Xanthine oxidase deficiency and 'Dalmatian' hypouricaemia: incidence and effect of exercise

The influence of allopurinol on urinary purine loss after repeated sprint exercise in man

The influence of allopurinol on urinary purine loss was examined in 7 active male subjects (age 24.9 +/- 3.0 years, weight 82.8 +/- 8.3 kg, V O2peak 48.1 +/- 6.9 mL.kg(-1).min(-1)). These subjects performed, in random order, a trial with 5 days of prior ingestion of a placebo or allopurinol. Each trial consisted of eight 10-second sprints on an air-braked cycle ergometer and was separated by at least a week. A rest period of 50 seconds separated each repeated sprint. Forearm venous plasma inosine, hypoxanthine (Hx) and uric acid concentrations were measured at rest and during 120 minutes of recovery from exercise. Urinary inosine, Hx, xanthine, and uric acid excretion were also measured before and for 24 hours after exercise. During the first 120 minutes of recovery, plasma Hx concentrations, as well as the urinary Hx and xanthine excretion rates, were higher (P < .05) with allopurinol compared with the placebo trial. In contrast, plasma uric acid concentration and urinary uric acid excretion rates were lower (P < .05) with allopurinol. The total urinary excretion of purines (inosine + Hx + xanthine + uric acid) above basal levels was higher in the allopurinol trial compared with placebo. These results indicate that the total urinary purine excretion after intermittent sprint exercise was enhanced with allopurinol treatment. Furthermore, the composition of urinary purines was markedly affected by this drug.

The importance of the measurement of ATP depletion and subsequent cell damage with an estimate of size and nature of the market for a practicable method: a review designed for technology transfer

ATP is the energy currency of cells. ATP depletion is a central process in pathogenesis, in particular ischaemia, hypoxia and hypoglycaemia. ATP depletion in cells can be indirectly measured from the increased concentrations of extracellular hypoxanthine, a central intermediate in the metabolism of ATP. Cell damage secondary to ATP depletion can also be measured from extracellular hypoxanthine. The relevant biochemistry and physiology is briefly reviewed. Since market size is needed for investment decisions that would allow technology transfer, the numbers of hypoxanthine analyses that are clinically justified from the extensive published evidence are calculated per million population from UK, Norwegian and other evidence. The concentration of oxygen in blood is measured to estimate whether mitochondrial oxidative phosphorylation is adequate. Measurements of bicarbonate are used to estimate anaerobic glycolysis. Since the indirect estimation of ATP depletion is a major objective of blood gas and acid-base analyses, the number of such analyses per million population provides a good estimate of potential market size for a more direct method of estimating ATP depletion. A method is required for the rapid, dispersed emergency analyses needed clinically. Routes for method development are indicated. Competition, risks, acceptability, consumer motivation and timetables are indicated for the development phase. There are medicolegal pressures, especially in the USA, for the proposed advances to be widely used.

Xanthinuria in a family of Cavalier King Charles spaniels

Xanthine calculi were found in a 7-month-old male Cavalier King Charles spaniel with urethral obstruction and renal insufficiency. Because the only two other reported cases of naturally occurring xanthine urolithiasis concerned a Cavalier King Charles and a King Charles spaniel the urine of the littermates and parents of the patient were also examined for xanthinuria. Semi-quantitative analysis revealed high urine concentrations of hypoxanthine and xanthine in the patient and his female littermate. Quantitative analysis by high-pressure liquid chromatography (HPLC) of the urine samples from the family of this Cavalier King Charles spaniel and nine control dogs revealed that hypoxanthine and xanthine excretion was 30 and 60 times higher in the affected patient and the female littermate than in the others dogs. The pattern of xanthinuria, which is caused by a deficiency of the enzyme xanthine oxidase, in the relation diagram of this family of Cavalier King Charles Spaniels was consistent with an autosomal recessive mode of inheritance.

Transport of hypoxanthine from plasma to cerebrospinal fluid and vitreous humor in newborn pigs

To determine whether an elevated level of hypoxanthine in cerebrospinal fluid or vitreous humor might reflect a high plasma hypoxanthine concentration, or whether it necessarily represents local tissue hypoxia, we infused hypoxanthine intravenously to normoxemic and normotensive piglets (n = 6). Hypoxanthine was measured in different body fluids using HPLC. During the 8 hours of infusion hypoxanthine increased in plasma (from 30 +/- 6 mumol/l (mean +/- SD) before the infusion to 68 +/- 20 mumol/l at the end of the infusion, p < 0.01), cerebrospinal fluid (CSF) (19 +/- 8 to 43 +/- 9 mumol/l, p < 0.05) and vitreous humor (15 +/- 5 to 30 +/- 6 mumol/l, p < 0.05). After infusion, hypoxanthine values in all three fluids were similar to those seen in pigs after severe hypoxia. Hypoxanthine in vitreous humor and plasma were significantly correlated (r = 0.80, 95% confidence interval 0.47-0.93, p < 0.001). Urinary excretion of hypoxanthine increased almost 40 times from 0.12 +/- 0.14 to 4.6 +/- 2.9 mumol/kg/h indicating that renal excretion of hypoxanthine is not achieved just by passive filtration. We conclude that in newborn piglets hypoxanthine can pass from plasma to CSF and vitreous humor. Thus an increased CSF hypoxanthine concentration is not definite proof that significant cerebral hypoxia has occurred.

The pathogenesis of the Lesch-Nyhan syndrome: ATP use is positively related to hypoxanthine supply to hypoxanthine guanine phosphoribosyltransferase

In order to explain features of severe hypoxanthine guanine phosphoribosyltransferase (HPRT) deficiency, the Lesch-Nyhan syndrome, a continuous supply of substrate, hypoxanthine, for the enzyme must be generated. This supply must be increased in association with increased ATP turnover. We have shown that ATP turnover continuously supplies hypoxanthine for recycling by the enzyme HPRT and that this supply increases curvilinearly with increasing ATP turnover. The effects of increasing exercise on ATP turnover were examined using a Latin square experimental design. The outputs of hypoxanthine, xanthine, urate and creatinine were measured. The data were then examined statistically.

Hypoxanthine phosphoribosyltransferase activity in tissues and hypoxanthine concentrations in plasma and CSF of the horse in comparison with other species

1. Plasma hypoxanthine and xanthine concentrations are very low in the horse and low in rat, mouse and greyhound compared to concentrations in beagles, man, sheep and rabbit. 2. Activities in erythrocytes of the main enzyme metabolizing hypoxanthine, hypoxanthine phosphori-bosyltransferase, show a similar pattern (Tax et al., 1976, Comp. Biochem. Physiol. 54B, 209-212); thus low activities have been found where plasma concentrations were low. 3. Hypoxanthine phosphoribosyltransferase activities in horse tissue other than erythrocytes are similar to those in man and rabbit with high activities in brain; this enzyme may therefore be functionally important in equine brain.

A new case with hereditary xanthinuria: response to exercise

The concentration of purines in plasma and urine from a 37-yr-old healthy man with a very low plasma urate concentration was measured by HPLC. A persistent increase in xanthine and a slight elevation of hypoxanthine was found. The metabolic response to intensive treadmill running and long distance running was investigated. The hypoxanthine concentration increased to about the same level as in healthy controls, but the elimination from plasma was considerably slower. The high xanthine level was practically unchanged by exercise.

Cerebrospinal fluid nucleotide metabolites following short febrile convulsions

Cerebrospinal fluid (CSF) markers of cerebral energy depletion were measured in 32 infants and children following short (less than 10 minutes) febrile convulsions, and in 19 controls. Specific and sensitive indices of high-energy phosphate compound depletion (hypoxanthine, xanthine and uridine) showed no marked changes. Values for patients and febrile controls were significantly higher than for afebrile controls, which is consistent with increased cerebral metabolism in febrile patients. There were no differences in pH, lactate or creatine kinase levels in the CSF of patients and controls. The results suggest that short febrile convulsions are benign and that in the absence of risk factors for the subsequent development of epilepsy, prophylactic anticonvulsant treatment is not indicated.

Cerebrospinal fluid nucleotide metabolites following non-convulsive status epilepticus

The authors studied specific and sensitive indicators of neuronal adenosine triphosphate (ATP) depletion--hypoxanthine, xanthine and uridine levels--in the cerebrospinal fluid (CSF) of nine children during non-convulsive status epilepticus. No evidence of ATP depletion was found and CSF pH and creatine kinase levels were similar to those of controls. Hypoxanthine, xanthine and uridine had a tendency to be low, but this was significant only for xanthine. The authors speculatively link this reduction to a reduction in neuronal protein synthesis. This might be a mechanism whereby non-convulsive status epilepticus could lead to intellectual deterioration and dementia.

Hypoxanthine, xanthine and uridine in body fluids, indicators of ATP depletion

Measurements of hyp, xan and urd in body fluids can provide evidence of energy, ATP, depletion in the body, in organs or in cells. Such information is clinically useful in the many diseases in which cellular energy supplies cannot be maintained like perinatal asphyxia, hydrocephalus and vascular insufficiency in brain, heart, limbs, kidneys or other organs. Similar HPLC methods using reversed-phase C18 columns and quantitation by UV absorption have been employed in a variety of centres to yield almost identical results. These have been assembled in this review to form a series of reference values. The current analytical problems are reviewed. Since concentrations of hyp and xan may alter independently situations are discussed in which separate measurements rather than their summed, total oxypurine concentrations are needed. The biochemistry and physiology underlying the use of such analyses is examined to guide sampling of the appropriate body fluid at a relevant time and to avoid oversimplified interpretation of results as well as unnecessary arguments. Specifically: (1) Intracellular concentrations of hyp and xan are inversely related to adenylate energy change and therefore to the energy currency of the cell ATP. Uridine in tissues is similarly 'controlled'. (2) There is extensive evidence that large increases in hyp, xan and urd in body fluids indicate ATP depletion. (3) Small changes in hyp probably reflect alterations of ATP turnover. (4) Xanthine arises mainly from guanine and can change independently of hyp. (5) Clinically useful information is obtainable from hyp and xan concentrations in CSF, amniotic fluid, urine and plasma. Extensive clinical correlations are reviewed. At present we are in a development phase for which HPLC is ideal but the most efficient way to perform and use such analyses in routine clinical practice remains to be established.

Clinical and biochemical assessments of damage due to perinatal asphyxia: a double blind trial of a quantitative method

Using conventional criteria, a series of 26 infants was selected for intrapartum asphyxia from about 4000 deliveries over one year at a single hospital to assess the efficacy of a new biochemical method. Tissue damage was estimated from urinary excretion of hypoxanthine, an important and central intermediate in purine metabolism. The overall pattern showed agreement between the grading (by previously accepted methods) of asphyxia in the perinatal period and our new biochemical approach. The association with handicap at one year of age following asphyxia was complex. This biochemical technique could be used to exclude postasphyxial damage as a cause of clinical disturbances and to select a small group (0.1% of all births) who require further investigation for rarer disorders which may also cause long term handicap.

The effects of fetal energy depletion on amniotic fluid concentrations of amino acids, organic acids and related metabolites

Concentrations of amino and organic acids, phosphate, sulphate, gluconic acid and gluconolactone were measured in amniotic fluid samples which contained either normal or raised hypoxanthine concentrations. In this way, the effect of mild fetal ATP depletion could be determined. The effects of this mild asphyxia were to raise concentrations of phenylalanine, tyrosine, lysine, glycine, phosphate, sulphate, gluconic acid and glucono-1,5-lactone. However, concentrations of a variety of other metabolites were unchanged; thus no diagnostic confusion should arise with organic acidurias in mild asphyxia in contrast to the biochemical mimickry produced by severe asphyxia. Since clinically normal parturition can produce changes in amniotic fluid, urine from newborn or cord blood may not reflect the metabolic balance in utero.

Clinical biochemistry of the neonatal period: immaturity, hypoxia, and metabolic disease

This review attempts to provide practical information on common problems in the laboratory medicine of newborn infants and also considers unresolved problems in achieving neonatal diagnoses. A common cause of upset in the newborn--intrapartum asphyxia--can now be positively diagnosed. This leaves a small group whom it is necessary to investigate because they may have metabolic disease. The initial investigation of metabolic disease at the district general hospital should be limited to the commoner conditions.

Renal hypouricaemia in a patient with 48,XXYY syndrome

Studies on hypouricaemia observed in a patient with 48,XXYY syndrome revealed an abnormality in renal urate handling. His renal urate clearance was abnormally increased. Inosine administration and provocative tests using probenecid and pyrazinamide identified an isolated renal tubular abnormality with increased urate secretion. Since the serum urate in his brother with a normal sex chromosome constitution was also low, the association of renal hypouricaemia and 48,XXYY syndrome in this patient is probably coincidental. Although the brother was not investigated, these siblings may be a previously unreported case of familial hypouricaemia due to isolated renal hypersecretion.

Pregnancy in xanthinuria: demonstration of fetal uric acid production?

This paper reports biochemical studies in a pregnant xanthinuric female (McKusick 27830) and compares the results with findings in three other xanthinurics studied by us, including a previously unreported female who had a nephrectomy for xanthine stones. The findings of raised levels of uric acid in plasma and urine at presentation in the third trimester of pregnancy, and the subsequent fall to almost undetectable levels 6 weeks post-partum, is regarded as evidence of the extent of fetal uric acid production and clearance by the maternal circulation.