Proteomic approach to the identification of early phase biomarker for anticancer peptides targeting thefolate pathway. F.Genovesea, A.Gualandia,b L.Taddiaa, G.Ponterinia, G.Marvertia, S.Pirondia, R.Guerrinic, M.Pelàa,c G.Pavesia, C.Trapellac, M.P.Costia aUniversity of Modena and Reggio Emilia, via Campi 183, 41125 Modena, Italy, bCRBA, S. Orsola University Hospital, Bologna, Italy, cDepartment of Pharmaceutical Science, University of Ferrara, Italy Many efforts to improve survival of patients affected by Ovarian Cancer (OC) have focused on more effective systemic therapies and on the search for new therapeutic targets. One of the molecular targets for OC is human Thymidylate Synthase (hTS), a homodimeric enzyme essential for DNA biosynthesis. In order to investigate the effects of hTS-interface-mimicking peptides at a cellular level, we started a study in which the cellular behavior of the peptides was investigated in combination with the proteomic differential analysis of the cytoplasmatic proteins of treated vs. untreated OC cells. The same experiment was performed with pemetrexed (PTX), a well known antifolate, for control purposes. The bioinformatic analysis of the effects of our peptide drug candidate indicates that deregulations can be mainly assigned to modulation of translational initiation, termination of RNA Pol-II transcription, transport, and protein catabolic events. Although apparently folate pathway members are not directly altered at a protein level, as the selection of ions to be sequenced is stochastic and biased towards abundant peptides, the bioinformatic analysis of peptide-modulated proteins suggested cellular investigations on the proteins of the folate-associated genes showing the largest number of dependencies to the species of the core set, which is required for the phosphorylation of several deoxyribonucleosides and nucleoside analogues. Comparison with the PTX-modulated proteins shows that some proteins of the proteasome complex and ribonucleoproteins are involved in both cases. These differences suggest that the two compounds may show a different mechanism of action which is in agreement with the hypothesized pharmacological model. Detailed cellular proteins profile based on the inferred roles of the identified proteins will further clarify the biological effects. 1.A proteomic approach to investigate the mechanism of action of anticancer peptides. F. Genovese, A. Gualandi, L. Taddia, M. Caselli, G. Ponterini, S.Ferrari, G. Marverti, R. Guerrini, M. Pela, G. Pavesi, C. Trapella, M.P. Costi, Proceeding 32EPS, p.466, ISBN 978-960-466-121-3). This work is supported by AIRC-DROC IG10474. www.unimore.airc-droc.it
Invited lecture to 18th World Congress on Advances in Oncology and 16th International Symposium on Molecular Medicine 10-12 October, 2013, Creta Maris, Hersonissos, Crete, Greece / Genovese, Filippo; Gualandi, Alessandra; Marverti, Gaetano; Taddia, Laura; Glauco, Ponterini; Pirondi, Silvia; Pela', Michela; Pavesi, Giorgia; Costi, Maria Paola. - In: INTERNATIONAL JOURNAL OF MOLECULAR MEDICINE. - ISSN 1791-244X. - ELETTRONICO. - 32:(2013), pp. 53-53. (Intervento presentato al convegno 18th World Congress on Advances in Oncology and 16th International Symposium on Molecular Medicine tenutosi a Crete-Greece nel 10-12 October 2013).
Invited lecture to 18th World Congress on Advances in Oncology and 16th International Symposium on Molecular Medicine 10-12 October, 2013, Creta Maris, Hersonissos, Crete, Greece
GENOVESE, Filippo;GUALANDI, Alessandra;MARVERTI, Gaetano;TADDIA, LAURA;PIRONDI, SILVIA;PELA', Michela;PAVESI, Giorgia;COSTI, Maria Paola
2013
Abstract
Proteomic approach to the identification of early phase biomarker for anticancer peptides targeting thefolate pathway. F.Genovesea, A.Gualandia,b L.Taddiaa, G.Ponterinia, G.Marvertia, S.Pirondia, R.Guerrinic, M.Pelàa,c G.Pavesia, C.Trapellac, M.P.Costia aUniversity of Modena and Reggio Emilia, via Campi 183, 41125 Modena, Italy, bCRBA, S. Orsola University Hospital, Bologna, Italy, cDepartment of Pharmaceutical Science, University of Ferrara, Italy Many efforts to improve survival of patients affected by Ovarian Cancer (OC) have focused on more effective systemic therapies and on the search for new therapeutic targets. One of the molecular targets for OC is human Thymidylate Synthase (hTS), a homodimeric enzyme essential for DNA biosynthesis. In order to investigate the effects of hTS-interface-mimicking peptides at a cellular level, we started a study in which the cellular behavior of the peptides was investigated in combination with the proteomic differential analysis of the cytoplasmatic proteins of treated vs. untreated OC cells. The same experiment was performed with pemetrexed (PTX), a well known antifolate, for control purposes. The bioinformatic analysis of the effects of our peptide drug candidate indicates that deregulations can be mainly assigned to modulation of translational initiation, termination of RNA Pol-II transcription, transport, and protein catabolic events. Although apparently folate pathway members are not directly altered at a protein level, as the selection of ions to be sequenced is stochastic and biased towards abundant peptides, the bioinformatic analysis of peptide-modulated proteins suggested cellular investigations on the proteins of the folate-associated genes showing the largest number of dependencies to the species of the core set, which is required for the phosphorylation of several deoxyribonucleosides and nucleoside analogues. Comparison with the PTX-modulated proteins shows that some proteins of the proteasome complex and ribonucleoproteins are involved in both cases. These differences suggest that the two compounds may show a different mechanism of action which is in agreement with the hypothesized pharmacological model. Detailed cellular proteins profile based on the inferred roles of the identified proteins will further clarify the biological effects. 1.A proteomic approach to investigate the mechanism of action of anticancer peptides. F. Genovese, A. Gualandi, L. Taddia, M. Caselli, G. Ponterini, S.Ferrari, G. Marverti, R. Guerrini, M. Pela, G. Pavesi, C. Trapella, M.P. Costi, Proceeding 32EPS, p.466, ISBN 978-960-466-121-3). This work is supported by AIRC-DROC IG10474. www.unimore.airc-droc.it
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