An isolation method for assessment of brain mitochondria function in neonatal mice with hypoxic-ischemic brain injury.

This work was undertaken to develop a method for the isolation of mitochondria from a single cerebral hemisphere in neonatal mice. Mitochondria from the normal mouse brain hemisphere isolated by the proposed method exhibited a good respiratory control ratio of 6.39 +/- 0.53 during glutamate-malate-induced phosphorylating respiration. Electron microscopy showed intact mitochondria. The applicability of this method was tested on mitochondria isolated from naïve mice and their littermates subjected to hypoxic-ischemic insult. Hypoxic-ischemic insult prior to reperfusion resulted in a significant (p < 0.01) inhibition of phosphorylating respiration compared to naïve littermates. This was associated with a profound depletion of the ATP content in the ischemic hemisphere. The expression for Mn superoxide dismutase and cytochrome C (markers for the integrity of the mitochondrial matrix and outer membrane) was determined by Western blot to control for mitochondrial integrity and quantity in the compared samples. Thus, we have developed a method for the isolation of the cerebral mitochondria from a single hemisphere adapted to neonatal mice. This method may serve as a valuable tool to study mitochondrial function in a mouse model of immature brain injury. In addition, the suggested method enables us to examine the mitochondrial functional phenotype in immature mice with a targeted genetic alteration.

Molecular cloning of the baboon UDP-glucuronosyltransferase 1A gene family: evolution of the primate UGT1 locus and relevance for models of human drug metabolism.

BACKGROUND: Glucuronidation by the UDP glucuronosyltransferase 1A enzymes (UGT1As) is a major pathway for elimination of drugs and endogenous substances, such as bilirubin. OBJECTIVE: To identify the baboon UGT1A gene family, compare it with that of the human, and evaluate the baboon as a model for human glucuronidation. METHODS AND RESULTS: Aligning the human and baboon UGT1 loci identified rearrangements occurring since the divergence of baboons and humans. The baboon UGT1A cDNAs were cloned and shown to have an orthologous relationship with several genes in the human UGT1A family. This indicates that most protein encoding UGT1A first exons were duplicated before the divergence of baboons and humans. Gene conversions interfered with the phylogenetic signal for exons 1A4, 1A5, and 1A10, and led to concerted evolution of exon groups 1A2-1A5 and 1A7-1A13. The activity of the baboon UGT1As resembled those of their human counterparts in glucuronidating endobiotics, such as serotonin, bilirubin, and various xenobiotics. CONCLUSION: These insights demonstrate that the baboon has significant clinical relevance as a model for examining toxicological metabolism in humans.

Fetal morphine metabolism and clearance are constant during late gestation.

Fetal metabolism significantly contributes to the clearance of drugs from the fetus. To understand how the changes in fetal metabolism expected in late gestation alter fetal drug clearance, serial measurements of morphine metabolism were made in the fetal baboon over the latter third of gestation. Clearance and metabolism were evaluated in the context of fetal growth, onset of labor, and the administration of classical enzyme induction agents. Morphine, a probe substrate for the enzyme uridine diphosphate glucuronosyltransferase 2B7 (UGT2B7), was continuously infused to chronically catheterized fetal baboons while measuring morphine, morphine-3-beta-glucuronide, and morphine-6-beta-glucuronide concentrations. In some animals, intermittent infusions of the metabolites provided estimates of metabolite clearance and, hence, the rate of formation of metabolites and metabolic clearance. Overall, metabolic clearance of morphine from the fetus was 27 +/- 9.0 ml x min(-1) or 32% of total clearance. This is similar to the overall clearance in the adult baboon when standardized to weight. No change in any measure of metabolism or clearance of morphine or its glucuronide metabolites was found with gestational age, the presence of labor, or administration of UGT enzyme induction agents. Interpreting these findings using a physiologically based approach suggests that the intrinsic clearance of the fetal liver toward morphine is of sufficient magnitude that fetal hepatic clearance is flow-limited. The implication of a high intrinsic clearance is for significant placento-hepatic first-pass metabolism when drugs are administered to the mother. The previously held view of the "inadequacy of perinatal glucuronidation" needs to be reconsidered.