Brian K. England

Mechanisms That Cause Protein and Amino Acid Catabolism in Uremia

Anorexia and/or a protein- and calorie-restricted diet can cause protein wasting by limiting the intake of essential amino acids (EAA) and, hence, protein synthesis. By this mechanism plus the effects of inadequate calories, restricted diets could contribute to the loss of lean body mass of uremic patients. Uremia also impairs the normal metabolic responses that must be activated to preserve body protein, thereby augmenting the adverse effects of anorexia. The responses impaired are those that conserve EAA and protein, which results in catabolism of EAA and muscle protein. An important factor that initiates abnormal adaptive responses in uremia is metabolic acidosis, because acidosis stimulates muscle protein degradation and increases the activity of branched-chain ketoacid dehydrogenase and, hence, the catabolism of branched-chain amino acids (BCAA). The effects of acidosis could be mediated by impaired regulation of intracellular pH and/or an increase in glucocorticoid production. Research directed at identifying the specific proteolytic pathways that are activated by metabolic acidosis has excluded a major role for Ca(2+)-activated or lysosomal proteases and suggests activation of an adenosine triphosphate (ATP)- and ubiquitin-dependent proteolytic pathway. The mechanism of activation of this pathway includes an increase in mRNA for enzymes involved in protein and amino acid catabolism.

Mechanisms causing muscle loss in chronic renal failure

The loss of lean body mass in uremia is associated with excessive morbidity and mortality. A potential mechanism causing protein catabolism is that uremia overcomes critical metabolic responses required to maintain protein balance whenever dietary protein is limited. These responses include reduced oxidation of essential amino acids, which improves the efficiency of protein utilization and a reduction in protein degradation. We find that metabolic acidosis stimulates both amino acid oxidation and protein degradation in muscle and thus could overcome the adaptive responses. The molecular mechanisms stimulating catabolism involve glucocorticoids and includes increased mRNAs of components of catabolic pathways. Studies in patients have confirmed that acidosis causes catabolism in chronic renal failure. Thus, we recommend that patients with metabolic acidosis receive an adequate diet and sufficient alkali to correct acidosis.

Metabolic Consequences of Uremia: Extending the Concept of Adaptive Responses to Protein Metabolism

An early response to metabolic acidosis is an increase in the degradation of muscle protein to provide the nitrogen needed to increase glutamine production so the kidney can excrete acid. In patients with renal insufficiency, this process may represent an example of a trade-off adaptation to uremia. It requires a hormone (glucocorticoids) and the metabolic response is maladaptive because the inability of the damaged kidney to maintain acid-base balance results in loss of muscle protein. Studies of cultured cells and rats and humans with normal kidneys demonstrate that acidosis stimulates the degradation of both amino acids and protein, which would block the normal adaptive responses to a low-protein diet (ie, to reduce the degradation of essential amino acids and protein). Evidence from studies in rats and humans with chronic uremia show that acidosis is a major stimulus for catabolism. The mechanism includes stimulation of specific pathways for the degradation of protein and amino acids. Since other catabolic conditions (eg, starvation) appear to stimulate the same pathways, understanding the mechanism in acidosis could be applicable to other conditions. Thus, the loss of lean body mass in uremia appears to be a consequence of a normal metabolic response that persists until acidosis is corrected.