Reengineered Anti-CD4 Cys-diabody Variants for ⁸⁹Zr-immunoPET of CD4⁺ T Cells in Immunocompetent Mice.

IF 2.5 4区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Molecular Imaging and Biology Pub Date : 2025-08-07 DOI:10.1007/s11307-025-02043-y

Felix B Salazar, Richard Tavaré, Arya Ökten, Maciej Kujawski, Anna M Wu, Kirstin A Zettlitz

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引用次数: 0

Abstract

Purpose: CD4⁺ T cells (T helper and T reg) play an important role in the immune system and are influential in autoimmune diseases (e.g., rheumatoid arthritis, inflammatory bowel disease) and cancer (antitumor immunity). Non-invasive, whole-body anti-CD4 immunoPET can provide dynamic and spatial information (localization, proliferation, and migration) on CD4⁺ T cells. The cys-diabody format enables site-specific radiolabeling and rapid renal clearance, which results in high-contrast images at early time points.

Procedures: In this work, an anti-CD4 cys-diabody based on the hybridoma GK1.5 was reengineered by CDR-grafting (GK1.5 FR cDb) for higher expression in mammalian cell lines. An N-glycosylation motif in the variable light chain domain framework was removed by site-directed mutagenesis, resulting in GK1.5 N80D cDb. To investigate the impact of the variable domain glycan on the in vivo biodistribution and pharmacokinetics, both cys-diabodies were site-specifically conjugated with deferoxamine-maleimide and radiolabeled by chelation of zirconium-89. Serial immunoPET/CT imaging was used for non-invasive, whole-body assessment of specific targeting, biodistribution, and differential clearance of the two novel anti-CD4 cys-diabodies.

Results: The anti-CD4 cys diabody was successfully re-engineered by CDR-grafting (GK1.5 FR cDb) and aglycosylation (GK1.5 N80D cDb), resulting in a higher expression yield (~ tenfold increase) without impacting antigen specificity or affinity. Both cys-diabody variants were successfully ⁸⁹Zr-radiolabeled with similar specific activity and radiochemical purity. ImmunoPET imaging of ⁸⁹Zr-GK1.5 FR cDb and ⁸⁹Zr-GK1.5 N80D cDb in immunocompetent mice showed CD4 antigen-specific lymphoid tissue uptake in vivo. ⁸⁹Zr-GK1.5 FR cDb exhibited rapid hepatic clearance, resulting in significantly reduced uptake in lymph nodes and the spleen. Removal of the N-glycosylation motif in ⁸⁹Zr-GK1.5 N80D cDb restored diabody-typical biodistribution (renal clearance), resulting in higher target tissue uptake.

Conclusion: The novel reengineered anti-CD4 GK1.5 N80D cDb overcomes the previous production yield bottleneck and provides same-day ⁸⁹Zr-immunoPET imaging for non-invasive, whole-body visualization of murine CD4⁺ T cells.

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免疫活性小鼠CD4+ T细胞89zr免疫pet重组抗CD4 cys -糖尿病变异体

目的：CD4+ T细胞（T helper和T reg）在免疫系统中发挥重要作用，在自身免疫性疾病（如类风湿关节炎、炎症性肠病）和癌症（抗肿瘤免疫）中发挥重要作用。非侵入性、全身抗CD4免疫pet可提供CD4+ T细胞的动态和空间信息（定位、增殖和迁移）。cys-diabody格式可实现部位特异性放射标记和快速肾脏清除率，从而在早期时间点获得高对比度图像。在这项工作中，基于杂交瘤GK1.5，通过cdr -graft （GK1.5 FR cDb）重组了抗cd4淋巴细胞-糖尿病体，使其在哺乳动物细胞系中表达更高。可变轻链结构域框架中的n -糖基化基序通过位点定向诱变去除，产生GK1.5 N80D cDb。为了研究可变结构域聚糖对体内生物分布和药代动力学的影响，两种cys-糖尿病体都与去铁胺-马来酰亚胺位点特异性结合，并通过锆-89螯合进行放射性标记。连续免疫pet /CT成像用于无创、全身评估特异性靶向、生物分布和两种新型抗cd4细胞糖尿病的差异清除。结果：通过cdr接枝（GK1.5 FR cDb）和糖基化（GK1.5 N80D cDb）成功重组抗cd4 cys抗体，在不影响抗原特异性和亲和力的情况下获得了更高的表达量（约10倍）。两种cyys -diabody变体都成功地进行了89zr放射性标记，具有相似的比活性和放射化学纯度。免疫功能正常小鼠的89Zr-GK1.5 FR cDb和89Zr-GK1.5 N80D cDb免疫pet成像显示体内CD4抗原特异性淋巴组织摄取。89Zr-GK1.5 FR cDb表现出快速的肝脏清除，导致淋巴结和脾脏的摄取显著减少。去除89Zr-GK1.5 N80D cDb中的n -糖基化基序恢复了糖尿病体典型的生物分布（肾脏清除率），导致更高的靶组织摄取。结论：新型重组抗CD4 GK1.5 N80D cDb克服了以往的产量瓶颈，为小鼠CD4+ T细胞的无创、全身可视化提供了当日89zr免疫pet成像。

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来源期刊

Molecular Imaging and Biology 医学-核医学

CiteScore

6.90

自引率

3.20%

发文量

审稿时长

3 months

期刊介绍： Molecular Imaging and Biology (MIB) invites original contributions (research articles, review articles, commentaries, etc.) on the utilization of molecular imaging (i.e., nuclear imaging, optical imaging, autoradiography and pathology, MRI, MPI, ultrasound imaging, radiomics/genomics etc.) to investigate questions related to biology and health. The objective of MIB is to provide a forum to the discovery of molecular mechanisms of disease through the use of imaging techniques. We aim to investigate the biological nature of disease in patients and establish new molecular imaging diagnostic and therapy procedures. Some areas that are covered are: Preclinical and clinical imaging of macromolecular targets (e.g., genes, receptors, enzymes) involved in significant biological processes. The design, characterization, and study of new molecular imaging probes and contrast agents for the functional interrogation of macromolecular targets. Development and evaluation of imaging systems including instrumentation, image reconstruction algorithms, image analysis, and display. Development of molecular assay approaches leading to quantification of the biological information obtained in molecular imaging. Study of in vivo animal models of disease for the development of new molecular diagnostics and therapeutics. Extension of in vitro and in vivo discoveries using disease models, into well designed clinical research investigations. Clinical molecular imaging involving clinical investigations, clinical trials and medical management or cost-effectiveness studies.