Faculty Bibliography

Phorbolol myristate acetate (PHMA) had been previously prepared from the potent mouse skin tumor promoter phorbol myristate acetate (PMA) by sodium borohydride reduction of the C-5 carbonyl group in PMA to a secondary alcohol. PHMA was shown to have an inflammatory effect in mouse skin equal to that of PMA. 2,3-Dihydrophorbol myristate acetate (DPMA), a new compound, was prepared from the 3-aldehyde of PMA by catalytic hydrogenation. DPMA exhibited no detectable inflammatory effect in mouse skin. Both DPMA and PHMA were tested on the dorsal skins of female ICR/Ha Swiss mice (30/group) for 433 and 380 days, respectively, in separate experiments. The tumor-promoting activity of both compounds was reduced significantly, compared with that of equimolar doses of PMA. For each treatment the number of mice with tumors per total number of tumors was: DPMA, 9/17; PMA, 29/553 at 10 microgram/mouse; PMA, 30/317; PHMA, 24/69 at 2.5 microgram/mouse. The results suggest that specific binding requirements influence the tumor-promoting and hyperplastic activity of PMA and its closely related derivatives in mouse skin

The isobutane chemical ionization mass spectra of a series of 4aalpha-phorbol esters have been determined. Phorbol myristate acetate, a diester of phorbol, is the most potent known tumor promoter in mouse skin carcinogenesis. Several esters of the stereoisomer of phorbol have been synthesized to study the effect of structure and stereochemistry on tumor promotion. Conventional electron impact mass spectra of these esters gave little or no molecular weight information due to their low volatility, tendency to dehydrate and complex fragmentation to peaks in the low mass end of the spectrum. Isobutane chemical ionization mass spectrometry greatly enhanced the molecular ion region and through functional group selectivity established the identity of the various substituted esters

In vitro reaction of beta-propiolactone (BPL) with calf thymus DNA and mouse liver DNA followed by acid (HCL) hydrolyses of the BPL-reacted DNA's resulted in the isolation of a new compound, 1-(2-carboxyethyl)-adenine (1-CEA). The structure was assigned on the basis of ultraviolet spectra at acidic, alkaline and neutral pH and electron impact and chemical ionization mass spectra as well as chemical synthesis of 1-CEA from BPL and 2'-adenosine-5'-monophosphoric acid. The only other compound previously isolated from the in vitro and in vivo reactions of BPL and DNA was 7-(2-carboxyethyl)guanine (7-CEG) which we also identified as a product of our in vitro reaction. Under the conditions used the main product of alkylation was 1-CEA and the ratios of the concentrations of 1-CEA to 7-CEG was approx 3 : 1. The possible effect of the formation of 1-CEA on the structure of DNA and its role in chemical carcinogenesis is discussed.