Redirection of Genetically Engineered CAR-T Cells Using Bifunctional Small Molecules

Kim, Min Soo; Jennifer, S. Y.; Yun, Hwayoung; Cao, Yu; Kim, Ji Young; Chi, Victor; Wang, Danling; Woods, Ashley K.; Sherwood, Lance; Caballero, Dawna; González, José; Schultz, Peter G.; Young, Travis S.; Kim, Chan Hyuk

doi:10.1021/jacs.5b00106

Cited by 145 publications

(130 citation statements)

References 28 publications

(37 reference statements)

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“…To redirect the specificity of CAR-T cells with a switch molecule, we first generated CAR-T cells that bind the synthetic dye, fluorescein (FITC), which is physiologically absent and has demonstrated excellent selectivity in imaging agents and in antibody or smallmolecule-based switch designs (18,20,23). We generated CAR-T cells using a range of anti-FITC scFv sequences that differ in their affinities toward FITC (24)(25)(26)(27), and found that all anti-FITC CAR-T cells elicit in vitro cytotoxicity with the same switch (vide infra) to a similar extent (SI Appendix, Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Examples of switches used in this approach include TAA-specific monoclonal antibodies that elicit antitumor activity from Fc-specific CAR-T cells (17), and chemically or enzymatically modified antibody-hapten conjugates that redirect antihapten CAR-T cells (18,19). Recently, we have demonstrated the redirection of anti-FITC CAR-T cells with a heterobifunctional small-molecule switch, folate-FITC, which selectively targets folate receptor-overexpressing cancers (20). Although these reports established the feasibility of eliciting an anticancer response with switchable CAR-T (sCAR-T) cells, it has yet to be shown whether the efficacy of sCAR-T cells is comparable to current CAR-T cell therapies in the clinic.…”

Section: Significancementioning

confidence: 99%

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Versatile strategy for controlling the specificity and activity of engineered T cells

Jennifer

Kim

Kazane

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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227

231

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The adoptive transfer of autologous T cells engineered to express a chimeric antigen receptor (CAR) has emerged as a promising cancer therapy. Despite impressive clinical efficacy, the general application of current CAR–T-cell therapy is limited by serious treatment-related toxicities. One approach to improve the safety of CAR-T cells involves making their activation and proliferation dependent upon adaptor molecules that mediate formation of the immunological synapse between the target cancer cell and T-cell. Here, we describe the design and synthesis of structurally defined semisynthetic adaptors we refer to as “switch” molecules, in which anti-CD19 and anti-CD22 antibody fragments are site-specifically modified with FITC using genetically encoded noncanonical amino acids. This approach allows the precise control over the geometry and stoichiometry of complex formation between CD19- or CD22-expressing cancer cells and a “universal” anti-FITC–directed CAR-T cell. Optimization of this CAR–switch combination results in potent, dose-dependent in vivo antitumor activity in xenograft models. The advantage of being able to titrate CAR–T-cell in vivo activity was further evidenced by reduced in vivo toxicity and the elimination of persistent B-cell aplasia in immune-competent mice. The ability to control CAR-T cell and cancer cell interactions using intermediate switch molecules may expand the scope of engineered T-cell therapy to solid tumors, as well as indications beyond cancer therapy.

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Section: Resultsmentioning

confidence: 99%

Section: Significancementioning

confidence: 99%

Versatile strategy for controlling the specificity and activity of engineered T cells

Jennifer

Kim

Kazane

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

227

231

View full text Add to dashboard Cite

show abstract

“…Such molecules mediate the binding between antigen and CAR, for example, a linker consisting of folate conjugated to fluorescein isothiocyanate (folate-FITC) can redirect and regulate FITC-specific CAR T cell activity toward folate receptor)-overexpressing tumour cells. 64 Finally, CAR T cells have been engineered that have split receptors, in which antigenbinding and all necessary intracellular signalling components assemble only in the presence of a titratable small molecule. 65 Regardless of the mechanism, on or off switches add in vivo control over CAR T cell function and potentially enhance safety.…”

Section: 61mentioning

confidence: 99%

Clinical Development and Manufacture of Chimeric Antigen Receptor T cells and the Role of Leukapheresis

Fesnak¹,

O’Doherty²

2017

European Oncology &Amp; Haematology

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Adoptive transfer of chimeric antigen receptor (CAR) T cells is a powerful targeted immunotherapeutic technique. CAR T cells are manufactured by harvesting mononuclear cells, typically via leukapheresis from a patient’s blood, then activating, modifying the T cells to express a transgene encoding a tumour-specific CAR, and infusing the CAR T cells into the patient. Gene transfer is achieved through the use of retroviral or lentiviral vectors, although non-viral delivery systems are being investigated. This article discusses the challenges associated with each stage of this process. Despite the need for a consistent end product, there is inherent variability in cellular material obtained from critically ill patients who have been exposed to cytotoxic therapy. It is important to carefully select target antigens to maximise effect and minimise toxicity. Various types of CAR T cell toxicity have been documented: this includes “on target, on tumour”, “on target, off tumour” and “off target” toxicity. A growing body of clinical evidence supports the efficacy and safety of CAR T cell therapy; CAR T cells targeting CD19 in B cell leukemias are the best-studied therapy to date. However, providing personalised therapy on a large scale remains challenging; a future aim is to produce a universal “off the shelf” CAR T cell.

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“…In an alternative approach, the CAR binds to a protein epitope, which is not encoded by the human genome and which is linked to cancer-targeting antibodies [54]. In another example, folate receptor-positive cancer cells were marked by a fluorescein isothiocyanate (FITC)-conjugated folate which binds to the cancer cells and is recognized by a FITC-specific CAR [55,56]. By using more than one FITC-labeled molecule which mark the cancer cells, the same CAR T cell can target multiple types of cells within the tumor lesion.…”

Section: Cars With Exchangeable Antigen Recognitionmentioning

confidence: 99%

CARs on the Highway: Chimeric Antigen Receptor Modified T Cells for the Adoptive Cell Therapy of Malignant Diseases

Holzinger¹,

Abken²

2017

Immunotherapy - Myths, Reality, Ideas, Future

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Adoptive therapy of malignant diseases by chimeric antigen receptor (CAR) redirected T cells takes advantage of the patient's own immune system to recognize and destroy cancer cells. This is impressively demonstrated by the induction of complete and lasting remissions of leukemia with CAR-engineered T cells in early phase trials. Recent developments in optimizing the CAR design, in the recognition of target cells and the production of modified cells for clinical use, have paved the path for a broader application than currently explored. The chapter reviews the differences in CAR design, the success in the treatment of hematologic malignancies, the challenges in treating solid cancer, the treatment-related toxicities, and strategies to improve safety of CAR T cell therapy. Challenges for future applications are discussed.

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Redirection of Genetically Engineered CAR-T Cells Using Bifunctional Small Molecules

Cited by 145 publications

References 28 publications

Versatile strategy for controlling the specificity and activity of engineered T cells

Versatile strategy for controlling the specificity and activity of engineered T cells

Clinical Development and Manufacture of Chimeric Antigen Receptor T cells and the Role of Leukapheresis

CARs on the Highway: Chimeric Antigen Receptor Modified T Cells for the Adoptive Cell Therapy of Malignant Diseases

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