CAR T targets and microenvironmental barriers of osteosarcoma

Osteosarcoma (OS) is one of the most common malignancies in children and adolescents. Multimodal chemotherapy and aggressive surgical resection have improved the prognosis of patients with osteosarcoma. However, the prognosis of OS patients with unresectable advanced tumors, distant metastasis or chemotherapy is still poor. Chimeric antigen receptor (CAR) T cells have achieved remarkable success in the treatment of hematologic malignancies, injecting new vitality into the field of adoptive cell therapy. However, the efficacy in solid tumors has been largely limited. The reason for the poor curative effect of solid tumors is mainly the heterogeneity of solid tumor antigen, immune escape, tumor microenvironment barrier, resistance of immunosuppressive cells and inhibitory factors, which lead to the obstruction of CAR T cell infiltration and the aggravation of failure. Potential antigenic targets for osteosarcoma CAR T cell therapy are under continuous exploration. Some of the antigenic targets, such as anti-HER2-CAR T cells, have achieved good results in preclinical studies, and some of them have entered clinical studies and achieved certain clinical effects. In this review, we discuss the research progress of potential antigen targets and osteosarcoma microenvironment of CAR T cells in the treatment of osteosarcoma.     

CD19‐CAR engineered NK‐92 cells are sufficient to overcome NK cell resistance in B‐cell malignancies

Many B‐cell acute and chronic leukaemias tend to be resistant to killing by natural killer (NK) cells. The introduction of chimeric antigen receptors (CAR) into T cells or NK cells could potentially overcome this resistance. Here, we extend our previous observations on the resistance of malignant lymphoblasts to NK‐92 cells, a continuously growing NK cell line, showing that anti‐CD19‐CAR (αCD19‐CAR) engineered NK‐92 cells can regain significant cytotoxicity against CD19 positive leukaemic cell lines and primary leukaemia cells that are resistant to cytolytic activity of parental NK‐92 cells. The ‘first generation’ CAR was generated from a scFv (CD19) antibody fragment, coupled to a flexible hinge region, the CD3ζ chain and a Myc‐tag and cloned into a retrovirus backbone. No difference in cytotoxic activity of NK‐92 and transduced αCD19‐CAR NK‐92 cells towards CD19 negative targets was found. However, αCD19‐CAR NK‐92 cells specifically and efficiently lysed CD19 expressing B‐precursor leukaemia cell lines as well as lymphoblasts from leukaemia patients. Since NK‐92 cells can be easily expanded to clinical grade numbers under current Good Manufactoring Practice (cGMP) conditions and its safety has been documented in several phase I clinical studies, treatment with CAR modified NK‐92 should be considered a treatment option for patients with lymphoid malignancies.     

Demonstrating the Manufacture of Human CAR‐T Cells in an Automated Stirred‐Tank Bioreactor

Chimeric antigen receptor T‐cell (CAR‐T) therapies have proven clinical efficacy for the treatment of hematological malignancies. However, CAR‐T cell therapies are prohibitively expensive to manufacture. The authors demonstrate the manufacture of human CAR‐T cells from multiple donors in an automated stirred‐tank bioreactor. The authors successfully produced functional human CAR‐T cells from multiple donors under dynamic conditions in a stirred‐tank bioreactor, resulting in overall cell yields which were significantly better than in static T‐flask culture. At agitation speeds of 200 rpm and greater (up to 500 rpm), the CAR‐T cells are able to proliferate effectively, reaching viable cell densities of >5 × 10⁶ cells ml‐1 over 7 days. This is comparable with current expansion systems and significantly better than static expansion platforms (T‐flasks and gas‐permeable culture bags). Importantly, engineered T‐cells post‐expansion retained expression of the CAR gene and retained their cytolytic function even when grown at the highest agitation intensity. This proves that power inputs used in this study do not affect cell efficacy to target and kill the leukemia cells. This is the first demonstration of human CAR‐T cell manufacture in stirred‐tank bioreactors and the findings present significant implications and opportunities for larger‐scale allogeneic CAR‐T production.     

嵌合抗原受体T细胞治疗的现状与展望

肿瘤严重威胁着人类健康,当前肿瘤传统的治疗方法有手术治疗、化疗、放疗和靶向药物治疗等。近年来,肿瘤免疫治疗,尤其是嵌合抗原受体（chimeric antigen receptor,CAR） T细胞免疫疗法在基础研究与临床应用中蓬勃发展,并在治疗血液系统恶性肿瘤方面取得了巨大成功。然而,大量研究显示,细胞免疫治疗后可出现不同程度的毒副反应,且部分患者缓解后再次复发。因此,了解细胞治疗面临的挑战与局限性,寻找解决的办法,对继续发挥细胞免疫疗法的潜能具有重要意义。本文就免疫细胞的CAR结构、病毒载体的选择、细胞治疗面临的挑战及前景进行综述。     

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.     

Inducible secretion of IL-21 augments anti-tumor activity of piggyBac-manufactured chimeric antigen receptor T cells

BackgroundThe efficiency of chimeric antigen receptor (CAR) T-cell-based therapies depends on a sufficient expansion of CAR T cells in vivo and can be weakened by intra-tumoral suppression of CAR T cell functions, leading to a failure of therapy. For example, certain B-cell malignancies such as chronic lymphocytic leukemia are weakly sensitive to treatment with CAR T cells. Co-expression of proinflamatory cytokines such as IL-12 and IL-18 by CAR T cells have been shown to enhance their antitumor function. We similarly engineered CAR T cell to co-express IL-21 and studied the effects of IL-21 on CAR T cells specific to CD19 and prostate-specific membrane antigens using an in vitro co-culture model and NSG mice transplanted with B-cell tumors.ResultsIL-21 enhanced the expansion of CAR T cells after antigenic stimulation, reduced the level of apoptosis of CAR T cells during co-culture with tumor cells and prevented differentiation of CAR T cells toward late memory phenotypes. In addition, induced secretion of IL-21 by CAR T cells promoted tumor infiltration by CD19-specific CAR (CAR19) T cells in NSG mice, resulting in reduced tumor growth. By co-culturing CAR19 T cells with bone-marrow fragments infiltrated with CLL cells we demonstrate that IL-21 reduces the immunosupressive activity of CLL cells against CAR19 T cells.ConclusionsCAR19 T cells armed with IL-21 exhibited enhanced antitumor functions. IL-21 promoted their proliferation and cytotoxicity against chronic lymphocytic leukemia (CLL). The results suggest that arming CAR T cells with IL-21 could boost the effectiveness of CAR T-mediated therapies.     

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.     

Secretion of human soluble programmed cell death protein 1 by chimeric antigen receptor-modified T cells enhances anti-tumor efficacy

Background aimsChimeric antigen receptor (CAR) T cells have achieved favorable responses in patients with hematologic malignancies, but the outcome has been far from satisfactory in the treatment of tumors with high expression of immunosuppressive molecules. To overcome this limitation, we modified CAR T cells to secrete types of human soluble programmed cell death protein 1 (PD-1) called sPD-1 CAR T cells.MethodsTo compare the effector function between second (conventional second-generation CAR targeting CD19) and sPD-1 CAR T cells, we measured cytotoxicity, cytokine secretion and activation markers incubated with or without tumor cells expressing CD19 and/or programmed cell death ligand 1 (PD-L1). Furthermore, the anti-tumor efficacy of second and sPD-1 CAR T cells was determined using an NSG mouse model bearing NALM-6-PD-L1. Finally, the underlying mechanism was investigated by metabolic parameters and RNA sequencing analysis of different CAR T cells.ResultsCompared with second CAR T cells, sPD-1 CAR T cells enhanced killing efficiency toward CD19⁺PD-L1⁺ tumor cells in vitro. Furthermore, sPD-1 CAR T cells reduced the tumor burden and prolonged overall survival of the NSG (NOD-SCID-IL2rg) mice bearing NALM-6-PD-L1. To explore the effect of soluble PD-1 on CAR T cells, we found that sPD-1 CAR T cells exhibited higher levels of activation and ameliorative profiles of differentiation, exhaustion, glycolysis and apoptosis.ConclusionsWith constitutive soluble PD-1 secretion, sPD-1 CAR T cells have tended to eradicate tumors with a high expression of PD-L1 more effectively than second CAR T cells. This may be due to soluble PD-1 enhancing apoptosis resistance, aerobic metabolism and a more “stem” differentiation of CAR T cells. Overall, our study presents a feasible strategy to increase the efficacy of CAR T cells.     

Irradiated chimeric antigen receptor engineered NK-92MI cells show effective cytotoxicity against CD19+ malignancy in a mouse model

Background aimsAnti-CD19 chimeric antigen receptor (CAR)-modified T cells have shown dramatic cytotoxicity against B-cell malignancies. Currently, autologous T cells are conventionally used to manufacture CAR T cells. Low quality or insufficient quantity of autologous T cells may lead to failure of CAR T preparations. Moreover, CAR T preparation usually takes 1–2 weeks, which is too long for patients with rapid disease progression to successfully infuse CAR T cells. Thus, the development of a ready-to-use CAR immunotherapy strategy is needed. NK-92, a natural killer (NK) cell line derived from an NK lymphoma patient, has been gradually applied as a CAR-modified effector cell. To avoid the potential development of secondary NK lymphoma in patients, large doses of radiation are used to treat NK-92 cells before clinical application, which ensures the safety but reduces the cytotoxicity of NK-92 cells. Therefore, it is crucial to explore a suitable radiation dose that ensures short life span and good cytotoxicity of CAR NK-92 cells.MethodsNK-92MI, a modified IL-2-independent NK-92 cell line, was used to establish an anti-CD19 CAR NK. The suitable radiation dose of CAR NK was then explored in vitro and validated in vivo, and the specific cytotoxicity of irradiated and unirradiated CAR NK against CD19⁺ malignant cells was assessed.ResultsCAR NK exhibited specific cytotoxicity against CD19⁺ malignant cells. Irradiation ensured a short life span of CAR NK in vitro and in vivo. Encouragingly, irradiated CAR NK displayed an anti-CD19⁺ malignancy capacity similar to that of unirradiated CAR NK.ConclusionsFive Gy is a suitable radiation dose to ensure the safety and effectiveness of CD19 CAR NK-92MI cells.     

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.     

Blocking CD38-driven fratricide among T cells enables effective antitumor activity by CD38-specific chimeric antigen receptor T cells

Chimeric antigen receptor T-cell(CAR T) therapy is a kind of effective cancer immunotherapy. However,designing CARs remains a challenge because many targetable antigens are shared by T cells and tumor cells. This shared expression of antigens can cause CAR T cell fratricide. CD38-targeting approaches(e.g.,daratumumab) have been used in clinical therapy and have shown promising results. CD38 is a kind of surface glycoprotein present in a variety of cells, such as T lymphocytes and tumor cells. It was previously reported that CD38-based CAR T cells may undergo apoptosis or T cell-mediated killing(fratricide) during cell manufacturing. In this study, a CAR containing a sequence targeting human CD38 was designed to be functional. To avoid fratricide driven by CD38 and ensure the production of CAR T cells, two distinct strategies based on antibodies(clone MM12 T or clone MM27) or proteins(H02 H or H08 H) were used to block CD38 or the CAR single-chain variable fragment(scFv) domain, respectively, on the T cell surface.The results indicated that the antibodies or proteins, especially the antibody MM27, could affect CAR T cells by inhibiting fratricide while promoting expansion and enrichment. Anti-CD38 CAR T cells exhibited robust and specific cytotoxicity to CD38~+ cell lines and tumor cells. Furthermore, the levels of the proinflammatory factors TNF-a, IFN-g and IL-2 were significantly upregulated in the supernatants of A549~(CD38~+) cells. Finally, significant control of disease progression was demonstrated in xenograft mouse models. In conclusion, these findings will help to further enhance the expansion, persistence and function of anti-CD38 CAR T cells in subsequent clinical trials.     

Predictive and therapeutic biomarkers in chimeric antigen receptor T-cell therapy: A clinical perspective

The adoptive transfer of genetically engineered T cells modified to express a chimeric antigen receptor (CAR) has shown remarkable activity and induces long-term remissions in patients with advanced hematologic malignancies. To date, little is known about predictive indicators of therapeutic efficacy or serious toxicity after CAR T-cell therapy in clinical practice. Biomarkers are not only potentially able to inform physicians and researchers of immunotherapy targets in particular but could also be used to monitor the effectiveness of treatments and to predict incidence of side effects in some circumstances. Identification of new biomarkers can therefore not only contribute to the development of new therapeutic and prognostic strategies for CAR T-cell therapy for cancer but also help to generate improved clinical practices for early recognition and minimization of adverse effects while preserving the antitumor activity of the CAR T cells. Herein, we will consider a variety of predictive and therapeutic biomarkers in CAR T-cell therapy and the state of current understanding of their clinical utility. The incorporation of biomarker studies in CAR T-cell clinical trials and practice will help to realize the potential clinical benefit of biomarker-guided therapy.     

Adoptive therapy with CAR redirected T cells for hematological malignancies

The survival of patients with hematological malignancies has been significantly improved due to the development of new therapeutic agents. However, relapse remains a major matter for concern. Recently, T cells engineered with chimeric antigen receptor(CAR) were reported to show unprecedented responses in a range of hematological malignancies. The persistence of the CAR-T cell can last for years and tends toward long-term antitumor memory by which relapses can be effectively prevented. The primary side effects that appear in most clinical trials are cytokine release syndrome and neurotoxicity. However, these symptoms can be treated and reversed. In this review, we describe CAR structure and function and summarize recent advances in CAR-T cell therapy in hematological malignancies.     

CAR T cells transform to trucks: chimeric antigen receptor–redirected T cells engineered to deliver inducible IL-12 modulate the tumour stroma to combat cancer

Adoptive T cell therapy recently achieved impressive efficacy in early-phase clinical trials; this significantly raises the profile of immunotherapy in the fight against cancer. A broad variety of tumour cells can specifically be targeted by patients' T cells, which are redirected in an antibody-defined, major histocompatibility complex-unrestricted fashion by endowing them with a chimeric antigen receptor (CAR). Despite promising results for some haematologic malignancies, the stroma of large, established tumours, the broad plethora of infiltrating repressor cells, and cancer cell variants that had lost the target antigen limit their therapeutic efficacy in the long term. This article reviews a newly described strategy for overcoming some of these shortcomings by engineering CAR T cells with inducible or constitutive release of IL-12. Once redirected, these T cells are activated, and released IL-12 accumulates in the tumour lesion where it promotes tumour destruction by at least two mechanisms: (1) induction of an innate immune cell response towards those cancer cells which are invisible to redirected T cells and (2) triggering programmatic changes in immune-suppressive cells. Given the enormous complexity of both tumour progression and immune attack, the upcoming strategies using CAR-redirected T cells for local delivery of immune-modulating payloads exhibited remarkable efficacy in pre-clinical models, suggesting their evaluation in clinical trials.     

CAR-NK治疗肿瘤的研究与临床进展

肿瘤细胞免疫疗法近年来的发展颇为瞩目,嵌合抗原受体T（CAR-T）的临床研究显示其对血液系统肿瘤具有良好的治疗效果。自然杀伤细胞（NK）是人体固有免疫的一类重要细胞,其不同于T细胞的非特异性识靶及杀伤机制吸引科学家将工程CAR-T技术沿袭并用于嵌合抗原受体NK（CAR-NK）改造。目前,无论在体外细胞模型还是小鼠动物模型中,CAR-?NK均显示出良好的肿瘤杀伤效果。最新的临床研究显示,CAR-NK细胞对血液系统肿瘤有良好的治疗效果,但治疗实体瘤效果尚待验证。与CAR-T细胞疗法一样,CAR-NK也有问题亟需解决,但是NK细胞作为效应细胞,其自身优点预示CAR-NK细胞在实体瘤治疗方面拥有良好的发展前景。     

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.     

Adoptive immunotherapy for acute leukemia: New insights in chimeric antigen receptors

Relapses remain a major concern in acute leukemia. It is well known that leukemia stem cells (LSCs) hide in hematopoietic niches and escape to the immune system surveillance through the outgrowth of poorly immunogenic tumor-cell variants and the suppression of the active immune response. Despite the introduction of new reagents and new therapeutic approaches, no treatment strategies have been able to definitively eradicate LSCs. However, recent adoptive immunotherapy in cancer is expected to revolutionize our way to fight against this disease, by redirecting the immune system in order to eliminate relapse issues. Initially described at the onset of the 90’s, chimeric antigen receptors (CARs) are recombinant receptors transferred in various T cell subsets, providing specific antigens binding in a non-major histocompatibility complex restricted manner, and effective on a large variety of human leukocyte antigen-divers cell populations. Once transferred, engineered T cells act like an expanding “living drug” specifically targeting the tumor-associated antigen, and ensure long-term anti-tumor memory. Over the last decades, substantial improvements have been made in CARs design. CAR T cells have finally reached the clinical practice and first clinical trials have shown promising results. In acute lymphoblastic leukemia, high rate of complete and prolonged clinical responses have been observed after anti-CD19 CAR T cell therapy, with specific but manageable adverse events. In this review, our goal was to describe CAR structures and functions, and to summarize recent data regarding pre-clinical studies and clinical trials in acute leukemia.     

Pharmacokinetic and pharmacodynamic studies of CD19 CAR T cell in human leukaemic xenograft models with dual-modality imaging

In recent years, chimeric antigen receptor T (CAR T)-cell therapy has shown great potential in treating haematologic disease, but no breakthrough has been achieved in solid tumours. In order to clarify the antitumour mechanism of CAR T cell in solid tumours, the pharmacokinetic (PK) and pharmacodynamic (PD) investigations of CD19 CAR T cell were performed in human leukaemic xenograft mouse models. For PK investigation, we radiolabelled CD19 CAR T cell with ⁸⁹Zr and used PET imaging in the CD19-positive and the CD19-negative K562-luc animal models. For PD evaluation, optical imaging, tumour volume measurement and DNA copy-number detection were performed. Unfortunately, the qPCR results of the DNA copy number in the blood were below the detection limit. The tumour-specific uptake was higher in the CD19-positive model than in the CD19-negative model, and this was consistent with the PD results. The preliminary PK and PD studies of CD19 CAR T cell in solid tumours are instructive. Considering the less efficiency of CAR T-cell therapy of solid tumours with the limited number of CAR T cells entering the interior of solid tumours, this study is suggestive for the subsequent CAR T-cell design and evaluation of solid tumour therapy.     

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.     

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.