Novartis Institutes for Biomedical Research, Cambridge, Massachusetts.
Royal Melbourne Hospital, Parkville VIC, Australia.
Clin Cancer Res. 2018 Jul 15;24(14):3465-3474. doi: 10.1158/1078-0432.CCR-17-3786. Epub 2018 Apr 3.
Hypersensitivity reactions (HSRs) were observed in three patients dosed in a phase I clinical trial treated with LOP628, a KIT targeted antibody drug conjugate. Mast cell degranulation was implicated as the root cause for the HSR. Underlying mechanism of this reported HSR was investigated with an aim to identifying potential mitigation strategies. Biomarkers for mast cell degranulation were evaluated in patient samples and in human peripheral blood cell-derived mast cell (PBC-MC) cultures treated with LOP628. Mitigation strategies interrogated include pretreatment of mast cells with small molecule inhibitors that target KIT or signaling pathways downstream of FcεR1, FcγR, and treatment with Fc silencing antibody formats. Transient elevation of serum tryptase was observed in patients 1-hour posttreatment of LOP628. In agreement with the clinical observation, LOP628 and its parental antibody LMJ729 induced degranulation of human PBC-MCs. Unexpectedly, KIT small molecule inhibitors did not abrogate mast cell degranulation. By contrast, small molecule inhibitors that targeted pathways downstream of Fc receptors blunted degranulation. Furthermore, interference of the KIT antibody to engage Fc receptors by pre-incubation with IgG or using engineered Fc silencing mutations reduced or prevented degranulation. Characterization of Fcγ receptors revealed human PBC-MCs expressed both FcγRII and low levels of FcγRI. Interestingly, increasing the level of FcγRI upon addition of IFNγ, significantly enhanced LOP628-mediated mast cell degranulation. Our data suggest LOP628-mediated mast cell degranulation is the likely cause of HSR observed in the clinic due to co-engagement of the FcγR and KIT, resulting in mast cell activation. .
在接受 LOP628 治疗的一项 I 期临床试验中,有 3 名患者出现过敏反应(HSR)。脱颗粒作用被认为是 HSR 的根本原因。为了确定潜在的缓解策略,对该报告的 HSR 的潜在机制进行了研究。在接受 LOP628 治疗的患者样本和人外周血细胞衍生的肥大细胞(PBC-MC)培养物中评估了肥大细胞脱颗粒的生物标志物。研究的缓解策略包括:用针对 KIT 或 FcεR1、FcγR 下游信号通路的小分子抑制剂预处理肥大细胞,以及用 Fc 沉默抗体形式进行治疗。在 LOP628 治疗后 1 小时,患者的血清类胰蛋白酶短暂升高。与临床观察一致,LOP628 和其亲本抗体 LMJ729 诱导人 PBC-MC 的脱颗粒。出乎意料的是,KIT 小分子抑制剂不能阻断肥大细胞脱颗粒。相比之下,针对 Fc 受体下游通路的小分子抑制剂则减弱了脱颗粒作用。此外,通过与 IgG 预孵育或使用工程化 Fc 沉默突变来干扰 KIT 抗体与 Fc 受体的结合,减少或防止了脱颗粒。Fcγ 受体的表征表明,人 PBC-MC 表达 FcγRII 和低水平的 FcγRI。有趣的是,通过添加 IFNγ 增加 FcγRI 的水平,显著增强了 LOP628 介导的肥大细胞脱颗粒作用。我们的数据表明,LOP628 介导的肥大细胞脱颗粒作用可能是由于 FcγR 和 KIT 的共同参与,导致肥大细胞激活,是临床上观察到的 HSR 的原因。
