The Potential of Iron Chelators of the Pyridoxal Isonicotinoyl Hydrazone Class as Effective Antiproliferative Agents III: The Effect of the Ligands on Molecular Targets Involved in Proliferation

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Blood, Vol. 94 No. 2 (July 15), 1999: pp. 781-792

The Potential of Iron Chelators of the Pyridoxal Isonicotinoyl Hydrazone Class as Effective Antiproliferative Agents III: The Effect of the Ligands on Molecular Targets Involved in Proliferation

G. Darnell and D.R. Richardson
From the Department of Medicine, University of Queensland, Royal Brisbane Hospital, Brisbane, Queensland, Australia.
We have identified specific iron (Fe) chelators of the pyridoxal isonicotinoyl hydrazone (PIH) class that are far more effectiveligands than desferrioxamine (DFO; Richardson et al, Blood 86:4295,1995; Richardson and Milnes, Blood 89:3025, 1997). In the presentstudy, we have compared the effect of DFO and one of the mostactive chelators (2-hydroxy-1-naphthylaldehyde isonicotinoyl hydrazone;311) on molecular targets involved in proliferation. This wasperformed to further understand the mechanisms involved in theantitumor activity of Fe chelators. Ligand 311 was far more activethan DFO at increasing Fe release from SK-N-MC neuroepitheliomaand BE-2 neuroblastoma cells and preventing Fe uptake from transferrin.Like DFO, 311 increased the RNA-binding activity of the iron-regulatoryproteins (IRPs). However, despite the far greater Fe chelationefficacy of 311 compared with DFO, a similar increase in IRP-RNAbinding activity occurred after 2 to 4 hours of incubation witheither chelator, and the binding activity was not inhibited bycycloheximide. These results suggest that, irrespective of theFe chelation efficacy of a ligand, an increase IRP-RNA bindingactivity occurred via a time-dependent step that did not requireprotein synthesis. Further studies examined the effect of 311and DFO on the expression of p53-transactivated genes that arecrucial for cell cycle control and DNA repair, namely WAF1, GADD45,and mdm-2. Incubation of 3 different cell lines with DFO or 311caused a pronounced concentration- and time-dependent increasein the expression of WAF1 and GADD45 mRNA, but not mdm-2 mRNA.In accordance with the distinct differences in Fe chelation efficacyand antiproliferative activity of DFO and 311, much higher concentrationsof DFO (150 µmol/L) than 311 (2.5 to 5 µmol/L) were required tomarkedly increase GADD45 and WAF1 mRNA levels. The increase inGADD45 and WAF1 mRNA expression was seen only after 20 hours ofincubation with the chelators and was reversible after removalof the ligands. In contrast to the chelators, the Fe(III) complexesof DFO and 311 had no effect on increasing GADD45 and WAF1 mRNAlevels, suggesting that Fe chelation was required. Finally, theincrease in GADD45 and WAF1 mRNAs appeared to occur by a p53-independentpathway in SK-N-MC and K562 cells, because these cell lines lackfunctional p53. Our results suggest that GADD45 and WAF1 may playimportant roles in the cell cycle arrest observed after exposureto thesechelators.

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  Copyright © 1999 by American Society of Hematology         Online ISSN: 1528-0020





	Copyright © 1999 by American Society of Hematology Online ISSN: 1528-0020