Assessing the mitochondrial safety profile of the molnupiravir active metabolite, β-d-N4-hydroxycytidine (NHC), in the physiologically relevant HepaRG model.

IF 2.2 4区 医学 Q3 TOXICOLOGY Toxicology Research Pub Date : 2024-02-07 eCollection Date: 2024-02-01 DOI:10.1093/toxres/tfae012
Robyn T Kiy, Saye H Khoo, Amy E Chadwick
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引用次数: 0

Abstract

Background: β-d-N4-Hydroxycytidine (NHC) is the active metabolite of molnupiravir, a broad-spectrum antiviral approved by the MHRA for COVID-19 treatment. NHC induces lethal mutagenesis of the SARS-CoV-2 virus, undergoing incorporation into the viral genome and arresting viral replication. It has previously been reported that several nucleoside analogues elicit off-target inhibition of mitochondrial DNA (mtDNA) or RNA replication. Although NHC does not exert these effects in HepG2 cells, HepaRG are proven to be advantageous over HepG2 for modelling nucleoside analogue-induced mitochondrial dysfunction. Therefore, the objective of this work was to assess the mitotoxic potential of NHC in HepaRG cells, a model more closely resembling physiological human liver.

Methods: Differentiated HepaRG cells were exposed to 1-60 μM NHC for 3-14 days to investigate effects of sub-, supra-, and clinically-relevant exposures (in the UK, molnupiravir for COVID-19 is indicated for 5 days and reported Cmax is 16 μM). Following drug incubation, cell viability, mtDNA copy number, mitochondrial protein expression, and mitochondrial respiration were assessed.

Results: NHC induced minor decreases in cell viability at clinically relevant exposures, but did not decrease mitochondrial protein expression. The effects on mtDNA were variable, but typically copy number was increased. At supra-clinical concentrations (60 μM), NHC reduced mitochondrial respiration, but did not appear to induce direct electron transport chain dysfunction.

Conclusions: Overall, NHC does not cause direct mitochondrial toxicity in HepaRG cells at clinically relevant concentrations, but may induce minor cellular perturbations. As HepaRG cells have increased physiological relevance, these findings provide additional assurance of the mitochondrial safety profile of NHC.

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在与生理相关的 HepaRG 模型中评估莫仑吡韦活性代谢物β-d-N4-羟基胞苷(NHC)的线粒体安全性。
背景:β-d-N4-羟基胞苷(NHC)是molnupiravir的活性代谢产物,molnupiravir是一种广谱抗病毒药物,已被MHRA批准用于COVID-19的治疗。NHC 可诱导 SARS-CoV-2 病毒发生致命突变,融入病毒基因组并阻止病毒复制。以前曾有报道称,几种核苷类似物会引起线粒体 DNA(mtDNA)或 RNA 复制的脱靶抑制。虽然 NHC 不会在 HepG2 细胞中产生这些影响,但事实证明,HepaRG 在模拟核苷类似物诱导的线粒体功能障碍方面比 HepG2 更有优势。因此,这项工作的目的是评估 NHC 在 HepaRG 细胞中的有丝分裂毒性潜力,HepaRG 细胞是一种更接近生理人肝的模型:方法:将分化的 HepaRG 细胞暴露于 1-60 μM 的 NHC 中 3-14 天,以研究亚临床、超临床和临床相关暴露的影响(在英国,COVID-19 的莫仑匹韦适用于 5 天,报告的 Cmax 为 16 μM)。药物孵育后,对细胞活力、mtDNA拷贝数、线粒体蛋白表达和线粒体呼吸进行了评估:结果:在临床相关暴露条件下,NHC 会导致细胞活力轻微下降,但不会降低线粒体蛋白的表达。对 mtDNA 的影响不尽相同,但拷贝数通常会增加。在超临床浓度(60 μM)下,NHC会降低线粒体呼吸,但似乎不会引起直接的电子传递链功能障碍:总之,在临床相关浓度下,NHC 不会对 HepaRG 细胞的线粒体产生直接毒性,但可能会引起轻微的细胞紊乱。随着 HepaRG 细胞的生理相关性增加,这些发现为 NHC 的线粒体安全性提供了更多保证。
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来源期刊
Toxicology Research
Toxicology Research TOXICOLOGY-
CiteScore
3.60
自引率
0.00%
发文量
82
期刊介绍: A multi-disciplinary journal covering the best research in both fundamental and applied aspects of toxicology
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