Recent advances in understanding and managing adenosine deaminase and purine nucleoside phosphorylase deficiencies.

PURPOSE OF THE REVIEW: To review the recent advances in the understanding and management of the immune and nonimmune effects of inherited adenosine deaminase (ADA) and purine nucleoside phosphorylase (PNP) deficiencies. RECENT FINDINGS: Abnormal thymocyte development and peripheral T-cell activation in ADA-deficient and PNP-deficient patients cause increased susceptibility to infections and immune dysregulation. The impaired purine homeostasis also damages many other cell types and tissues. Animal studies suggest that defects in surfactant metabolism by alveolar macrophages cause the pulmonary alveolar proteinosis commonly seen in ADA-deficient infants, while toxicity of purine metabolites to cerebellar Purkinje cells may lead to the ataxia frequently observed in PNP deficiency. Patients' outcome with current treatments including enzyme replacement and stem cell transplantations are inferior to those achieved in most severe immunodeficiency conditions. New strategies, including intracellular enzyme replacement, gene therapy and innovative protocols for stem cell transplantations hold great promise for improved outcomes in ADA and PNP deficiency. Moreover, newborn screening and early diagnosis will allow prompt application of these novel treatment strategies, further improving survival and reducing morbidity. SUMMARY: Better understanding of the complex immune and nonimmune effects of ADA and PNP deficiency holds great promise for improved patients' outcome.

Neurologic presentation, diagnostics, and therapeutic insights in a severe case of adenylosuccinate lyase deficiency.

Epilepsy in adenylosuccinate lyase deficiency may be difficult to treat, and there is no standardized therapy. The authors describe a case of severe adenylosuccinate lyase deficiency resulting from a heterozygous mutation of the ADSL gene (p.D215H/p.I351T). The patient presented with tonic-clonic seizures, opisthotonus, tremor, and myoclonus in the 4th day of life. The seizures were refractory on various combinations of antiepileptic treatment. A ketogenic diet was introduced at the age of 2 resulting in a seizure-free period. The patient, however, developed a metabolic hyperchloremic acidosis with Fanconi syndrome, which disappeared a month after cessation of the diet at the age of 5. Since the withdrawal of the ketogenic diet, seizures have returned to a frequency of several times a day. In conclusion, a ketogenic diet could be considered a valid therapeutic option in patients with intractable seizures in a course of adenylosuccinate lyase deficiency; however, it requires a formal study.

[A case of Xanthinuria in a patient with marked hypouricemia]. / Un caso di xantinuria in una paziente con marcata ipouricemia.

Xanthinuria is a rare autosomal recessive disorder associated with a deficiency of xanthine oxidoreductase (XOR), which normally catalyzes the conversion of hypoxanthine to uric acid. The effects of this deficit are an elevated concentration of hypoxanthine and xanthine in the blood and urine, hypouricemia, and hypouricuria. The deficit in XOR can be isolated (type I xanthinuria) or associated with a deficit in aldehyde oxidase (type II xanthinuria) and sulfite oxidase (type III xanthinuria). While the first two variants have a benign course, are often asymptomatic (20%), and clinically indistinguishable, type III xanthinuria is a harmful form that leads to infant death due to neurological damage. The clinical symptoms (kidney stones, CKD, muscle and joint pain, peptic ulcer) are the result of the accumulation of xanthine, which is highly insoluble, in the body fluids. We describe a case of type I xanthinuria in a 52-year-old woman who presented with hypouricemia, hypouricuria and kidney stones. The diagnosis was based on purine catabolite levels in urine and serum measured by 3 nonroutine methods: high-pressure liquid chromatography, mass spectrometry, and magnetic resonance imaging. To identify the type of xanthinuria the allopurinol test was used. We believe that these tests will facilitate the diagnosis of xantinuria especially in asymptomatic patients without the need for a biopsy of the liver or intestines, which is useful only for scientific purposes.

Purine and pyrimidine metabolism in hereditary orotic aciduria: some unexpected effects of allopurinol.

Purine and pyrimidine metabolism have been investigated in the longest surviving case of hereditary orotic aciduria after 15 years of chronic uridine therapy. Several unusual features were recorded: 1. Although the uridine dosage (0.5 mmol/kg) was adequate to control an otherwise normal clinical status, orotic acid excretion was still excessive (in congruent 7 mmol/24 h). Urinary drug metabolites (uracil and uridine), however, accounted for less than 7% of the daily uridine dose, and no orotidine, or any abnormal pyrimidines or purines, were identified at any time. 2. Urinary uric acid excretion was high and plasma uric acid low, resulting in a clearance up to 4 times normal. This was attributed to the uricosuric effect of orotic acid. 3. In direct contrast to previous findings in gouty subjects and healthy male controls we noted: (i) no increase in plasma or urinary uric acid levels, or uric acid clearance, following the change from a low to a high nucleoprotein regime (normally up to two-fold); (ii) allopurinol reduced both urinary uric acid and total oxypurine levels by more than 50% on the low (normally unaffected) as well as the high (normally reduced 20-50%) nucleoprotein regime; (iii) a substantial (up to 70%) reduction in orotic acid excretion during allopurinol therapy (normally mild orotic aciduria), of similar magnitude and in parallel with the reduction in uric acid levels. Uric acid and orotic acid excretion were closely related throughout. These findings differ from those of a similar study of hereditary orotic aciduria and suggest there is competitive transport between exogenous (dietary) purines and pyrimidines, as well as an important interdependence between endogenous purine and pyrimidine metabolism, by mechanisms as yet undefined.

Urinary excretion of orotic acid, orotidine and other pyrimidines in a patient with purine nucleoside phosphorylase deficiency.

Urinary orotidine and orotic acid have been determined in a patient with purine nucleoside phosphorylase (PNP) deficiency under various dietary therapeutic conditions. For this purpose a new procedure for the analysis of both compounds has been developed, consisting of prefractionation with Dowex 1X8, followed by two HPLC steps on a micro Bondapak NH2 and a micro Bondapak C18 column. With this method normal as well as slightly elevated excretions of orotic acid have been found in our patient. No evidence was obtained for inhibition of OPRT by purine (deoxy)nucleosides as a cause of pyrimidine starvation. A significant increase of urinary orotidine was found after loading with allopurinol. For comparison excretory values in a patient with ornithine transcarbamylase deficiency and also in a patient with orotic aciduria type I are shown. The possible cause of the slight increase in urinary orotic acid in our patient has been discussed.