The increasing worldwide incidence of cancer is a serious global health problem. Despite significant advances in cancer treatment and drug development, there is an urgent need for additional and better tolerated anticancer drugs to treat primary and recurrent cancers. Unfortunately, the development and discovery of new anticancer drugs is expensive, time-consuming, and in the worst case, must be terminated during clinical trials due to the occurrence of intolerable side effects or poor effectiveness (1,2).

Testing of already approved therapeutic drugs for additional purposes, so-called drug repositioning, is a recently growing approach to discover new applications for already existing drugs (1,3). When screening tests or preclinical data indicate a new possible application for a specific drug, pre-existing knowledge on its pharmacokinetics, bioavailability, and side effects facilitate the assessment of its possible application in humans. Recent studies have indicated that HIV drugs may represent a valuable source of possible new anticancer drugs (4,5). In particular, the HIV protease inhibitor nelfinavir was found to be highly active on a variety of human cancer cells (6–10), and is currently being tested in several clinical studies on cancer patients (7,11–13).

A screening of anti-retroviral drugs for their efficacy on human cancer cells revealed a striking sensitivity of cancer cells to the non-nucleoside reverse transcriptase inhibitor (NNRTI) efavirenz (14–17). Recently we observed that efavirenz could influence cell viability of endothelial cells (14). Moreover, this inhibition was associated with an increase in oxidative stress markers, endoplasmic reticulum (ER) stress markers, and autophagy (14). A cytotoxic effect has been demonstrated on several tumor cell lines including colorectal, pancreatic and the human leukemia cell lines Jurkat (acute T-cell leukemia cells) (17). Blood cancer cells are highly sensitive to cytostatic drugs but, depending on the cancer type, often become resistant after initial therapy, necessitating second and even third line treatment therapies (7,11,18). Thus, there is a need for additional new anticancer drugs that induce specific cell death pathways in leukemia cells (11,18). The present study describes the effect of efavirenz on the leukemia cancer cell lines Jurkat (acute T-cell leukemia), HL60 (acute promyelocytic leukemia), and IM9 (EBV-transformed B-lymphoblastoid).

The results of the present study reveal that the HIV drug efavirenz effectively induces apoptosis in leukemia cells. This indicates a possible new perspective for the application of efavirenz in the treatment of human non-solid cancer. Efavirenz induces the classical apoptotic pathway associated with an enhanced phosphorylation of H2AX, suggesting efavirenz-induced DNA damage as a possible trigger for apoptosis. The H2AX histone subtype is not a DNA repair enzyme itself, but forms a platform and recognition site for DNA repair enzymes and DNA damage-associated signaling factors, especially at DNA double strand breaks (19,20).

Recently we demonstrated that efavirenz can induce cell stress and reduced cell proliferation of endothelial cells (14). However, concentrations of up to 10 µg/ml, which efficiently induce cell death in leukemia cells, left endothelial cells viable and did not destroy endothelial cell meshwork formations (14). Efavirenz has demonstrated a significant anti-proliferative effect in pancreatic cancer cells (15). A cytotoxic effect has been demonstrated on several tumor cell lines including colorectal, pancreatic and Jurkat leukemia cells (17). Interestingly, while a change in the phosphorylation of ERK and AKT was not observed, the tumor suppressor protein p53 revealed an increased activation of phosphorylation (17). Moreover, a synergistic effect with cannabinoid agonists has been observed (17).

The exact mechanism of efavirenz-induced DNA damage remains to be elucidated, especially since efavirenz does not represent a nucleoside analogue. The induction of oxidative stress has often been suggested as the mechanism mediating DNA damage caused by xenobiotics (21). Indeed, Apostolova et al recently described the induction of oxidative stress in efavirenz-treated human hepatocytes and hepatoma cells (22), and we have recently described enhanced oxidative stress by efavirenz in human endothelial cells (14). However, we did not observe the induction of oxidative stress in efavirenz-treated leukemia cancer cells as analyzed by the same standardized ROS assay. Therefore, the different tissue sensitivity against efavirenz resulting in oxidative stress still remains to be elucidated.

In a phase II trial with 53 patients with a metastatic castration-resistant prostate cancer (mCRPC), the use of an increased dosage regime of efavirenz may be beneficial for treatment (16). In the treatment of leukemia, efavirenz could be tested as a single agent, based on data showing that the effective drug concentrations (~10 µg/ml) are not substantially higher than the doses currently used for the long-term treatment of HIV-infected persons receiving daily efavirenz treatment. The long-term pharmacological experience with this drug, its oral bioavailability, tolerable side effects, and its good compliance (23,24) are further aspects that could facilitate the design and implementation of clinical trials on efavirenz with leukemia patients.