Pharmacogenomics: personalizing pediatric heart transplantation.

Abstract

In recent years, outcomes for pediatric cardiac transplantation (PCTx) have steadily improved, with current 5-year overall survival rates estimated at 83%.1 This progress may be attributed to improvements in pretransplantation management, selection of donor hearts, surgical technique, prevention and treatment of rejection, and minimization of treatment-related adverse events. Despite these advances, children who receive cardiac transplants experience significant morbidity and mortality, and there is considerable variability in outcomes, much of which cannot be explained by known clinical risk factors. One source of interindividual variability is genetic variation in the host. There is growing evidence that genomic variation leads to differences in immune response, response to therapies, and susceptibility to adverse outcomes such as malignancy and infection.2–4 This review will focus on the effect of variation in genes that encode enzymes, transporters, and drug target molecules that influence drug response. After review of the foundational principles of pharmacogenomics, evidence for the pharmacogenomic effects on cyclosporine, tacrolimus, azathioprine, mycophenolate mofetil (MMF), and the mammalian target of rapamycin (mTOR) inhibitors sirolimus and everolimus will be reviewed and clinical implications of these findings discussed. Given the limited nature of evidence from studies of PCTx patients, support will also be drawn from non-PCTx research and pediatric renal transplantation. Genetic studies of nonpharmacogenes such as those in immunomodulatory pathways and variation in the donor genotype may contribute to risk prediction but are beyond the scope of this review. ### Genetic Variation DNA variation can alter biological function through several mechanisms (Figure 1). Variation within the coding sequence or in intron/exon borders can change the protein product through changes in start codons, stop codons, splice sites, or within the coding sequence, leading to nonsense-mediated decay or altered protein function. Other variants associated with pharmacogenomic outcomes are not predicted to change the encoded protein. These synonymous and …