Synergistic Effect of Endogenous and Exogenous Aldehydes on Doxorubicin Toxicity in Yeast.

Anthracyclines are frequently used to treat many cancers including triple negative breast cancer, which is commonly observed in African-American women (AA), and tend to be more aggressive, carry worse prognoses, and are harder to manage because they lack molecular targets. Although effective, anthracyclines use can be limited by serious side effects and eventually the development of drug resistance. In S. cerevisiae, mutants of HOM6 display hypersensitivity to doxorubicin. HOM6 is required for synthesis of threonine and interruption of the pathway leads to accumulation of the threonine intermediate L-aspartate-semialdehyde. This intermediate may synergize with doxorubicin to kill the cell. In fact, deleting HOM3 in the first step, preventing the pathway to reach the HOM6 step, rescues the sensitivity of the hom6 strain to doxorubicin. Using several S. cerevisiae strains (wild type, hom6, hom3, hom3hom6, ydj1, siz1, and msh2), we determined their sensitivity to aldehydes and to their combination with doxorubicin, cisplatin, and etoposide. Combination of formaldehyde and doxorubicin was most effective at reducing cell survival by 31-fold-39-fold (in wild type cells) relative to doxorubicin and formaldehyde alone. This effect was dose dependent on doxorubicin. Cotreatment with formaldehyde and doxorubicin also showed increased toxicity in anthracycline-resistant strains siz1 and msh2. The hom6 mutant also showed sensitivity to menadione with a 2.5-fold reduction in cell survival. The potential use of a combination of aldehydes and cytotoxic drugs could potentially lead to applications intended to enhance anthracycline-based therapy.

The Role of HSP40 Conserved Motifs in the Response to Cytotoxic Stress.

Doxorubicin, a highly effective therapeutic agent against several types of cancer, is associated with serious side-effects, particularly cardiotoxicity. In addition, drug resistance leads to unsuccessful outcomes in many patients. There are no current biomarkers to indicate doxorubicin treatment response in patients. To understand the mechanisms of toxicity of doxorubicin, a whole-genome sensitivity screen was performed in the yeast S. cerevisiae. A deletion mutant of the yeast DNAJ (YDJ1), a J-domain heat-shock protein 40 (HSP40) was among the most sensitive strains. HSP40 is a co-chaperone to HSP70 and together refold denatured proteins into native conformation. The HSP40 YDJ1 is comprised of several highly-conserved domains and motifs that are essential in the heat-shock response. The cysteine-rich region has been implicated in protein-protein interaction with client proteins, farnesylation of YDJ1 facilitates attachment of YDJ1 to the ER and perinuclear membranes, and the histidine-proline-aspartic acid (HPD) tripeptide motif present in the J-domain, is responsible for the regulation of the ATPase activity of HSP70s. We have investigated the role of these motifs in the protection cytotoxic stress. We find that mutations in the HPD motif and cysteine-rich region of YDJ1 sensitize cells to doxorubicin and cisplatin, while a mutation in farnesylation results in a slightly protective effect. The sensitivity of the HPD and cysteine mutants is specific to oxidative stress and not to DNA double-strand breaks.