Nicotinic acid phosphoribosyltransferase activity in human erythrocytes: studies using a new HPLC method

Inborn errors of purine and pyrimidine metabolism: how much we owe to H. Anne Simmonds

Purines and pyrimidines, regarded for a long time merely as building blocks for nucleic acid synthesis and intermediates in the transfer of metabolic energy, have attracted increasing attention after genetically determined aberrations in their metabolism were linked to a range of symptoms from hyperuricemia and immunodeficiency to neurological disorders. The pathogenesis of such disorders involves cell or mitochondrial damage, but the molecular mechanisms underlying symptoms is often unclear. H. Anne Simmonds made major contributions to the metabolic, clinical, and molecular aspects of these disorders and the Purine Research Laboratory, which she established in London, became the world center for clinical and experimental studies in the field. We owe her gratitude not only for this direct contribution but also for her enthusiasm for purine and pyrimidine research that she transmitted to generations of scientists. Our research in this field stemmed from expertise in pyridine metabolism and its connection with purines, and from clinical involvement with biochemical diagnosis of enzyme deficiencies. We joined H. Anne Simmonds in studying the biochemical basis of altered NAD content in erythrocytes of PNP- and HPRT-deficient patients, discovering some alterations in NAD synthesis and breakdown.

Biochemical and molecular study of mentally retarded patient with partial deficiency of hypoxanthine-guanine phosphoribosyltransferase

Nucleotide metabolism was studied in erythrocytes of a mentally retarded child and family members. Partial hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency was found in the propositus and an asymptomatic maternal uncle. Studies in crude lysates demonstrated decreased apparent V(max) and slightly decreased apparent K(m) for hypoxanthine in both HPRT-deficient subjects. Genomic DNA analysis revealed a single nucleotide change with leucine-147 to phenylalanine substitution in both subjects; mother and grandmother were heterozygous carriers of the same defect. This new variant has been termed HPRT(Potenza). Increased erythrocyte concentration of NAD and rate of synthesis by intact erythrocytes were found in the patient; increased activities of nicotinic acid phosphoribosyltransferase (NAPRT) and NAD synthetase (NADs) were demonstrated in erythrocyte lysates, with normal apparent K(m) for their substrates and increased V(max). These alterations were not found in any member of the family, including the HPRT-deficient uncle. These findings show multiple derangement of nucleotide metabolism associated with partial HPRT deficiency. The enzyme alteration was presumably not the cause of neurological impairment since no neurological symptoms were found in the HPRT-deficient uncle, whereas they were present in the propositus' elder brother who had normal HPRT activity.

Enzyme activities leading to NAD synthesis in human lymphocytes

Pyridine nucleotide levels and the activities of enzymes involved in NAD synthesis (nicotinic acid phosphoribosyltransferase, nicotinic acid- and nicotinamide mononucleotide-adenylyltransferase) have been assayed in human normal lymphocytes by an HPLC method using radioactive or nonradioactive substrates. NAD concentration was 46.4 +/- 17.2 pmol 10(-6) cells, and that of NADP was 14.5 +/- 3.9 pmol 10(-6) cells (mean +/- standard deviation). The adenylyltransferase activity using nicotinic acid mononucleotide as substrate was 1.530 +/- 0.216 nmol h(-1) 10(-6) cells, using nicotinamide mononucleotide was 1.466 +/- 0.354 nmol h(-1) 10(-6) cells. The apparent K(M) values were 0.015 mM for the former substrate and 0.167 mM for the latter. The mean activity of nicotinic acid phosphoribosyltransferase was 0.038 +/- 0.014 nmol h(-1) 10(-6) cells, and the apparent K(M) for nicotinic acid was 0.165 mM. The proposed methods, easy and rapid to perform, are reliable and sensitive, avoiding the use of radiolabels except for NAPRT and displaying a very low activity. The reported findings, together with the previous ones in human erythrocytes, can provide an useful base to investigate NAD metabolism in humans through the study of blood cells.

Hypoxanthine-guanine phosphoribosyltransferase deficiency and erythrocyte synthesis of pyridine coenzymes

Purine and pyridine metabolism were studied in ten Lesch-Nyhan patients, with virtually no hypoxanthine-guanine phosphoribosyltransferase (HPRT) activity in erythrocytes. Increased NAD erythrocyte concentrations were found in all patients. Raised activities of two enzymes catalysing NAD synthesis from nicotinic acid (nicotinic acid phosphoribosyltransferase: NAPRT, and NAD synthetase: NADs) was found in erythrocyte lysates from all patients. The two enzymes had normal apparent Km for their substrates and increased Vmax. The rate of synthesis of pyridine nucleotides from nicotinic acid by intact erythrocytes in vitro was also increased in most patients. These findings suggest that raised NAD concentrations in HPRT- erythrocytes are due to enhanced synthesis as a result of increased enzyme activities.