High-affinity transferrin receptor binding improves brain delivery of bispecific antibodies at tracer dose.

IF 6.2 1区医学 Q1 NEUROSCIENCES

Fluids and Barriers of the CNS Pub Date : 2025-08-21 DOI:10.1186/s12987-025-00693-2

Gillian Bonvicini, Sunitha Singh, Lisa Sandersjöö, Tiffany Dallas, Eva Schlein, Amelia D Dahlén, Sara Lopes van den Broek, Dag Sehlin, Ken G Andersson, Stina Syvänen

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引用次数: 0

Abstract

Background: Transferrin receptor (TfR)-mediated transcytosis is a well-established method for delivering biologic therapeutics and diagnostics to the brain. Although moderate affinity towards TfR is beneficial for TfR-mediated brain delivery at therapeutic doses, emerging evidence has indicated that high TfR affinity may be more beneficial at tracer doses. With the development of antibody-based PET radioligands for neurodegenerative diseases, such as Alzheimer's disease, understanding the pharmacokinetics of TfR-binders at tracer dose is essential. Thus, this study aimed to evaluate the effect of TfR affinity on brain uptake at a tracer dose in both wild-type (WT) and amyloid-beta (Aβ) pathology presenting mice and to demonstrate the usability of TfR-mediated brain delivery of immunoPET diagnostic radioligands to visualize intrabrain Aβ pathology in vivo.

Methods: Three different affinity variants of anti-mouse TfR-binding antibody 8D3, engineered by alanine point mutations, were selected. Bispecific antibodies were designed with knob-into-hole technology with one arm targeting TfR (8D3) and the other arm targeting human Aβ (bapineuzumab). Antibody affinities were measured in an in vitro cell assay. In vivo pharmacokinetic analyses of radioiodinated bispecific antibodies and bapineuzumab in brain, blood and peripheral organs were performed over 7 days post-injection in WT mice and a model of Aβ pathology (App^NL-G-F). The strongest TfR affinity bispecific antibody was also evaluated as a positron emission tomography (PET) radioligand for detecting Aβ pathology in WT and App^NL-G-F mice.

Results: The three bispecific antibodies bound to TfR with affinities of 10 nM, 20 nM and 240 nM. Independent of genotype, stronger TfR-affinity resulted in higher initial brain uptake. The two higher-affinity bispecific antibodies behaved similarly and differentiated between WT and App^NL-G-F mice earlier than the lowest affinity variant. Finally, the 10 nM bispecific antibody was able to clearly differentiate between WT and App^NL-G-F mice when used as a PET radioligand.

Conclusion: This study supports the hypothesis that stronger TfR affinity enhances brain uptake at a tracer dose. With the more effective detection of Aβ pathology, stronger TfR affinity is a crucial design feature for future bispecific immunoPET radioligands for intrabrain targets via TfR-mediated transcytosis.

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高亲和力转铁蛋白受体结合改善双特异性抗体在示踪剂剂量下的脑递送。

背景：转铁蛋白受体（TfR）介导的胞吞作用是一种成熟的向大脑传递生物治疗和诊断的方法。虽然在治疗剂量下，对TfR的中等亲和力有利于TfR介导的脑递送，但新出现的证据表明，在示踪剂剂量下，高TfR亲和力可能更有益。随着基于抗体的PET放射配体治疗神经退行性疾病（如阿尔茨海默病）的发展，了解示踪剂剂量下tfr结合物的药代动力学至关重要。因此，本研究旨在评估示踪剂剂量下TfR亲和力对野生型（WT）和淀粉样蛋白- β (a β)病理小鼠脑摄取的影响，并证明TfR介导的免疫pet诊断放射配体脑递送在体内观察脑内a β病理的可用性。方法：选择三种不同亲和力的抗小鼠tfr结合抗体8D3，通过丙氨酸点突变工程化。采用旋孔技术设计双特异性抗体，一只手臂靶向TfR (8D3)，另一只手臂靶向人Aβ (bapineuzumab)。抗体亲和力是通过体外细胞试验测定的。注射后7天，在WT小鼠和a β病理模型（AppNL-G-F）中进行了放射性碘化双特异性抗体和巴哌珠单抗在脑、血液和外周器官中的体内药代动力学分析。最强的TfR亲和双特异性抗体也被评估为正电子发射断层扫描（PET）放射配体，用于检测WT和AppNL-G-F小鼠的a β病理。结果：三种双特异性抗体与TfR结合的亲和度分别为10 nM、20 nM和240 nM。与基因型无关，较强的tfr亲和力导致较高的初始脑摄取。两种高亲和力的双特异性抗体表现相似，在WT和AppNL-G-F小鼠之间的分化早于低亲和力变体。最后，当作为PET放射配体时，10 nM双特异性抗体能够明显区分WT和AppNL-G-F小鼠。结论：本研究支持在示踪剂剂量下，更强的TfR亲和力可以促进脑摄取的假设。随着更有效地检测a β病理，更强的TfR亲和力是未来双特异性免疫pet放射配体通过TfR介导的胞吞噬作用用于脑内靶标的关键设计特征。

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

Fluids and Barriers of the CNS Neuroscience-Developmental Neuroscience

CiteScore

10.70

自引率

8.20%

发文量

审稿时长

14 weeks

期刊介绍： "Fluids and Barriers of the CNS" is a scholarly open access journal that specializes in the intricate world of the central nervous system's fluids and barriers, which are pivotal for the health and well-being of the human body. This journal is a peer-reviewed platform that welcomes research manuscripts exploring the full spectrum of CNS fluids and barriers, with a particular focus on their roles in both health and disease. At the heart of this journal's interest is the cerebrospinal fluid (CSF), a vital fluid that circulates within the brain and spinal cord, playing a multifaceted role in the normal functioning of the brain and in various neurological conditions. The journal delves into the composition, circulation, and absorption of CSF, as well as its relationship with the parenchymal interstitial fluid and the neurovascular unit at the blood-brain barrier (BBB).