Department of Pharmacology and Pharmaceutical Sciences, School of Pharmacy, University of Southern California, Los Angeles, CA, 90089, United States.
Department of Chemical and Biomolecular Engineering, Johns Hopkins University, Baltimore, MD, 21218, United States.
Biomaterials. 2020 Dec;262:120338. doi: 10.1016/j.biomaterials.2020.120338. Epub 2020 Aug 31.
Despite advancements in antibody-based therapies for non-Hodgkin lymphoma (NHL), at least two major therapeutic needs remain unmet: i) heterogenous activation of host immunity towards B cell NHL; and ii) lack of antibody-based therapeutics for T cell NHL. This study explores the molecular characteristics of an adaptable modality called antibody Nanoworms and demonstrates their receptor clustering activity as a means to overcome and address abovementioned needs. To test this, four selected therapeutic receptors of B cell (CD19, CD20, HLA-DR10) and T cell (CD3) NHL were targeted by Nanoworms. Regardless of the target or the cell type, Nanoworms inherently clustered bound receptors on the cell-surface through their multivalency and activated intracellular signaling without any secondary crosslinker. As a sole agent, Nanoworms induced apoptosis by clustering CD20 or HLA-DR10, and arrested the cell cycle upon CD19 clustering. Interestingly, CD3 clustering was particularly advantageous in inducing activation-induced cell death (AICD) in an aggressive form of T cell NHL named Sézary syndrome that is fatal, limited in antibody-based therapeutics, and has poor outcomes to traditional chemotherapy. As Nanoworms can be easily designed to target any receptor for which a scFv is available, they may provide solutions and add therapeutic novelty to underserved diseases.
尽管针对非霍奇金淋巴瘤 (NHL) 的抗体治疗取得了进展,但至少仍有两个主要的治疗需求未得到满足:i)宿主对 B 细胞 NHL 免疫的异质性激活;ii)缺乏针对 T 细胞 NHL 的抗体治疗方法。本研究探索了一种称为抗体纳米蠕虫的适应性治疗模式的分子特征,并证明了其受体聚类活性可作为克服和解决上述需求的手段。为了验证这一点,研究选择了四种针对 B 细胞 NHL(CD19、CD20、HLA-DR10)和 T 细胞 NHL(CD3)的治疗性受体进行了纳米蠕虫靶向治疗。无论目标或细胞类型如何,纳米蠕虫都通过其多价性固有地在细胞表面聚集结合受体,并激活细胞内信号转导,而无需任何二级交联剂。作为单一药物,纳米蠕虫通过聚集 CD20 或 HLA-DR10 诱导细胞凋亡,并在聚集 CD19 时使细胞周期停滞。有趣的是,CD3 聚类在诱导一种名为 Sézary 综合征的侵袭性 T 细胞 NHL 中的激活诱导细胞死亡 (AICD) 方面特别有利,该综合征是致命的,在抗体治疗中受限,并且对传统化疗的效果不佳。由于纳米蠕虫可以很容易地设计为针对任何具有 scFv 的受体进行靶向,因此它们可能为未满足的疾病提供解决方案并增加治疗的新颖性。
