Relevance of experimental models for investigation of genotoxicity induced by antiretroviral therapy during human pregnancy

The current incidence of human immunodeficiency virus (HIV-1)/AIDS affects around 7000 pregnant women in the United States. When given during pregnancy, the nucleoside analog 3'-azido-3'-deoxythymidine (AZT) significantly reduces maternal-fetal transmission. It has been previously shown that AZT is incorporated into DNA, where it causes mutations in the HPRT and TK genes. It also changes cell cycle gene expression, and induces S-phase arrest, micronuclei, chromosomal aberrations, sister chromatid exchanges, telomeric attrition, and other genotoxic effects in cultured cells. A predicted consequence of these events is genomic instability that together, with clastogenicity may contribute to the carcinogenic potency of AZT. Various aspects of genotoxicity are explored in this contribution seeking to understand the multiple effects of this antiretroviral agent in animal models and humans. This mini-review describes some of the experimental models used to elucidate the genotoxicity induced by antiretroviral therapy during human pregnancy. The use of diverse methods to detect biomarkers of exposure, such as an AZT-specific radioimmunoassay, micronuclei bearing intact chromosomes, and telomeric DNA attrition highlight the role of in vitro models to elucidate exposure and risk. The relevance of the in vitro models is followed by the introduction of the role of the nucleoside analogs in transplacental carcinogenesis along with the description of a transplacental perfusion model and a transplacental carcinogenesis rodent model. In a more direct clinical application the use of AZT-DNA incorporation as a biomarker of exposure, in experiments conducted in vivo in Erythrocebus patas monkeys and in humans, addresses the possibility of elucidation of potential cancer risk in those infants exposed in utero. Two relevant aspects of this contribution are the potential application of some of the models described in this mini-review, as diagnostic tools in antiretroviral-exposed populations, and the use of these models to understand the nature of the genotoxicities and minimize the undesirable side effects of the antiretroviral therapy.