The prematurely evoked synthesis of liver tryptophan oxygenase

Maternal and fetal tryptophan metabolism in gestating rats: effects of intrauterine growth restriction

L-Tryptophan (L-Trp) is a precursor for serotonin (5-HT) and nicotinamide adenine dinucleotide (NAD) synthesis. Both 5-HT and NAD may impact energy metabolism during gestation given that recent studies have demonstrated that increased 5-HT production is crucial for increasing maternal insulin secretion, and that sirtuin, an NAD(+)-dependent protein deacetylase, regulates endocrine signaling. Infants born with intrauterine growth restriction (IUGR) are at a higher risk of metabolic disease once they reach adulthood. IUGR is associated with altered maternal-fetal amino acid transfer. Whether IUGR affects L-Trp metabolism in mother and fetus has not been fully elucidated. Recently, we developed an analytical method using stable isotope-labeled L-Trp to explore the metabolism of L-Trp and its main metabolites, L-kynurenine (L-Kyn), 5-HT and quinolinic acid (QA). In this study, dams submitted to dietary protein restriction throughout gestation received intravenous infusions of stable isotope-labeled (15)N2-L-Trp to determine whether L-Trp metabolism is affected by IUGR. Samples were obtained from maternal, fetal and umbilical vein plasma, as well as the amniotic fluid (AF), placenta and liver of the mother and the fetus after isotope infusion. We observed evidence for active L-Trp transfer from mother to fetus, as well as de novo synthesis of 5-HT in the fetus. Plasma 5-HT was decreased in undernourished mothers. In IUGR fetuses, maternal-fetal L-Trp transfer remained unaffected, but conversion to QA was impaired, implying that NAD production also decreased. Whether such alterations in tryptophan metabolism during gestation have adverse consequences and contribute to the increased risk of metabolic disease in IUGR remains to be explored.

Moderate food restriction suppresses the conversion of L-tryptophan to nicotinamide in weaning rats

Calorie restriction leads to a change in the metabolism of nutrients. Nicotinamide is biosynthesized from L-tryptophan. We attempted to determine the effects of food restriction on the biosynthesis of nicotinamide from L-tryptophan. Weaning male rats were fed a conventional chemically defined diet without preformed niacin for 63 d. However, the food intake was restricted to 80 and 65% of the intake of the ad libitum-fed control group of rats. The 24-h urine samples were periodically collected, and the urinary excretion of nicotinamide and its catabolites was measured. The conversion percentages were lower in both restricted groups than in the ad libitum-fed control group during the experimental period (control group, 1.37 ± 0.24%; 80%-restricted group, 0.20 ± 0.04%; 65%-restricted group, 0.15 ± 0.02%; control vs. restricted groups, p < 0.01). Food restriction, even at mild level, suppressed the conversion of L-tryptophan to nicotinamide when compared to the ad libitum-fed control group.

Perinatal development of the liver in rat and spiny mouse. Its relation to altricial and precocial timing of birth

Rat (Rattus norvegicus) and spiny mouse (Acomys cahirinus) are closely related murinoid species that mainly differ in the developmental timing of birth. A comparison between the developmental profiles of some characteristic enzymes of the liver of both species was carried out to elucidate the question to what extent are these enzymic profiles and hence the maturation of the liver related to the timing of birth? It was found that these organotypic enzymes first become detectable at the same developmental stage in both species. Likewise, the weaning phase of the enzymic profiles occurs at the same developmental time point in both species. It is argued that both the first appearance and the weaning increase in enzyme activity levels occur at endogenously programmed timepoints with only superimposed effects of hormones. In contrast, the perinatal phase of the enzymic profile is completely dependent on the developmental timing of birth and therefore appears not to be anchored to a particular developmental timepoint, but rather to be dependent on birth-associated (hormonal) adaptation. In accordance with this hypothesis it was found that the morphological development of the liver proceeded independent of the timing of birth. Furthermore, the hormonal regulation of the investigated enzymes was found to be the same in both species. Despite the more advanced state of morphological development of the liver in the spiny mouse at birth, it was found that the inducibility of organotypic gene expression by hormones in spiny mouse fetuses was as limited as in rat fetuses. This observation therefore suggests that the intra-uterine environment is responsible for the limited inducibility of enzymes before birth.

Adrenalectomy: its effects on systemic tryptophan metabolism in normal and protein malnourished rats

Rats born to dams fed either a low protein diet (8% casein) or a normal diet (25% casein) started 5 weeks prior to conception and continued through lactation were bilaterally adrenalectomized or received a sham-operation at 30 days of age. At 60 days of age, the systemic tryptophan metabolism of th 8% and 25% adrenalectomized rats was compared to the sham-operated controls of each diet group. While adrenal ablation produced significant decreases in the brain serotonin and metabolite concentrations and marked increases in brain tryptophan concentrations for both diet groups compared to their respective controls, these substances remained significant higher in all malnourished rats than in the well-nourished groups. Also, the major modulator of the peripheral metabolic pathways which regulates the availability of free plasma tryptophan (total tryptophan, albumin, and nonesterified fatty acid concentrations) was the nutritional status of the rats rather than their treatment condition. Only plasma corticosterone concentrations showed changes (significantly decreases) as a consequence of adrenal ablation for either diet group. Overall, the data indicated that under physiological conditions the adrenal cortex has an important function in determining brain tryptophan utilization, whereas its role in regulating peripheral tryptophan metabolism is minimal.

L-Tryptophan action on hepatic RNA synthesis and enzyme induction

L-Tryptophan increases the activity of hepatic amino acid metabolizing enzymes, affects gluconeogenesis and displays a modulatory effect on several enzymes connected with RNA synthesis. The underlying mechanism differ in individual cases and result in both an increase of enzyme synthesis de novo and a decrease of enzyme degradation. Tryptophan displays a unique effect causing aggregation of hepatic polyribosomes connected with enhanced protein synthesis and preceded by a higher transport of poly (A) messenger RNA from the nucleus to the cytoplasm. The variety of rather specific effects mediated by tryptophan brings to mind hormonal action and the existence of specific tryptophan receptors is predicted.

Developmental control of messenger RNA for hepatic tryptophan 2,3-dioxygenase

The enzyme tryptophan 2,3-dioxygenase [EC 1.13.11.11; L-tryptophan:oxygen 2,3-oxidoreductase (decyclizing)] first appears in the livers of young rats around the 15th postnatal day, and increases to the adult level by the 22nd day. Studies have shown that the appearance and subsequent development of the enzyme activity result from an increase in the rate of its synthesis and thus in the amount present in the liver. In this study, we have attempted to ascertain whether the appearance and development of tryptophan 2,3-dioxygenase mRNA coincided with, and thus led to, the development of enzyme activity, or whether the biosynthesis of this enzyme was due to a developmental event enabling translation of a preexisting, sequestered, reservoir of its mRNA. Using a cell-free protein-synthesizing system based on a wheat germ S30 supernatant, we measured the level of tryptophan 2,3-dioxygenase mRNA in the livers of rats between 0 and 22 days of age. We found that functional tryptophan 2,3-dioxygenase mRNA is not detectable in rat liver until the 15th postnatal day. It increases to the adult level by the 22nd postnatal day, in parallel with the enzyme. The appearance and development of tryptophan 2,3-dioxygenase are the direct consequence of the parallel appearance and development of its mRNA. It has been shown that glucocorticoids, which induce tryptophan 2,3-dioxygenase activity in adult rats, are capable of inducing the appearance of this enzyme precociously in 8- and 10-day-old rats. We have found that it is also possible to induce tryptophan 2,3-dioxygenase catalytic activity with hydrocortisone precociously in 4-day-old rats. Moreover, precocious induction of enzyme activity and the induction that occurs during the enzyme's normal developmental rise to the adult level between 15 and 22 days, are mediated through parallel increases in the level of tryptophan 2,3-dioxygenase mRNA. The present findings indicate that glucocorticoids are developmental hormones that act upon the postnatal hepatocyte to evoke elevated levels of the mRNA species coding for tryptophan 2,3-dioxygenase; the findings are compatible with the hypothesis that such hormones act by initiating and accelerating transcription of the structural genes coding for the alpha and beta protomers of this enzyme.

Premature induction of hepatic tryptophan oxygenase

Subcutaneous administration of hydrocortisone acetate to the newborn rat produces a premature induction of hepatic tryptophan oxygenase consisting of a transient rise in activity 6-8 h after treatment, followed by a second sustained rise beginning 40 h later, which plateaus at 10 days of age. Cycloheximide treatment at the midpoint of this second elevation inhibits protein synthesis, but not tryptophan oxygenase activity. In older animals, cycloheximide treatment does both. Tryptophan administration at this midpoint rapidly elevates tryptophan oxygenase activity. This elevation can be partially blocked by treatment with actinomycin D within 1 h of tryptophan administration, but not thereafter. Actinomycin treatment is ineffective in blocking the tryptophan-induced rise in older animals. Administration of hydrocortisone acetate to 5- and 10-day-old pups leads to a more rapid and sustained rise in tryptophan oxygenase activity without appearance of a transient induction phase. Neither tryptophan alone, δ-aminolevulinic acid alone, nor tryptophan plus δ-aminolevulinic acid prematurely induces tryptophan oxygenase in newborn or 5-day-old rats.

Regulation of hepatic L-serine dehydratase and L-serine-pyruvate aminotransferase in the developing neonatal rat

1. The activities of l-serine dehydratase and l-serine-pyruvate aminotransferase were determined in rat liver during foetal and neonatal development. 2. l-Serine-pyruvate aminotransferase activity begins to develop in late-foetal liver, increases rapidly at birth to a peak during suckling and then decreases at weaning to the adult value. 3. l-Serine dehydratase activity is very low prenatally, but increases rapidly after birth to a transient peak. After a second transient peak around the time weaning begins, activity gradually rises to the adult value. Both of these peaks have similar isoenzyme compositions. 4. In foetal liver both l-serine dehydratase and l-serine-pyruvate aminotransferase activities are increased after injection in utero of glucagon or dibutyryl cyclic AMP. Cycloheximide or actinomycin D inhibited the prenatal induction of both enzymes and actinomycin D blocked the natural increase of l-serine dehydratase immediately after birth. Glucose or insulin administration also blocked the perinatal increase of l-serine dehydratase. 5. After the first perinatal peak of l-serine dehydratase, activity is increased by cortisol and this is inhibited by actinomycin D. After the second postnatal peak, activity is increased by amino acids or cortisol and this is insensitive to actinomycin D inhibition. Glucose administration blocks the cortisol-stimulated increase in l-serine dehydratase and also partially lowers the second postnatal peak of activity. 6. The developmental patterns of the enzymes are discussed in relation to the pathways of gluconeogenesis from l-serine. The regulation of enzyme activity by hormonal and dietary factors is discussed with reference to the changes in stimuli that occur during neonatal development and to their possible mechanisms of action.

Subcellular morphometric and biochemical analysis of developing rat hepatocytes

Livers of rats between the 16th gestational and 100th postnatal day of age were subjected to quantitative biochemical and electron microscope, morphometric analyses. The amount of total mitochondrial protein per gram of liver remained at 34% of the adult level throughout the last 4 days of gestation but this was the period of rapid rise in the levels of cytochrome c oxidase, aspartate aminotransferase, and glutamate dehydrogenase in mitochondria; the nuclear fraction also acquired some glutamate dehydrogenase but lost most of it during postnatal development. During early postnatal life the amount of mitochondrial protein rose in parallel with the levels of cytochrome c oxidase and glutamate dehydrogenase but the upsurges of glutaminase and, later, of ornithine aminotransferase were accompanied by relatively little change in total mitochondrial protein. The surface area of rough endoplasmic reticulum per unit volume of hepatocyte cytoplasm (S(v) (RER)) did not change significantly throughout the period of development studied. From the 16th day of gestation to term the surface area of smooth ER (S(v) (SER)), the volume occupied by mitochondria (V(v) (MT)) and their number (N(v) (MT)) remained at 30, 66, and 45% of their adult values, respectively. V(v) (MT) and N(v) (MT) attained their maximal levels by the 2nd postnatal day and S(v) (SER) between days 2 and 12. Mitochondria of adult liver are thus smaller and contain more protein per unit volume than do those of fetal liver. After the 12th postnatal day, hepatocytes treble their size; they acquire more cytoplasm with additional enzymes but without further change in organelle concentration. The data reveal several distinct phases in the differentiation of hepatocytes. Each phase can be characterized by the extent to which the quantity and composition of various subcellular compartments evolve.

The adaptive behaviour of isoenzyme forms of rat liver alanine aminotransferases during development

1. The activities of the mitochondrial and cytosol isoenzyme forms of l-alanine-glyoxylate and l-alanine-2-oxoglutarate aminotransferases were determined in rat liver during foetal and neonatal development. 2. The mitochondrial glyoxylate aminotransferase activity begins to develop in late-foetal liver, increases rapidly at birth to a peak during suckling and then decreases at weaning to the adult value. 3. The cytosol glyoxylate aminotransferase and the mitochondrial and cytosol 2-oxoglutarate aminotransferase activities first appear prenatally, increase further after birth and then rise to the adult values during weaning. 4. In foetal liver the mitochondrial glyoxylate aminotransferase and the cytosol 2-oxoglutarate aminotransferase activities are increased after injection in utero of glucagon, dibutyryl cyclic AMP (6-N,2'-O-dibutyryladenosine 3':5'-cyclic monophosphate) or thyroxine. The cytosol glyoxylate aminotransferase and the mitochondrial 2-oxoglutarate aminotransferase activities are increased after injection in utero of cortisol or thyroxine. 5. After birth the further normal increases in the mitochondrial and cytosol 2-oxoglutarate aminotransferase activities can be hastened by cortisol injection, whereas the increase in cytosol glyoxylate aminotransferase activity requires cortisol treatment together with the intragastric administration of casein. 6. The results are discussed with reference to the metabolic patterns and the changes in regulatory stimuli (hormonal and dietary) that occur during the period of development.