RESUMO
The rationale behind this study is that controlled starvation of poorly differentiated (anaplastic) fast-growing tumor cells, but not host cells, might be possible in vivo. The energy metabolism of anaplastic tumor cells, but not host cells, is largely dependent on carbohydrate metabolism at all times. Therefore depleting plasma of carbohydrate fuels could place these tumor cells at a significant metabolic disadvantage. Hence an animal model was developed in which all cells would be required to oxidize fatty acids, ketoacids, and/or 1,3-butanediol to satisfy their energy needs. To achieve this aim, one would need ketosis, severe hypoglycemia, and low lactatemia. Anesthetized normal dogs were infused with somatostatin and a mixture of (R,S)-1,3-butanediol monoacetoacetate and (R,S)-1,3-butanediol diacetoacetate; these latter compounds are nonionized precursors of ketoacids. They were infused at 90% of the dog's caloric requirement. After establishment of a moderate ketosis (2-3 mM) over < 100 min, a severe degree of hypoglycemia (close to 0.5 mM) without rebound and without hyperlactatemia was induced by infusing insulin and dichloroacetate. Tracer kinetic measurements showed 1) a 20% decrease in the rate of appearance of glucose, 2) 50 and 62% increases in glycerol and nonesterified fatty acid rates of appearance, reflecting stimulation of lipolysis, and 3) no change in the rate of glutamine appearance. We suggest that this model may prove useful for selectively starving those cancer cells that are unable to utilize fat-derived fuels while preserving nutrient supply to vital organs.
Assuntos
Acetoacetatos , Butileno Glicóis , Hipoglicemia/sangue , Cetose/sangue , Cetose/induzido quimicamente , Ácido 3-Hidroxibutírico , Acetoacetatos/metabolismo , Animais , Glicemia/análise , Butileno Glicóis/metabolismo , Ácido Dicloroacético/farmacologia , Cães , Hidroxibutiratos/metabolismo , Corpos Cetônicos/sangue , Rim/metabolismo , Lactatos/sangue , MasculinoRESUMO
We developed gas chromatographic-mass spectrometric assays for the enantiomers of 1,2-propanediol, 1,3-butanediol, 1,3-pentanediol, and their corresponding hydroxyacids, lactate, beta-hydroxybutyrate, and beta-hydroxypentanoate (3-hydroxyvalerate) in biological fluids. The corresponding ketoacids, acetoacetate and beta-ketopentanoate, can be assayed simultaneously by pretreating the samples with NaB2H4. The assays involve spiking the samples with deuterated internal standards, deproteinization, ether extraction, and derivatization of the carboxyl groups with (R,S)-2-butanol/HCl and of the hydroxyl groups with chiral (S)-(+)-2-phenylbutyryl chloride. Mass spectrometric analysis is conducted under ammonia positive chemical ionization. We used these assays to follow the metabolism of diol enantiomers in dogs. For (R,S)-1,3-butanediol and (R,S)-1,3-pentanediol, the uptakes from dog plasma of the R and S enantiomer of each diol were identical. In contrast, the metabolism of (S)-1,2-propanediol was faster than that of (R)-1,2-propanediol. (R)-1,2-Propanediol is formed during acetone metabolism, while (R,S)-1,3-butanediol and (R,S)-1,3-pentanediol are potential nutrients. The assays developed will allow further investigations of the metabolisms of acetone, (R)-lactate, and artificial nutrients derived from the 1,3-butanediol and 1,3-pentanediol enantiomers.
Assuntos
Butileno Glicóis/sangue , Glicóis/sangue , Hidroxiácidos/sangue , Propilenoglicóis/sangue , Ácido 3-Hidroxibutírico , Animais , Boroidretos , Butileno Glicóis/metabolismo , Cães , Cromatografia Gasosa-Espectrometria de Massas/métodos , Glicóis/metabolismo , Hidroxiácidos/metabolismo , Hidroxibutiratos/sangue , Hidroxibutiratos/metabolismo , Indicadores e Reagentes , Lactatos/sangue , Lactatos/metabolismo , Ácido Láctico , Ácidos Pentanoicos/sangue , Ácidos Pentanoicos/metabolismo , Propilenoglicol , Propilenoglicóis/metabolismo , Sensibilidade e Especificidade , Estereoisomerismo , Relação Estrutura-AtividadeRESUMO
We developed gas chromatography-mass spectrometric methods for assaying the enrichment of 99 at.% [6,6-2H2]glucose and 30 at.% [U-13C6]glucose, although both tracers are mostly M + 2. 13C enrichment is determined either by the C-1 to C-5 fragment of glucose aldonitrile pentaacetate or by oxidation of glucose to glucarate. 2H enrichment is assayed as the difference between the 13C enrichment of glucarate and the 2H + 13C enrichment of glucose. The techniques, which were validated in in vivo experiments, are applicable to the determination of simultaneous or sequential measurements of the rate of glucose appearance before and after an intervention. They could also be applied to the simultaneous determination of (i) gluconeogenesis by incorporation of a 13C-labeled precursor into glucose and (ii) the rate of glucose appearance by [6,6-2H2]glucose infusion.