities for enhancing the delivery and efficacy of checkpoint inhibitors for cancer immunotherapy

Francis

Thomas

2017

Advanced Drug Delivery Reviews

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Despite the advent of immune checkpoint blockade for effective treatment of advanced malignancies, only a minority of patients respond to therapy and significant immune-related adverse events remain to be minimized. Innovations in engineered drug delivery systems and controlled release strategies can improve drug accumulation at and retention within target cells and tissues in order to enhance therapeutic efficacy while simultaneously reducing drug exposure in off target tissues to minimize the potential for treatment-associated toxicities. This review will outline basic principles of the immune physiology of checkpoint signaling, the existing knowledge of dose-efficacy relationships in checkpoint inhibition, the influence of administration route on treatment efficacy, as well as the resulting checkpoint inhibitor antibody biodistribution profiles amongst target versus systemic tissues. It will also highlight recent successes in the application of drug delivery principles and technologies towards augmenting checkpoint blockade therapy in cancer. Delivery strategies that have been developed for other therapeutic and immunotherapy applications with as-of-yet underexplored potential in checkpoint inhibition therapy will also be discussed.

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Control of In Vivo Collateral Damage Generated by T Cell Immunity

Cited by 17 publications

References 30 publications

Exploiting autoimmunity unleashed by low‐dose immune checkpoint blockade to treat advanced cancer

Exploiting autoimmunity unleashed by low‐dose immune checkpoint blockade to treat advanced cancer

To drive or be driven: the path of a mouse model of recurrent pregnancy loss

Progress and opportunities for enhancing the delivery and efficacy of checkpoint inhibitors for cancer immunotherapy

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