设计合成激动剂,定向激活 Notch 信号

bioRxiv Pub Date : 2024-08-08 DOI:10.1101/2024.08.06.606897
David H. Perez, Daniel Antfolk, Elliot Medina, David Gonzalez-Perez, Vincent C. Luca
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引用次数: 0

摘要

Notch信号调节细胞命运的决定,并具有依赖环境的致瘤或抑瘤功能。虽然有几种 Notch 抑制剂正被开发为癌症疗法,但 Notch 受体激活所需的机械力阻碍了生成可溶性激动剂的尝试。为了解决这个问题,我们设计了合成 Notch 激动剂(SNAG)蛋白,模拟内源性配体的张力产生机制。SNAG 蛋白是通过将 Notch 配体 Delta-like 4 (DLL4) 的高亲和力变体与诱导目标内化的抗体片段融合而设计的。这种双特异性形式使与 SNAG 结合的生物标记物能够 "牵引 "Notch 受体,在表达生物标记物和不表达生物标记物的混合细胞群中触发 Notch 激活。靶向免疫检查点 PDL1 的 SNAGs 在 Notch1 和 PDL1 表达细胞的共同培养物中能有效激活 Notch,但在单独的 Notch1 表达细胞的单培养物中则不起作用。其他靶向肿瘤抗原 CD19 和 HER2 的 SNAG 也能在混合细胞群中激活 Notch,这表明 SNAG 的设计理念可适用于多种生物标记物。SNAG介导的Notch活化被一种达纳敏抑制剂阻断,当SNAG通过与抗体Fc结构域融合而二聚化时,其功效显著增加,这表明内吞和多聚化对SNAG的最佳功能非常重要。这些见解将大大提高我们调节Notch信号的能力,从而应用于免疫疗法和再生医学。
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Engineering synthetic agonists for targeted activation of Notch signaling
Notch signaling regulates cell fate decisions and has context-dependent tumorigenic or tumor suppressor functions. Although several Notch inhibitors are under development as cancer therapies, the mechanical force requirement for Notch receptor activation has hindered attempts to generate soluble agonists. To address this problem, we engineered synthetic Notch agonist (SNAG) proteins that mimic the tension-generating mechanism of endogenous ligands. SNAGs were designed by fusing a high-affinity variant of the Notch ligand Delta-like 4 (DLL4) to antibody fragments that induce target internalization. This bispecific format enables the SNAG-bound biomarkers to “pull” on Notch receptors, triggering Notch activation in mixed populations of biomarker-expressing and non-expressing cells. SNAGs targeting the immune checkpoint PDL1 potently activated Notch in co-cultures of Notch1-and PDL1-expressing cells, but not in monocultures of Notch1-expressing cells alone. Additional SNAGs targeting the tumor antigens CD19 and HER2 also activated Notch in mixed cell populations, indicating that the SNAG design concept is adaptable to multiple biomarkers. SNAG-mediated Notch activation was blocked by a dynamin inhibitor, and efficacy increased dramatically when SNAGs were dimerized via fusion to antibody Fc domains, suggesting that endocytosis and multimerization are important for optimal SNAG function. These insights will greatly expand our ability to modulate Notch signaling for applications in immunotherapy and regenerative medicine.
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