Influence of drinking water and diet on the stable-hydrogen isotope ratios of animal tissues.

Despite considerable interest in using stable-hydrogen isotope ratio (deltaD) measurements in ecological research, it was previously unknown whether hydrogen derived from drinking water, in addition to that derived from diet, contributed to the nonexchangeable hydrogen in animal tissues. We raised four experimental groups of quail (Coturnix coturnix japonica) from hatch on two isotopically distinct diets (mean nonexchangeable deltaD: -146 and -60 per thousand, Vienna Standard Mean Ocean Water Standard) and drinking waters (mean deltaD: -130 and +196 per thousand, Vienna Standard Mean Ocean Water Standard). Here we show that both dietary and drinking water hydrogen are incorporated into nonexchangeable hydrogen in both metabolically active (i.e., muscle, liver, blood, fat) and inactive (i.e., feather, nail) tissues. Approximately 20% of hydrogen in metabolically active quail tissues and 26-32% of feathers and nail was derived from drinking water. Our findings suggest environmental interpretations of deltaD values from modern and fossil animal tissues may need to account for potentially large isotopic differences between drinking water and food and require a good understanding of the physiological ecology of study organisms.

Age, gender, and sensitivity to bleomycin-induced chromosome breakage in Down's syndrome and control populations.

The free radical theory of aging suggests that cells from individuals with premature aging syndromes, such as Down's syndrome, might be especially sensitive to radical-induced DNA damage. Although existing studies support this hypothesis, little work has been done on examining the impact of increasing age on radical sensitivity within the Down's syndrome population. Additionally, intercellular heterogeneity and gender differences in radical sensitivity have not been investigated. In this study, bleomycin-induced chromosome breakage was measured in lymphocytes from a population of adult men and women with Down's syndrome (age range 20-60 years) and a population of normal control men and women of the same age range. Change in breakage rates as a function of age and intercellular heterogeneity in breakage rates were examined in males and females of both groups. The findings are discussed in connection with longevity and cancer risk in the old male population.

Synthesis and biological evaluation of 14-alkoxymorphinans. 1. Highly potent opioid agonists in the series of (-)-14-methoxy-N-methylmorphinan-6-ones.

A series of eight (-)-14-methoxymorphinan-6-ones was synthesized and biologically evaluated. The morphinanones 3-7 were prepared from 3-desoxy-7,8-dihydro-14-hydroxymorphinone (1). The key step in this synthetic sequence, O-methylation in position 14, was accomplished with dimethyl sulfate. Hydrolysis followed by reductive opening of the 4,5-oxygen bridge afforded the phenol 4, which was O-methylated to give 5. Removal of the 4-OH group yielded the aromatic unsubstituted morphinan 7. The synthesis of 9 and 10 was accomplished by starting from 14-methoxy-7,8-dihydrocodeinone and involved a similar reaction sequence. The compounds 12-15 were synthesized from oxymorphone (11), which was 3-O-benzylated, 6,14-bis-O-methylated with dimethyl sulfate, hydrolyzed, and hydrogenated to yield the oxymorphone 14-O-methyl ether 15. The derivatives 3, 4, 5, 7, 9, 10, 14, and 15 exhibited high antinociceptive potency in the hot-plate assay in mice, after both subcutaneous and oral administration. The most potent derivative in this series (15) showed a potency (sc) about 400 times higher than that of morphine and about 40 times higher than its 14-OH analogue oxymorphone (11). The 14-OCH3 series also exhibited a considerably higher affinity to opioid receptors in binding studies using [3H]naloxone as ligand when compared to their 14-OH analogues.

Biological effects of modified colchicines. 2. Evaluation of catecholic colchicines, colchifolines, colchicide, and novel N-acyl- and N-aroyldeacetylcolchicines.

A series of natural and synthetic colchicine derivatives was examined for their potency in the lymphocytic leukemia P388 screen in mice, for their toxicity in mice, and for their binding to microtubule protein. The natural alkaloids cornigerine and colchifoline and several N,O-substituted analogues of colchifoline were found to be as potent and as toxic as colchicine in the P388 screen with good affinity for tubulin. The 1,2-(methylenedioxy)-substituted isomer of cornigerine was considerably less potent in vivo than could have been anticipated from the in vitro tubulin binding data. Several N-acyl and N-aroyl derivatives prepared from deacetylcolchicine showed high potency in the in vitro and in vivo screens. Colchicide was found to be highly potent in vivo, and N-carbethoxydeacetylcolchicine, a synthetic analogue of colchicine with a N-carbethoxy instead of an N-acetyl function, showed interesting biological properties.

Biological effects of modified colchicines. Improved preparation of 2-demethylcolchicine, 3-demethylcolchicine, and (+)-colchicine and reassignment of the position of the double bond in dehydro-7-deacetamidocolchicines.

A variety of colchicine, demecolcine, and isocolchicine derivatives were examined for their potency in the lymphocytic leukemia P388 screen in mice, for their toxicity in mice, and for their binding to microtubule protein. A qualitatively direct correlation was found between in vivo potency and toxicity; potency appeared to be less well correlated with tubulin binding. The most potent compounds were N-acylated analogues of colchicine and demecolcine. Among the monophenols, only 3-demethylcolchicine showed an appreciable effect in vitro and in vivo and was less toxic than colchicine. Improved methods were found for the preparation of 3- and 2-demethylcolchicine, which involved the use of 85% phosphoric acid and concentrated sulfuric acid, respectively. Decoupling experiments with 1H NMR proved that the double bond of dehydro-7-deacetamidocolchiceine and its derived tropolonic methyl ethers 24 and 25 was in the 5,6 position, rather than the 6,7 position formerly tentatively assigned.