The Diagnosis Of HPRT Deficiency in the 21St Century

We have studied 36 patients with HPRT deficiency, 25 with Lesch-Nyhan syndrome and 11 with partial HPRT deficiency (grades 1 to 3). Patients diagnosed with HPRT deficiency have increased 50% since 2000. The most relevant recent advances have been made in molecular diagnosis. Nevertheless, enzyme determinations are still essential for the diagnosis of HPRT deficiency. Therapy for the neurological manifestations of HPRT deficiency has not advanced. Allopurinol remains the drug of choice to diminish uric acid overproduction, but the optimal allopurinol dose must be established in each patient to prevent xanthine or uric acid urolithiasis, a process aided by sequential determination of urinary oxypurines and uric acid.     

Efficacy and Safety of Allopurinol in Patients with the Lesch-Nyhan Syndrome and Partial Hypoxanthine- Phosphoribosyltransferase Deficiency: a Follow-up Study of 18 Spanish Patients

Allopurinol is used widely for the treatment of purine disorders such as gout, but efficacy and safety of allopurinol has not been analyzed systematically in an extensive series of patients with HPRT deficiency. From 1984 to 2004 we have diagnosed 30 patients with HPRT deficiency. Eighteen patients (12 with Lesch-Nyhan syndrome or complete HPRT deficiency, and 6 with partial HPRT deficiency) were treated with allopurinol (mean dose, 6.44 mg/Kg of weight per day) and followed-up for at least 12 months (mean follow-up 7,6 years per patient). Mean age at diagnosis was 7 years (range, 5 months to 35 years). Treatment with allopurinol was associated to a mean reduction of serum urate concentration of 50%, and was normalized in all patients. Mean urinary uric acid excretion was reduced by 75% from baseline values, and uric acid to creatinine ratio was close or under 1.0 in all patients. In contrast, hypoxanthine and xanthine urinary excretion rates increased by a mean of 6 and 10 times, respectively, compared to baseline levels. These modifications were similar in patients with complete or partial HPRT deficiency. In 2 patients xanthine stones were documented despite allopurinol dose adjustments to prevent markedly increased oxypurine excretion rates. Neurological manifestations did not appear to be influenced by allopurinol therapy. Allopurinol is a very efficacy and fairly safety drug for the treatment of uric acid overproduction in patients with complete and partial HPRT deficiency. Allopurinol was associated with xanthine lithiasis.     

Efficacy and safety of allopurinol in patients with the Lesch-Nyhan syndrome and partial hypoxanthine- phosphoribosyltransferase deficiency: a follow-up study of 18 Spanish patients

Allopurinol is used widely for the treatment of purine disorders such as gout, but efficacy and safety of allopurinol has not been analyzed systematically in an extensive series of patients with HPRT deficiency. From 1984 to 2004 we have diagnosed 30 patients with HPRT deficiency. Eighteen patients (12 with Lesch-Nyhan syndrome or complete HPRT deficiency, and 6 with partial HPRT deficiency) were treated with allopurinol (mean dose, 6.44 mg/Kg of weight per day) and followed-up for at least 12 months (mean follow-up 7,6 years per patient). Mean age at diagnosis was 7 years (range, 5 months to 35 years). Treatment with allopurinol was associated to a mean reduction of serum urate concentration of 50%, and was normalized in all patients. Mean urinary uric acid excretion was reduced by 75% from baseline values, and uric acid to creatinine ratio was close or under 1.0 in all patients. In contrast, hypoxanthine and xanthine urinary excretion rates increased by a mean of 6 and 10 times, respectively, compared to baseline levels. These modifications were similar in patients with complete or partial HPRT deficiency. In 2 patients xanthine stones were documented despite allopurinol dose adjustments to prevent markedly increased oxypurine excretion rates. Neurological manifestations did not appear to be influenced by allopurinol therapy. Allopurinol is a very efficacy and fairly safety drug for the treatment of uric acid overproduction in patients with complete and partial HPRT deficiency. Allopurinol was associated with xanthine lithiasis.     

Unusual presentation of Kelley-Seegmiller syndrome

Female carriers of hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency have somatic cell mosaicism of HPRT activity and are healthy. We report a 50-year-old woman without gout or nephrolithiasis. She was never on allopurinol. Normal serum uric acid concentrations, increased plasma hypoxanthine, and xanthine were found. HPRT activity in erythrocytes was surprisingly low: at 8.6 nmol h(-1) mg (-1) haemoglobin. Mutation analysis revealed a heterozygous HPRT gene mutation, c.215A > G (p.Tyr72Cys). Assessment of X-inactivation ratio has shown that > 75% of the active X-chromosome bears the mutant allele and could explain these unusual, previously undescribed findings.     

A review of the molecular basis of hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency

Hypoxanthine-guanine phosphoribosyltransferase (HPRT, EC 2.4.2.8) is a purine salvage enzyme that catalyses the conversion of hypoxanthine and guanine to their respective mononucleotides. Partial deficiency of this enzyme can result in the overproduction of uric acid leading to a severe form of gout, whilst a virtual absence of HPRT activity causes the Lesch-Nyhan syndrome which is characterised by hyperuricaemia, mental retardation, choreoathetosis and compulsive self-mutilation. The HPRT-encoding gene is located on the X chromosome in the region q₂₆–q₂₇ and consists of nine exons and eight introns totalling 57 kb. This gene is transcribed to produce an mRNA of 1.6 kb, which contains a protein encoding region of 654 nucleotides. With the advent of increasingly refined techniques of molecular biology, it has been possible to study the HPRT gene of individuals with a deficiency in HPRT activity to determine the genetic basis of the enzyme deficiency. Many different mutations throughout the coding region have been described, but in the absence of precise information on the three-dimensional structure of the HPRT protein, it remains difficult to determine any consistent correlation between the structure and function of the enzyme.     

Unusual Presentation of Kelley-Seegmiller Syndrome

Female carriers of hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency have somatic cell mosaicism of HPRT activity and are healthy. We report a 50-year-old woman without gout or nephrolithiasis. She was never on allopurinol. Normal serum uric acid concentrations, increased plasma hypoxanthine, and xanthine were found. HPRT activity in erythrocytes was surprisingly low: at 8.6 nmol h^?1 mg ^?1 haemoglobin. Mutation analysis revealed a heterozygous HPRT gene mutation, c.215A > G (p.Tyr72Cys). Assessment of X-inactivation ratio has shown that > 75% of the active X-chromosome bears the mutant allele and could explain these unusual, previously undescribed findings.     

Genetic analysis of human hypoxanthine-guanine phosphoribosyltransferase deficiency

Hypoxanthine-guanine phosphoribosyltransferase (HPRT; IMP: pyrophosphate phosphoribosyltransferase, EC 2.4.2.8) functions in the purine-metabolic salvage pathway. Two clinical syndromes are associated with a deficiency in HPRT enzyme activity. Virtually complete deficiency leads to the Lesch-Nyhan syndrome, whereas partial deficiency results in hyperuricemia and severe gouty arthritis. Marked heterogeneity in the mutations leading to HPRT deficiency has been found. Mutant enzymes vary with respect to levels of HPRT immunoreactive protein, electrophoretic migration, kinetic properties and amino acid sequence. Analysis of DNA and RNA from patients with HPRT deficiency has revealed point mutations, an internal gene duplication and partial as well as complete gene deletions accounting for the various HPRT mutant enzymes.     

Identification of 17 independent mutations responsible for human hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency.

Complete hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency causes the Lesch-Nyhan syndrome, an X-linked, purine metabolism disorder manifested by hyperuricemia, hyperuricaciduria, and neurologic dysfunction. Partial HPRT deficiency causes hyperuricemia and gout. One requirement for understanding the molecular basis of HPRT deficiency is the determination of which amino acids in this salvage enzyme are necessary for structural or catalytic competence. In this study we have used the PCR coupled with direct sequencing to determine the nucleotide and subsequent amino acid changes in 22 subjects representing 17 unrelated kindreds from the United Kingdom. These mutations were confirmed by using either RNase mapping or Southern analyses. In addition, experiments were done to determine enzyme activity and electrophoretic mobility, and predictive paradigms were used to study the impact of these amino acid substitutions on secondary structure.     

Human hypoxanthine-guanine phosphoribosyltransferase: a single nucleotide substitution in cDNA clones isolated from a patient with Lesch-Nyhan syndrome (HPRTMidland)

We have determined the molecular basis for hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency in a patient, J.H., with Lesch-Nyhan syndrome. Radioimmunoassay of lysates of erythrocytes or cultured B-lymphoblasts showed that this patient had no detectable HPRT enzyme activity or HPRT protein. HPRT-specific mRNA levels were normal by Northern analysis. We created a cDNA library from mRNA isolated from cultured lymphoblasts derived from this patient. Nucleotide sequencing of full-length HPRT cDNA clones revealed a single nucleotide (nt) substitution: a T-to-A transversion at nt 389. We have designated this variant HPRTMidland. The predicted amino acid (aa) substitution in HPRTMidland is a valine to aspartic acid at aa 130. This substitution is within 2 aa of the amino acid substitution in a previously defined HPRT variant, HPRTAnn Arbor. Both mutations are within a highly conserved sequence in the putative 5-phosphoribosyl-1-pyrophosphate-binding domain. The amino acid substitution in HPRTMidland causes a significant perturbation in the predicted secondary structure of this region. The HPRTMidland mutation affects a different domain of HPRT than the HPRTFlint mutation located at 167 nt away.     

HPRT Deficiency in Spain: What Have We Learned in the Past 30 Years (1984–2013)?

Since 1984, we have diagnosed at the La Paz University Hospital, Madrid, Spain, 41 patients with hypoxanthine phosphoribosyltransferase (HPRT) activity deficiency. These patients belonged to 34 families. We have also performed molecular and enzymatic diagnosis in three patients from India, one from Belgium, and three from Colombia. About 1/3 of these patients were followed up at La Paz University Hospital at least every year. This fact has allowed us to examine the complete spectrum of HPRT deficiency as well as to perform a more accurate diagnosis and treatment. In the present review, we also summarized our studies on the basis of physiopathology of the neurological manifestation of Lesch Nyhan disease (LND).     

高尿酸血症和痛风的遗传学研究进展

痛风是由高尿酸血症引发的一种常见炎性关节炎,受遗传因素和环境因素共同作用。早期研究表明,PRPS1和HPRT1等单基因稀有突变会引起嘌呤合成代谢紊乱,从而引发高尿酸血症和痛风。近年来,全基因组关联分析(Genome-wide association studies,GWAS)已检出多个导致高尿酸血症和痛风的易感位点及相关候选基因。其中SLC2A9、SLC22A11和SLC22A12基因功能缺失性突变可引起遗传性低尿酸血症,而过表达则会加强尿酸的重吸收。ABCG2、SLC17A1和SLC17A3基因功能缺陷型变异会降低肾脏和肠道对尿酸的排泄量。因此,诱发尿酸排泄障碍(高重吸收和低排泄)的基因变异是影响高尿酸血症和痛风的主要遗传因素。另外,抑制-激活生长因子系统、转录因子、细胞骨架以及基因和环境的互作等因素也一定程度影响血液尿酸水平。在中国汉族人群中,两个新发现的易感基因RFX3和KCNQ1可能造成免疫应答受损和胰岛B细胞功能缺陷,从而直接或间接引起高尿酸酸血症和痛风。本文系统综述了高尿酸血症和痛风的遗传学研究,以促进人们对高尿酸血症和痛风发病机理的理解。     

Hypoxanthine-Guanine Phosphoribosyltransferase Deficiency: Biochemical and Molecular Findings in Six Argentine Patients

Hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency is an inborn error of purine metabolism responsible for Lesch-Nyhan Disease (LND) and its partial phenotypes, HPRT-related hyperuricemia with neurologic dysfunction (HRND) and hyperuricemia alone. We report here the recognition of six Argentine patients, two with LND and four with HRND. All patients presented elevated excretion of uric acid, hypoxanthine, and xanthine and decreased HPRT enzyme activities <1 nmol/h/mg Hb. The molecular analysis demonstrated in the two LND patients a novel inherited transition mutation, c.203T >C (L68P), in one subject and a germline transition mutation, c.209G >A (G70E), in the other. In the HRND patients a novel transversion mutation, c.584 A >C (Y195S), was found in three related patients and an inherited transition mutation, c.143G >A (R48H), in the fourth subject.     

Urinary Guanidinoacetate and Creatine Levels in Patients with HPRT Deficiency

Neurobehavioral manifestations of complete HPRT deficiency include severe action dystonia, choreathetosis, alteration of executive functions, and self-injurious behavior. Dystonic manifestations are also present in patients with partial HPRT deficiency. Pathophysiology of these manifestations is unknown. Guanidinoacetate is a neurotoxin implicated in certain dystonic syndromes. We have examined guanidinoacetate and creatine levels in urine from 11 HPRT deficient patients (9 with Lesch-Nyhan syndrome and 2 with partial deficiency). Urinary guanidinoacetate and creatine levels in HPRT deficient patients were within the normal range. Guanidinoactetate alteration does not seem to be implicated in the pathogenesis of the neurological disease associated with HPRT deficiency.     

Molecular Characterization and Structure Analysis of Hprt in a Chinese Patient with Lesch-Nyhan Disease

Lesch-Nyhan disease (LND) is caused by deficiency of hypoxanthine guanine phosphoribosyltransferase (HPRT). The aim of the present study is to characterize the molecular deficiency of a clinical diagnosed Chinese patient with attenuated variant of LND. The coding region and the intron-exon boundaries of HPRT1 gene were sequenced by standard methods, and HPRT activity was assayed by HPLC method. Structure analysis was performed to estimate the consequence of the mutant of HPRT1 gene. A new mutation c.245T>G (p.Ile82Ser) was identified in this patient, and heterozygous mutation was found in the patient's mother. The activity of HPRT in the patient was completely undetectable. Structure study indicates that the mutation of p.Ile82Ser may lead to loss of hydrophobic side chain and disrupt its normal conformation of HPRT protein. It is helpful for diagnosis of LND that sequencing analysis of HPRT1 gene is performed in male infant and juvenile with hyperuricaemia and neurologic dysfunction in Chinese.     

Urinary guanidinoacetate and creatine levels in patients with HPRT deficiency

Neurobehavioral manifestations of complete HPRT deficiency include severe action dystonia, choreathetosis, alteration of executive functions, and self-injurious behavior. Dystonic manifestations are also present in patients with partial HPRT deficiency. Pathophysiology of these manifestations is unknown. Guanidinoacetate is a neurotoxin implicated in certain dystonic syndromes. We have examined guanidinoacetate and creatine levels in urine from 11 HPRT deficient patients (9 with Lesch-Nyhan syndrome and 2 with partial deficiency). Urinary guanidinoacetate and creatine levels in HPRT deficient patients were within the normal range. Guanidinoactetate alteration does not seem to be implicated in the pathogenesis of the neurological disease associated with HPRT deficiency.     

Hypoxanthine-guanine phosphoribosyltransferase deficiency: biochemical and molecular findings in six Argentine patients

Hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency is an inborn error of purine metabolism responsible for Lesch-Nyhan Disease (LND) and its partial phenotypes, HPRT-related hyperuricemia with neurologic dysfunction (HRND) and hyperuricemia alone. We report here the recognition of six Argentine patients, two with LND and four with HRND. All patients presented elevated excretion of uric acid, hypoxanthine, and xanthine and decreased HPRT enzyme activities <1 nmol/h/mg Hb. The molecular analysis demonstrated in the two LND patients a novel inherited transition mutation, c.203T >C (L68P), in one subject and a germline transition mutation, c.209G >A (G70E), in the other. In the HRND patients a novel transversion mutation, c.584 A >C (Y195S), was found in three related patients and an inherited transition mutation, c.143G >A (R48H), in the fourth subject.     

Human hypoxanthine-guanine phosphoribosyltransferase deficiency. The molecular defect in a patient with gout (HPRTAshville)

The genetic basis of hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency has been identified by nucleotide sequence analysis of HPRT cDNAs cloned from a patient with gout. A single nucleotide change was identified in two independent clones: an A to G transition at nucleotide 602. Confirmation of a mutation at this site was provided by RNase mapping analysis. The predicted consequence of this transition is an aspartic acid to glycine substitution at amino acid 201. We have designated this variant HPRTAshville. Prior to this report, enzyme activity in HPRTAshville had not been detected by routine assay. Using more sensitive techniques, including an in situ gel assay for HPRT activity, we were able to demonstrate electrophoretic, kinetic, and structural differences between HPRTAshville and normal HPRT. Electrophoretic migration of HPRTAshville has elevated Michaelis constants for 5-phosphoribosyl-1-pyrophosphate and hypoxanthine. Predicted secondary structural alterations may result from the aspartic acid to glycine substitution.     

Molecular and tissue-specific heterogeneity in HPRT deficiency

In several patients with different degrees of HPRT deficiencies, residual activities have been determined in both lysed and intact erythrocytes. No close correlation could be found between the degree of HPRT deficiency and the severity of the clinical expression. Unless HPRT activity in both intact and lysed erythrocytes was below detection level, the residual activity in intact red blood cells was higher than in lysates. Tissue-specific heterogeneity was illustrated with a patient suffering from X-linked gout. Lysates from erythrocytes, leukocytes, and cultured fibroblasts showed 1%, 8%, and 100% of normal HPRT activity, respectively. Characterization of the erythrocyte and fibroblast HPRT from this patient showed no kinetic abnormalities. However, there was a decreased heat stability. It is concluded that for a better understanding of the pathophysiology in HPRT deficiency studies on nucleated cells from the different tissues are needed.     

Purine nucleotide reutilization by human lymphoblast lines with aberrations of the inosinate cycle

A purine nucleotide (inosinate) cycle is demonstrated with human lymphoblasts. The lymphoblast requires approximately 50 nmol of purine/10(6) cell increment. When the inosinate cycle is interrupted by the genetic, severe deficiency of either or both purine nucleoside phosphorylase (PNP) or hypoxanthine phosphoribosyltransferase (HPRT), purine accumulates in the culture medium as inosine, guanosine, deoxyinosine, and deoxyguanosine (PNP deficiency or PNP, HPRT deficiency) or hypoxanthine and guanine (HPRT deficiency). This accumulation represents an additional 25 to 32 nmol of purine which must be synthesized per 10(6) cell increment. PNP-deficient lymphoblasts have PPRibP contents characteristic of normal lymphoblasts, about 20 to 25 pmol/10(6) cells. HPRT-deficient lymphoblasts have four times higher PPRibP contents. The lymphoblast deficient for both PNP and HPRT has only a marginal elevation of PPRibP content, 1.5 times normal values. The elevated PPRibP content of HPRT-deficient cells reflects the efficient, unilateral reutilization of the ribose moiety of purine ribonucleotides and is not a cause of purine overproduction. Purine overproduction characterizing PNP-deficient lymphoblasts appears similar to overproduction from deficiency of HPRT, i.e. a break in the inosinate cycle rather than overactive de novo purine synthesis.     

Structural and functional studies of the human phosphoribosyltransferase domain containing protein 1

Human hypoxanthine-guanine phosphoribosyltransferase (HPRT) (EC 2.4.2.8) catalyzes the conversion of hypoxanthine and guanine to their respective nucleoside monophosphates. Human HPRT deficiency as a result of genetic mutations is linked to both Lesch-Nyhan disease and gout. In the present study, we have characterized phosphoribosyltransferase domain containing protein 1 (PRTFDC1), a human HPRT homolog of unknown function. The PRTFDC1 structure has been determined at 1.7 ? resolution with bound GMP. The overall structure and GMP binding mode are very similar to that observed for HPRT. Using a thermal-melt assay, a nucleotide metabolome library was screened against PRTFDC1 and revealed that hypoxanthine and guanine specifically interacted with the enzyme. It was subsequently confirmed that PRTFDC1 could convert these two bases into their corresponding nucleoside monophosphate. However, the catalytic efficiency (k(cat)/K(m)) of PRTFDC1 towards hypoxanthine and guanine was only 0.26% and 0.09%, respectively, of that of HPRT. This low activity could be explained by the fact that PRTFDC1 has a Gly in the position of the proposed catalytic Asp of HPRT. In PRTFDC1, a water molecule at the position of the aspartic acid side chain position in HPRT might be responsible for the low activity observed by acting as a weak base. The data obtained in the present study indicate that PRTFDC1 does not have a direct catalytic role in the nucleotide salvage pathway.