Effects of protein and amino acid diets in chronically uremic and control rats

Extremely short small bowel induces focal tubulointerstitial fibrosis

BACKGROUND

Arginine becomes an essential amino acid after massive resection of the small bowel as a result of decreased biosynthesis of citrulline in the remaining small bowel. It is also reported that nitric oxide (NO) is synthesized from l-arginine by NO synthase (NOS), and NO is involved in the regulation of blood flow in the kidney. The authors observed a patient with an extremely short small bowel, showing focal tubulointerstitial fibrosis. The experiment was designed to clarify whether massive small bowel resection (SBR) produces focal tubulointerstitial fibrosis in the kidney.

METHODS

An experimental study was performed using 4-week-old rats with 90% proximal SBR either with or without arginine supplementation for 6 weeks after surgery.

RESULTS

In rats without arginine supplementation, low plasma levels of citrulline and arginine increased urinary excretion of orotate, and focal tubulointerstitial fibrosis was observed 6 weeks after 90% SBR. The data from plasma amino acid chromatography and increased excretion of urinary orotate suggested the presence of arginine deficiency. The kidney pathology was similar to that of our patient. Rats with arginine supplementation after 90% SBR and pair-fed control rats without 90% SBR showed almost normal glomeruli and tubulointerstitium.

CONCLUSIONS

Experimental study strongly suggests that arginine deficiency causes focal tubulointerstitial fibrosis in the kidney after massive SBR.

Contribution of experimental studies on the nutritional management of children with chronic renal failure

A few of the many reports of experimental chronic renal failure have been summarized. Anorexia and food selection have been studied in experimental uremia and the findings are comparable with those observed in uraemic children. The optimal dietary protein content for growth is close to the minimal requirement for "optimal" growth. Protein excess leads to growth retardation and renal deterioration in uraemic rats, at least with the commonly used dry diets. The increased water requirement may be more critical for growth than the blood urea level or acidosis, although this requires further investigation. Reduction of the dietary protein by 50% and supplementation with essential amino acids (EAA) results in growth similar to that of the 100% protein diet. There is no growth improvement despite low blood urea levels, but the renal parenchymal is preserved. Supplementation with nitrogen-free analogues is more frequently associated with defective growth; the optimal mixture remains to be defined, and to date, when nutrition is identical, nitrogen-free analogues offer no benefit for renal preservation compared with EAA. Sucrose-rich diets have adverse effects on uraemia. These effects are associated with fructose intolerance and with reduced energy storage in the liver. The precise metabolic alteration remains to be defined.

Acidosis, not azotemia, stimulates branched-chain, amino acid catabolism in uremic rats

To investigate branched-chain, amino acid metabolism (BCAA) in muscle in chronic renal failure (CRF), we studied rats with moderately severe uremia (PUN 110 approximately mg/dl) and spontaneous metabolic acidosis (bicarbonate, 19 +/- 1 mEq/liter). Plasma BCAA levels in CRF compared to pair-fed control rats were approximately 15% lower and muscle valine was 93 microM lower (P less than 0.05). BCAA metabolism was measured in incubated epitrochlearis muscles using L-[1-14C]valine or L-[1-14C]leucine in the presence and absence of insulin. BCAA decarboxylation was increased (P less than 0.05) and insulin-stimulated BCAA incorporation into protein was blunted (P less than 0.05) by CRF. Since we have found that metabolic acidosis, by itself, stimulates muscle branched-chain, ketoacid dehydrogenase activity, another group of CRF and control rats was given NaHCO3 which corrected the acidosis, but not the azotemia. BCAA decarboxylation in muscle was reduced in CRF rats given NaHCO3, and this was reflected in increased plasma and muscle BCAA concentrations. We conclude that in CRF, chronic metabolic acidosis stimulates BCAA decarboxylation in skeletal muscle and this could contribute to the reduced intra- and extracellular concentrations of BCAA. Correction of acidosis should be a goal of therapy in CRF, especially when dietary regimens restrict intake of BCAA.

The effect of vitamin B6 deficiency on food intake, growth, and renal function in chronically azotemic rats

Chronically uremic patients appear to have an increased nutritional requirement for vitamin B6, and vitamin B6 deficiency occurs frequently when such individuals do not receive supplements of this vitamin. Since manifestations of vitamin B6 deficiency in renal failure are not well defined, this study examined two aspects of the chronic renal failure syndrome which might be influenced by vitamin B6: impaired growth and progressive loss of renal function. We examined food intake, weight gain, the food efficiency ratio, degree of azotemia, and renal function in chronically azotemic rats pair-fed for 6 weeks either a vitamin B6-deficient diet or a diet containing a surfeit of vitamin B6. In the azotemic vitamin B6-deficient rats, as compared to the azotemic B6-replete rats, there was evidence of reduced appetite, decreased weight gain, a lower food efficiency ratio, increased azotemia, and a reduced glomerular filtration rate as estimated from the urea clearance or the mean of the urea and creatinine clearances. These findings suggest that vitamin B6 deficiency may contribute to decreased food intake, reduced growth, and lower renal function in animals with chronic renal insufficiency.

Protein synthesis and degradation in skeletal muscle of chronically uremic rats

We used the perfused hemicorpus preparation to measure individual rates of protein synthesis and degradation. Using fed animals, perfused either with or without insulin, muscle protein synthesis and hemicorpus protein degradation rates were similar, but myofibrillar protein degradation was clearly increased in the uremic preparations. When the animals were fasted, differences in the rates of skeletal muscle protein turnover were apparent. Uremic rats lost more wt at both 24 and 48 hr of fasting when compared to either ad libitum fed or pair-fed controls who started fasting at body wts equivalent to our uremic rats. The accelerated wt loss was accompanied by lower rates of protein synthesis, higher degradation rates, and greater net protein catabolism in our uremic rats. Alterations in body lipid content were present in uremia and correlated with the rate of protein degradation in both control and uremic rats. These data demonstrated that even in the fed state, uremia is associated with subtle alterations in skeletal muscle protein turnover. When stressed, these alterations become more pronounced. Insufficient stores of body lipids, either due to inadequate nutrition or altered metabolism, may contribute to the alterations in muscle protein turnover seen in chronic renal insufficiency.

Protein loss induced by complement activation during peritoneal dialysis

A variable loss of macromolecules during peritoneal dialysis has been noted in both humans and experimental animals. We investigated the potential role of the complement system for inducing protein loss during peritoneal dialysis, both to shed light on clinical variability of protein loss and to develop a model for quantitatively studying complement-induced microvascular protein leakage. Rats received intra-arterial injections of a fluorescent dye conjugated to rat serum albumin and underwent a 3.5-hr series of 15-min peritoneal dialysis exchanges. After the control exchanges, rats received either intra-arterial zymosan-activated rat serum, saline, unactivated rat serum, or endotoxin; other rats received an intraperitoneal injection of endotoxin, histamine, phenylephrine, or nitroprusside. The drainage volume from each exchange was measured, and the concentrations of labeled albumin, total protein, and urea were determined by spectroscopy. Zymosan-activated rat serum and endotoxin injections (both intraperitoneal and intra-arterial), each of which may activate the alternative pathway of complement, produced a dramatic increase in dialysate protein concentrations. In addition, histamine, which is a vasodilator but which may also be involved as a mediator of the activated complement system and/or endotoxemia, also produced an increase in dialysate protein concentrations. On the other hand, drugs which may alter peritoneal blood flow such as the vasodilator nitroprusside or the vasoconstrictor phenylephrine, did not affect dialysate protein concentrations. These data suggest that activation of the alternative pathway of complement may cause variation in protein loss during peritoneal dialysis and that in some situations, pharmacological control of this system could be an important therapeutic consideration.

Effects of dietary intake and hemodialysis on protein turnover in uremic children

The dynamic aspects of protein metabolism in uremic children were studied by using newly developed gas chromatography and mass spectrometry micromethods for determining nitrogen-15 enrichment in plasma lysine during a continuous i.v. infusion of 15N-lysine. Protein flux in uremic children was low and varied directly with protein and energy intake, which themselves were closely related in the diets consumed by the study subjects. Hemodialysis did not alter acutely protein flux. Protein flux in children undergoing chronic hemodialysis was still reduced below normal but was higher than that in nondialyzed uremic children at each level of protein-energy intake. The ratio of protein flux to protein intake was 0.05 +/- 0.003 g of protein x kg-1 x day-1 x kcal ingested in the nondialyzed uremic children, but it increased to a normal vaue of 0.11 +/- 0.03 g x kg-1 x day-1 x kcal in those on longterm hemodialysis. We conclude that the low protein turnover rates in our uremic population reflect the decreased protein-energy intake commonly found in such patients and that reduction of azotemia by chronic hemodialysis may improve whole body transport at a given energy intake.

Effect of various protein diets on growth, renal function, and survival of uremic rats

The effects on growth, renal function, and survival of three isocaloric diets of various protein content (14, 27, and 37 g/100 g in diets I, II, and III, respectively) were compared in uremic rats and in controls. Diet I provided the minimal requirements in all amino acids for gorwing rats. In controls fed ad lib, weight and length gain were better with high protein diets, whereas they were inversely related to the diet protein content in uremic rats. The higher the protein intake, the higher the progressive elevation of BUN and serum creatinine and the mortality rate. Because proteins were supplied by fish flour, their increase was associated with increased mineral content, and the conclusions are restricted to the use of natural proteins: a moderately restricted protein diet securing only the minimal requirements had a beneficial effect on growth and survival of rats with reduced kidney mass. Avoiding any excess in proteins from the early stage of renal disease is suggested.