Renal ammoniagenesis in an early stage of metabolic acidosis in man.

Total renal ammonia production and ammonia precursor utilization were evaluated in patients under normal acid-base balance and in patients with 24-h NH4Cl acidosis by measuring (a) ammonia excreted with urine and that added to renal venous blood, and (b) amino acid exchange across the kidney. In 24-h acidosis not only urinary ammonia excretion is increased, but also total ammonia production is augmented (P less than 0.005) in comparison with controls. By evaluating the individual role of acid-base parameters, urine pH and urine flow in influencing renal ammonia production, it was shown that the degree of acidosis and urine flow are likely major factors stimulating ammoniagenesis. Both urine pH and urine flow are determinant in the preferential shift of ammonia into urine. In 1-d acidosis, renal extraction of glutamine was not increased and the total ammonia produced/glutamine N extracted ratio was higher than in controls (P less than 0.005) and was inversely correlated with the log of arterial bicarbonate concentration (P less than 0.001). In the same condition, renal glycine and ornithine uptake took place; the more severe the acidosis, the greater was the renal extraction of these amino acids (P less than 0.001). These data indicate that at the early stages of metabolic acidosis, in spite of a brisk increase in ammonia production, the mechanisms responsible for the increased glutamine use, which are operative in chronic acidosis, are not activated and other ammonia precursors, besides glutamine, are probably used for ammonia production.

Renal metabolism of amino acids and ammonia in subjects with normal renal function and in patients with chronic renal insufficiency.

The net renal metabolism of amino acids and ammonia in the post absorptive state was evaluated in subjects with normal renal function and in patients with chronic renal insufficiency by measuring renal uptake and release, and urinary excretion of free amino acids and ammonia. In normal subjects the kidney extracts glutamine, proline, citrulline, and phenylalanine and releases serine, arginine, taurine, threonine, tyrosine, ornithine, lysine, and perhaps alanine. The renal uptake of amino acids from arterial blood occurs by way of plasma only, whereas approximately a half of amino acid release takes place by way of blood cells. Glycine is taken up from arterial plasma, while similar amounts of this amino acid are released by way of blood cells. In the same subjects total renal ammonia production can be largely accounted for by glutamine extracted. In patients with chronic renal insufficiency (a) the renal uptake of phenylalanine and the release of taurine and ornithine disappear; (b) the uptake of glutamine and proline, and the release of serine and threonine are reduced by 80--90%; (c) the uptake of citrulline and the release of alanine, arginine, tyrosine, and lysine are reduced by 60--70%; (d) no exchange of glycine is detectable either by way of plasma or by way of blood cells; (e) exchange of any other amino acid via blood cells disappears, and (f) total renal ammonia production is reduced and not more than 35% of such production can be accounted for by glutamine extracted, so that alternative precursors must be used. A 140% excess of nitrogen release found in the same patients suggests an intrarenal protein and peptide breakdown, which eventually provides free amino acids for ammonia production.

Effects of recombinant human growth hormone on muscle protein turnover in malnourished hemodialysis patients.

To assess the effect of recombinant human growth hormone (rhGH) on muscle protein metabolism in uremic patients with malnutrition, forearm [3H]phenylalanine kinetics were evaluated in six chronically wasted (body weight 79% of ideal weight) hemodialysis (HD) patients in a self-controlled, crossover study. Forearm protein dynamics were evaluated before, after a 6-wk course of rhGH (5 mg thrice weekly) and after a 6-wk washout period. After rhGH: (a) forearm phenylalanine net balance--the difference between phenylalanine incorporation into and phenylalanine release from muscle proteins--decreased by 46% (-8+/-2 vs. -15+/-2 nmol/min x 100 ml at the baseline and -11+/-2 after washout, P < 0.02); (b) phenylalanine rate of disposal, an index of protein synthesis, increased by 25% (25+/-5 vs. 20+/-5 at the baseline and 20+/-4 after washout, P < 0.03); (c) phenylalanine rate of appearance, an index of protein degradation, was unchanged (33+/-5 vs. 35+/-5 at the baseline and 31+/-4 after washout); (d) forearm potassium release declined (0.24+/-0.13 vs. 0.60+/-0.15 microeq/min at the baseline, and 0.42+/-0.20 microeq/min after washout P < 0.03); (e) changes in the insulin-like growth factor binding protein (IGFBP)-1 levels and insulin-like growth factor-I (IGF-I)/IGFBP-3 ratios accounted for 15.1% and 47.1% of the percent variations in forearm net phenylalanine balance, respectively. Together, these two factors accounted for 62.2% of variations in forearm net phenylalanine balance during and after rhGH administration. These data indicate: (a) that rhGH administration in malnourished hemodialysis patients is followed by an increase in muscle protein synthesis and by a decrease in the negative muscle protein balance observed in the postabsorptive state; and (b) that the reduction in net protein catabolism obtained with rhGH can be accounted for by the associated changes in circulating free, but not total, IGF-I levels.

Erythrocyte deficiency in calpain inhibitor activity in essential hypertension.

The calpain-calpain inhibitor system was evaluated in erythrocytes of patients with essential hypertension and normotensive controls, either with or without a family history of hypertension. Calpain levels were similar in the controls and hypertensive patients, whereas the inhibitor activity level was significantly reduced in the latter (301.8 +/- 26.4 vs 220 +/- 14 U/mg hemoglobin, p less than 0.001). Borderline hypertensive patients and a few controls with a history of hypertension showed low inhibitor activity. Similar results have recently been reported in genetically hypertensive rats of the Milan strain. A significant inverse correlation (r = -0.43, p less than 0.001) was found between mean arterial pressure and calpain inhibitor. Although the pathophysiological significance of these observations is not yet clear, they suggest a new area of investigation into the molecular mechanisms underlying essential hypertension and its complications.

Splanchnic exchange of amino acids after amino acid ingestion in patients with chronic renal insufficiency.

Splanchnic exchange (net uptake or release) of amino acids (AAs) was evaluated by measuring arterial-hepatic venous differences for AAs and hepatic blood flow in patients with chronic renal insufficiency (CRI) and control subjects before and for 70 min after the ingestion of an AA mixture simulating an animal protein meal. In CRI after AA ingestion, splanchnic exchange area for total nonessential AAs (NEAAs) is increased 135% over control subjects because of an augmented escape of proline, glutamate, serine, glycine, alanine, and cyst(e)ine; contrarily, glutamine shows an increased splanchnic uptake. Splanchnic exchange area for total essential AAs (EAAs) is increased only by 67% over controls because of a higher escape of threonine, isoleucine, phenylalanine, and histidine. Abnormalities in arterial areas for AAs parallel those in splanchnic areas except for glutamine and isoleucine. Data indicate that in CRI, at least for 70 min after an AA meal, splanchnic organs metabolize abnormally ingested AAs and export an increased and unbalanced bulk of AAs, severely affecting postprandial arterial profile of AAs.

Amino acid metabolism and the liver in renal failure.

The study of amino acid metabolism across the splanchnic organs can be useful for investigating derangements in nitrogen metabolism in chronic renal insufficiency. For this purpose, arterial-hepatic venous differences for 19 free amino acids, ammonia and urea, determined in whole blood, were measured in six patients with chronic renal insufficiency and in six subjects with normal renal function. In normal conditions, the hepatosplanchnic bed significantly extracts glutamine, alanine, glycine, serine, threonine, lysine, arginine, phenylalanine, valine, tyrosine, histidine, leucine, and ammonia, and releases glutamate, citrulline, and urea. In chronic renal insufficiency, glutamine uptake decreases, serine, valine and ammonia uptake disappears, proline extraction becomes present, citrulline output is no longer detectable and glutamate release falls slightly. Furthermore, the splanchnic uptake of ammonia and the output of urea into the hepatic veins are markedly reduced. Since glutamine and ammonia are major substrates for urea synthesis, their lower uptakes, as observed in renal insufficiency, may be consistent with the reduced urea output. The changes in splanchnic metabolism observed in chronic renal insufficiency have a minor effect on the abnormalities in circulating amino acids. Finally, the splanchnic metabolism shows an important role in the homeostasis of circulating tyrosine and proline.

Effect of amino acid ingestion on blood amino acid profile in patients with chronic renal failure.

Arterial whole blood levels of amino acids (AA) were determined in patients with chronic renal failure (CRF) and in healthy volunteers before and for 75 min after the ingestion of an AA mixture simulating the AA content of an animal-protein meal. In CRF patients, total AA increased more than in control subjects as a consequence of an exaggerated rise in nonessential AA (+86%), mainly glutamine, proline, glutamate, serine, glycine, and alanine. Total essential AA in patients increased as much as in control subjects; however, threonine and phenylalanine showed greater increases while leucine had a smaller increase. As a consequence of the observed alterations, a striking unbalance in the postprandial pattern of arterial AA ensued in CRF patients. The flow of AA to all the organs is altered during the absorptive phase, which is crucial for body nitrogen-pool replenishment.

Disposal of exogenous amino acids by muscle in patients with chronic renal failure.

Muscle exchange of amino acids (AAs) was evaluated by using the arteriovenous-difference technique across the leg in seven patients with chronic renal failure (CRF) and eight control subjects before and for 75 min after the ingestion of an AA mixture simulating an animal-protein meal. Total AAs increased in arterial blood much more in patients with CRF after AA ingestion than in control subjects, as a consequence of an exaggerated increase in nonessential AAs (NEAAs) (+127%). Moreover, total AAs were taken up by the leg in larger amounts than in control subjects (+71%, P < 0.0025) because of increased uptake of NEAAs (+156%, P < 0.005). Branched-chain AA uptake by the leg was, in absolute values, similar to that of control subjects; however, because of the increased uptake of total AAs, branched-chain AA uptake was only 30% of total AA extraction, compared with 46% in control subjects. Abnormalities in AA uptake by muscle paralleled those in arterial AAs. In fact the same AAs that increased abnormally in blood were taken up by the leg at higher rates than in control subjects. Variations in arterial concentrations and muscle uptake of AAs were inversely related to arterial bicarbonate concentration, suggesting a role for acid-base status in modifying both the arterial supply and muscle metabolism of AAs. Results indicate that in CRF patients the normal pattern of postprandial AA repletion is disrupted. Muscle tissue faces the increased and unbalanced postprandial supply of AAs with an augmented and unbalanced uptake. Data are consistent with an abnormal use of exogenous AAs in CRF patients, possibly induced by metabolic acidosis.

Glucose interorgan exchange in chronic renal failure.

The mechanisms responsible for the altered glucose metabolism observed in chronic renal failure (CRF) were investigated in the postabsorptive state. In 11 patients with CRF and in 15 subjects with normal renal function, the hepato-splanchnic (HS), leg, and brain exchanges of glucose were measured; the HS exchange of gluconeogenic amino acids was also evaluated. Patients with CRF had normal glucose levels, whereas insulin levels and the ratio of insulin to glucose were significantly increased in comparison with controls. In CRF, HS glucose output was slightly lower in comparison with controls (0.46 +/- 0.04 vs. 0.57 +/- 0.04 mmoles/min X 1.73 m2 in controls; P less than 0.1). Arterial levels of alanine and glycine and their uptake by the HS bed were similar in both groups, but in CRF HS serine uptake disappeared, mainly as a consequence of a reduction of its fractional extraction. Conversely, a significant proline extraction became evident, primarily depending on the increased arterial levels of this amino acid. The total HS uptake of potential gluconeogenic amino acids was not different in the two groups, and its ratio to glucose output was increased in CRF (28.0 +/- 4.7 vs. 16.0 +/- 1.9 in controls). In CRF, the arterial-femoral venous differences of glucose were significantly reduced (0.11 +/- 0.04 vs. 0.25 +/- 0.04 mmoles/liter in controls), as was the fractional extraction of glucose in the leg. Finally, in CRF both glucose uptake and its fractional extraction by the brain were unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)

Branched-chain amino acid metabolism in chronic renal failure.

Interorgan exchange of branched-chain amino acids (BCAA) in the postabsorptive state was evaluated in 16 patients with chronic renal failure (CRF) and in 20 subjects with normal renal function, by measuring arterial-venous differences of BCAAs across the leg, brain, hepato-splanchnic (HS) bed, and kidney. In CRF, arterial blood levels of valine are significantly reduced, whereas leucine and isoleucine levels are not different from controls; valine and leucine levels are directly related to GFR. In CRF, a significant decrease in the release of valine by the leg is observed; the leucine release tends to be lower; for both these amino acids, leg release is directly related to their arterial levels. Both ratios of valine and leucine release to total amino acid release by the leg are significantly reduced in CRF. Furthermore, in CRF cerebral uptake and fractional extraction of valine and isoleucine are decreased. In normal subjects, valine and leucine are significantly extracted by the HS bed, whereas in CRF the HS uptake of valine and its fractional extraction fall significantly and leucine uptake is unchanged. The kidney releases significant amounts of leucine both in CRF and in controls. In conclusion, in CRF in the postabsorptive state the exchange of BCAAs, mainly valine, is altered rather early at the major sites of production and utilization, and the flux of these amino acids among the organs is decreased. The primary defect is the decreased output by peripheral tissue, which reduces the supply of BCAAs to the brain and HS bed. Regional metabolic disturbances further impair BCAA utilization.