Protein synthesis by attached pulmonary macrophages effect of phagocytosis

We studied the effect of phagocytosis of polystyrene latex beads on protein synthesis by pulmonary macrophages. To do this we determine the specific radioactivity of extracellular and intracellular free phenylalanine and of phenylalanine released from tRNA and used this information in calculating the rates of protein synthesis. Phagocytosis resulted in an increased rate of protein synthesis irrespective of which precursor specific radioactivity was used in the calculation. The rate of protein synthesis was increased per μg polyribosomal RNA; but there was no increase in the amount of polyribosomal RNA in phagocytizing macrophages. The increase in the rate of protein synthesis (1.4-fold) was almost identical to the increase (1.3-fold) in the rate of ribosome transit in phagocytizing compared to nonphagocytizing macrophages. The decreased ribosome transit time during phagocytosis occurred without a fall in the average molecular weight of macrophage proteins. We conclude that phagocytosis increases the rate of protein synthesis in attached pulmonary macrophages and that this increased rate of synthesis can be accounted for almost completely by an increased rate of polypeptide chain elongation and/or termination.     

Protein synthesis by attached pulmonary macrophages. Effect of phagocytosis

We studied the effect of phagocytosis of polystyrene latex beads on protein synthesis by pulmonary macrophages. To do this we determine the specific radioactivity of extracellular and intracellular free phenylalanine and of phenylalanine released from tRNA and used this information in calculating the rates of protein synthesis. Phagocytosis resulted in an increased rate of protein synthesis irrespective of which precursor specific radioactivity was used in the calculation. The rate of protein synthesis was increased per microgram polyribosomal RNA; but there was no increase in the amount of polyribosomal RNA in phagocytizing macrophages. The increase in the rate of protein synthesis (1.4-fold) was almost identical to the increase (1.3-fold) in the rate of ribosome transit in phagocytizing compared to nonphagocytizing macrophages. The decreased ribosome transit time during phagocytosis occurred without a fall in the average molecular weight of macrophage proteins. We conclude that phagocytosis increases the rate of protein synthesis in attached pulmonary macrophages and that this increased rate of synthesis can be accounted for almost completely by an increased rate of polypeptide chain elongation and/or termination.     

Messenger RNA-controlled Increase of Phenylalanine Ammonia-Lyase Activity in Parsley: Light-Independent Induction by Dilution of Cell Suspension Cultures into Water

A specific antiserum, raised against purified phenylalanine ammonialyase from irradiated cell suspension cultures of parsley (Petroselinum hortense Hoffm.), was used to compare the enzyme species induced either by dilution or by irradiation of the cell suspensions, to investigate the effect of dilution on the rate of synthesis of the enzyme protein in vivo, and to analyze the changes in specific activity of polyribosomal mRNA for the enzyme subunits in vitro. The mRNA activity in vitro was measured by translation of the polyribosomal RNA in a rabbit reticulocyte lysate.     

Effect of tryptophan on livers of pregnant and lactating rats and their fetuses and pups

The effect of the administration of L-tryptophan on hepatic polyribosomes and protein synthesis in pregnant rats and their fetuses and in lactating rats and their pups was investigated. Pregnant rats tube-fed tryptophan 1 hr before killing revealed increased hepatic protein synthesis but essentially unmodified polyribosomal aggregation of maternal livers while no changes were observed in fetal livers in comparison to controls (water-treated). Lactating rats tube-fed tryptophan 1 hr before killing revealed increased polyribosomal aggregation and protein synthesis of the livers in comparison to controls. Pups of these mothers that received tryptophan intraperitoneally 1 hr before killing did not reveal a significant change in the hepatic polyribosomes or protein synthesis.     

INCORPORATION OF AMINO ACIDS INTO PROTEINS IN NEURONAL AND NEUROPIL FRACTIONS OF RAT CEREBRAL CORTEX: PRESENCE OF A RAPIDLY LABELLING NEURONAL FRACTION

Abstract— The time course of incorporation of intraperitoneally injected [³H]lysine and [¹⁴C]phenylalanine into neuronal and neuropil proteins has been followed for up to 8 days. At short times after injection (<2 h) the specific activity of the neuronal fraction was higher than that of the neuropil. At longer time intervals, although the total brain specific activity continued to rise, neuronal perikaryal specific activity fell below that of neuropil. Thus the neuronal/neuropil incorporation ratio with [³H]lysine as substrate was 1·5 at 1 h, but by 4 h had fallen to 0·4, a ratio which was maintained for up to 8 days. A similar reversal occurred with phenylalanine as substrate. These changes were interpreted as evidence for the presence of a rapidly-labelling protein fraction in the neurons which is subsequently transported out. Subcellular fractionation showed that over the 4 h period the rapidly labelling fraction was not transported to the synaptosomes. Incubation of prelabelled cortex slices followed by cell fractionation showed that a differential transport of protein of higher than average specific activity from both neurons and neuropil fractions occurred; there is a tendency for preformed highly labelled protein to accumulate during the in vitro incubation in Fraction D, a pellet enriched in red cells, some large neuronal perikarya and cell nuclei. When cell fractions were prepared after in vitro incubation, the distribution of the material down the gradient differed from that when fresh tissue was fractionated, as demonstrated by microscopic examination and the distribution of β-galactosidase, a neuronal marker. Double-label experiments showed that this redistribution could not account for the preferential loss and accumulation of prelabelled protein. It was noted that in vivo incorporation into the rapidly labelling neuronal protein is suppressed under certain changed environmental conditions, such as dark rearing. This is interpreted as lending support to the concept of the state-dependence of neuronal and neuropil protein synthesis and their inter-relations.     

Cellular compartmentation of aromatic amino acids in Neurospora crassa. I. Occupation of a protein synthesis pool by phenylalanine in Tyr-1 mutants

The p-fluorophenylalanine (FPA) resistance of acc ^phe, which has previously been shown (Brooks et al., 1972) to be a try-1 mutant, has been further investigated. When incubated in the absence of tyrosine, acc ^phe and also tyr-1 auxotrophs show a gradual increase in free phenylalanine in the cell but a sharp decrease in FPA incorporation into protein. The decrease in FPA incorporation is apparently due to the excess phenylalanine in the mutants, since the normal endogenous pool component in wild type and also in the mutants incubated on tyrosine does not appear to compete with FPA for incorporation. The rate of FPA incorporation into protein in acc ^phe remains at 10–15% of the wild-type rate even when the ratio of free FPA to excess phenylalanine in the cell is high as 8:1. If wild type is supplied with exogenous phenylalanine and FPA simultaneously, phenylalanine is preferentially incorporated into protein but, in contrast to the mutant, the rate of FPA incorporation increases as the ratio of free FPA to phenylalanine increases. On the basis of differences in competition with FPA and in susceptibilities to mild extraction procedures, it is proposed that phenylalanine can be located in at least three compartments in Neurospora: a small constant-size endogenous pool always seen in wild type; an expandable exogenous pool; and a protein synthesis pool which is preferentially populated by endogenous phenylalanine but can be entered by exogenous molecules when biosynthesis is regulated. In acc ^phe, where phenylalanine biosynthesis is not regulated, the excess phenylalanine is located primarily in the protein synthesis pool where it only has to compete with a small FPA component and is thereby preferentially incorporated into protein in this mutant.This work was supported, in part, by an Atomic Energy Commission grant to the Institute of Molecular Biophysics, The Florida State University, and by the Genetics Training Grant, funded by the National Institutes of Health. It contains, in part, data from the doctoral thesis of the senior author, who was supported by a Florida State University Nuclear Fellowship and by a Public Health Service Fellowship.     

In utero glucocorticoid exposure reduces fetal skeletal muscle mass in rats independent of effects on maternal nutrition

Maternal stress and undernutrition can occur together and expose the fetus to high glucocorticoid (GLC) levels during this vulnerable period. To determine the consequences of GLC exposure on fetal skeletal muscle independently of maternal food intake, groups of timed-pregnant Sprague-Dawley rats (n = 7/group) were studied: ad libitum food intake (control, CON); ad libitum food intake with 1 mg dexamethasone/l drinking water from embryonic day (ED)13 to ED21 (DEX); pair-fed (PF) to DEX from ED13 to ED21. On ED22, dams were injected with [(3)H]phenylalanine for measurements of fetal leg muscle and diaphragm fractional protein synthesis rates (FSR). Fetal muscles were analyzed for protein and RNA contents, [(3)H]phenylalanine incorporation, and MuRF1 and atrogin-1 (MAFbx) mRNA expression. Fetal liver tyrosine aminotransferase (TAT) expression was quantified to assess fetal exposure to GLCs. DEX treatment reduced maternal food intake by 13% (P < 0.001) and significantly reduced placental mass relative to CON and PF dams. Liver TAT expression was elevated only in DEX fetuses (P < 0.01). DEX muscle protein masses were 56% and 70% than those of CON (P < 0.01) and PF (P < 0.05) fetuses, respectively; PF muscles were 80% of CON (P < 0.01). Muscle FSR decreased by 35% in DEX fetuses (P < 0.001) but were not different between PF and CON. Only atrogin-1 expression was increased in DEX fetus muscles. We conclude that high maternal GLC levels and inadequate maternal food intake impair fetal skeletal muscle growth, most likely through different mechanisms. When combined, the effects of decreased maternal intake and maternal GLC intake on fetal muscle growth are additive.     

Cellular compartmentation of aromatic amino acids in Neurospora crassa. II. Synthesis and misplaced accumulation of phenylalanine in Phen-2 auxotrophs

Two mutants which require phenylalanine for normal growth and which show no prephenate dehydratase activity in vitro have been found to accumulate and excrete phenylalanine when incubated on minimal medium or grown on low concentrations of phenylalanine. The high levels of phenylalanine accumulated in these mutants apparently cannot be used for protein synthesis or for the regulation of the biosynthetic enzymes in the aromatic pathway. Mutant mycelia grown in high phenylalanine maintain a much lower level of free phenylalanine in the cells than do those grown on low phenylalanine or those which eventually grow on minimal. If all the phenylalanine required for the protein in a 3-day mycelial pad is supplied, little or no phenylalanine can be found in the medium after 3 days: if only a fraction of the total protein phenylalanine is supplied, the concentration of phenylalanine in the medium after 3 days is actually higher than the initial concentration. It is proposed that the mutation in these organisms has resulted in abnormal compartmentation of the phenylalanine produced so it cannot be utilized by the cells until it has been excreted and transported back into the normal pool channels. In this case, the transport (exogenous) and protein synthesis pools would be involved. The abnormal mislocation of the phenylalanine in the cell might be a result of the diffusion of free prephenate to low pH regions in the cell where it is nonenzymatically converted to phenylpyruvate. If, however, the mutant prephenate dehydratase is active in vivo, the mutation must somehow affect the activity or stability of the enzyme in vitro and also cause the release of the end product in the wrong place in the cell. This might be expected if the normal wild-type prephenate dehydratase is directionally oriented, e.g., as a result of membrane association, to release the product into normal cell channels (protein synthesis pool) while such oriented release might not occur in the mutants.This work was supported, in part, by an Atomic Energy Commission grant to the Institute of Molecular Biophysics, The Florida State University, and by the Genetics Training Grant, funded by the National Institutes of Health. It contains, in part, data from the doctoral thesis of the senior author, who was supported by a Florida State University Nuclear Fellowship and by a Public Health Service Fellowship.     

Polyribosome disaggregation and cell-free protein synthesis in preparations from cerebral cortex of hyperphenylalaninemic rats

Abstract— Seven-day-old rats were injected intraperitoneally with l -phenylalanine (1 g/kg) and the time course of brain polyribosome disaggregation and changes in brain levels of phenylalanine, tryptophan and tyrosine were determined. Disaggregation of brain polyribosomes preceded the increase in levels of phenylalanine in brain, and followed the same time course as depletion of tryptophan from brain. The effects of several metabolites of phenylalanine (which are formed in phenylketonuria) on protein synthesis in vitro was determined for brain and liver systems. None of the compounds tested was inhibitory at concentrations below 10 mM and in all cases hepatic protein synthesis was more sensitive to inhibition than was the corresponding system from brain. Ribosomal dimers, formed in brain after injection of phenylalanine, were incapable of supporting high levels of protein synthesis in vitro, a finding that suggested that the inhibition of protein synthesis in vitro in cell-free systems of brain tissue after injection of phenylalanine into young rats was mediated by disaggregation of brain polyribosomes associated with tryptophan deficiency in brain.     

Primary cultures of fetal hepatocytes from the genetically obese Zucker rat: Protein synthesis

Summary Primary fetal hepatocytes derived from Zucker rats with expectedfa gene frequencies of 0.0 and 0.75 have been established and can be used to detect early effects of thefa gene on hepatocellular metabolism. Paired incubation experiments demonstrate that protein synthesis in 0.75fa gene cultures is significantly less than in 0.0fa gene cultures under basal conditions. Insulin stimulates protein synthesis in 0.0fa gene cultures but has no effect on 0.75fa gene cultures. Cycloheximide inhibits protein synthesis in both types of culture. NH₄Cl inhibits protein synthesis in 0.0 but not in 0.75fa gene cultures. These data suggest that fetal hepatocytes bearing thefa gene have in vitro a generally sluggish anabolic capacity and a blunted capacity to respond to insulin compared to fetal hepatocytes without thefa gene. These diminished capacities may be expressions of a genetic error in lysosomal function. A portion of this work was presented in preliminary form at the 1980 meeting of the Tissue Culture Association. This work was supported in part by National Institutes of Health Grants AM19382 and AM06197.     

Cord blood ASP is predicted by maternal lipids and correlates with fetal birth weight

Background: The acylation stimulating protein (ASP) is a potent lipogenic adipokine that correlates with postprandial triglyceride (TG) clearance and is linked to the pathophysiology of obesity and related disorders. Objective: To investigate ASP levels in cord blood and its relation to maternal and cord blood lipid parameters and fetal birth weight. Methods and Procedures: Thirty nondiabetic pregnant women, their newborns, and thirty‐three nonpregnant controls were included in this study. Fasting maternal and cord blood ASP, TGs, nonesterified fatty acids (NEFAs), cholesterol, glucose levels, in addition to maternal BMI and fetal birth weight were measured. Results: No significant difference was found between cord blood ASP (16.3 ± 0.96 nmol/l) and ASP levels in the adult controls (15.7 ± 1.0 nmol/l). Cord blood ASP, however, was lower than maternal plasma ASP levels (25.4 ± 1.6 nmol/l, P < 0.001). Yet, lipid levels in cord blood, particularly TGs were markedly decreased compared to control and maternal TG levels (threefold and 7.4‐fold, P < 0.001 respectively). Maternal TGs significantly correlated with fetal birth weight (r = 0.54, P = 0.002). Multiple regression analysis showed that maternal TGs (β = 0.57, P = 0.01) and NEFAs (β = 0.43, P = 0.024) predicted 45% variation in cord blood ASP levels, independent of all measured maternal and cord blood parameters. Cord blood ASP showed a positive correlation with fetal birth weight (r = 0.524, P = 0.037) in neonates above average fetal birth weight of the studied population. Discussion: This is the first study investigating ASP in cord blood. We suggest that maternal hypertriglyceridemia is associated with increased fetal ASP production, thus enhancing fetal fat storage independent of maternal glucose variations in nondiabetic women.     

Synthesis of phenylalanine ammonia-lyase in anthocyanin-containing and anthocyanin-free callus cells of Daucus carota L.

When callus cells of Daucus carota are grown on a medium containing gibberellic acid (GA₃) in a physiological concentration of 3x10^-6 M the cells cease to accumulate anthocyanins. This anthocyanin-free cell line has a very low activity of phenylalanine ammonia-lyase. After density labelling with D₂O an intensive de novo synthesis of the phenylalanine ammonia-lyase (E.C. 4.3.1.5; PAL) in the anthocyanin-containing cells does occur. 58% of the C-bound H-atoms are replaced by deuterium. The anthocyanin-free cells show only a very low enzyme synthesis which is difficult to detect with density labelling experiments. To ascertain that de novo synthesis occurs in the anthocyanin-free cells, the incorporation of ¹⁴C-labelled amino acids into the partially purified enzyme protein was measured after separation of the protein a) in CsCl gradients and b) on polyacrylamide gels. In both cases the enzyme bears ¹⁴C-label. These results suggest that in the anthocyanin-free cells de novo synthesis of PAL is still occuring but the synthesis is reduced in comparison to the anthocyanin-containing cells.Abbreviations GA₃ gibberellic acid - PAL phenylalanine ammonia-lyase (E.C.4.3.1.5) - DCb anthocyanin-containing cells - DCw anthocyanin-free cells     

Ethanol-induced inhibition of ventricular protein synthesis in vivo and the possible role of acetaldehyde

We have determined the extent to which acute ethanol administration perturbs the synthesis of ventricular contractile and non-contractile proteins in vivo. Male Wistar rats were treated with a standard dose of ethanol (75 mmol kg^?1 body weight; i.p.). Controls were treated with isovolumetric amounts of saline (0·15 mol 1^?1 NaCl). Two metabolic inhibitors of ethanol metabolism were also used namely 4-methylpyrazole (alcohol dehydrogenase inhibitor) and cyanamide (acetaldehyde dehydrogenase inhibitor) which in ethanol-dosed rats have been shown to either decrease or increase acetaldehyde formation, respectively. After 2·5 h, fractional rates of protein synthesis (i.e. the percentage of tissue protein renewed each day) were measured with a large (i.e. ‘flooding’) dose of L -[4-³H]phenylalanine (150 μmol (100 g)^?1 body weight into a lateral vein). This dose of phenylalanine effectively floods all endogenous free amino acid pools so that the specific radioactivity of the free amino acid at the site of protein synthesis (i.e. the amino acyl tRNA) is reflected by the specific radioactivity of the free amino acid in acid-soluble portions of cardiac homogenates. The results showed that ethanol alone and ethanol plus 4-methylpyrazole decreased the fractional rates of mixed, myofibrillar (contractile) and sarcoplasmic (non-contractile) protein synthesis to the same extent (by approx. 25 per cent). Profound inhibition (i.e. 80 per cent) in the fractional rates of mixed, myofibrillar and sarcoplasmic protein synthesis occurred when cyanamide was used to increase acetaldehyde formation. There was also a significant decrease in cardiac DNA content. The results suggest that acute ethanol-induced cardiac injury in the rat may be mediated by both acetaldehyde and ethanol.     

Influence of amino acids and organic antimetabolites on growth and biosynthesis of the chemoautotroph Thiobacillus neapolitanus strain C

Summary The growth of Thiobacillus neapolitanus strain C in liquid cultures was depressed by phenylalanine, p-fluorophenylalanine, cysteine, methionine, nor-leucine, azetidine-2-carboxylic acid, and chloramphenicol, but was little affected by glutamic acid, glycine, proline, azathymine, or oligomycin.Growing cultures assimilated ¹⁴C-labelled glycine, glutamic acid, phenylalanine, and tyrosine into protein. Tyrosine and phenylalamine were incorporated unchanged, but glutamate was used also for synthesis of arginine and proline. Glycine-¹⁴C contributed also to adenine and guanine synthesis. The extremely large amounts of phenylalanine incorporated into protein could indicate its toxicity to depend on its producing abnormal protein synthesis. Azetidine-2-carboxylic acid appeared to lower the amount of proline in the protein.Assimilation of glutamate and glycine by non-growing organisms was almost entirely dependent on energy from thiosulphate oxidation, thus suggesting a cause of obligate chemoautotrophy. Chloramphenicol specifically inhibited this thiosulphate-dependent incorporation of glutamate, glycine or CO₂ into protein at concentrations which did not affect total CO₂-fixation. Provided that energy is available from thiosulphate-oxidation this Thiobacillus is thus able to (a) activate exogenous amino acids; (b) incorporate them and CO₂ into protein by a chloramphenicol sensitive mechanism; (c) synthesise proline and arginine from glutamate; or adenine and guanine from glycine. Its biosynthesis thus depends on mechanisms like those of heterotrophs but requires to be driven by a chemolithotrophic energy supply.     

Measurement of protein synthesis in rat lungs perfused in situ

Compartmentalization of amino acid was investigated to define conditions required for accurate measurements of rates of protein synthesis in rat lungs perfused in situ. Lungs were perfused with Krebs–Henseleit bicarbonate buffer containing 4.5% (w/v) bovine serum albumin, 5.6mm-glucose, normal plasma concentrations of 19 amino acids, and 8.6–690μm-[U-¹⁴C]phenylalanine. The perfusate was equilibrated with the same humidified gas mixture used to ventilate the lungs [O₂/CO₂ (19:1) or O₂/N₂/CO₂ (4:15:1)]. [U-¹⁴C]Phenylalanine was shown to be a suitable precursor for studies of protein synthesis in perfused lungs: it entered the tissue rapidly (t_½, 81s) and was not converted to other compounds. As perfusate phenylalanine was decreased below 5 times the normal plasma concentration, the specific radioactivity of the pool of phenylalanine serving as precursor for protein synthesis, and thus [¹⁴C]phenylalanine incorporation into protein, declined. In contrast, incorporation of [¹⁴C]histidine into lung protein was unaffected. At low perfusate phenylalanine concentrations, rates of protein synthesis that were based on the specific radioactivity of phenylalanyl-tRNA were between rates calculated from the specific radioactivity of phenylalanine in the extracellular or intracellular pools. Rates based on the specific radioactivities of these three pools of phenylalanine were the same when extracellular phenylalanine was increased. These observations suggested that: (1) phenylalanine was compartmentalized in lung tissue; (2) neither the extracellular nor the total intracellular pool of phenylalanine served as the sole source of precursor for protein; (3) at low extracellular phenylalanine concentrations, rates of protein synthesis were in error if calculated from the specific radioactivity of the free amino acid; (4) at high extracellular phenylalanine concentrations, the effects of compartmentalization were negligible and protein synthesis could be calculated accurately from the specific radioactivity of the free or tRNA-bound phenylalanine pool.     

Synthesis and analysis of the enantiomers of calmidazolium,and a 1H NMR demonstration of a chiral interaction with calmodulin

Calmidazolium {R24571, 1-[bis(4-chlorophenyl)methyl]-3-[2-(2,4-dichlorophenyl)-2-[(2,4-dichlorophenyl)methoxy]ethyl]-1H-imidazolium chloride} is a potent calmodulin inhibitor. This paper describes the synthesis and properties of the enantiomers of calmidazolium from the enantiomers of miconazole {1(N)-(2-(2,4-dichlorobenzyloxy)-2-(2,4-dichlorophenyl))-ethyl imidazole}, prepared from the racemate by chiral preparative scale high performance liquid chromatography. Overlap between ligand and protein resonances in the aromatic region of the ¹H NMR spectrum of the calmidazolium-calmodulin complexes has been obviated by preparation of the protein with all of its nine phenylalanine rings deuterated (Phe-d₅ calmodulin). This has been accomplished by the overexpression of calmodulin derived from Trypanosoma brucei rhodiesiense in E. coli in a medium supplemented with ring-deuterated phenylalanine. The kinetics of binding of each enantiomer are slow on the ¹H NMR time scale as judged by the behaviour of the H2 resonance of Histidine-107, which is clearly visible under the sample conditions used. The aromatic spectral regions of the protein-bound (+) and (−) enantiomers contrast strikingly, reflecting differences in bound environment and/or conformation. Chirality 8:545–500, 1996. © 1997 Wiley-Liss, Inc.     

Tryptophan metabolism,disposition and utilization in pregnancy

Tryptophan (Trp) requirements in pregnancy are several-fold: (1) the need for increased protein synthesis by mother and for fetal growth and development; (2) serotonin (5-HT) for signalling pathways; (3) kynurenic acid (KA) for neuronal protection; (4) quinolinic acid (QA) for NAD⁺ synthesis (5) other kynurenines (Ks) for suppressing fetal rejection. These goals could not be achieved if maternal plasma [Trp] is depleted. Although plasma total (free + albumin-bound) Trp is decreased in pregnancy, free Trp is elevated. The above requirements are best expressed in terms of a Trp utilization concept. Briefly, Trp is utilized as follows: (1) In early and mid-pregnancy, emphasis is on increased maternal Trp availability to meet the demand for protein synthesis and fetal development, most probably mediated by maternal liver Trp 2,3-dioxygenase (TDO) inhibition by progesterone and oestrogens. (2) In mid- and late pregnancy, Trp availability is maintained and enhanced by the release of albumin-bound Trp by albumin depletion and non-esterified fatty acid (NEFA) elevation, leading to increased flux of Trp down the K pathway to elevate immunosuppressive Ks. An excessive release of free Trp could undermine pregnancy by abolishing T-cell suppression by Ks. Detailed assessment of parameters of Trp metabolism and disposition and related measures (free and total Trp, albumin, NEFA, K and its metabolites and pro- and anti-inflammatory cytokines in maternal blood and, where appropriate, placental and fetal material) in normal and abnormal pregnancies may establish missing gaps in our knowledge of the Trp status in pregnancy and help identify appropriate intervention strategies.     

IGF2 DNA methylation is a modulator of newborn’s fetal growth and development

The insulin-like growth factor 2 (IGF2) gene, located within a cluster of imprinted genes on chromosome 11p15, encodes a fetal and placental growth factor affecting birth weight. DNA methylation variability at the IGF2 gene locus has been previously reported but its consequences on fetal growth and development are still mostly unknown in normal pediatric population. We collected one hundred placenta biopsies from 50 women with corresponding maternal and cord blood samples and measured anthropometric indices, blood pressure and metabolic phenotypes using standardized procedures. IGF2/H19 DNA methylation and IGF2 circulating levels were assessed using sodium bisulfite pyrosequencing and ELISA, respectively. Placental IGF2 (DMR0 and DMR2) DNA methylation levels were correlated with newborn’s fetal growth indices, such as weight, and with maternal IGF2 circulating concentration at the third trimester of pregnancy, whereas H19 (DMR) DNA methylation levels were correlated with IGF2 levels in cord blood. The maternal genotype of a known IGF2/H19 polymorphism (rs2107425) was associated with birth weight. Taken together, we showed that IGF2/H19 epigenotype and genotypes independently account for 31% of the newborn’s weight variance. No association was observed with maternal diabetic status, glucose concentrations or prenatal maternal body mass index. This is the first study showing that DNA methylation at the IGF2/H19 genes locus may act as a modulator of IGF2 newborn’s fetal growth and development within normal range. IGF2/H19 DNA methylation could represent a cornerstone in linking birth weight and fetal metabolic programming of late onset obesity.     

The energetic cost of protein synthesis in isolated hepatocytes of rainbow trout (Oncorhynchus mykiss)

Summary To establish the energetic cost of protein synthesis, isolated trout hepatocytes were used to measure protein synthesis and respiration simultaneously at a variety of temperatures. The presence of bovine serum albumin was essential for the viability of isolated hepatocytes during isolation, but, in order to measure protein synthesis rates, oxygen consumption rates and RNA-to-protein ratios, BSA had to be washed from the cells. Isolated hepatocytes were found to be capable of protein synthesis and oxygen consumption at constant rates over a wide range of oxygen tension. Cycloheximide was used to inhibit protein synthesis. Isolated hepatocytes used on average 79.7±9.5% of their total oxygen consumption on cycloheximide-sensitive protein synthesis and 2.8±2.8% on maintaining ouabain-sensitive Na⁺/K⁺-ATPase activity. The energetic cost of protein synthesis in terms of moles of adenosine triphosphate per gram of protein synthesis decreased with increasing rates of protein synthesis at higher temperatures. It is suggested that the energetic cost consists of a fixed (independent of synthesis rate) and a variable component (dependent on synthesis rate).Abbreviations BSA bovine serum albumin - dpm disintegrations per min - k _s fractional rate of protein synthesis - HEPES N-2-hydroxyethylpiperazine-N-2-ethane sulphonic acid - PHE phenylalanine; PO₂ oxygen tension - PCA perchloric acid     

Ontogeny of gluconeogenesis in the bovine fetus: influence of maternal dietary energy.

The influence of maternal energy intake on the development of gluconeogenesis was studied in the liver of the bovine fetus from Days 88 to 270 of gestation. Fetal liver activities (units per gram of tissue) of cytoplasmic GTP:oxalacetate carboxy-lyase (transphosphorylating) (PEPCK) and mitochondrial l-malate:NAD⁺ oxidoreductase (MDH) increased linearly with increasing gestational age. Fetal cytoplasmic MDH activities reached maternal levels by 120 days of gestation, and fetal mitochondrial pyruvate carboxylase approached maternal levels by 200 days of gestation. Fetal activities of mitochondrial and cytoplasmic propionyl-CoA:carbondioxide ligase (ADP-forming) (PCC) did not change with gestational age and were about 45 and 7%, respectively, of maternal levels. Fetal activities of mitochondrial and cytoplasmic l-aspartate: 2-oxoglutarate aminotransferase were both about 24% of the maternal activities throughout gestation. Maternal and fetal liver activities of d-fructose-1,6-diphosphate 1-phosphohydrolase (FDP) were similar and did not change with gestational age. Glucose synthesis from lactate by fetal liver slices in vitro was slightly lower and, from alanine and aspartate, was slightly higher than glucose synthesis by maternal liver slices. Restriction of maternal dietary energy intake did not significantly alter gluconeogenic-related enzyme activity in vitro in maternal or fetal liver or in the metabolism of aspartate, alanine, or lactate to glucose or CO₂ by liver slices in vitro. A capacity for gluconeogenesis has been measured in the bovine fetus as early as 88 days of gestation.