Διερεύνηση των μηχανισμών με τους οποίους χημικές ενώσεις με αντινεοπλασματικές ιδιότητες προκαλούν γενετικές ανωμαλίες

Abstract

Nitrogen mustards represent an effective class of drugs that are used in chemotherapy. Recent findings of our group have shown that nitrogen mustard analogues, melphalan (MEL), chlorambucil (CAB) and PHE, in addition to their clastogenic activity, they exert their aneugenic potential by affecting chromosome segregation due to modifications of mitotic apparatus. In the present study, we investigated the mechanism by which the above compounds display their aneugenicity in comparison with two new steroidal analogues of PHE, EA-92 and EA-97, which were designed aiming at most effective antineoplasmatic activity. The ability of MEL, CAB and PHE to induce chromosome delay events was studied in comparison with the steroidal analogues EA-92 and EA-97. The mechanism of micronucleation was determined by Cytokinesis Block Micronucleus assay (CBMN assay) in combination with Fluorescence In Situ Hybridization (FISH) using pancentromeric DNA probe. It was confirmed that MEL, CAB and PHE generated MNi by two mechanisms, chromosome breakage and chromosome delay, while EA-92 and EA-97 induced the formation of MN originated exclusively from chromosome breakage events. The ability of the tested compounds to induce chromosome delay was also investigated in C2C12 mouse cells by CREST analysis. The dual genetic activity of MEL, CAB, and PHE was confirmed in a different biological system. The analogues EA-92 and EA-97 appeared as weaker MN inducers and they induced mainly chromosome breakage, while a weak aneugenic activity was observed for EA-92. The ability of the nitrogen mustard analogues to affect the organization of mitotic apparatus was investigated in comparison with MEL, CAB and PHE by double immunofluorescence of β- and γ-tubulin in C2C12 mouse cells. It was observed that all compounds, except EA-97, induced mutlipolar metaphases, and also generated interphase cells with abnormal centrosome number. All compounds displayed increased cytotoxicity and they caused cell cycle delay in human lymphocyte cultures and in C2C12 mouse cells. The ability of the tested compounds to induce apoptosis was studied by Annexin V/PI assay. It was revealed that all compounds induced apoptosis. The effect of apoptosis on the genetic activity of MEL, CAB and PHE was investigated by inhibition of apoptosis in the presence of the inhibitor Z-VAD-FMK and the use of specific inhibitors for caspase -3, -6, -8 and -1. For this reason Annexin V/PI assay and double immunofluorescence of β- and γ-tubulin were performed, independently in C2C12 mouse cells. Caspases -3, -6 and -8 are involved in melphalan-induced apoptosis, but they are not involved in the elimination of cells in the presence of melphalan. Apoptosis is the responsible mechanism for the exclusion of cells with MNi and normal centrosome number that are induced by MEL, CAB and PHE. On the contrary, cells exerting supernumerary centrosomes are not eliminated by apoptosis in the presence of the above compounds. To further elucidate the mechanisms by which MEL and CAB exert their aneugenic potential, we examined the ability of the compounds to alter the expression of proteins having important role in chromosome segregation, such as the proteins Aurora-B, survivin, Aurora-A and γ-tubulin. The analysis was performed by Western blot method in C2C12 mouse cells. We also studied the steroid analogue EA-97, which according to our findings acts as a pure clastogen and do not exert aneugenic potential as opposed to MEL and CAB. MEL and CAB exert their aneugenic potential by the reduction of Aurora-B and survivin expression and by enhancing the expression of Aurora-A. γ-tubulin was upregulated in the presence of MEL. These findings show the implication of these proteins in chromosome delay events induced by MEL and CAB. On the other hand, the analogue EA-97 did not affect the expression of the above proteins.