The progress and perspectives of CAR-T cell therapy

CAR-T cell therapy has already achieved world-renowned clinical effects in the treatment of hematological malignancies. Due to the tumor heterogeneity, immunosuppressive microenvironment, and other factors, CAR-T cell therapy has still not shown obvious clinical efficacy in clinical treatment of solid tumors. However, great progress has been made in the preparation of CAR-T cells in recent years, including T cells redirected for universal cytokine mediated killing, universal CAR -T cells, non-viral vector CAR-T cells, SynNotch technology, SUPRA CAR technology, regulated CAR-T cells, and bi-specific CAR-T cells, etc. Future research and development of CAR-T cell therapy will be focused on these following aspects: the combined application of CAR-T cells with different targets, known as "Cocktail CAR-T cells", is expected to increase efficiency toward solid tumors; based on systemic biology/synthetic biology theories, CAR-T cells are likely to be transformed to robot or intelligent system by introducing sensors, logic gates, and logic circuits. This article mainly comments on research progress and perspectives on CAR-T cell therapy in solid tumor treatment.     

Clinical trials of CAR-T cells in China

Novel immunotherapeutic agents targeting tumor-site microenvironment are revolutionizing cancer therapy. Chimeric antigen receptor (CAR)-engineered T cells are widely studied for cancer immunotherapy. CD19-specific CAR-T cells, tisagenlecleucel, have been recently approved for clinical application. Ongoing clinical trials are testing CAR designs directed at novel targets involved in hematological and solid malignancies. In addition to trials of single-target CAR-T cells, simultaneous and sequential CAR-T cells are being studied for clinical applications. Multi-target CAR-engineered T cells are also entering clinical trials. T cell receptor-engineered CAR-T and universal CAR-T cells represent new frontiers in CAR-T cell development. In this study, we analyzed the characteristics of CAR constructs and registered clinical trials of CAR-T cells in China and provided a quick glimpse of the landscape of CAR-T studies in China.     

Combining the best of two worlds: highly flexible chimeric antigen receptor adaptor molecules (CAR-adaptors) for the recruitment of chimeric antigen receptor T cells

Chimeric antigen receptor (CAR)-engineered T cells have a proven efficacy for the treatment of refractory hematological B cell malignancies. While often accompanied by side effects, CAR-T technology is getting more mature and will become an important treatment option for various tumor indications. In this review, we summarize emerging approaches that aim to further evolve CAR-T cell therapy based on combinations of so-called universal or modular CAR-(modCAR-)T cells, and their respective adaptor molecules (CAR-adaptors), which mediate the crosslinking between target and effector cells. The activity of such modCAR-T cells is entirely dependent on binding of the respective CAR-adaptor to both a tumor antigen and to the CAR-expressing T cell. Contrary to conventional CAR-T cells, where the immunological synapse is established by direct interaction of CAR and membrane-bound target, modCAR-T cells provide a highly flexible and customizable development of the CAR-T cell concept and offer an additional possibility to control T cell activity.     

Rational design of chimeric antigen receptor T cells against glypican 3 decouples toxicity from therapeutic efficacy

BackgroundChimeric antigen receptor (CAR) T cell therapy has yielded impressive clinical results in hematological malignancies and is a promising approach for solid tumor treatment. However, toxicity, including cytokine-release syndrome (CRS) and neurotoxicity, is a concern hampering its broader use.MethodsIn selecting a lead CAR-T candidate against the oncofetal antigen glypican 3 (GPC3), we compared CARs bearing a low- and high-affinity single-chain variable fragment (scFv) binding to a similar epitope and cross-reactive with murine GPC3.ResultsWhere the high-affinity CAR-T cells were toxic in vivo, the low-affinity CAR maintained cytotoxic function against antigen-positive tumor cells but did not show toxicity against normal tissues. High-affinity CAR-induced toxicity was caused by on-target, off-tumor binding, based on the observation that higher doses of the high-affinity CAR-T caused toxicity in non–tumor-bearing mice and accumulated in organs with low expression of GPC3. To explore another layer of controlling CAR-T toxicity, we developed a means to target and eliminate CAR-T cells using anti-TNF-α antibody therapy after CAR-T infusion. The antibody was shown to function by eliminating early antigen-activated, but not all, CAR-T cells, allowing a margin where the toxic response could be effectively decoupled from antitumor efficacy with only a minor loss in tumor control. By exploring additional traits of the CAR-T cells after activation, we identified a mechanism whereby we could use approved therapeutics and apply them as an exogenous kill switch that eliminated early activated CAR-T following antigen engagement in vivo.ConclusionsBy combining the reduced-affinity CAR with this exogenous control mechanism, we provide evidence that we can modulate and control CAR-mediated toxicity.     

CAR-T immunotherapies: Biotechnological strategies to improve safety,efficacy and clinical outcome through CAR engineering

T cells engineered to express a chimeric antigen receptor (CAR) have re-shaped the way hematological malignancies are treated. Despite the overwhelming early clinical success, CAR-T therapies are associated with severe side-effects, disease relapse and often exhibit limited efficacy. In this Review article we summarize the most recent biotechnological advances that have been developed to enhance the efficacy and specificity of CAR-T therapies, as well as to address the key challenges associated with them. We place particular emphasis on the most recent clinical data that indicate which CAR-T populations are the most relevant to clinical success, and indicate how the molecular structure of the CAR receptor can affect clinical outcome. Finally, we outline what we believe is the next generation of immunotherapies.     

Time to abandon CAR-T monotherapy for solid tumors

In recent decades, chimeric antigen receptor T (CAR-T) cell therapy has achieved dramatic success in patients with hematological malignancies. However, CAR-T cell therapy failed to effectively treat solid tumors as a monotherapy. By summarizing the challenges of CAR-T cell monotherapy for solid tumors and analyzing the underlying mechanisms of combinatorial strategies to counteract these hurdles, we found that complementary therapeutics are needed to improve the scant and transient responses of CAR-T cell monotherapy in solid tumors. Further data, especially data from multicenter clinical trials regarding efficacy, toxicity, and predictive biomarkers are required before the CAR-T combination therapy can be translated into clinical settings.     

嵌合抗原受体T细胞介绍及抗肿瘤临床应用

过继性细胞免疫治疗（adoptive cellular immunotherapy,ACI）是目前较为有效的恶性肿瘤的治疗方法之一。随着技术的日趋成熟,已在多种实体瘤和血液肿瘤的t临床治疗中取得较好疗效。其中,嵌合抗原受体（chimeric antigen receptor,CAR）T细胞技术是近年来发展非常迅速的一种细胞治疗技术。通过基因改造技术,效应T细胞的靶向性、杀伤活性和持久性均较常规应用的免疫细胞高,并可克服肿瘤局部免疫抑制微环境和打破宿主免疫耐受状态。目前,CAR的信号域已从第一代的单一信号分子发展为包含CD28、4—1BB等共刺激分子的多信号结构域（第二、三代）,临床应用广泛。但是,该技术也存在脱靶效应、插入突变等临床应用风险。该文将就CAR—T细胞技术在恶性肿瘤免疫治疗中的应用及可能存在的问题作一综述。     

Chimeric antigen receptor T cells in solid tumors: a war against the tumor microenvironment

Chimeric antigen receptor(CAR) T cell is a novel approach, which utilizes anti-tumor immunity for cancer treatment. As compared to the traditional cell-mediated immunity, CAR-T possesses the improved specificity of tumor antigens and independent cytotoxicity from major histocompatibility complex molecules through a monoclonal antibody in addition to the Tcell receptor. CAR-T cell has proven its effectiveness, primarily in hematological malignancies, specifically where the CD19 CAR-T cells were used to treat B-cell acute lymphoblastic leukemia and B-cell lymphomas. Nevertheless, there is little progress in the treatment of solid tumors despite the fact that many CAR agents have been created to target tumor antigens such as CEA,EGFR/EGFRvIII, GD2, HER2, MSLN, MUC1, and other antigens. The main obstruction against the progress of research in solid tumors is the tumor microenvironment, in which several elements, such as poor locating ability, immunosuppressive cells,cytokines, chemokines, immunosuppressive checkpoints, inhibitory metabolic factors, tumor antigen loss, and antigen heterogeneity, could affect the potency of CAR-T cells. To overcome these hurdles, researchers have reconstructed the CAR-T cells in various ways. The purpose of this review is to summarize the current research in this field, analyze the mechanisms of the major barriers mentioned above, outline the main solutions, and discuss the outlook of this novel immunotherapeutic modality.     

通用型CD19 CAR-T的体外构建及初步功能鉴定

CAR-T免疫细胞治疗已经在血液肿瘤领域取得突破性进展.然而,目前上市和国内临床试验的CAR-T细胞均来自肿瘤患者自身,即自体型CAR-T.因受制于患者T细胞的质量和数量、制备周期长且价格昂贵等原因,很难将其进行大规模临床应用.该研究利用CRISPR/Cas9基因编辑技术敲除健康人脐带血来源T细胞的TCR分子和HLA-...     

细胞治疗的典范：嵌合抗原受体T细胞疗法

嵌合抗原受体T(CAR-T)细胞疗法是一种利用合成受体特异性靶向抗原的过继性细胞疗法(ACT),目前在血液肿瘤的治疗中有极大的临床应用价值。虽然美国食品药品监督管理局(FDA)已经批准两款CAR-T药物上市,但CAR-T疗法在治疗过程中仍然存在一些副作用,如细胞因子释放综合征(CRS)、神经毒性、B细胞功能缺失等。同时,CAR-T疗法在实体瘤治疗中的效果甚微,主要原因是缺乏特异性靶点以及肿瘤微环境对CAR-T细胞功能的抑制等。文中将从CAR的结构设计、临床应用、合成生物学对新型CAR的优化来阐述应用CAR-T细胞疗法治疗肿瘤所面临的挑战及广阔前景。     

Micro-hydrogel injectables that deliver effective CAR-T immunotherapy against 3D solid tumor spheroids

Chimeric antigen receptor (CAR-) T cells are revolutionizing cancer treatment, as a direct result of their clinical impact on the treatment of hematological malignancies. However for solid tumors, CAR-T cell therapeutic efficacy remains limited, primarily due to the complex immunosuppressive tumor microenvironment, inefficient access to tumor cells and poor persistence of the killer cells. In this in vitro study, an injectable, gelatin-based micro-hydrogel system that can encapsulate and deliver effective CAR-T therapy is investigated. CAR-T cells targeting TAG-72, encapsulated in these microgels possessed high viability (> 87%) after 7 days, equivalent to those grown under normal expansion conditions, with retention of the T cell phenotype and functionality. Microgel recovered CAR-T cells demonstrated potent on-target cytotoxicity against human ovarian cancer in vitro and on three-dimensional tumor spheroids, by completely eliminating tumor cells. The gelatin-based micro-hydrogels have the potential to serve as carrier systems to augment CAR-T immunotherapeutic treatment of solid tumors.     

GPC3-targeted CAR-T cells secreting B7H3-targeted BiTE exhibit potent cytotoxicity activity against hepatocellular carcinoma cell in the in vitro assay

Hepatocellular carcinoma (HCC), the most common primary liver cancer has a high mortality in China, and it is usually diagnosed at a late stage, thereby leaving patients with few effective treatment options. Chimeric antigen receptor-T (CAR-T) cell therapy, a novel immunotherapy that has shown promising results in leukemia, lymphoma and multiple myeloma, is also expected to work well in solid tumors, including HCC. However, the ideal therapeutic efficacy has not yet been achieved, in part due to tumor antigen escape caused by antigen heterogeneity. To overcome such challenge, we screened a panel of biomarkers in HCC cell lines and found that GPC3 and B7H3 were highly expressed on HCC with expression heterogeneity. Then we developed a novel bispecific T cell engagers CAR-T (CAR.T-BiTEs) that drives the expression of a CAR specific for GPC3 and BiTEs against CD3 and B7H3, herein referred to as “GPC3-BiTE CAR.” We found that BiTEs promoted the increased activation of untransduced T cells and IFN-γ release. Moreover, BiTEs secreted by GPC3-BiTE CAR-HEK293T cells promoted increased cytotoxicity activity of untransduced T cells against GPC3+/B7H3+ (GPC3 positive/B7H3 positive) and GPC3-/B7H3+(GPC3 negative/B7H3 positive) HCC cell lines. In vitro function assays showed that GPC3-BiTE CAR-T cells exhibited greater cytotoxicity activity against GPC3+/B7H3+ HCC cell lines than GPC3 CAR-T cells (GPC3-targeted CAR-T cells) and B7H3 CAR-T cells (B7H3-targeted CAR-T cells). Furthermore, GPC3-BiTE CAR-T cells exhibited superior cytotoxicity against GPC3 negative HCC cell lines compared with GPC3 CAR T cells. In conclusion, our study showed that GPC3-BiTE CAR T cells exhibited superior antitumor activity than single-target CAR-T cells and can overcome tumor escape induced by antigen heterogeneity, suggesting that this could be a promising therapeutic strategy for HCC.     

Hurdles of CAR-T cell-based cancer immunotherapy directed against solid tumors

Recent reports on the impressive efficacy of chimeric antigen receptor (CAR)-modified T cells against hematologic malignancies have inspired oncologists to extend these efforts for the treatment of solid tumors. Clinical trials of CAR-T-based cancer immunotherapy for solid tumors showed that the efficacies are not as remarkable as in the case of hematologic malignancies. There are several challenges that researchers must face when treating solid cancers with CAR-T cells, these include choosing an ideal target, promoting efficient trafficking and infiltration, overcoming the immunosuppressive microenvironment, and avoiding associated toxicity. In this review, we discuss the obstacles imposed by solid tumors on CAR-T cell-based immunotherapy and strategies adopted to improve the therapeutic potential of this approach. Continued investigations are necessary to improve therapeutic outcomes and decrease the adverse effects of CAR-T cell therapy in patients with solid malignancies in the future.     

Application of CAR-T cell technology in autoimmune diseases and human immunodeficiency virus infection treatment

Chimeric antigen receptor (CAR) T-cell therapy is an immunotherapy approach that has played a tremendous role in the battle against cancer for years. Since the CAR T lymphocytes are unrestricted-major histocompatibility complex T lymphocytes, they could identify more targets than natural T cells, resulting in practical and widespread functions. The good prospects of CAR T-cell therapy in oncology can be additionally applied to treat other diseases such as autoimmune and infectious diseases. CAR-T cell-derived immunotherapy for autoimmune disorders can be allocated to CAR-Tregs and chimeric autoantibody receptor T cells. Other generations of CARs target human immunodeficiency virus (HIV) proteins. In this review, we summarize CAR-T cell therapies in autoimmune disorders and HIV infection.     

Bicistronic CAR-T cells targeting CD123 and CLL1 for AML to reduce the risk of antigen escape

PurposeAcute myeloid leukemia (AML) is a highly heterogeneous neoplastic disease with a poor prognosis that relapses even after its treatment with chimeric antigen receptor (CAR)-T cells targeting a single antigen. CD123 and CLL1 are expressed in most AML blasts and leukemia stem cells, and their low expression in normal hematopoietic stem cells makes them ideal targets for CAR-T. In this study, we tested the hypothesis that a new bicistronic CAR targeting CD123 and CLL1 can enhance antigenic coverage and prevent antigen escape and subsequent recurrence of AML.MethodsCD123 and CLL1 expressions were evaluated on AML cell lines and blasts. Then, in addition to concentrating on CD123 and CLL1, we introduced the marker/suicide gene RQR8 with a bicistronic CAR. Xenograft models of disseminated AML and in vitro coculture models were used to assess the anti-leukemia efficacy of CAR-T cells. The hematopoietic toxicity of CAR-T cells was evaluated in vitro by colony cell formation assays. It was demonstrated in vitro that the combination of rituximab and NK cells caused RQR8-mediated clearance of 123CL CAR-T cells.ResultsWe have successfully established bicistronic 123CL CAR-T cells that can target CD123 and CLL1. 123CL CAR-T cells effectively cleared AML cell lines and blasts. They also demonstrated appreciable anti-AML activity in animal transplant models. Moreover, 123CL CAR-T cells can be eliminated in an emergency by a natural safety switch and don't target hematopoietic stem cells.ConclusionsThe bicistronic CAR-T cells targeting CD123 and CLL1 may be a useful and secure method for treating AML.     

Remote controlling of CAR-T cells and toxicity management: Molecular switches and next generation CARs

Cell-based immunotherapies have been selected for the front-line cancer treatment approaches. Among them, CAR-T cells have shown extraordinary effects in hematologic diseases including chemotherapy-resistant acute lymphoblastic leukemia (ALL), chronic lymphocytic leukemia (CLL), and non-Hodgkin lymphoma (NHL). In this approach, autologous T cells isolated from the patient''s body genetically engineered to express a tumor specific synthetic receptor against a tumor antigen, then these cells expanded ex vivo and re-infusion back to the patient body. Recently, significant clinical response and high rates of complete remission of CAR T cell therapy in B-cell malignancies led to the approval of Kymriah and Yescarta (CD19-directed CAR-T cells) were by FDA for treatment of acute lymphoblastic leukemia and diffuse large B-cell lymphoma. Despite promising therapeutic outcomes, CAR T cells also can elicit the immune-pathologic effects, such as Cytokine Release Syndrome (CRS), Tumor Lysis Syndrome (TLS), and on-target off-tumor toxicity, that hampered its application. Ineffective control of these highly potent synthetic cells causes discussed potentially life-threatening toxicities, so researchers have developed several mechanisms to remote control CAR T cells. In this paper, we briefly review the introduced toxicities of CAR-T cells, then describe currently existing control approaches and review their procedure, pros, and cons.     

Genetic engineering of T cells with chimeric antigen receptors for hematological malignancy immunotherapy

The host immune system plays an instrumental role in the surveillance and elimination of tumors by recognizing and destroying cancer cells. In recent decades, studies have mainly focused on adoptive immunotherapy using engineered T cells for the treatment of malignant diseases. Through gene engraftment of the patient’s own T cells with chimeric antigen receptor (CAR), they can recognize tumor specific antigens effectively and eradicate selectively targeted cells in an MHC-independent fashion. To date, CAR-T cell therapy has shown great clinical utility in patients with B-cell leukemias. Owing to different CAR designs and tumor complex microenvironments, genetically redirected T cells may generate diverse biological properties and thereby impact their long-term clinical performance and outcome. Meanwhile some unexpected toxicities that result from CAR-T cell application have been examined and limited the curative effects. Diverse important parameters are closely related with adoptively transferred cell behaviors, including CAR-T cells homing, CAR constitutive signaling, T cell differentiation and exhaustion. Thus, understanding CARs molecular design to improve infused cell efficacy and safety is crucial to clinicians and patients who are considering this novel cancer therapeutics. In this review, the developments in CAR-T cell therapy and the limitations and perspectives in optimizing this technology towards clinical application are discussed.     

CAR-T Cell Therapy for Breast Cancer: From Basic Research to Clinical Application

Breast cancer rises as the most commonly diagnosed cancer in 2020. Among women, breast cancer ranks first in both cancer incidence rate and mortality. Treatment resistance developed from the current clinical therapies limits the efficacy of therapeutic outcomes, thus new treatment approaches are urgently needed. Chimeric antigen receptor (CAR) T cell therapy is a type of immunotherapy developed from adoptive T cell transfer, which typically uses patients'' own immune cells to combat cancer. CAR-T cells are armed with specific antibodies to recognize antigens in self-tumor cells thus eliciting cytotoxic effects. In recent years, CAR-T cell therapy has achieved remarkable successes in treating hematologic malignancies; however, the therapeutic effects in solid tumors are not up to expectations including breast cancer. This review aims to discuss the development of CAR-T cell therapy in breast cancer from preclinical studies to ongoing clinical trials. Specifically, we summarize tumor-associated antigens in breast cancer, ongoing clinical trials, obstacles interfering with the therapeutic effects of CAR-T cell therapy, and discuss potential strategies to improve treatment efficacy. Overall, we hope our review provides a landscape view of recent progress for CAR-T cell therapy in breast cancer and ignites interest for further research directions.     

Chimeric antigen receptor-modified T cells for the immunotherapy of patients with EGFR-expressing advanced relapsed/refractory non-small cell lung cancer

The successes achieved by chimeric antigen receptor-modified T(CAR-T) cells in hematological malignancies raised the possibility of their use in non-small lung cancer(NSCLC). In this phase I clinical study(NCT01869166), patients with epidermal growth factor receptor(EGFR)-positive(50% expression), relapsed/refractory NSCLC received escalating doses of EGFR-targeted CAR-T cell infusions. The EGFR-targeted CAR-T cells were generated from peripheral blood after a 10 to 13-day in vitro expansion. Serum cytokines in peripheral blood and copy numbers of CAR-EGFR transgene in peripheral blood and in tissue biopsy were monitored periodically. Clinical responses were evaluated with RECIST1.1 and immune-related response criteria, and adverse events were graded with CTCAE 4.0. The EGFR-targeted CAR-T cell infusions were well-tolerated without severe toxicity. Of 11 evaluable patients, two patients obtained partial response and five had stable disease for two to eight months. The median dose of transfused CAR+ T cells was 0.97×10~7 cells kg~(-1)(interquartile range(IQR), 0.45 to 1.09×10~7 cells kg~(-1)). Pathological eradication of EGFR positive tumor cells after EGFR-targeted CAR-T cell treatment can be observed in tumor biopsies, along with the CAR-EGFR gene detected in tumor-infiltrating T cells in all four biopsied patients. The EGFR-targeted CAR-T cell therapy is safe and feasible for EGFR-positive advanced relapsed/refractory NSCLC.     

CAR19/22 T cell cocktail therapy for B-ALL relapsed after allogeneic hematopoietic stem cell transplantation

B cell acute lymphocytic leukemia (B-ALL) patients who have relapsed after hematopoietic stem cell transplantation (HSCT) have a poor prognosis, and there is currently no standard approach available. Chimeric antigen receptor (CAR)-T cells induce high rates of initial response and long-term remission among patients with B-cell malignancies, especially B-ALL. Meanwhile, sequential infusion of CAR19/22 T cells has been proven to be effective at preventing tumor immune escape. In the present study, we retrospectively analyzed 23 B-ALL patients who relapsed after allogeneic (allo)-HSCT and underwent sequential infusion of CAR19/22 T cells, including nine donor-derived and 14 recipient-derived, in our center from July 2016 to July 2020, to evaluate the safety and efficacy of the cocktail of two single-specific CAR-T cells in B-ALL patients relapsed after transplantation. Except for one patient refusing evaluation, the remaining 22 patients achieved minimal residual disease (MRD)-negative complete remission within 30 days after CAR-T infusion. Most toxicities were slight and reversible. The estimated 12-month progression-free survival (PFS) rate was 59.2% (95% confidence interval [CI], 35.9% to 76.5%), and the estimated 12-month overall survival (OS) rate was 67.4% (95% CI, 43.2% to 83.1%). Only two patients had CD19-negative recurrence. In addition, early recurrence after transplantation, graft-versus-host disease (GVHD) and severe infection after CAR-T infusion were poor prognostic factors. Our results indicate that sequential infusion of CAR19/22 T cells is safe and effective for relapsed ALL patients after HSCT. This trial was registered at www.chictr.org.cn as #ChiCTR-OPN-16008526.