Monomethyl auristatin E (MMAE), a payload for multiple antibody drug conjugates (ADCs), demonstrates differential red blood cell partitioning across human and animal species.

IF 1.3 4区 医学 Q4 PHARMACOLOGY & PHARMACY
Xenobiotica Pub Date : 2024-08-01 Epub Date: 2024-09-27 DOI:10.1080/00498254.2024.2345849
Victor Yip, Ola M Saad, Doug Leipold, Chunze Li, Amrita Kamath, Ben-Quan Shen
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引用次数: 0

Abstract

Background: Monomethyl auristatin E (MMAE) has been used as a payload for several Food and Drug Administration (FDA) approved antibody-drug conjugates (ADCs). It is known that MMAE is released from the ADC following binding, internalisation and proteolytic degradation in target tissues. A striking discrepancy in systemic MMAE levels has been observed across species with 50-fold higher MMAE levels in human than that in rodents when normalised by ADC dose with unknown mechanism.Hypothesis and purpose: Multiple factors could affect systemic MMAE levels such as production and elimination of unconjugated MMAE following ADC dosing. In this study, we have explored whether MMAE displays differential red blood cell (RBC) partitioning across species that may contribute to the different MMAE levels seen between human and animals.Experiments: To determine MMAE RBC partitioning, tritium labelled MMAE ([3H]-MMAE) was incubated in whole blood from mice, rats, monkeys and humans in vitro, then RBC partitioning was determined and compared across species. To test whether MMAE released from the ADC would show any difference in RBC partitioning, pinatuzumab vedotin or polatuzumab vedotin was administered to mice, rats, and monkeys. MMAE levels were measured in both blood and plasma, and the ratios of MMAE levels were calculated as blood-to-plasma ratio (in vivo RBC partitioning).Results: Our in vitro data showed that unconjugated MMAE has a species-dependent RBC partitioning with strong RBC partitioning in mouse, rat, followed by monkey blood, whereas minimal RBC partitioning was seen in human blood. Incubation of 2 nM of MMAE in mouse blood resulted in a blood-to-plasma ratio of 11.8 ± 0.291, followed by rat, monkey, and human at 2.36 ± 0.0825, 1.57 ± 0.0250, and 0.976 ± 0.0620, respectively. MMAE RBC partitioning is also concentration-dependent, with an inverse relationship between RBC partitioning and MMAE concentration (higher RBC partitioning at lower concentration). In vivo dosing of pinatuzumab vedotin in mouse displayed systemic MMAE at about a 5-fold higher blood concentration compared to plasma concentration once MMAE reached a pseudo-equilibrium, while systemic MMAE from blood and plasma concentration showed a 1.65-fold difference in rat.Implication and conclusion: These data demonstrated that MMAE has a distinct RBC partitioning across different species, which may contribute to, at least in part, to the differential in the systemic MMAE levels observed in vivo between preclinical and clinical studies. These findings highlight the importance of fully characterising the ADME properties of both the ADC and its payload, to enable better translation from animals to human for ADC development.

多种抗体药物共轭物 (ADC) 的有效载荷--单甲基 Auristatin E (MMAE)--在人类和动物物种中显示出不同的红细胞分布。
背景:单甲基金丝桃素 E(MMAE)已被用作几种经美国食品药品管理局(FDA)批准的抗体药物共轭物(ADC)的有效载荷。众所周知,MMAE 与 ADC 结合后会从 ADC 中释放出来,在靶组织中发生内化和蛋白水解降解。假设和目的:多种因素可能影响全身 MMAE 水平,如 ADC 给药后未结合 MMAE 的产生和清除。在本研究中,我们探讨了 MMAE 在不同物种中是否显示出不同的红细胞(RBC)分配,这可能会导致人类和动物之间出现不同的 MMAE 水平:为了确定 MMAE 在红细胞中的分配情况,我们将氚标记的 MMAE([3H]-MMAE)在小鼠、大鼠、猴子和人的全血中进行体外培养,然后确定红细胞的分配情况,并对不同物种进行比较。为了测试从 ADC 中释放的 MMAE 在红细胞分配中是否会出现差异,给小鼠、大鼠和猴子注射了 pinatuzumab vedotin 或 polatuzumab vedotin。测量了血液和血浆中的 MMAE 水平,并计算了 MMAE 水平的血浆比(体内 RBC 分配):我们的体外数据显示,非结合型 MMAE 的红细胞分配依赖于物种,在小鼠、大鼠和猴子血液中的红细胞分配较强,而在人类血液中的红细胞分配极小。在小鼠血液中培养 2 nM 的 MMAE 后,血液与血浆的比率为 11.8 ± 0.291,其次是大鼠、猴子和人,分别为 2.36 ± 0.0825、1.57 ± 0.0250 和 0.976 ± 0.0620。MMAE 的红细胞分配率也与浓度有关,红细胞分配率与 MMAE 浓度呈反比关系(浓度越低,红细胞分配率越高)。小鼠体内注射皮那珠单抗维多汀后,一旦 MMAE 达到假平衡,全身 MMAE 的血药浓度比血浆浓度高出约 5 倍,而大鼠全身 MMAE 的血药浓度与血浆浓度相差 1.65 倍:这些数据表明,MMAE 在不同物种的红细胞中具有不同的分配,这可能至少部分导致了临床前研究和临床研究中观察到的体内全身 MMAE 水平的差异。这些发现凸显了充分描述 ADC 及其有效载荷的 ADME 特性的重要性,以便更好地将 ADC 开发从动物转化到人体。
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来源期刊
Xenobiotica
Xenobiotica 医学-毒理学
CiteScore
3.80
自引率
5.60%
发文量
96
审稿时长
2 months
期刊介绍: Xenobiotica covers seven main areas, including:General Xenobiochemistry, including in vitro studies concerned with the metabolism, disposition and excretion of drugs, and other xenobiotics, as well as the structure, function and regulation of associated enzymesClinical Pharmacokinetics and Metabolism, covering the pharmacokinetics and absorption, distribution, metabolism and excretion of drugs and other xenobiotics in manAnimal Pharmacokinetics and Metabolism, covering the pharmacokinetics, and absorption, distribution, metabolism and excretion of drugs and other xenobiotics in animalsPharmacogenetics, defined as the identification and functional characterisation of polymorphic genes that encode xenobiotic metabolising enzymes and transporters that may result in altered enzymatic, cellular and clinical responses to xenobioticsMolecular Toxicology, concerning the mechanisms of toxicity and the study of toxicology of xenobiotics at the molecular levelXenobiotic Transporters, concerned with all aspects of the carrier proteins involved in the movement of xenobiotics into and out of cells, and their impact on pharmacokinetic behaviour in animals and manTopics in Xenobiochemistry, in the form of reviews and commentaries are primarily intended to be a critical analysis of the issue, wherein the author offers opinions on the relevance of data or of a particular experimental approach or methodology
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