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CAR 2.0: The Next Generation of Synthetic Receptor–Based Cellular Therapy for Cancer
Introduction
The growing clinical experience with chimeric antigen receptor (CAR) T-cells targeting CD19 has indicated that this therapy can induce remission in a high percentage of relapsed and refractory patients with B-cell precursor acute lymphoblastic leukemia (BCP-ALL) or B-cell non-Hodgkin's lymphoma (NHL) that is durable in some patients but has also highlighted a number of challenges. These include relapse of malignancy that retains expression of CD19 associated with lack of CAR persistence or the emergence of leukemia no longer expressing the target antigen. In addition, complex patterns of toxicities are being observed that, unlike cytokine release syndrome (CRS), can be unpredictable. These challenges have led to ongoing efforts to improve the CAR manufacturing platform and construct design. These improvements are also being developed to facilitate the expansion of this promising therapy to novel indications for other hematologic malignancies, solid tumors, and nonmalignant disorders. These challenges, along with potential solutions, are summarized in Table 13.1 and will be addressed throughout this chapter. The first three challenges have already been observed in patients treated with products targeting CD19 already approved by the Food and Drug Administration (FDA) and the European Medicines Agency (EMA), while the remaining represent gaps likely to emerge in the future design of CAR T-cells for hematologic and nonhematologic malignancies.
Table 13.1
Brief summary of challenges and potential solutions in CAR T-cell therapy.
| Challenges | Potential Solutions |
|---|---|
| Loss of CAR T-cell persistence |
|
| Loss of target antigen on the malignant T-cells |
|
| Short-term toxicity (CRS and ICANS) |
|
| Specificity of targeting, preventing on-target, off-tumor effects |
|
| Improved localization in the tumor microenvironment or CNS |
|
| Using off-the-shelf platforms for cellular therapy |
|
CAR , chimeric antigen receptor; CNS , central nervous system; CRS , cytokine release syndrome; ICANS , immune effector cell–associated neurotoxicity syndrome; NK , natural killer; TCR , T-cell receptor.
Improving Persistence
The Advantage of Costimulation
The major design improvement leading to success of CAR T-cells in patients was the addition of a costimulatory domain to the CAR backbone, providing a second signal in addition to that provided by the T-cell receptor signaling domain, leading to enhanced T-cell engagement and persistence in preclinical models and clinical trials. , The two most common costimulatory domains included in the CAR construct are CD28 and 4-1BB (CD137) although others, such as OX40 , have been tested in patients. Inherent differences between CD28 and 4-1BB in relation to T-cell activation via the endogenous T-cell receptor appear to have functional implications when implemented in the CAR design. CD28 is uniformly expressed on T-cells, is activated by binding to CD80 or CD86 on antigen-presenting cells, and leads to rapid activation of the T-cell with a skewing toward effector differentiation. 4-1BB, on the other hand, is expressed only on activated T-cells and, when engaged by its ligand (4-1BBL), leads to further stimulation of the T-cell but skewed toward a memory T-cell phenotype. Consistent with this natural biology, preclinical work has shown that synthetic 4-1BB-containing CARs are less prone to T-cell exhaustion and lead to superior T-cell persistence in animal models. , Indeed, T-cell durability has been observed in many clinical trials using 4-1BB-based CARs and, although not directly compared, seems more prolonged than persistence of CD28-based CARs. Third-generation CARs, incorporating two costimulatory domains, introduce an additional layer of complexity and have shown superiority to second-generation CD28-based CARs in small series although results have been inconsistent. Preclinical work incorporating ICOS in addition to 4-1BB has demonstrated superiority of these third-generation CARs in some studies but have not been tested in patients. An alternative design was introduced, which uses the natural ligand for 4-1BB, 4-1BBL introduced into the T-cells with a CD28-based second generation CAR, and generates the complementary ligand activation by cis-signaling, leading to improved function and durability in preclinical models. This approach, termed “armored CAR,” is currently tested in a clinical trial ( NCT03085173 ), with preliminary results demonstrating persistence in several patients. Finally, targeted mutation-selective immune-receptor tyrosine-based activation motifs (ITAMs) in the CD3 zeta chain of CD28 containing CARs have also demonstrated improved persistence in preclinical studies, suggesting that the alterations to the CAR design can modify in vivo behavior of CAR T-cells.
Targeting T-Cell Inhibitory Checkpoints
Exhaustion is a main contributor to loss of functionality and durability of T-cells stimulated through the endogenous T-cell receptor and is mediated by several receptors, including CTLA-4 and PD-1. Administration of antibodies blocking these immune checkpoint pathways has led to long-term remissions in patients with solid tumors and Hodgkin's lymphoma, resulting in FDA and EMA approval. Theoretically, these agents could enhance activity and persistence of CAR T-cells, a question being studied in numerous clinical trials (for example, NCT03726515 and NCT03287817 ). As an engineering strategy, genetic deletion of PD-1 in T-cells prior to CAR transduction was performed and showed improved functionality in preclinical models. This approach has not reached clinical trials yet.
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