Two strains of Mus musculus musculus, C57BL/6J and CD-1, and Mus musculus poschiavinus, the tobacco mouse, were used to study the effects of increased gene dosage of mouse chromosome 16 (MMU 16). A developmental delay has been found in the brains of murine trisomy 16 (Ts16) fetuses. Both the brain weight (in all three strains) and DNA content (in CD-1) were reduced, while protein content was unchanged in Ts16 compared to normal littermates. The daily increments of weight and protein (except in M. m. poschiavinus) were significantly greater in Ts16. The activities of choline acetyltransferase and acetylcholinesterase and muscarinic receptor binding were reduced. Their daily increments were also reduced to less than 56% that of littermates in Ts16 brains. The rate limiting enzymes of catecholaminergic neurons, tyrosine hydroxylase and dopamine beta-hydroxylase, and the concentration of catecholamines in the brains of Ts16 animals were lower. The activities of three other catecholaminergic enzymes, DOPA decarboxylase, catechol O-methyltransferase, and monoamine oxidase, were generally elevated in Ts16 brain, as were their daily increments. These observations indicate a significant developmental alteration in the maturation of the trisomic brain and suggest future avenues for defining the effect of increased gene dosage of MMU 16 in the CNS.
1. In 48 h-starved 6-week-old rats the 14C incorporation in vivo into blood glucose from a constant-specific-radioactivity pool of circulating [14c]actateconfirmed that lactate is the preferred gluconeogenic substrate. 2. Increasing the blood [alanine] to that occurrring in the fed state increased 14C incorporation into blood glucose 2.3-fold from [14c]alanine and 1.7-fold from [14c]lactate. 3. When the blood [alanine] was increased to that in the fed state, the 14C incorporation into liver glycogen from circulating [14c]alanine or [14c]lactate increased 13.5- and 1.7-fold respectively. 4. The incorporation of 14C into blood acetoacetate and 3-hydroxybutyrate from a constant-specific-radioactivity pool of circulating [14c]oleate was virtually abolished by increasing the blood [alanine] to that existing in the fed state. However, the [acetoacetate] remained unchanged, whereas [3-hydroxybutyrate] decreased, although less rapidly than did its radiochemical concentration. 5. It is concluded that during starvation in 6-week-old rats, the blood [alanine] appears to influence ketogenesis for circulating unesterfied fatty acids and inversely affects gluconeogenesis from either lactate or alanine. A different pattern of gluconeogenesis may exist for alanine and lactate as evidenced by comparative 14C incorporation into liver glycogen and blood glucose.
The effects of ethanol on the physical development and maturation of the CNS in the offspring of lactating rats were investigated. Dams were fed: 1) regular stock diet (control), 2) liquid diet containing 35% of the calories as ethanol (ETOH) or 3) liquid diet with maltose-dextrin substituted for the calories supplied by ethanol (isoenergetic = IE). Diets were administered from the 14th day of gestation until 3 weeks post-partum (pre- and post-natal exposure) or from birth until 3 weeks post-partum (post-natal exposure). Body weight, crown-rump length and tail length, as well as brain weight were followed longitudinally in the pups. The growth in the pups of dams fed ETOH diet and those fed IE diet were significantly less than that observed in the pups of control dams. Furthermore, pups of dams fed the ETOH diet showed retardation in growth indices and brain weight at various ages when compared to pups of equivalent age from dams fed the IE diet. Therefore, administration of ethanol to pregnant or lactating dams impaired the physical growth, including central nervous systems (CNS), of their offspring more than those changes caused by nitritional deprivation.
1. The injection of L-alanine (50-100 mg/kg) into 35-day-old rats that had been starveed for 48 h increased blood L-alanine concentration to values observed in fed animals and lowered the blood concentration of 3-hydroxybutyrate within 2 min. 2. This hypoketon aemic action of L-alanine was specific for 3-hydroxybutyrate, since the acetoacetate concentrations did not change significantly. 3. The decrease in 3-hydroxybutyrate elicited by L-alanine was not related to changes in the blood concentrations of insulin, glucagon, growth hormone, glucose, unesterified fatty acids, lactate or pyruvate. 4. The injection of L-alanine resulted in a decrease in total ketones that was apparently unrelated to their increased peripheral utilization. These results are interpreted as an anti-ketogenic action of L-alanine. 5. The data suggest that L-alamine lowers ketone-body formation in starved rats, possibly via an alteration in hepatic redox equilibrium.
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