A mechanism of action study was performed with 14 novel DNA binding agents characterized structurally as 2-(arylmethylamino)-1,3-propanediols (AMAPs). Correlations between 8226 myeloma cell colony formation and DNA damage were performed using soft agar colony-forming assays and alkaline elution filter techniques respectively. The frequency of double-stranded breaks (DSBs), single-stranded breaks (SSBs) and DNA-protein cross-links were compared with cell growth inhibitory potency. Highly potent AMAPs in the colony formation assays included 91U86, an N-methyl-5-benzo(c)carbazole derivative, 773U82, a 3-substituted fluoranthene derivative, and crisnatol (770U82), the 6-substituted chrysene derivative. There was a high frequency of SSBs and DSBs with many analogues, but only SSBs occurred in a concentration-dependent fashion. Using regression analysis, the degree of single-strand damage correlated with cytotoxic potency for the AMAPs, with an R-value of 0.57 (P = 0.04). By gel electrophoresis assays, three clinically tested AMAPs, crisnatol BW 770U82, BW 502U83 and BW 773U82, were shown to inhibit the decatenation of pBR 322 DNA by purified topoisomerase-II (TOPO-II) enzymes. These results suggest that while some active AMAPs, such as crisnatol (BW 770U82), BW 502U83 and BW 773U82, inhibit TOPO-II enzymes, leading to protein-associated SSBs, other mechanisms, which do not involve DNA strand damage, must also contribute to the cytotoxic effects of this class of antitumor compounds. Intercalation has been well documented for these drugs and this may explain some of the growth inhibitory activity of the AMAPs.

01 Jul 1991·Journal of medicinal chemistryQ1 · MEDICINE

2-[(Arylmethyl)amino]-2-methyl-1,3-propanediol DNA intercalators. An examination of the effects of aromatic ring variation on antitumor activity and DNA binding

Q1 · MEDICINE

Article

Author: Tuttle, Richard L. ; McKee, David D. ; Cory, Michael ; Andrews, C. Webster ; Knick, Vincent C. ; Bair, Kenneth W.

The effects of variation of aromatic ring size, shape, and side-chain position on antitumor activity and DNA binding in a series of carbocyclic 2-[(arylmethyl)amino]-2-methyl-1,3-propanediols (AMAPs) were examined. In general, the interaction of AMAPs with DNA increases as the intercalating ring system grows in area, with three distinct binding levels evident. Isomers from a specific ring system appear to bind DNA similarly. DNA binding is not the sole criterion for antitumor activity for the AMAPs studied; the magnitude of the delta Tm does not correlate with the antitumor activity observed. Significant in vivo P388 activity was seen for AMAP congeners from several tetracyclic ring systems. However, isomers from each of the specific ring systems produced a wide range of in vivo P388 activity. Thus, AMAP antitumor activity is not a function of the ring system per se, but rather appears to be related to the shape of the specific molecule. Three AMAP congeners (crisnatol (770U82, 773U82, and 502U83) are currently in clinical trials.

01 May 1991·Investigational new drugsQ3 · MEDICINE

Effects of isomeric 2-(Arylmethylamino)-1,3-propanediols (AMAPs) and clinically established agents on macromolecular synthesis in P388 and MCF-7 cells

Q3 · MEDICINE

Article

Author: Kenneth W. Bair ; Christopher A. Carter

The in vitro effects of the 2-(arylmethylamino)-1,3-propanediols (AMAPs) on macromolecular synthesis have been examined using the murine leukemia, P388, and the human mammary adenocarcinoma, MCF-7, under conditions of short-term drug exposure. AMAPs that were observed to inhibit macromolecular synthesis produced nearly equipotent inhibition of DNA and RNA synthesis. Equivalent inhibition of protein synthesis generally required significantly greater concentrations of AMAP. There is a general correlation between inhibition of polynucleotide synthesis and in vivo antitumor activity. The effects of four clinical candidate AMAPs (crisnatol, 773U82, 502U83, and 7U85) on macromolecular synthesis were further compared with those of actinomycin D, doxorubicin, mitoxantrone, etoposide, amsacrine, and cisplatin in MCF-7 cells. The pattern of AMAP action was most similar to that observed for doxorubicin and mitoxantrone. Finally, the effects of these four AMAPs on the size, specific activity, and rate of incorporation of [3H]-dTTP into DNA of MCF-7 cells synchronized by pretreatment with hydroxyurea was determined. It was found that DNA synthesis was inhibited by AMAPs independent of inhibition of the uptake, phosphorylation, or retention of the metabolic precursors. These results support the theory that antitumor AMAPs interfere with the normal functioning of enzymes, such as topoisomerase II or DNA and RNA polymerases, which interact with DNA.

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