Physiological levels of folic acid reveal purine alterations in Lesch-Nyhan disease.

Lesch-Nyhan disease (LND), caused by a deficient salvage purine pathway, is characterized by severe neurological manifestations and uric acid overproduction. However, uric acid is not responsible for brain dysfunction, and it has been suggested that purine nucleotide depletion, or accumulation of other toxic purine intermediates, could be more relevant. Here we show that purine alterations in LND fibroblasts depend on the level of folic acid in the culture media. Thus, physiological levels of folic acid induce accumulation of 5-aminoimidazole-4-carboxamide riboside 5'-monophosphate (ZMP), an intermediary of de novo purine biosynthetic pathway, and depletion of ATP. Additionally, Z-nucleotide derivatives (AICAr, AICA) are detected at high levels in the urine of patients with LND and its variants (hypoxanthine-guanine phosphoribosyltransferase [HGprt]-related neurological dysfunction and HGprt-related hyperuricemia), and the ratio of AICAr/AICA is significantly increased in patients with neurological problems (LND and HGprt-related neurological dysfunction). Moreover, AICAr is present in the cerebrospinal fluid of patients with LND, but not in control individuals. We hypothesize that purine alterations detected in LND fibroblasts may also occur in the brain of patients with LND.

Novel mutation in HPRT1 causing a splicing error with multiple variations.

Lesch-Nyhan disease (LND) is a rare X-linked recessive disorder caused by deficiency of the purine salvage enzyme hypoxanthine-guanine phosphoribosyltransferase (HPRT), encoded by the HPRT1. To date, nearly all types of mutations have been reported in the whole gene; however, duplication mutations are rare. We here report the case of a 9-month-old boy with LND. He showed developmental delay, athetosis, and dystonic posture from early infancy, but no self-injurious behaviors. Hyperuricemia was detected, and his HPRT enzyme activity in erythrocytes was completely deficient. A novel duplication mutation (c.372dupT, c.372_374 TTT > c.372_375 TTTT) was identified in exon 4 of the HPRT1, which causes aberrant splicing. This is the third case of a duplication mutation in the HPRT1 that causes splicing error.

Fuzzy optimization for detecting enzyme targets of human uric acid metabolism.

MOTIVATION: Mathematical modeling and optimization have been used for detecting enzyme targets in human metabolic disorders. Such optimal drug design methods are generally differentiated as two stages, identification and decision-making, to find optimal targets. We developed a unified method named fuzzy equal metabolic adjustment to formulate an optimal enzyme target design problem for drug discovery. The optimization framework combines the identification of enzyme targets and a decision-making strategy simultaneously. The objectives of this algorithm include evaluations of the therapeutic effect of target enzymes, the adverse effects of drugs and the minimum effective dose (MED). RESULTS: An existing generalized mass action system model of human uric acid (UA) metabolism was used to formulate the fuzzy optimization method for detecting two types of enzymopathies: hyperuricemia caused by phosphoribosylpyrophosphate synthetase (PRPPS) overactivity and Lesch-Nyhan syndrome. The fuzzy objectives were set so that the concentrations of the metabolites were as close as possible to the healthy levels. The target design included a diet control of ribose-5-phospahate (R5P). The diet control of R5P served as an extra remedy to reduce phosphate uptake entering the purine metabolic pathway, so that we could obtain a more satisfactory treatment than obtained for those without a diet control. Moreover, enhancing UA excretion resulted in an effective treatment of hyperuricemia caused by PRPPS overactivity. This result correlates with using probenecid and benbromazone, which are uricosuric agents present in current clinical medications. By contrast, the Lesch-Nyhan syndrome required at least three enzyme targets to cure hyperuricemia.

Adenosine, dopamine and serotonin receptors imbalance in lymphocytes of Lesch-Nyhan patients.

Lesch-Nyhan disease (LND) is caused by complete deficiency of the hypoxanthine-guanine phosphoribosyltransferase enzyme. It is characterized by overproduction of uric acid, jointly with severe motor disability and self-injurious behaviour which physiopathology is unknown. These neurological manifestations suggest a dysfunction in the basal ganglia, and three neurotransmitters have been implicated in the pathogenesis of the disease: dopamine, adenosine and serotonin. All of them are implicated in motor function and behaviour, and act by binding to specific G-protein coupled receptors in the synaptic membrane where they seem to be integrated through receptor-receptor interactions. In this work we have confirmed at protein level the previously reported increased expression of DRD5 and the variably aberrant expression of ADORA2A, in LND PBL respect to control PBL. We have also described, for the first time, a decreased expression and protein level of 5-HTR1A in LND PBL respect to control PBL. If these results were confirmed in the Lesch-Nyhan patients basal ganglia cells, this would support the hypothesis that pathogenesis of neurological manifestations of Lesch-Nyhan patients may be related to an imbalance of neurotransmitters, rather than to the isolated disturbance of one of the neurotransmitters, and this fact should be taken into account in the design of pharmacologic treatment for their motor and behavioural disturbances.

Molecular analysis of two enzyme genes, HPRT1 and PRPS1, causing X-linked inborn errors of purine metabolism.

Inherited mutation of hypoxanthine guanine phosphoribosyltransferase (HPRT) gives rise to Lesch-Nyhan syndrome or HPRT-related gout. On the other hand, PRPS1 mutations cause PRPP synthetase superactivity associated with hyperuricemia and gout, sometimes including neurodevelopmental abnormalities. We have identified two mutations in two Lesch-Nyhan families after our last report. One of them, a new single nucleotide substitution (130G>T) resulting in a missense mutation D44Y was detected in exon 2 of HPRT1. RT-PCR amplification showed not only a cDNA fragment with normal size, but also a small amount of shorter fragment skipping exons 2 and 3. The other missense mutation F74L (222C > A) was detected in a Japanese patient but has been reported previously in European families. In four hyperuricemic patients with mild neurological abnormality, no mutations responsible for partial HPRT deficiency were identified in HPRT1. In these four patients, we also performed molecular analysis of PRPS1, but no mutations in PRPP synthetase were found.

Is ZMP the toxic metabolite in Lesch-Nyhan disease?

The genetic deficiency of hypoxanthine-guanine phosphoribosyltransferase (HPRT), located on the X chromosome, causes a severe neurological disorder in man, known as Lesch-Nyhan disease (LND). The enzyme HPRT is part of the savage pathway of purine biosynthesis and catalyzes the conversion of hypoxanthine and guanine to their respective nucleotides, IMP and GMP. HPRT deficiency is associated with a relatively selective dysfunction of brain dopamine systems. Several metabolites that accumulate in the patients (phosphoribosylpyrophosphate (PRPP), hypoxanthine, guanine, xanthine, and Z-nucleotides) have been proposed as toxic agents in LND. Some authors have pointed that Z-riboside, derived from the accumulation of ZMP, could be the toxic metabolite in LND. However, the available experimental data support a better hypothesis. I suggest that ZMP (and not Z-riboside) is the key toxic metabolite in LND. ZMP is an inhibitor of the bifunctional enzyme adenylosuccinate lyase, and a deficiency of this enzyme causes psychomotor and mental retardation in humans. Moreover, it has been reported that ZMP inhibits mitochondrial oxidative phosphorylation and induces apoptosis in certain cell types. ZMP is also an activator of the AMP-activated protein kinase (AMPK), a homeostatic regulator of energy levels in the cell. The AMPK has been implicated in the regulation of cell viability, catecholamine biosynthesis and cell structure. I propose that accumulation of ZMP will induce a pleiotropic effect in the brain by (1) a direct inhibition of mitochondrial respiration and the bifunctional enzyme adenylosuccinate lyase, and (2) a sustained activation of the AMPK which in turns would reduce cell viability, decrease dopamine synthesis, and alters cell morphology. In addition, a mechanism to explain the accumulation of ZMP in LND is presented. The knowledge of the toxic metabolite, and the way it acts, would help to design a better therapy.

HPRT mutations in humans: biomarkers for mechanistic studies.

The X-chromosomal gene for hypoxanthine-guanine phosphoribosyltransferase (HPRT), first recognized through its human germinal mutations, quickly became a useful target for studies of somatic mutations in vitro and in vivo in humans and animals. In this role, HPRT serves as a simple reporter gene. The in vivo mutational studies have concentrated on peripheral blood lymphocytes, for obvious reasons. In vivo mutations in T cells are now used to monitor humans exposed to environmental mutagens with analyses of molecular mutational spectra serving as adjuncts for determining causation. Studies of the distributions of HPRT mutants among T cell receptor (TCR) gene-defined T cell clones in vivo have revealed an unexpected clonality, suggesting that HPRT mutations may be probes for fundamental cellular and biological processes. Use of HPRT in this way has allowed the analyses of V(D)J recombinase mediated mutations as markers of a mutational process with carcinogenic potential, the use of somatic mutations as surrogate markers for the in vivo T cell proliferation that underlies immunological processes, and the discovery and study of mutator phenotypes in non-malignant T cells. In this last application, the role of HPRT is related to its function, as well as to its utility as a reporter of mutation. Most recently, HPRT is finding use in studies of in vivo selection for in vivo mutations arising in either somatic or germinal cells.

Cell imaging and morphology: application to studies of inherited purine metabolic disorders.

A number of inherited or drug-induced metabolic disorders involving dysfunctions in purines and pyrimidines are strongly associated with neurological dysfunction, e.g., Lesch Nyhan syndrome. Such disorders have been studied extensively using biochemical and molecular techniques in order to examine how such defects occur, sometimes using in vitro models based upon cultured neuroblastoma cell lines. However, these metabolic dysfunctions may manifest their effects in other ways, such as impaired synaptic transmission and gross abnormalities in neuronal growth and differentiation. This review outlines the latter novel facet of purine research. It is proposed that by employing cell imaging techniques and cultured neuroblastoma cell lines, believed to model the nervous system, significant insights into how inherited disorders of purine metabolism affect neuronal development can be obtained. This review provides an example of the application of these techniques to understand the etiology of Lesch Nyhan syndrome, and encourages further study of the role of purines and pyrimidines in the development of the nervous system.

Hypoxanthine impairs morphogenesis and enhances proliferation of a neuroblastoma model of Lesch Nyhan syndrome.

Extracellular purines have essential roles in neuronal development; hence, disruptions in their metabolism as reported in Lesch Nyhan syndrome (LNS) could result in developmental abnormalities. The deficiency of hypoxanthine-guanine phosphoribosyl transferase (HGPRT) in LNS leads to increased hypoxanthine and uric acid production. We have reported that HGPRT-deficient B103-4C neuroblastoma, a neuronal model of LNS, proliferated less and differentiated more than their HGPRT-positive B103 counterparts. Here, we sought to determine whether differences in proliferation and differentiation would occur when these cells were cultured in the presence of hypoxanthine or in a hypoxanthine-/serum-free chemically defined media (NBMN2). In media with 1% serum, hypoxanthine (50 microM) significantly increased the proliferation of both cell lines with a greater effect on B103-4C cells. In 1% serum media, hypoxanthine increased differentiation of B103 but decreased B103-4C differentiation. In NBMN2, B103 proliferated far more than B103-4C, but both cell types differentiated to the same extent. These results are interpreted to suggest that elevated levels of central nervous system (CNS) hypoxanthine as reported in LNS may affect neuronal development, and to implicate hypoxanthine and abnormal neuronal development as causative factors in the etiology of LNS.

Lesch-Nyhan syndrome and its pathogenesis: normal nicotinamide-adenine dinucleotide but reduced ATP concentrations that correlate with reduced poly(ADP-ribose) synthetase activity in HPRT-deficient lymphoblasts.

In hypoxanthine (guanine) phosphoribosyltransferase- (HPRT; EC 2.4.2.8) deficient lymphoblasts, ATP but not nicotinamide-adenine dinucleotide coenzyme concentrations are reduced by limited nutrition. Such reduced ATP concentrations are correlated with reduced poly(ADP-ribose) synthetase (polyADPRT; EC 2.4.2.30) activity; this reduces the breakdown of nicotinamide-adenine dinucleotide coenzymes and thus explains their normal intracellular concentrations. Since reductions in poly(ADP-ribose) synthetase activity reduce DNA repair, alterations in DNA could accumulate even in non-multiplying cells such as neurons, especially in the continuously active 'respiratory centre'. Our Lesch-Nyhan patients suffered respiratory deaths between 15 and 20 years of age.

Postnatal expression of hypoxanthine guanine phosphoribosyltransferase in the mouse brain.

The distributional and activity changes of hypoxanthine guanine phosphoribosyltransferase (HGPRT) were investigated in the developing mouse brain. The HGPRT activity level was low at birth, increased rapidly during the first 7 days of life, and underwent a gradual increase thereafter to the mature level. Polyclonal antibody against HGPRT purified from mouse brain was prepared for immunohistochemical demonstration of the enzyme during brain development. In the cerebellum, part of the Purkinje cells was consistently immunostained throughout growth, and the presence of HGPRT was observed in the dendrites of mature Purkinje cells. The most dominant change in HGPRT localization was observed in the hippocampus. Little HGPRT was detectable in the newborn mouse hippocampus. At postnatal day 7, cytoplasmic HGPRT appeared sporadically in the granular cells independently of the region of the hippocampus. The number of positive immunoreactive cells increased with growth, and the dendrites of granular cells were also immunostained on postnatal day 28. Further immunostaining was noted in the granule cells of the dentate gyrus on postnatal day 35. The above results suggest that HGPRT may play an important role in the developing hippocampus. Further investigations of the HGPRT in the human hippocampus may help to clarify the mechanism underlying the neurological disorders encountered in the Lesch-Nyhan syndrome.

Aspectos clínicos y bioquímicos del síndrome de Lesch-Nyhan

El síndrome de Lesch-Nyhan es una enfermedad genética ligada al cromosoma X, originada por un defecto en el gen que codifica la hipoxantia guanina fosforribosiltransferasa (HGPRT). Esta enzima participa en la recuperación de la guanina e hipoxantina. La deficiencia enzemática conlleva una acumulación exagerada del ácido úrico. La deficiencia total o casi total de la enzima, produce el síndrome de Lesch-Nyhan, el cual se caracteriza por hiperruricemia, hiperaciduria, coreoatetosis, hiperreflexia, retardo mental y autoagresividad. La deficiencia parcial de la enzima ocasiona artritis gotosa y nefrolitiasis sin daño neurológico.