Harnessing apoptotic cells to enhance efficiency of macrophage-based cell therapy

IF 7.9 1区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL
Imke Liebold, Lidia Bosurgi
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Restoring phagocytosis by inhibiting “do-not-eat me” signals or by blocking the programmed cell death protein 1-programmed death-ligand 1 (PD1-PD-L1) axis, increases macrophage phagocytosis of tumour cells, thereby enhancing survival in mouse models of cancer in a macrophage-dependent manner.<span><sup>1, 2</sup></span></p><p>Besides its involvement in the direct clean-up of dying cells, efferocytosis also directly shapes the function of phagocytic macrophages. This complicates our understanding of the impact of the efferocytic process on the damaged environment.</p><p>It is long-established that the engulfment of apoptotic cells by macrophages leads to the induction of molecules with immunosuppressive functions, such as interleukin (IL)-10, transforming growth factor beta 1, prostaglandins and platelet-activating factors while reducing the secretion of proinflammatory cytokines such as tumour necrosis factor-alpha, IL-1β and IL-8.<span><sup>3, 4</sup></span> Thus, in certain disease settings, efficient efferocytosis is required to prevent chronic inflammation. In line with this, during a helminth infection, the uptake of dying cells promotes macrophage acquisition of a tissue remodelling profile and the associated parasite clearance.<span><sup>5</sup></span> Additionally, metabolites released by apoptotic cells, such as spermidine and adenosine, contribute to fostering anti-inflammatory properties in the engulfing macrophages.<span><sup>6</sup></span></p><p>Consistent with these findings, apoptotic cells and their subsequent clearance by efferocytic macrophages have uncovered numerous potential therapeutic opportunities while also bringing to light several challenges.</p><p>The beneficial consequences of administering apoptotic cells have been reported in clinical practice. Infusion of apoptotic cells as a result of extracorporeal photopheresis, a procedure that induces cell death in peripheral blood mononuclear cells by ultraviolet light exposure, has been effectively used in patients with hematologic malignancies who undergo hematopoietic cell transplantation. This helps to prevent- acute graft-versus-host disease. Based on various promising data on pre-clinical models,<span><sup>7</sup></span> the induction of apoptosis in peripheral blood leukocytes and their consequent infusion is also planned to be tested in patients with rheumatoid arthritis (NCT02903212). Despite being used in clinical settings, the mechanism by which apoptotic cell transfer prevents pathological inflammation, particularly its impact on the efferocytic process, has not yet been clarified.</p><p>Importantly, cell death induced upon damage is often not restricted to a single cell type. 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Consequently, the adoptive transfer of differentially fed macrophages in <i>Schistosoma mansoni</i>-infected mice differentially alters the disease outcome, with only apoptotic neutrophil-fed macrophages actively promoting parasitic egg clearance (Figure 1).</p><p>Based on our recent findings, the effectiveness of macrophage-based cell therapies might be improved in a range of diseases by selective apoptotic cell feeding.</p><p>Either activation or expansion of macrophages before adoptive cell transfer has already been reported in different macrophage-based cell therapies. Stimulation of macrophages ex vivo with recombinant human GMCSF or expansion via ixmyelocel-T is occurring prior to autologous cell transfer in patients with ischaemic and haemorrhagic stroke (NCT01845350) and in patients with heart failure due to dilated cardiomyopathy (NCT01670981), respectively. 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引用次数: 0

Abstract

Phagocytosis of apoptotic cells by macrophages, also known as efferocytosis, is a core function of macrophages in every tissue of our body. Here the prompt elimination of dying cells ensures the reestablishment of homeostasis in physiological and pathological conditions.

By leading to the accumulation of apoptotic cells, impaired efferocytosis is indeed a key contributor to many diseases, from autoimmune conditions such as systemic lupus erythematosus to cancer. Restoring phagocytosis by inhibiting “do-not-eat me” signals or by blocking the programmed cell death protein 1-programmed death-ligand 1 (PD1-PD-L1) axis, increases macrophage phagocytosis of tumour cells, thereby enhancing survival in mouse models of cancer in a macrophage-dependent manner.1, 2

Besides its involvement in the direct clean-up of dying cells, efferocytosis also directly shapes the function of phagocytic macrophages. This complicates our understanding of the impact of the efferocytic process on the damaged environment.

It is long-established that the engulfment of apoptotic cells by macrophages leads to the induction of molecules with immunosuppressive functions, such as interleukin (IL)-10, transforming growth factor beta 1, prostaglandins and platelet-activating factors while reducing the secretion of proinflammatory cytokines such as tumour necrosis factor-alpha, IL-1β and IL-8.3, 4 Thus, in certain disease settings, efficient efferocytosis is required to prevent chronic inflammation. In line with this, during a helminth infection, the uptake of dying cells promotes macrophage acquisition of a tissue remodelling profile and the associated parasite clearance.5 Additionally, metabolites released by apoptotic cells, such as spermidine and adenosine, contribute to fostering anti-inflammatory properties in the engulfing macrophages.6

Consistent with these findings, apoptotic cells and their subsequent clearance by efferocytic macrophages have uncovered numerous potential therapeutic opportunities while also bringing to light several challenges.

The beneficial consequences of administering apoptotic cells have been reported in clinical practice. Infusion of apoptotic cells as a result of extracorporeal photopheresis, a procedure that induces cell death in peripheral blood mononuclear cells by ultraviolet light exposure, has been effectively used in patients with hematologic malignancies who undergo hematopoietic cell transplantation. This helps to prevent- acute graft-versus-host disease. Based on various promising data on pre-clinical models,7 the induction of apoptosis in peripheral blood leukocytes and their consequent infusion is also planned to be tested in patients with rheumatoid arthritis (NCT02903212). Despite being used in clinical settings, the mechanism by which apoptotic cell transfer prevents pathological inflammation, particularly its impact on the efferocytic process, has not yet been clarified.

Importantly, cell death induced upon damage is often not restricted to a single cell type. On this basis, in Liebold et al.,8 we recently described how the cellular identity of the ingested apoptotic cell differentially influences macrophage behaviour. This opens the door to defining the nature of the apoptotic cell targets as a factor that determines the outcome of efferocytosis.8 In an environment enriched with IL-4, such as during the infection with the helminth Schistosoma mansoni, the accumulation of distinct apoptotic cells occurs in the damaged liver. Their efferocytosis by hepatic monocytes/macrophages influences the profile signature of the phagocytic cells in different ways. Via an in vitro experimental setup, we have found that macrophages acquire a tissue-remodelling profile only after the uptake of apoptotic neutrophils, but not after stimulation in vitro with other apoptotic cells, such as hepatocytes or thymocytes. Consequently, the adoptive transfer of differentially fed macrophages in Schistosoma mansoni-infected mice differentially alters the disease outcome, with only apoptotic neutrophil-fed macrophages actively promoting parasitic egg clearance (Figure 1).

Based on our recent findings, the effectiveness of macrophage-based cell therapies might be improved in a range of diseases by selective apoptotic cell feeding.

Either activation or expansion of macrophages before adoptive cell transfer has already been reported in different macrophage-based cell therapies. Stimulation of macrophages ex vivo with recombinant human GMCSF or expansion via ixmyelocel-T is occurring prior to autologous cell transfer in patients with ischaemic and haemorrhagic stroke (NCT01845350) and in patients with heart failure due to dilated cardiomyopathy (NCT01670981), respectively. In these scenarios, it would be worthwhile to investigate whether ex vivo feeding of monocytes/macrophages with specific types of apoptotic cells, such as apoptotic neutrophils to promote tissue remodelling, prior to macrophage adoptive transfer, could enhance clinical outcomes. This approach could pave the way for the establishment of a novel methodology in regenerative medicine.

Additionally, while our data in preclinical models still do not clarify which apoptotic cell mediators contribute to macrophage commitment toward the acquisition of certain functions, we found that there is a complementary between the identity of the apoptotic cell phagocytosed and the type of phagocytic receptor engaged. Here, engagement of the receptor tyrosine kinases AXL and MERTK preferentially leads to the uptake of apoptotic neutrophils and consequent acquisition of a tissue remodelling signature in efferocytic macrophages.8 This supports the idea that signalling downstream different phagocytic receptors might control the functional profile acquired by the phagocytic cell counterpart.

This concept should now be considered, especially when employing the chimeric antigen receptor for phagocytosis,9 which involves expressing engineered receptors in phagocytic cells to promote the engulfment and elimination of selected target cells. For instance, the engineering of macrophages with the cytosolic domain from MERTK, which has been described to trigger tumour cell cytotoxicity via targeting of immunosuppressive CCR7+ cells inside the tumour,10 might exert its effect in prolonging survival in mouse models also because of the post-engulfment consequences of taking up apoptotic cells with specific identities.

Therefore, based on our findings, it is tempting to speculate that in the future, we could engineer macrophages to express selected phagocytic receptors based on the desired functional outcome or predict the outcome of the macrophage immune response based on the identity of the apoptotic cells located in the damaged tissue. While further studies need to be performed to address these points, our findings indicate that macrophages are pivotal in advancing cell-based therapies due to the possibility of programming them toward specific functions by simply letting them phagocytose apoptotic cells with different identities. This versatility enhances their therapeutic potential and paves the way for promising future approaches to effectively treating various diseases for which macrophage-based cell therapies are already ongoing.

The authors declare no conflict of interest.

Not applicable.

Not applicable.

利用凋亡细胞提高基于巨噬细胞的细胞疗法的效率。
巨噬细胞对凋亡细胞的吞噬作用,也被称为 "排出吞噬作用",是人体各组织中巨噬细胞的一项核心功能。通过导致凋亡细胞的积聚,渗出功能受损确实是导致许多疾病的关键因素,从自身免疫性疾病(如系统性红斑狼疮)到癌症,不一而足。通过抑制 "不要吃我 "信号或阻断程序性细胞死亡蛋白 1-程序性死亡配体 1(PD1-PD-L1)轴来恢复吞噬功能,可以增加巨噬细胞对肿瘤细胞的吞噬,从而以巨噬细胞依赖的方式提高癌症小鼠模型的存活率。长期以来,巨噬细胞吞噬凋亡细胞会诱导白细胞介素(IL)-10、转化生长因子β1、前列腺素和血小板活化因子等具有免疫抑制功能的分子,同时减少肿瘤坏死因子α、IL-1β和IL-8等促炎细胞因子的分泌。3, 4 因此,在某些疾病情况下,需要有效的排泄来防止慢性炎症。5 此外,凋亡细胞释放的代谢物(如亚精胺和腺苷)有助于增强吞噬巨噬细胞的抗炎特性。与这些研究结果相一致,凋亡细胞及其随后被出胞巨噬细胞清除的过程发现了许多潜在的治疗机会,同时也带来了一些挑战。体外光化疗法是一种通过紫外线照射诱导外周血单核细胞死亡的方法,在接受造血细胞移植的血液恶性肿瘤患者中,输注体外光化疗法产生的凋亡细胞已被有效地应用。这有助于预防急性移植物抗宿主疾病。根据临床前模型的各种有希望的数据7 ,诱导外周血白细胞凋亡及随后的输注也计划在类风湿性关节炎患者中进行试验(NCT02903212)。尽管凋亡细胞转移已被用于临床,但其防止病理炎症的机制,尤其是其对流出过程的影响,尚未得到阐明。在此基础上,我们最近在 Liebold 等人的研究中8 描述了被摄取的凋亡细胞的细胞特性如何对巨噬细胞的行为产生不同影响。8 在富含 IL-4 的环境中,例如在感染曼氏血吸虫时,受损的肝脏中会积累不同的凋亡细胞。肝脏单核细胞/巨噬细胞对凋亡细胞的吞噬作用会以不同方式影响吞噬细胞的特征。通过体外实验装置,我们发现巨噬细胞只有在摄取凋亡的中性粒细胞后才会获得组织重塑特征,而在体外刺激其他凋亡细胞(如肝细胞或胸腺细胞)后则不会。因此,在曼氏血吸虫感染的小鼠中,采用不同喂养方式的巨噬细胞会不同程度地改变疾病结果,只有喂养凋亡中性粒细胞的巨噬细胞才能积极促进寄生虫卵的清除(图 1)。在缺血性和出血性中风患者(NCT01845350)和扩张型心肌病引起的心力衰竭患者(NCT01670981)的自体细胞转移之前,分别用重组人GMCSF刺激巨噬细胞或通过ixmyelocel-T扩增巨噬细胞。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
15.90
自引率
1.90%
发文量
450
审稿时长
4 weeks
期刊介绍: Clinical and Translational Medicine (CTM) is an international, peer-reviewed, open-access journal dedicated to accelerating the translation of preclinical research into clinical applications and fostering communication between basic and clinical scientists. It highlights the clinical potential and application of various fields including biotechnologies, biomaterials, bioengineering, biomarkers, molecular medicine, omics science, bioinformatics, immunology, molecular imaging, drug discovery, regulation, and health policy. With a focus on the bench-to-bedside approach, CTM prioritizes studies and clinical observations that generate hypotheses relevant to patients and diseases, guiding investigations in cellular and molecular medicine. The journal encourages submissions from clinicians, researchers, policymakers, and industry professionals.
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