Abstract
Background Evidence supports an important link between mitochondrial DNA (mtDNA) variation and adverse drug reactions such as idiosyncratic drug-induced liver injury (iDILI). Here we describe the generation of HepG2-derived transmitochondrial cybrids in order to investigate the impact of mtDNA variation upon mitochondrial (dys)function and susceptibility to iDILI against a constant nuclear background. In this study, cybrids were created to contain mitochondrial genotypes of haplogroup H and haplogroup J for comparison.
Methods Briefly, HepG2 cells were depleted of mtDNA to make rho zero cells before the introduction of known mitochondrial genotypes using platelets from healthy volunteers (n=10), thus generating 10 distinct transmitochondrial cybrid cell lines. The mitochondrial function of each was assessed at basal state and following treatment with compounds associated with iDILI; flutamide, 2-hydroxyflutamide and tolcapone, by ATP assays and extracellular flux analysis.
Findings Overall, baseline mitochondrial function was similar between haplogroups H and J. However, haplogroup specific responses to mitotoxic drugs were observed; haplogroup J was more susceptible to the inhibition of respiratory complexes I and II, and also to the effects of tolcapone, an uncoupler of mitochondrial respiration.
Conclusions This study demonstrates that HepG2 transmitochondrial cybrids can be created to contain the mitochondrial genotype of any individual of interest, thus providing a practical and reproducible system to investigate the cellular consequences of variation in mitochondrial genome against a constant nuclear background. Additionally the results support that that inter-individual variation in mitochondrial genotype and haplogroup may be a factor in determining sensitivity to mitochondrial toxicants.
Funding This work was supported by the Centre for Drug Safety Science supported by the Medical Research Council, United Kingdom (Grant Number G0700654); and GlaxoSmithKline as part of an MRC-CASE studentship (grant number MR/L006758/1).
Competing Interest Statement
The authors have declared no competing interest.