Anticancer drugs as inducers of thermotolerance in yeast

A subset of histamine receptor ligands improve thermotolerance of the yeast Saccharomyces cerevisiae

AIMS

Histamine interacts with the stress response in eukaryotes. This study investigated the effects of antihistamines on the heat shock (HS) response in yeast, thereby exploring their functions in a well-established histamine receptor (H(x) R)-free model.

METHODS AND RESULTS

Stress response was evaluated by determining growth and viability of postlogarithmic phase grown yeast cultures after HS at 53°C for 30 min. The effects of H(x) R ligands were investigated following short- and long-term administration. The H(1) R antagonist dimethindene exerted dose-related antifungal actions, whereas the H(2) R antagonist ranitidine failed to elicit any effect. In contrast, the H(3/4) R and H(4) R ligands, thioperamide and JNJ7777120, respectively, induced the thermotolerant phenotype. The circumvention of thermotolerance by cycloheximide and the induction of Hsp70 and Hsp104 expression indicated the contribution of de novo protein synthesis in the adaptive process, likely directed towards alterations in Hsp expression.

CONCLUSIONS

The data provide evidence for the differential function of H(x) R ligands in thermotolerance induction in yeast.

SIGNIFICANCE AND IMPACT OF THE STUDY

First demonstration of the action of antihistamines in the HS response in yeast. The work supports the potential H(x) R-independent functions of histaminergic compounds in fungal adaptation and stimulates research on the prospect of their exploitation in eukaryotic (patho)physiology.

Effect of the Hsp90 modulators on the heat-shock response in eukaryotic cells

The possible role of the heat-shock protein 90 (Hsp90) complex on the heat-shock (HS) response in yeast using the Hsp90 inhibitors geldanamycin (GA) and 17-allylamino-17-demethoxygeldanamycin (AAG), and prednisolone and 17beta-estradiol as modulators was investigated. Following long- or short-term administration of the drugs, either alone or in combination, the response was determined as cell viability and growth after exposure to HS. Upon short-term preconditioning, both Hsp90 inhibitors conferred cycloheximide-dependent thermal resistance to the yeast cultures, while upon long-term treatment the induction of thermotolerance was confined only to AAG. Co-administration of prednisolone or 17beta-estradiol failed to significantly alter the response to Hsp90 inhibitors. However, since short-term incubation with prednisolone alone induced thermotolerance, increased the budding cell fraction and tended to reduce the adaptive response to GA, its effect on GA-induced thermotolerance is not yet explained. Generally, GA and AAG showed a comparable short-term action but a different long-term effect on the HS response in yeast; this response was not related to any regulation by prednisolone or 17beta-estradiol (while 17beta-estradiol was unable to modify the response, the action of prednisolone in both the stress response and the cell cycle was equivocal).

The heat shock response is dependent on the external environment and on rapid ionic balancing by pharmacological agents in Saccharomyces cerevisiae

AIMS

To investigate whether non-preconditioned yeast cells survive under heat shock, when placed in growth medium originated from protected cells and to provide insights into the ionic contribution in the response.

METHODS AND RESULTS

The heat shock response was investigated by determining cell viability following exposure of yeast cells to 53 degrees C for 30 min, either in the absence or presence of drugs. Preconditioning was performed by incubating the cultures at 37 degrees C for 2 h. Under heat shock, non-preconditioned cell survival was significantly enhanced by the presence of the cell-free supernatant of resistant cultures. Addition of omeprazole or tetraethylammonium ions during the heat shock resulted in similar increases. Neither amiodarone nor mepivacaine showed any analogous effect. Omeprazole enhanced survival when added before the heat shock, while amiodarone exhibited a cytocidic action.

CONCLUSIONS

Rapid balancing of ions may contribute to cell survival during heat shock, while survival under mild stress could probably be co-ordinated by additional events.

SIGNIFICANCE AND IMPACT OF THE STUDY

Evidence is provided for the implication of the external environment and ionic homeostasis in the survival of yeast cells under unfavourable environmental conditions. This knowledge may be of importance in controlling both fermentation and therapeutic approaches.

Induction of morphological alterations by antineoplastic agents in yeast

Saccharomyces cerevisiae was used as an alternative experimental model in order to investigate the effects of antineoplastic agents on eukaryotic cells. After being exposed to the most common clinically used antineoplastic agents, yeast cells were examined under the light microscope. Folate and pyrimidine antagonists, platinum derivatives, mitomycin C, actinomycin D and bleomycin induced alterations in yeast cellular morphology, which were not observed following treatment with drugs belonging to any category other than the antineoplastics, leading to the suggestion that these alterations could potentially be used as an experimental tool in pre-screening for new chemotherapeutic leads.