Hypercholesterolemia impairs basal nitric oxide synthase turnover rate: a study investigating the conversion of L-[guanidino-(15)N(2)]-arginine to (15)N-labeled nitrate by gas chromatography--mass spectrometry.

Endothelial function is impaired in hypercholesterolemia and atherosclerosis, which is probably due to reduced biological activity of endothelium-derived nitric oxide (NO). NO is synthesized in functionally intact endothelium by oxidation of the terminal guanidino nitrogen atom(s) of the amino acid precursor, L-arginine. We applied stable isotope dilution techniques and gas chromatographic-mass spectrometric approaches to investigate metabolism of L-[guanidino-(15)N(2)]-arginine to (15)N-labeled nitrate in hypercholesterolemic rabbits and controls. After 4 weeks on control or 1% cholesterol-enriched diet, rabbits received 267 +/- 6 micromol of L-[guanidino-(15)N(2)]-arginine/kg of body weight via gastric cannulation. (15)N-isotope content of L-arginine in plasma and in platelet lysates increased 2h later in both groups, and almost returned to baseline until 24h. (15)N-isotope content of plasma nitrite and nitrate also increased in both groups at 2h, and had almost returned to natural content 24h later. (15)N-isotope content of urinary nitrate was significantly increased in control animals in urines collected from 0 to 12, 12 to 24, and had returned to baseline in the urine sample collected from 24 to 48 h. In the cholesterol group only a slight, insignificant elevation of (15)N-isotope content was observed for urinary nitrate. The extent of conversion of L-[guanidino-(15)N(2)]-arginine to (15)N-labeled nitrate was strongly and inversely correlated to plasma concentration of the endogenous NO synthase inhibitor, asymmetric dimethylarginine (ADMA), which was elevated in cholesterol-fed rabbits (R=0.77; p < 0.05). Our data show that baseline NO synthase turnover rate is reduced in rabbits during early hypercholesterolemia. Our study gives evidence that the mechanism of the impaired conversion of L-[guanidino-(15)N(2)]-arginine to (15)N-labeled nitrate most likely involves inhibition of NO synthase by ADMA, which is present in elevated concentrations in hypercholesterolemia.     

Nitrate biosynthesis in the rat. Precursor-product relationships with respect to ammonia.

The endogenous biosynthesis of nitrate in rats was investigated by using 15NH3 administered as a continuous intravenous infusion for as long as 96 h. A comparison of the enrichment of 15N in urinary nitrate after a 24 h infusion revealed that it was 36% of the enrichment of plasma NH3 and about 50% of the enrichment of plasma urea and urinary NH3. Continuous infusion of 15NH3 for 96 h showed that a plateau for the incorporation of NH3 into nitrate is reached by 24 h, whereas the enrichment of urinary NH3 and urea increase during the 96 h. After the infusion of progressively larger doses of 15NH3, the concentration of nitrate synthesized de novo increased. Although there was a significant correlation between plasma 15NH3 concentration and 15NO3- appearance, a given change in plasma NH3 concentration does not produce a direct proportional change in nitrate synthesis. Our findings indicate that NH3 is a quantitatively significant nitrogen precursor for nitrate, but that approx. 50% of nitrate nitrogen is derived from other, as yet unidentified, sources.     

Regulation of urea synthesis by agmatine in the perfused liver: studies with 15N

Administration of arginine or a high-protein diet increases the hepatic content of N-acetylglutamate (NAG) and the synthesis of urea. However, the underlying mechanism is unknown. We have explored the hypothesis that agmatine, a metabolite of arginine, may stimulate NAG synthesis and, thereby, urea synthesis. We tested this hypothesis in a liver perfusion system to determine 1) the metabolism of l-[guanidino-15N2]arginine to either agmatine, nitric oxide (NO), and/or urea; 2) hepatic uptake of perfusate agmatine and its action on hepatic N metabolism; and 3) the role of arginine, agmatine, or NO in regulating NAG synthesis and ureagenesis in livers perfused with 15N-labeled glutamine and unlabeled ammonia or 15NH4Cl and unlabeled glutamine. Our principal findings are 1) [guanidino-15N2]agmatine is formed in the liver from perfusate l-[guanidino-15N2]arginine ( approximately 90% of hepatic agmatine is derived from perfusate arginine); 2) perfusions with agmatine significantly stimulated the synthesis of 15N-labeled NAG and [15N]urea from 15N-labeled ammonia or glutamine; and 3) the increased levels of hepatic agmatine are strongly correlated with increased levels and synthesis of 15N-labeled NAG and [15N]urea. These data suggest a possible therapeutic strategy encompassing the use of agmatine for the treatment of disturbed ureagenesis, whether secondary to inborn errors of metabolism or to liver disease.     

15N-ammonium and 15N-nitrate uptake of a 15-year-old Picea abies plantation

Throughfall nitrogen of a 15-year-old Picea abies (L.) Karst. (Norway spruce) stand in the Fichtelgebirge, Germany, was labeled with either ¹⁵N-ammonium or ¹⁵N-nitrate and uptake of these two tracers was followed during two successive growing seasons (1991 and 1992). ¹⁵N-labeling (62 mg ¹⁵N m^-2 under conditions of 1.5 g N m^-2 atmospheric nitrogen deposition) did not increase N concentrations in plant tissues. The ¹⁵N recovery within the entire stand (including soils) was 94%±6% of the applied ¹⁵N-ammonium tracer and 100%±6% of the applied ¹⁵N-nitrate tracer during the 1st year of investigation. This decreased to 80%±24% and 83%±20%, respectively, during the 2nd year. After 11 days, the ¹⁵N tracer was detectable in 1-year-old spruce needles and leaves of understory species. After 1 month, tracer was detectable in needle litter fall. At the end of the first growing season, more than 50% of the ¹⁵N taken up by spruce was assimilated in needles, and more than 20% in twigs. The relative distribution of recovered tracer of both ¹⁵N-ammonium and ¹⁵N-nitrate was similar within the different foliage age classes (recent to 11-year-old) and other compartments of the trees. ¹⁵N enrichment generally decreased with increasing tissue age. Roots accounted for up to 20% of the recovered ¹⁵N in spruce; no enrichment could be detected in stem wood. Although ¹⁵N-ammonium and ¹⁵N-nitrate were applied in the same molar quantities (¹⁵NH ₄ ⁺ : ¹⁵NO ₃ ^- =1:1), the tracers were diluted differently in the inorganic soil N pools (¹⁵NH ₄ ⁺ /NH ₄ ⁺ : ¹⁵NO ₃ ^- /NO ₃ ^- =1:9). Therefore the measured ¹⁵N amounts retained by the vegetation do not represent the actual fluxes of ammonium and nitrate in the soil solution. Use of the molar ammonium-to-nitrate ratio of 9:1 in the soil water extract to estimate ¹⁵N uptake from inorganic N pools resulted in a 2–4 times higher ammonium than nitrate uptake by P. abies.     

Body nitrosation potential measured by a novel 15N breath test

Oxygenated nitrogen species, for example, the protonated form of nitrous acid (H2ONO+), dinitrogentrioxide (N2O3), dinitrogentetroxide (N2O4), or peroxynitrite (ONOO-), can react with amines to form molecular nitrogen. These reactions can occur spontaneously with primary aliphatic amines or via cytochrome P450 catalysed reactions with secondary amines. In principle measurements of the excretion of the molecular nitrogen generated by these reactions could be used as an index of the levels of oxygenated nitrogen compounds acting as nitrosating agents. To test this idea, [15N2]urea (3 mmol) was administered orally to five patients infected with Helicobacter pylori (as diagnosed by the [13C]urea breath test) and to four healthy volunteers. All participants ingested 3-mmol sodium nitrate as a precursor for NA 5 min before the ingestion of the nitrogen tracer. During the test the participants breathed 100% oxygen to increase the sensitivity of detection of endogenous molecular nitrogen. After the administration of [15N2]urea, the patients with H. pylori showed significantly increased 15N enrichments of exhaled N2, expressed as delta value (per 1000), compared with healthy volunteers (patients: 3.5 +/- 0.9 vs. volunteers: 1.3 +/- 0.4; p < .05). We speculate that the endogenous production of molecular nitrogen is a protective process controlling the body NO and nitrite levels. The 15N breath technique allows the noninvasive estimation of the body nitrosation and could indicate the health risk, possibly the oxidative stress status, caused by highly reactive oxygenated nitrogen species and carbenium ion intermediates.     

Relative role of the glutaminase, glutamate dehydrogenase, and AMP-deaminase pathways in hepatic ureagenesis: studies with 15N.

We have studied the relative roles of the glutaminase versus glutamate dehydrogenase (GLDH) and purine nucleotide cycle (PNC) pathways in furnishing ammonia for urea synthesis. Isolated rat hepatocytes were incubated at pH 7.4 and 37 degrees C in Krebs buffer supplemented with 0.1 mM L-ornithine and 1 mM [2-15N]glutamine, [5-15N]glutamine, [15N]aspartate, or [15N]glutamate as the sole labeled nitrogen source in the presence and absence of 1 mM amino-oxyacetate (AOA). A separate series of incubations was carried out in a medium containing either 15N-labeled precursor together with an additional 19 unlabeled amino acids at concentrations similar to those of rat plasma. GC-MS was utilized to determine the precursor product relationship and the flux of 15N-labeled substrate toward 15NH3, the 6-amino group of adenine nucleotides ([6-15NH2]adenine), 15N-amino acids, and [15N]urea. Following 40 min incubation with [15N]aspartate the isotopic enrichment of singly and doubly labeled urea was 70 and 20 atom % excess, respectively; with [15N]glutamate these values were approximately 65 and approximately 30 atom % excess for singly and doubly labeled urea, respectively. In experiments with [15N]aspartate as a sole substrate 15NH3 enrichment exceeded that in [6-NH2]adenine, indicating that [6-15NH2]adenine could not be a major precursor to 15NH3. Addition of AOA inhibited the formation of [15N]glutamate, 15NH3 and doubly labeled urea from [15N]aspartate. However, AOA had little effect on [6-15NH2]adenine production. In experiments with [15N]glutamate, AOA inhibited the formation of [15N]aspartate and doubly labeled urea, whereas 15NH3 formation was increased. In the presence of a physiologic amino acid mixture, [15N]glutamate contributed less than 5% to urea-N. In contrast, the amide and the amino nitrogen of glutamine contributed approximately 65% of total urea-N regardless of the incubation medium. The current data indicate that when glutamate is a sole substrate the flux through GLDH is more prominent in furnishing NH3 for urea synthesis than the flux through the PNC. However, in experiments with medium containing a mixture of amino acids utilized by the rat liver in vivo, the fraction of NH3 derived via GLDH or PNC was negligible compared with the amount of ammonia derived via the glutaminase pathway. Therefore, the current data suggest that ammonia derived from 5-N of glutamine via glutaminase is the major source of nitrogen for hepatic urea-genesis.     

Effect of a recombinant human growth hormone preparation on the urinary 15nitrogen balance in growth-hormone-deficient children

In 10 patients with idiopathic growth hormone (GH) deficiency (9 boys and 1 girl, aged 7.5-14.5 years, mean 12.1 +/- 2.2 years), urinary 15N-balance studies were performed before and on recombinant hGH (2 x 3 IU/m2 of body surface area subcutaneously on consecutive days). Before and on the 2nd day of recombinant hGH, 99% 15N-labeled ammonium chloride (0.05 g/kg, divided in 3 doses per day, corresponding to 389 +/- 30 mg/m2 of 15N) was administered and 24 h urine was collected. In urine, total nitrogen and the percentage of 15N were measured. From the ingested and excreted quantity, a urinary 15N balance was calculated. Mean 15N percentage from total N was 3.3 +/- 0.5. In 9 patients, basal 15N balance was +79 +/- 15 mg/m2 or +2.9 +/- 0.4 mg/kg. On recombinant hGH, it was +166 +/- 16 mg/m2 or +6.1 +/- 0.6 mg/kg (p less than 0.001). The recombinant hGH-induced positive 15N balance change was +87 +/- 17 mg/m2 or +3.2 +/- 0.6 mg/kg. 1 patient with a higher basal 15N balance (+196 mg/m2, +7.1 mg/kg) had no positive 15N balance change due to latent hypothalamic hypothyroidism. In previous similar studies with pituitary hGH the change of 15N balance was +80 +/- 27 mg/m2 or +2.8 +/- 1.1 mg/kg. It is concluded that the acute nitrogen-retaining effect of recombinant hGH is at least equal to that of pituitary hGH.     

Nitrate reduction to ammonia: a dissimilatory process in Enterobacter amnigenus

Thirty-four bacterial isolates from an agricultural soil anaerobically preincubated in the presence of glucose were tested for their ability to reduce nitrate to ammonia or to denitrify in two different media: nitrate broth and a minimal medium enriched with glucose. Ten isolates were considered denitrifying bacteria and 7 were dissimilatory ammonia producers. Ammonia production by the isolate identified as Enterobacter amnigenus was quantified and attained 50% of 138?mg?L(-1) of added NO(3)(-) N. The dissimilatory character of this reduction was clearly confirmed by culturing this (15)N-labeled bacterium in the presence of unlabeled nitrite. Nitrous oxide was produced at the same time as nitrite was reduced to ammonia. Increasing nitrate N levels from 48 to 553?mg?L(-1) in culture medium resulted in an increase in the level of nitrite produced and simultaneously a decrease in ammonia and nitrous oxide production. Key words: dissimilatory nitrate reduction, dissimilatory ammonia production, denitrification, Enterobacter amnigenus, (15)N.     

Nitrate Uptake and Assimilation by Wheat Seedlings during Initial Exposure to Nitrate

Nitrate uptake, reduction, and translocation were examined in intact, 14-day-old, nitrogen-depleted wheat (Triticum vulgare var. Knox) seedlings during a 9-hour exposure to 0.2 mm Ca (NO(3))(2). The nitrate uptake rate was low during the initial 3-hour period, increased during the 3- to 6-hour period, and then declined. By the 3rd hour, 14% of the absorbed nitrate had been reduced, and this increased to 36% by the 9th hour. Shoots accumulated reduced (15)N more rapidly than roots and the ratio of reduced (15)N to (15)N-nitrate was higher in the shoots. A significant proportion of the total reduction occurred in the root system under these experimental conditions. Accumulation of (15)N in ethanol-insoluble forms was evident in both roots and shoots by the 3rd hour and, after 4.5 hours, increased more rapidly in shoots than in roots.An experiment in which a 3-hour exposure to 0.2 mm Ca ((15)NO(3))(2) was followed by a 12-hour exposure to 0.2 mm Ca ((14)NO(3))(2) revealed a half-time of depletion of root nitrate of about 2.5 hours. A large proportion of this depletion, however, was due to loss of (15)N-nitrate to the ambient (14)N-nitrate solution. The remaining pool of (15)N-nitrate was only slowly available for reduction. Total (15)N translocation to the shoot was relatively efficient during the first 3 hours after transfer to Ca ((14)NO(3))(2) but it essentially ceased after that time in spite of significant pools of (15)N-nitrate and alpha-amino-(15)N remaining in the root tissue.     

Ammonia production from amino acids and urea in the caecal contents of the chicken

1. Ammonia production from urea and amino acids in the caecal contents of the chicken was evaluated using 15N-labeled nitrogenous compounds. 2. About 43% of each of urea nitrogen and glutamine amide nitrogen was converted to ammonia nitrogen, but only 25% of epsilon-nitrogen of the added arginine, a precursor of urea, was found in ammonia. 3. Amino nitrogen of the separately added glutamic acid and glycine to be converted to ammonia was 19-20% of their added amounts, whereas that of alpha-alanine was 11%. 4. It is concluded that dietary and urinary amino acids and urea which find their ways into the caeca are useful nitrogen sources for ammonia production by microflora in the caeca of the chicken.     

Daily delivery of dietary nitrogen to the periphery is stable in rats adapted to increased protein intake

Dietary nitrogen was traced in rats adapted to a 50% protein diet and given a meal containing 1.50 g (15)N-labeled protein (HP-50 group). This group was compared with rats usually consuming a 14% protein diet and fed a meal containing either 0.42 g (AP-14 group) or 1.50 g (AP-50 group) of (15)N-labeled protein. In the HP group, the muscle nonprotein nitrogen pool was doubled when compared with the AP group. The main adaptation was the enhancement of dietary nitrogen transferred to urea (2.2 +/- 0.5 vs. 1.3 +/- 0.1 mmol N/100 g body wt in the HP-50 and AP-50 groups, respectively). All amino acids reaching the periphery except arginine and the branched-chain amino acids were depressed. Consequently, dietary nitrogen incorporation into muscle protein was paradoxically reduced in the HP-50 group, whereas more dietary nitrogen was accumulated in the free nitrogen pool. These results underline the important role played by splanchnic catabolism in adaptation to a high-protein diet, in contrast to muscle tissue. Digestive kinetics and splanchnic anabolism participate to a lesser extent in the regulation processes.     

Studies of hepatic glutamine metabolism in the perfused rat liver with (15)N-labeled glutamine.

This study examines the role of glucagon and insulin in the incorporation of (15)N derived from (15)N-labeled glutamine into aspartate, citrulline and, thereby, [(15)N]urea isotopomers. Rat livers were perfused, in the nonrecirculating mode, with 0.3 mM NH(4)Cl and either 2-(15)N- or 5-(15)N-labeled glutamine (1 mM). The isotopic enrichment of the two nitrogenous precursor pools (ammonia and aspartate) involved in urea synthesis as well as the production of [(15)N]urea isotopomers were determined using gas chromatography-mass spectrometry. This information was used to examine the hypothesis that 5-N of glutamine is directly channeled to carbamyl phosphate (CP) synthesis. The results indicate that the predominant metabolic fate of [2-(15)N] and [5-(15)N]glutamine is incorporation into urea. Glucagon significantly stimulated the uptake of (15)N-labeled glutamine and its metabolism via phosphate-dependent glutaminase (PDG) to form U(m+1) and U(m+2) (urea containing one or two atoms of (15)N). However, insulin had little effect compared with control. The [5-(15)N]glutamine primarily entered into urea via ammonia incorporation into CP, whereas the [2-(15)N]glutamine was predominantly incorporated via aspartate. This is evident from the relative enrichments of aspartate and of citrulline generated from each substrate. Furthermore, the data indicate that the (15)NH(3) that was generated in the mitochondria by either PDG (from 5-(15)N) or glutamate dehydrogenase (from 2-(15)N) enjoys the same partition between incorporation into CP or exit from the mitochondria. Thus, there is no evidence for preferential access for ammonia that arises by the action of PDG to carbamyl-phosphate synthetase. To the contrary, we provide strong evidence that such ammonia is metabolized without any such metabolic channeling. The glucagon-induced increase in [(15)N]urea synthesis was associated with a significant elevation in hepatic N-acetylglutamate concentration. Therefore, the hormonal regulation of [(15)N]urea isotopomer production depends upon the coordinate action of the mitochondrial PDG pathway and the synthesis of N-acetylglutamate (an obligatory activator of CP). The current study may provide the theoretical and methodological foundations for in vivo investigations of the relationship between the hepatic urea cycle enzyme activities, the flux of (15)N-labeled glutamine into the urea cycle, and the production of urea isotopomers.     

Incorporation of intravenously administered urea-15N into sheep plasma proteins and their amide groups.

Two sheep with a low and high nitrogen intake (7.6 and 24 g N/day respectively) were given a single intravenous dose of 15N-labelled urea (15.3 mg 15N/kg b.w.) The findings were as follows. The greater part of non-retained 15N from the administered dose was excreted during the first day after the intravenous administration of 15N-urea. Daily excretion in the faeces amounted to 1.35-2.37% of the 15N in the given dose. With a low N intake, more 15N from the given dose (59.4%) was retained in the N pool than with a high N intake (50.5%). The net passage of 15N into the rumen and 15N incorporation into the amide-N of the plasma proteins was likewise greater. 15N incorporation into the amide-N of the plasma proteins rose steadily for 3 days. The porportion of amidic 15N in the plasma proteins rose steadily for 3 days. The proportion of amidic 15N in the plasma protein total 15N changed on the second and third day after administering 15N-urea from 8% to 16%, with the maximum at the beginning of the second day. The amount of 15N incorporated into the proteins in 1 litre plasma attained up to 3% of the given dose. It is concluded from the results that the synthesis of amino acids and their amide groups is both a quantitatively and a qualitatively important metabolic route for the reutilization of blood urea nitrogen for protein synthesis in ruminants.     

Effect of subacute dietary nitrate on production traits and plasma analytes in Suffolk ewes

Elevated dietary nitrate (NO3-) is associated with production losses in ruminant livestock, resulting in substantial economic losses incurred by producers. Severe drought, fertilization practices and poorly maintained pastures increase the risk of elevated NO3- intake among cattle and sheep. Nitrate is metabolized to nitrite (NO2-) in the rumen and further reduced to ammonia. Ruminants consuming high dietary NO3- vary in ability to efficiently reduce excess NO2- to ammonia. This leads to methemoglobin formation and ultimately NO3- toxicity signs. Variation in individual tolerance to elevated dietary NO3- can be partially attributed to rate and duration of exposure, rate of elimination, metabolism, species and dose. Our objectives were to confirm and quantify variation in individual tolerance to subacute levels of dietary NO3-, and determine if individuals could be identified as highly or lowly tolerant to elevated dietary NO3- based on production traits, plasma analytes and(or) signs of subacute NO3- toxicity. Purebred Suffolk ewes were administered supplement mixed with tap water (control; n = 8) or potassium nitrate (NO3- treated; 300 mg NO3-/kg BW daily; n = 47) for 8 days. Coefficients of variation (CV) indicated that supplement intake was more variable in NO3- treated ewes (CV = 59.3%) than in control ewes (CV = 13.6%). Among NO3- treated ewes, six ewes highly tolerant and six ewes lowly tolerant to elevated dietary NO3- were identified based on individual performance, NO3- treated supplement intake, and signs of toxicity. Supplement intake was lower (P < 0.0001) in NO3- treated ewes than in control ewes, indicating elevated dietary NO3- influences feed intake. Supplement intake differed (P < 0.0001) between control, highly tolerant and lowly tolerant ewes. Supplement intake of highly and lowly tolerant ewes was 82% and 23%, respectively, of the control ewes' intake. Weight change and plasma concentrations of NO2-, cortisol, glucose and retinol were not different (P 0.38) among control, highly tolerant and lowly tolerant ewes. Plasma urea nitrogen (PUN) levels were not different (P = 0.25) between control and lowly tolerant ewes, but were lower (P = 0.02) in highly tolerant ewes than in control ewes. Furthermore, PUN and NO3- treated supplement intake were highly correlated (0.71; P < 0.0001) in lowly tolerant ewes. These results confirm and quantify variation in response to subacute levels of dietary NO3- and indicate that individuals can be identified as highly or lowly tolerant to elevated dietary NO3- based on their performance and NO3- toxicity signs.     

AtDUR3 represents the major transporter for high-affinity urea transport across the plasma membrane of nitrogen-deficient Arabidopsis roots

Despite the fact that urea is a ubiquitous nitrogen source in soils and the most widespread form of nitrogen fertilizer used in agricultural plant production, membrane transporters that might contribute to the uptake of urea in plant roots have so far been characterized only in heterologous systems. Two T-DNA insertion lines, atdur3-1 and atdur3-3, that showed impaired growth on urea as a sole nitrogen source were used to investigate a role of the H+/urea co-transporter AtDUR3 in nitrogen nutrition in Arabidopsis. In transgenic lines expressing AtDUR3-promoter:GFP constructs, promoter activity was upregulated under nitrogen deficiency and localized to the rhizodermis, including root hairs, as well as to the cortex in more basal root zones. Protein gel blot analysis of two-phase partitioned root membrane fractions and whole-mount immunolocalization in root hairs revealed the plasma membrane to be enriched in AtDUR3 protein. Expression of the AtDUR3 gene in nitrogen-deficient roots was repressed by ammonium and nitrate but induced after supply of urea. Higher accumulation of urea in roots of wild-type plants relative to atdur3-1 and atdur3-3 confirmed that urea was the substrate transported by AtDUR3. Influx of 15N-labeled urea in atdur3-1 and atdur3-3 showed a linear concentration dependency up to 200 microM external urea, whereas influx in wild-type roots followed saturation kinetics with an apparent Km of 4 microM. The results indicate that AtDUR3 is the major transporter for high-affinity urea uptake in Arabidopsis roots and suggest that the high substrate affinity of AtDUR3 reflects an adaptation to the low urea levels usually found in unfertilized soils.     

Validation of lactose[15N,15N]ureide as a tool to study colonic nitrogen metabolism

In vitro experiments have shown that fermentation of carbohydrates prevents accumulation of nitrogen in the colon. Variable results have been obtained on modulation of dietary intakes in vivo. Lactose[15N,15N]-labeled ureide has been proposed as a tool to study colonic nitrogen metabolism. However, on oral administration of the marker, different urinary excretion patterns of the 15N label have been found. In this study, 50 mg lactose[15N,15N]ureide was directly instilled in the colon through an orocecal tube to investigate the colonic handling of this molecule in a direct way. In basal conditions, 42% (range, 37-48%) of labeled nitrogen administered as lactose[15N,15N]ureide was retrieved in urine after 72 h. A substantial variability in total urinary excretion of the label was found, but the urinary excretion pattern of the label was similar in all volunteers. When inulin, a fermentable carbohydrate, was administered together with the labeled marker, a significant decrease in urinary excretion of 15N after 72 h was found, to 29% (range, 23-34%). The effect of a smaller dose of inulin (250 mg) on colonic handling of lactose[15N,15N]ureide (50 mg), was investigated in another group of volunteers, and this time, fecal excretion of the marker was also evaluated. The results seem to indicate that fermentation of inulin causes an increased fecal excretion of the marker, thereby reducing urinary excretion but not retention in the human nitrogen pool. This instillation study shows that lactose[15N,15N]ureide is a tool with good properties to investigate the effect of different types of carbohydrates on nitrogen metabolism in the proximal colon in vivo.     

Gas chromatography-mass spectrometry determination of [15N]ammonia enrichment in blood and urine

A rapid gas chromatography-mass spectrometry method for [¹⁵N]ammonia analysis is deseribed which is based on the formation of [¹⁵N]glutamic acid from ammonia and analysis of isotopic abundance in the N-trifluoroacetyl-n-butylester glutamate derivative. Mean recovery of [¹⁵N]ammonia added to either plasma or urine was greater than 99% with a relative standard deviation of less than 10%. The method can be applied to the determination of extremely low levels of ammonia through an isotope dilution technique. The [¹⁵N]ammonia abundance of blood and urine was determined in an adult following on oral dose (500 mg) of ¹⁵NH₄Cl. A peak isotopic abundance of 13 atoms% excess was reached by 30 min. Urinary excretion of [¹⁵N]ammonia during the first 4 h after administration of the isotope amounted to 4.1% of the isotope administered.     

Quantifying foliar uptake of gaseous nitrogen dioxide using enriched foliar delta15N values.

The magnitude and impact of gaseous nitrogen dioxide (NO(2)) directly entering the leaves were investigated using foliar nitrogen isotopic composition (delta(15)N) values in tomato (Lycopersicon esculentum) and tobacco (Nicotiana tabacum). Using a hydroponics-fumigation system, (15)NO(2) (20 and 40 ppb) was supplied to shoot systems and (50 and 500 microM) was supplied to root systems. Morphological, stable isotope and nitrate reductase activity (NRA) analyses were used to quantify foliar NO(2) uptake and to examine whether realistic concentrations of NO(2) influenced plant metabolism. Nicotiana tabacum and L. esculentum incorporated 15 and 11%, respectively, of (15)NO(2)-N into total biomass via foliar uptake under low supply. On a mass basis, N. tabacum and L. esculentum incorporated 3.3 +/- 0.9 and 3.1 +/- 0.8 mg of (15)NO(2)-N into biomass, respectively, regardless of availability. There were no strong effects on biomass accumulation or allocation, leaf delta(13)C values, or leaf or root NRA in response to NO(2) exposure. Foliar NO(2 )uptake may contribute a significant proportion of N to plant metabolism under N-limited conditions, does not strongly influence growth at 40 ppb, and may be traced using foliar delta(15)N values.     

控释氮肥对洞庭湖区双季稻田表面水氮素动态及其径流损失的影响

用渗漏池模拟洞庭湖区2种主要稻田土壤(河沙泥和紫潮泥),研究了施用尿素(CF)和控释氮肥(CRNF)对双季稻田表面水pH、电导率(EC)、全氮（TN）、铵态氮（NH₄⁺-N）和硝态氮（NO₃^--N）浓度变化规律及TN径流损失的影响.结果表明,双季稻田施用尿素后,表面水TN、NH₄⁺-N浓度分别在第1、3天达到高峰,然后迅速下降;NO₃^--N浓度普遍很低;早稻表面水pH在施用尿素后15 d内(晚稻3 d)逐渐升高;EC与NH₄⁺动态变化一致.与尿素相比,施用CRNF能显著降低双季稻田表面水pH、EC、TN和NH₄⁺-N浓度,70% N控释氮肥的控制效果最显著;但后期NO₃^--N浓度略有升高.径流监测结果表明,洞庭湖区种植双季稻期间施用尿素的TN径流损失为7.70 kg·hm^-2,占施氮量的2.57%;施肥后20 d内发生的径流事件对双季稻田TN径流损失的贡献极为显著;与施用尿素相比,施用控释氮肥显著降低了施肥后10 d内发生的第1次径流液中的TN浓度,施用CRNF和70%N CRNF的氮素径流损失分别降低24.5%和27.2%.     

Manipulation of citrulline availability in humans

To determine whether circulating citrulline can be manipulated in vivo in humans, and, if so, whether citrulline availability affects the levels of related amino acids, nitric oxide, urinary citrulline, and urea nitrogen, 10 healthy volunteers were studied on 3 separate days: 1) under baseline conditions; 2) after a 24-h treatment with phenylbutyrate (0.36 g.kg(-1).day(-1)), a glutamine "trapping" agent; and 3) during oral L-citrulline supplementation (0.18 g.kg(-1).day(-1)), in randomized order. Plasma, erythrocyte (RBC), and urinary citrulline concentrations were determined by gas chromatography-mass spectrometry at 3-h intervals between 1100 and 2000 on each study day. Regardless of treatment, RBC citrulline was lower than plasma citrulline, with an RBC-to-plasma ratio of 0.60 +/- 0.04, and urinary citrulline excretion accounted for <1% of the citrulline load filtered by kidney. Phenylbutyrate induced an approximately 7% drop in plasma glutamine (P = 0.013), and 18 +/- 14% (P < 0.0001) and 19 +/- 17% (P < 0.01) declines in plasma and urine citrulline, respectively, with no alteration in RBC citrulline. Oral L-citrulline administration was associated with 1) a rise in plasma, urine, and RBC citrulline (39 +/- 4 vs. 225 +/- 44 micromol/l, 0.9 +/- 0.3 vs. 6.2 +/- 3.8 micromol/mmol creatinine, and 23 +/- 1 vs. 52 +/- 9 micromol/l, respectively); and 2) a doubling in plasma arginine level, without altering blood urea or urinary urea nitrogen excretion, and thus enhanced nitrogen balance. We conclude that 1) depletion of glutamine, the main precursor of citrulline, depletes plasma citrulline; 2) oral citrulline can be used to enhance systemic citrulline and arginine availability, because citrulline is bioavailable and very little citrulline is lost in urine; and 3) further studies are warranted to determine the mechanisms by which citrulline may enhance nitrogen balance in vivo in humans.