Biotin deficiencies, metabolic blocks

Fig. 5 Metabolic blocks caused by biotin deficiencies. There are a small number of proteins that are biotinylated in vivo. Note that the naturally occurring biotin and biotinylated proteins may interfere with applications that use strept(avidin) on biological samples...

Reduced activities of carboxylase enzymes can cause a metabolic block of certain substrates and a use of alternative pathways for catabolism. Therefore, 3-hydroxyisovaleric acid and 3-methylcrotonyl glycine are formed consequently to a shunt of 3-methylcrotonyl carboxylase counterbalancing its activity decrease. Marginal biotin deficiency experimentally induced by 20 days of free biotin diets in human increased 3-hydroxyisovaleric acid excretion in urine above the upper limit of normal. The normal urinary excretion of 3-hydroxyisovaleric acid in healthy adults is 112 38 pmol per 24 hours (Mock et al. 1997). This suggests that 3-hydroxyisovaleric acid urinary excretion is a good indicator of marginal biotin deficiency. 

Figure 12-2. Metabolic pathways involving the four biotin-dependent carboxylases. The solid rectangular blocks indicate the locations of the enzymes ACC, acetyl-CoA carboxylase PMCC, P-methylcrotonyl-CoA carboxylase PC, pyruvate carboxylase PCC, propionyl-CoA carboxylase. Isolated deficiencies of the first three carboxylases (mitochondrial) have been established (isolated ACC deficiency has not been confirmed). At least the activities of the three mitochondrial carboxylases can be secondarily deficient in the untreated multiple carboxylase deficiencies, biotin holocarboxylase synthetase deficiency and biotinidase deficiency. Lowercase characters indicate metabolites that are frequently found at elevated concentrations in urine of children with both multiple carboxylase deficiencies. The isolated deficiencies have elevations of those metabolites directly related to their respective enzyme deficiency.

Inherited isolated deficiencies of the three mitochondrial biotin-dependent carboxylases were described during the 1970s (Fig. 12-2). Children with each of the isolated deficiencies exhibit neurological symptoms during infancy or early childhood associated with metabolic compromise caused by the accumulation of abnormal metabolites resulting from the respective enzyme block. Each isolated deficiency is due to a structural abnormality in the respective mitochondrial enzyme, whereas the activities of... 

The answer is d. (Murray, pp 238-249. Scriver, pp 2165-2194. Sack, pp 121-144. Wilson, pp 287-324.) Propionic acidemia (232000) results from a block in propionyl CoA carboxylase (PCC), which converts propionic to methylmalonic acid. Excess propionic acid in the blood produces metabolic acidosis with a decreased bicarbonate and increased anion gap (the serum cations sodium plus potassium minus the serum anions chloride plus bicarbonate). The usual values of sodium (-HO meq/L) plus potassium ( 4 meq/T) minus those for chloride (-105 meq/L) plus bicarbonate (—20 meq/L) thus yield a normal anion gap of -20 meq/L. A low bicarbonate of 6 to 8 meq/L yields an elevated gap of 32 to 34 meq/L, a gap of negative charge that is supplied by the hidden anion (propionate in propionic acidemia). Biotin is a cofactor for PCC and its deficiency causes some types of propionic acidemia. Vitamin B deficiency can cause methylmalonic aciduria because vitamin Bn is a cofactor for methylmalonyl coenzyme A mutase. Glycine is secondarily elevated in propionic acidemia, but no defect of glycine catabolism is present. 

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