Banka Vinay, Kelleher Andrew, Sehlin Dag, Hultqvist Greta, Sigurdsson Einar M, Syvänen Stina, Ding Yu-Shin
Department of Radiology, New York University School of Medicine, New York, NY, United States.
Department of Public Health and Caring Sciences, Uppsala University, Uppsala, Sweden.
Front Nucl Med. 2023;3. doi: 10.3389/fnume.2023.1173693. Epub 2023 May 4.
Alzheimer's disease (AD) is characterized by the misfolding and aggregation of two major proteins: amyloid-beta (Aβ) and tau. Antibody-based PET radioligands are desirable due to their high specificity and affinity; however, antibody uptake in the brain is limited by the blood-brain barrier (BBB). Previously, we demonstrated that antibody transport across the BBB can be facilitated through interaction with the transferrin receptor (TfR), and the bispecific antibody-based PET ligands were capable of detecting Aβ aggregates via imaging. Since tau accumulation in the brain is more closely correlated with neuronal death and cognition, we report here our strategies to prepare four F-18-labeled specifically engineered bispecific antibody probes for the selective detection of tau and Aβ aggregates to evaluate their feasibility and specificity, particularly for PET imaging.
We first created and evaluated (via both and studies) four specifically engineered bispecific antibodies, by fusion of single-chain variable fragments (scFv) of a TfR antibody with either a full-size IgG antibody of Aβ or tau or with their respective scFv. Using [F]SFB as the prosthetic group, all four F-labeled bispecific antibody probes were then prepared by conjugation of antibody and [F]SFB in acetonitrile/0.1 M borate buffer solution (final pH ~ 8.5) with an incubation of 20 min at room temperature, followed by purification on a PD MiniTrap G-25 size exclusion gravity column.
Based on both and evaluation, the bispecific antibodies displayed much higher brain concentrations than the unmodified antibody, supporting our subsequent F18-radiolabeling. [F]SFB was produced in high yields in 60 min (decay-corrected radiochemical yield (RCY) 46.7 ± 5.4) with radiochemical purities of >95%, confirmed by analytical high performance liquid chromatography (HPLC) and radio-TLC. Conjugation of [F]SFB and bispecific antibodies showed a 65%-83% conversion efficiency with radiochemical purities of 95%-99% by radio-TLC.
We successfully labeled four novel and specifically engineered bispecific antibodies with [F]SFB under mild conditions with a high RCY and purities. This study provides strategies to create brain-penetrable F-18 radiolabeled antibody probes for the selective detection of tau and Aβ aggregates in the brain of transgenic AD mice via PET imaging.
阿尔茨海默病(AD)的特征是两种主要蛋白质——淀粉样β蛋白(Aβ)和tau蛋白的错误折叠和聚集。基于抗体的PET放射性配体因其高特异性和亲和力而备受青睐;然而,抗体在大脑中的摄取受到血脑屏障(BBB)的限制。此前,我们证明通过与转铁蛋白受体(TfR)相互作用可促进抗体跨血脑屏障的转运,且基于双特异性抗体的PET配体能够通过成像检测Aβ聚集体。由于tau蛋白在大脑中的积累与神经元死亡和认知更为密切相关,我们在此报告我们制备四种F-18标记的特异性工程双特异性抗体探针的策略,用于选择性检测tau蛋白和Aβ聚集体,以评估其可行性和特异性,特别是用于PET成像。
我们首先通过将TfR抗体的单链可变片段(scFv)与Aβ或tau的全尺寸IgG抗体或其各自的scFv融合,创建并(通过体外和体内研究)评估了四种特异性工程双特异性抗体。使用[F]SFB作为辅基,然后在乙腈/0.1 M硼酸盐缓冲溶液(最终pH约8.5)中,将抗体与[F]SFB在室温下孵育20分钟进行偶联,制备所有四种F标记的双特异性抗体探针,随后在PD MiniTrap G-25尺寸排阻重力柱上进行纯化。
基于体外和体内评估,双特异性抗体在大脑中的浓度比未修饰的抗体高得多,这支持了我们随后的F18放射性标记。[F]SFB在60分钟内高产率产生(衰变校正后的放射化学产率(RCY)为46.7±5.4),放射化学纯度>95%,经分析型高效液相色谱(HPLC)和放射性薄层色谱(radio-TLC)确认。[F]SFB与双特异性抗体的偶联显示出65%-83%的转化效率,通过放射性薄层色谱法测定放射化学纯度为95%-99%。
我们在温和条件下成功地用[F]SFB标记了四种新型的特异性工程双特异性抗体,具有高放射化学产率和纯度。本研究提供了创建可穿透大脑的F-18放射性标记抗体探针的策略,用于通过PET成像选择性检测转基因AD小鼠大脑中的tau蛋白和Aβ聚集体。
