Also published as: Abdolmaleki A, Abdullrahman A, Adesina A, Ahad A, Ahmed A, Aldhahrani A, Alexiou A, Alihosseinzadeh A, Allot A, Alsalme A, Alvarez A, Alvarez, A, Alvarez-Valdes A, Ambriović-Ristov A, Amos A, Annunziata A, Anoop A, Arcangeli A, Arsenijevic A, Arsenijević A, Arunachalam A, Asumendi, A, Banerjee A, Banyasz A, Baraniak A, Barta A, Barthe A, Barzowska A, Basava Punna Rao A, Bateman A, Bellamkonda A, Bender A, Benedi A, Benson A, Bento-Oliveira A, Bera A, Bergamo A, Bhattacharjee A, Bhattacharyya A, Bijelic A, Bileck A, Bogdanov A, Bogdanović A, Boletta A, Bonfiglio A, Bort A, Bridge A, Brock A, Brozovic A, Buceta A, Budniok A, Burhop A, Bytzek A, Bényei A, Böhm A, Błauż A, Caković A, Canette A, Capuozzo A, Carballal A, Carbayo A, Caruso A, Carvalho A, Casey A, Casini A, Castonguay A, Catalano A, Cervantes A, Chakchouk-Mtibaa A, Chakraborty A, Chalasani A, Chatterjee A, Chaudhary A, Cheilari A, Chworos A, Chylewska A, Clouet A, Colonna A, Congreve A, Corner, G A, Criscuolo A, Crochet A, Dag A, Daniels A, Danielsen, S A, Dao A, Das A, Dawson A, De Luca A, De Palo A, Decottignies A, Delgadillo A, Deng A, Desideri A, Deyà A, Dillin A, Diman A, Diridl A, Djuric A, Dobrov A, Domán A, Donaire A, Dołęga A, Dutta A, Dąbrowska A, Eichinger A, Eilertsen, I A, El Wakil A, El-Sokkary A, Enriquez Garcia A, Erdem A, Erxleben A, Eskandari A, Espinosa A, Estreicher A, Ethirajan A, Favrelle A, Felgenträger A, Fennes A, Fernández A, Ferreira A, Fluck A, Francés-Monerris A, Frei A, Fuller A, Galindo A, Gallen A, Gamble A, Gandioso A, Garai A, García-Fernández A, Garoufis A, Garza-Ortiz A, Gatti A, Gautam A, Gavriluta A, Ghion A, Gilewska A, Giussani A, Gobbo A, González-Bakker A, Gonzalez-Sarrias A, Gonzalez-Sarrías A, Gos A, Grabulosa A, Grau-Campistany A, Grozav A, Guerri A, Guerriero A, Gupta A, Habtemariam A, Haddad A, Halpern A, Halu A, Halámiková A, Hamaguchi A, Hamilton A, Heras A, Hernández-García A, Ho A, Hoag A, Hurbin A, Hussan A, Hussein A, Idbaih A, Ignatchenko A, Ingels A, Innocenti A, Irkle A, Iwamoto A, Jabłońska-Wawrzycka A, Jacquier A, Jedidi A, Juan A, König A, Kaiser A, Kamecka A, Kamel A, Karaer Tunçay A, Karaiskou A, Karanath-Anilkumar A, Kate A, Keating A, Kerhornou A, Khalifa A, Khireldin A, Khrystenko A, Kisova A, Knaus A, Kobayashi A, Kokkosi A, Kokubu A, Koning A, Kosińska A, Kozarić A, Kromm A, Królicka A, Kubas A, Kumar A, Kumar S K A, Kumari A, Kumbhar A, Kunwar A, Kurzwernhart A, Kwiecień A, Kyzioł A, Lakshminarayanan A, Lara-Sánchez A, Leczkowska A, Legin A, Leniart A, Leonidova A, Levina A, Lin A, Lo A, Lock A, Lopez-Sanchez A, Lothe, R A, Luchini A, Luciani A, Lv A, Madan Kumar A, Maier A, Maisse-Francois A, Makal A, Mambanda A, Mandal A, Mani A, Maniero A, Manteca A, Maréchal A, Marceron A, Marchi A, Marco A, Mariconda A, Marishta A, Martins-Oliveira A, Martín A, Martínez A, Masi A, Massaguer A, Matos A, Merlino A, Meschkov A, Meyer A, Meščić Macan A, Mizeranschi A, Mondal A, Moorthy A, Moreno A, Moretton A, Morgat A, Moro A, Mukherjee A, Muniesa-Vargas A, Muñoz-Castro A, Namatalla A, Nano A, Nelson A, Nencioni A, Neves A, Nigam A, Niorettini A, Notaro A, Nsubuga A, Ocaña A, Odani A, Ooi A, P K A, Pahl A, Palladino A, Paneth A, Panwar A, Pariente A, Parkin A, Pasch A, Patt A, Pavic A, Pavićević A, Pazos A, Petrini A, Petrović A, Pettke A, Pevec A, Pineda-Lucena A, Pitto-Barry A, Pogorzelska A, Poletti A, Pomiankowski A, Ponce A, Prado-Roller A, Pratesi A, Prescimone A, Preto A, Prokop A, Ptak-Belowska A, Puerta A, Qiao A, Radulescu A, Rahardjo A, Ranieri A, Ratanaphan A, Rathgeb A, Rayrikar A, Restrepo-Acevedo A, Riabtseva A, Rilak A, Rilak Simovic A, Riyasdeen A, Rodger A, Rodríguez-Bárzano A, Rodríguez-Diéguez A, Roichman A, Roller A, Rovira A, Ruggi A, Saha A, Samphao A, Sancar A, Sanches A, Santos Dias Mourão A, Sarkar A, Savić A, Scheurer A, Schintlmeister A, Schulze A, Shafir A, Sharma S A, Sikora A, Singh A, Sinopoli A, Sipos A, Skórska-Stania A, Srishailam A, Sveshnikova A, Tadić A, Tamene A, Terenzi A, Tilley A, Tombesi A, Topčagić A, Trevisan A, Triller A, Turjeman A, Uma A, Upadhyay A, Valencia A, Valente A, Valenzuela, Carlos A, Vidal A, Višnjevac A, Vollrath A, Wang A, Waseem A, Welsh A, Westhorpe A, Wheeler A, Wołoszyn A, Wu A, Xu A, Yadav A, Young A, Zafar A, Zahirović A, Zaichenko A, Zamora A, Zarkadoulas A, Zernickel A, Zhang A, Ziółkowska A, Zoleo A, di Biase A, Żak A
The platinum compound oxaliplatin has been shown to be an effective chemotherapeutic agent for the treatment of colorectal cancer. In this study, we investigate the molecular mechanisms of action of o Show more
The platinum compound oxaliplatin has been shown to be an effective chemotherapeutic agent for the treatment of colorectal cancer. In this study, we investigate the molecular mechanisms of action of oxaliplatin to identify means of predicting response to this agent. Exposure of colon cancer cells to oxaliplatin resulted in G2/M arrest and apoptosis. Immunofluorescent staining demonstrated that the apoptotic cascade initiated by oxaliplatin is characterised by translocation of Bax to the mitochondria and cytochrome c release into the cytosol. Oxaliplatin treatment resulted in caspase 3 activation and oxaliplatin-induced apoptosis was abrogated by inhibition of caspase activity with z-VAD-fmk, but was independent of Fas/FasL association. Targeted inactivation of Bax or p53 in HCT116 cells resulted in significantly increased resistance to oxaliplatin. However, the mutational status of p53 was unable to predict response to oxaliplatin in a panel of 30 different colorectal cancer cell lines. In contrast, the expression profile of these 30 cell lines, assessed using a 9216-sequence cDNA microarray, successfully predicted the apoptotic response to oxaliplatin. A leave-one-out cross-validation approach was used to demonstrate a significant correlation between experimentally observed and expression profile predicted apoptosis in response to clinically achievable doses of oxaliplatin (R=0.53; P=0.002). In addition, these microarray experiments identified several genes involved in control of apoptosis and DNA damage repair that were significantly correlated with response to oxaliplatin. Show less
Ru(II) sulfoxide-maltolato complexes, Ru(ma)(2)(L)(2) (L = DMSO (1a) and TMSO (1b) or L(2) = BESE (1c)), were synthesized, as well as the analogous ethylmaltolato derivatives, Ru(etma)(2)(L)(2) (2a-c) Show more
Ru(II) sulfoxide-maltolato complexes, Ru(ma)(2)(L)(2) (L = DMSO (1a) and TMSO (1b) or L(2) = BESE (1c)), were synthesized, as well as the analogous ethylmaltolato derivatives, Ru(etma)(2)(L)(2) (2a-c) (ma = 3-hydroxy-2-methylpyran-4-onate, etma = 2-ethyl-3-hydroxypyran-4-onate, TMSO = tetramethylene sulfoxide, BESE = 1,2-bis(ethylsulfinyl)ethane). A Ru(II) bidentate sulfoxide-metronidazole complex, RuCl(2)(BESE)(metro)(2) (3), was also synthesized (metro = metronidazole = 2-methyl-5-nitroimidazole-1-ethanol). The complexes were characterized generally by (1)H NMR, UV-vis, and IR spectroscopies, as well as MS, elemental analysis, solution conductivity, and cyclic voltammetry. The molecular structures of Ru(ma)(2)(S,R-BESE) (1c) and trans-RuCl(2)(R,R-BESE)(metro)(2) (3) were determined by X-ray crystallography. All sulfoxide ligands are S-bonded. The complexes were tested against human breast cancer cells (MDA-MB-435S) using an in vitro MTT assay, a colorimetric determination of cell viability: 2a,b exhibit the lowest IC(50) values of 190 +/- 10 and 220 +/- 10 microM, respectively. Cisplatin exhibits an IC(50) value of 30 +/- 5 microM. Show less
We have studied the effect of N-(4-hydroxyphenyl)retinamide on either malignant human leukaemia cells or normal cells and investigated its mechanism of action. We demonstrate that 4HPR induces reactiv Show more
We have studied the effect of N-(4-hydroxyphenyl)retinamide on either malignant human leukaemia cells or normal cells and investigated its mechanism of action. We demonstrate that 4HPR induces reactive oxygen species increase on mitochondria at a target between mitochondrial respiratory chain complex I and II. Such oxidative stress causes cardiolipin peroxidation which in turn allows cytochrome c release to cytosol, caspase-3 activation and therefore apoptotic consumption. Moreover, this apoptotic pathway seems to be bcl-2/bax independent and count only on malignant cells but not normal nor activated lymphocytes. Show less
Inhibition of the growth of the human ovarian cancer cell line A2780 by organometallic ruthenium(II) complexes of the type [(eta(6)-arene)Ru(X)(Y)(Z)], where arene is benzene or substituted benzene, X Show more
Inhibition of the growth of the human ovarian cancer cell line A2780 by organometallic ruthenium(II) complexes of the type [(eta(6)-arene)Ru(X)(Y)(Z)], where arene is benzene or substituted benzene, X, Y, and Z are halide, acetonitrile, or isonicotinamide, or X,Y is ethylenediamine (en) or N-ethylethylenediamine, has been investigated. The X-ray crystal structures of the complexes [(eta(6)-p-cymene)Ru(en)Cl]PF(6) (5), [(eta(6)-p-cymene)RuCl(2)(isonicotinamide)] (7), and [(eta(6)-biphenyl)Ru(en)Cl]PF(6) (9) are reported. They have "piano stool" geometries with eta(6) coordination of the arene ligand. Complexes with X,Y as a chelated en ligand and Z as a monofunctional leaving group had the highest activity. Complexes 5, 6 (the iodo analogue of 5), 9, and 10 (ethylethylenediamine analogue of 9) were as active as carboplatin. Hydrolysis of the reactive Ru-Cl bond in complex 5 was detected by HPLC but was suppressed by the addition of chloride ions. Complex 5 binds strongly and selectively to G bases on DNA oligonucleotides to form monofunctional adducts. No inhibition of topoisomerase I or II by complexes 5, 6, or 9 was detected. These chelated Ru(II) arene complexes have potential as novel metal-based anticancer agents with a mechanism of action different from that of the Ru(III) complex currently on clinical trial. Show less