Lucja Kierat

Differential diagnosis of hyperphenylalaninaemia by a combined phenylalanine-tetrahydrobiopterin loading test

We describe a new fully reliable method for the differential diagnosis of tetrahydrobiopterin-dependent hyperphenylalaninaemia (HPA). The method comprises the combined phenylalanine (Phe) plus tetrahydrobiopterin (BH4) oral loading test and enables the selective screening of BH4 deficiency when pterin analysis is not available or when a clear diagnosis has not been previously made. It should be performed together with the measurement of dihydropteridine reductase (DHPR) activity in blood. The new combined loading test was performed in nine patients with primary HPA, three with classical phenylketonuria (PKU), three with DHPR deficiency, and three with 6-pyruvoyl tetrahydropterin synthase (PTPS) deficiency. Three hours after oral Phe loading (100 mg/kg body weight), synthetic BH4 was administered orally at doses of either 7.5 or 20 mg/kg body weight. Amino acid (Phe and tyrosine) and pterin (neopterin and biopterin) metabolism and kinetics were analysed. By exploiting the decrease in serum Phe 4 and 8h after administration, a clear response was obtained with the higher BH4 dose (20 mg/kg body weight), allowing detection of all cases of BH4 deficiency, as well as differentiation of BH4 synthesis from regeneration defects. Since DHPR deficient patients who were previously shown to be non-responsive to the simple BH4 loading test gave a positive response, the combined Phe plus BH4 loading test can be used as a more reliable tool for the differential diagnosis of HPA in these patients. Moreover, it takes advantage of being performed while patients are on a Phe-restricted diet.

Hyperphenylalaninemia and pterin metabolism in serum and erythrocytes

The relationship between blood phenylalanine concentrations and serum and erythrocyte biopterin and neopterin concentrations was investigated in 20 phenylketonuric patients with different dietary compliance. At serum phenylalanine concentrations ranging from 43 to 1004 mumol/l, a good correlation was found with serum biopterin (r = 0.76, P < 0.001) and with red blood cell biopterin (r = 0.62, P < 0.001). A similar correlation was found between serum neopterin and phenylalanine (r = 0.60, P < 0.001). The correlation between red blood cell neopterin and serum phenylalanine was less evident, however (r = 0.47, P < 0.005). After oral loading with phenylalanine (100 mg/kg body weight), serum and red blood cell biopterin concentrations increased in patients with classical phenylketonuria as well as in one patient with dihydropteridine reductase deficiency in response to the induced acute hyperphenylalaninemia. One patient suffering from 6-pyruvoyl tetrahydropterin synthase deficiency was loaded orally with tetrahydrobiopterin (20 mg/kg body weight). The kinetics of administered cofactor confirmed its rapid absorption, with early increase of serum concentrations followed by its transport into the red blood cells. The half-life of biopterin was approximately 7 h in serum and 15 h in red blood cells. Because both values are less than the half-life of phenylalanine (20-30 h) in serum, biopterin measurement offers no advantage in monitoring dietary control in hyperphenylalaninemic patients.

Antenatal diagnosis of tetrahydrobiopterin deficiency by quantification of pterins in amniotic fluid and enzyme activity in fetal and extrafetal tissue

Prenatal diagnosis of tetrahydrobiopterin (BH4) deficiency was undertaken by evaluating the pterin patterns in amniotic fluid and the specific enzyme activities in fetal or extrafetal tissues. This allowed the prenatal diagnosis in 19 pregnancies at risk. In 8 families with a child already affected by dihydropteridine reductase deficiency 4 fetuses were diagnosed as homozygotes and 4 as heterozygotes for the defect. In 11 families with a child affected by 6-pyruvoyl tetrahydropterin synthase deficiency 4 fetuses were homozygous, 4 heterozygous and 3 normal. This study also advanced our knowledge of tetrahydrobiopterin metabolism during fetal development. The key enzymes involved in the biosynthesis of BH4 are expressed early and allow the fetus to be autotrophous for its cofactor requirement. In a twin pregnancy, both fetuses were diagnosed to be heterozygotes for dihydropteridine reductase deficiency and primapterin (7-biopterin) in amniotic fluid was increased. This indicates that pterin-4 alpha-carbinolamine dehydratase activity seems to be differently expressed during fetal life. As a consequence, pterins detected in amniotic fluid are of fetal origin and 6- and 7-substituted pterins can be present in amniotic fluid in higher proportions when compared with other body fluids.

Induction of tetrahydrobiopterin synthesis in human umbilical vein smooth muscle cells by inflammatory stimuli.

Tetrahydrobiopterin (BH4) is an obligatory cofactor and regulator of nitric oxide synthases (NOS). We evaluated the biosynthesis of BH4 in human umbilical vein smooth muscle cells (HUVSMC). Trace amounts of BH4 were found intra- and extracellularly in untreated cells. When HUVSMC were activated by individual inflammatory stimuli (IL-1beta, TNFalpha, IFNgamma or LPS), both intra- and extracellular levels of BH4 increased significantly, with TNFalpha being the most potent single stimulus. Combined inflammatory cytokines synergized in the induction of an up to 600-fold increase of BH4 synthesis. Addition of LPS to the cytokine mixture led to a further increase of BH4 synthesis. Neopterin, a product of the first intermediate in BH4 biosynthesis, was also raised, but to a much lesser extent. The increase of BH4 synthesis was paralleled by an enhanced expression of isoform-1 (the only isoform coding for the active enzyme) of GTP cyclohydrolase I in cytokine treated cells. Our results show for the first time that BH4 biosynthesis is strongly induced by combinations of inflammatory stimuli in HUVSMC. The importance of BH4-dependent NO synthesis in HUVSMC needs, however, additional detailed studies.

Systemic Tetrahydrobiopterin (BH4) Levels and Coronary Artery Disease

Accessible online at: www.karger.com/journals/crd Dear Sir, The vascular endothelium has important secretory, metabolic, and immunologic functions. The impairment of such functions is an early step in the pathogenesis of several diseases including atherosclerosis [1], and endothelium-dependent vasodilation induced by nitric oxide (NO) is certainly a key function. Tetrahydrobiopterin (BH4) is intimately involved in NO-mediated vasomotion. The exact role of BH4 in NO catalysis remains debated, but may include stabilization of the active conformation of the enzyme, action as an allosteric effector enhancing substrate binding, coupling of substrate oxidation to NADPH consumption thereby reducing the ratio of superoxide to NO production, and posttranscriptional stabilization of NO synthase mRNA [2, 3]. In addition, BH4 is a potent antioxidant and scavenger of oxygen-derived free radicals [2, 4]. Impaired NO production and increased free radical formation have been observed in several diseases predisposing to atherosclerosis [4]. In states of BH4 depletion, endotheliumlocated NO synthase switches from NO to superoxide production. Thus, a local BH4 deficiency in endothelial cells may be of major importance in the pathogenesis of a dysfunctional endothelium as a mechanism of oxidative vascular injury [3]. This consideration is corroborated by several in vitro and Table 1. BH4 levels in 17 patients with normal coronary vessels and in 17 patients with 3-vessel disease

Severe mucitis after sublingual administration of tetrahydrobiopterin in a patient with tetrahydrobiopterin-responsive phenylketonuria

Tetrahydrobiopterin (BH4) is the cofactor for phenylalanine hydroxylase (PAH) and is essential to treat different forms of hyperphenylalaninaemia, i.e. patients with defects in the biosynthesis of BH4, but also in the PAH gene [1, 4,5]. Responsiveness of mutant PAH to BH4 administration relies on a chemical chaperon effect of BH4 preventing PAH from protein misfolding and inactivation [6], but several other mechanisms may also be involved [2]. Recently, we reported that sublingual administration of BH4 tablets in a single control person resulted in 58%–67% higher plasma BH4 concentrations than the usual oral route [3]. Drawbacks included rapid decomposition of tablets, acidic taste, and increased salivation. Since sublingual application could reduce therapy costs, orange flavoured artificially sweetened BH4 pastilles were tested on four healthy volunteers and a child with mild phenylketonuria (PKU). BH4 (Schircks, Switzerland) was administered to four healthy male volunteers (age 28–57 years) on 2 subsequent days either as tablets (50 mg) or pastilles (100 mg, containing 5 mg aspartame and orange aroma) with a 1 week wash-out between the two trials. Blood was collected before, and 1, 2, 3, and 4 h after administration. An 8-year-old patient with mild PKU (genotype P281L/R261Q) who was already on regular BH4 therapy was treated with BH4 pastilles (sublingually, 12 mg/kg/day; bid) in addition to P-AM 2 formula for 2 weeks. Written consensus was obtained from the family. In the four healthy male volunteers, total biopterin values before and up to 4 h after oral and sublingual administration were compared (Fig. 1A). No statistically significant difference between oral and sublingual administration was observed. Pterin concentrations increased after both oral and sublingual administration, reflecting instability of BH4 in blood. The ratio of pterin to cumulated biopterin and pterin ranged between 22.8% and 33.5%. Summing biopterin and pterin instead of total biopterin did not alter the ratio between oral and sublingual administration (data not shown). Changing from standard therapy to sublingual administration in a child with mild PKU resulted in almost unchanged plasma phenylalanine concentrations (Fig. 1B). After 2 weeks of twice daily sublingual BH4 administration, the patient complained of a painful prickling sensation at the tip of the tongue. He nevertheless continued the treatment for a further 10 days, moving the tablets in his mouth from one side to the other, which resulted in severe mucitis. His condition normalised rapidly upon discontinuation of the sublingual form. No mucitis appeared in healthy volunteers. A clinical trial with sublingual BH4 in a patient with mild PKU failed despite pharmacological effectiveness on blood phenylalanine levels because of an adverse pastille-related side-effect. Formulation of buffered tablets approaching neutral pH and further investigations on BH4 metabolism and pharmacokinetics are needed.