Dwarfism and Low Insulin-like Growth Factor-1 Due to Dopamine Depletion in Pts/ Mice Rescued by Feeding Neurotransmitter Precursors and H4-biopterin*

Lina Elzaouk {ddagger}, Walter Leimbacher {ddagger}, Matteo Turri {ddagger} §, Birgit Ledermann ¶, Kurt Bürki ¶, Nenad Blau {ddagger} and Beat Thöny {ddagger} ||

From the {ddagger}Division of Clinical Chemistry and Biochemistry, Department of Pediatrics, Division of Animal Facility, University of Zürich, Steinwiesstrasse 75, CH-8032 Zurich, Switzerland

Received for publication, April 16, 2003 , and in revised form, May 5, 2003.


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
The tetrahydrobiopterin (BH4) cofactor is essential for the biosynthesis of catecholamines and serotonin and for nitric-oxide synthase (NOS). Alterations in BH4 metabolism are observed in various neurological and psychiatric diseases, and mutations in one of the human metabolic genes causes hyperphenylalaninemia and/or monoamine neurotransmitter deficiency. We report on a knockout mouse for the Pts gene, which codes for a BH4-biosynthetic enzyme. Homozygous Pts/ mice developed with normal morphology but died after birth. Upon daily oral administration of BH4 and neurotransmitter precursors the Pts/ mice eventually survived. However, at sexual maturity (6 weeks) the mice had only one-third of the normal body weight and were sexually immature. Biochemical analysis revealed no hyperphenylalaninemia, normal brain NOS activity, and almost normal serotonin levels, but brain dopamine was 3% of normal. Low dopamine leads to impaired food consumption as reflected by the severe growth deficiency and a 7-fold reduced serum insulin-like growth factor-1 (IGF-1). This is the first link shown between 6-pyruvoyltetrahydropterin synthase- or BH4-biosynthetic activity and IGF-1.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Tetrahydrobiopterin (BH4)1 plays a central essential role in metabolism, involving monoamine neurotransmitter biosynthesis, hepatic phenylalanine degradation, and nitric oxide (NO) production. The absolute requirement of BH4 for such enzymatic functions is reflected by severe disturbances or even lethality in the case of cofactor limitation due to mutations in BH4-metabolic genes. Patients with cofactor deficiency may exhibit severe dopamine and serotonin neurotransmitter deficiency, hyperphenylalaninemia, and reduced NO production (1, 2).

The BH4 cofactor is synthesized from guanosine triphosphate (GTP) by a set of reactions involving three enzymes. GTP cyclohydrolase I (GTPCH), the first enzyme in BH4 biosynthesis, catalyzes the formation of dihydroneopterin triphosphate from GTP (3). GTPCH activity is regulated by its substrate GTP, BH4, and phenylalanine. A physiological mechanism for post-translational control of GTPCH activity involves feedback inhibition by BH4. Notably, feedback inhibition results from BH4-induced complex formation of GTPCH with a regulatory protein known as GTPCH feedback regulatory protein (GFRP) (46). In the second step, the 6-pyruvoyltetrahydropterin synthase (PTPS) catalyzes the conversion of dihydroneopterin triphosphate to 6-pyruvoyltetrahydropterin. PTPS must be phosphorylated to be fully active (7, 8). Sepiapterin reductase (SR) is required for the final step reductions of the diketo intermediate, 6-pyruvoyl-tetrahydropterin to BH4.

BH4 is required as cofactor for phenylalanine hydroxylase (PAH), tyrosine hydroxylase, and tryptophan hydroxylase. The latter two are key enzymes in the biosynthesis of the neurotransmitters dopamine and serotonin (9). The complete hydroxylating system of aromatic amino acids consists of the two additional BH4-regenerating enzymes: pterin 4{alpha}-carbinolamine dehydratase and dihydropteridine reductase (DHPR) (10). BH4 is also required for the nitric oxide synthase enzymes (11).

A deficiency of phenylalanine catabolism, leading to hyperphenylalaninemia (HPA), comprises a heterogeneous group of disorders caused by a partial or complete deficiency of the hepatic apoenzyme PAH, or by one of the enzymes involved in cofactor biosynthesis (GTPCH or PTPS) (12, 13), or regeneration (DHPR and pterin 4{alpha}-carbinolamine dehydratase) (1416). Whereas severe HPA, leading to classic phenylketonuria, can only be treated with a low phenylalanine diet, patients with BH4-responsive PAH deficiency can be treated with BH4 alone (17). Two disorders of BH4 metabolism may present without HPA. These are dopa-responsive dystonia (Segawa disease) (18) and sepiapterin reductase deficiency (19, 20). Although dopa-responsive dystonia is caused by a mutation in the GTPCH gene and is inherited in an autosomal dominant manner, SR deficiency is an autosomal recessive trait. Both diseases manifest severe biogenic amine deficiencies.

To diagnose BH4 deficiencies and follow-up of the resulting pathologies, only limited possibilities are available, including measurements of metabolites in body fluids, and follow-up of the disease development almost exclusively under treated conditions. Diagnosis starts in most cases with screening of HPA with the Guthrie card and determination of plasma phenylalanine levels as an indirect measurement of hepatic phenylalanine hydroxylase (PAH) activity. Analysis of phenylalanine and tyrosine in serum or plasma before and after a BH4 challenge are often applied as an additional diagnostic tool for differentiation between classic phenylketonuria and biopterin variants. Furthermore, urinary pterin analysis and enzymatic measurements in erythrocytes or skin fibroblasts are carried out to gather information on biopterin-metabolizing enzymes. These data are then combined with a neurotransmitter status. For neurotransmitters, the dopamine and serotonin neurotransmitter degradation products homovanillic acid (HVA) and 5-hydroxyindoleacetic acid (5-HIAA), respectively, are measured in cerebrospinal fluid (CSF), thus following the activities of tyrosine and tryptophan hydroxylases. Furthermore, NO metabolites at least for brain nitric-oxide synthase (NOS) isoenzyme activity are determined in CSF.

Symptoms of BH4 deficiency include a vast range of abnormalities of the central nervous system, including microcephaly, seizures, hypertonia, hypersalivation, temperature instability, feeding difficulties, and mental retardation. The goals of treatment are to control HPA by dietary restriction of phenylalanine (in PAH deficiency) or BH4 administration (in GTPCH and PTPS deficiency) and to restore neurotransmitter homeostasis by oral administration of the dopamine and serotonin precursors L-dopa and 5-hydroxytryptophan, respectively, in BH4 deficiencies. Late detection and introduction of treatment leads to irreversible brain damage. For patients with BH4 deficiency, HPA is controllable with oral doses of 2–10 mg of synthetic BH4/kg/day. However, such relatively low doses of BH4 do not allow the cofactor to penetrate the blood-brain barrier efficiently (21, 22). To some extent, this problem can be overcome by administering higher doses of BH4, up to 20 mg/kg/day, together with corresponding neurotransmitter precursors (23). The combined therapy is mandatory to avoid neurological damage; however, this treatment is not sufficient in every case (24).

To analyze in more detail the consequences of BH4 deficiency and its treatment, and to study pathologies in the organism, the use of animal models is required. Here we report on the generation of an animal model for PTPS deficiency by knocking out the Pts gene in the mouse. This led to perinatal lethality of otherwise normal born animals. Treatment studies with daily oral administration of different concentrations of BH4, L-dopa, and 5-hydroxytryptophan for BH4 led to the observation that mice can be rescued but exhibit severe growth deficiency leading to dwarfism due to low serum insulin-like growth factor-1 (IGF-1).


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Pts Gene Targeting
A genomic clone containing the Pts gene encoding the mouse PTPS was isolated from a 129/Sv-{lambda} phage library and characterized previously (25). To construct a targeting vector, a KpnI-NcoI fragment, generated by PCR and spanning exon 1, and the first nine codons from exon 2 were used for the short arm of homology (Fig. 1A). Exon 2 of this fragment was ligated in-frame with an NcoI-BamHI fragment containing the prokaryotic lacZ gene, followed by a phosphoglycerate kinase promoter (Pgk)-neo cassette. A Pgk-tk cassette was added 5' to this short arm of homology. The long arm of homology was a 5.4-kb HindIII fragment containing exons 5 and 6 of the Pts gene. The final targeting vector, plasmid pMSY23, was linearized, electroporated into 129/Sv embryonic stem (ES) cells, and selected for G418 and FIAU (1(1,2-deoxy-2-fluoro-{beta}-D-arabinofuranosyl)-5-iodouracil) resistance as described previously (26). For PCR screening of ES clones, a nested PCR with two rounds of 40 cycles under standard amplification conditions with an annealing temperature of 55 °C was applied. For the first PCR, the 5' primer MSY69 annealed outside (upstream) of the short arm of homology, and the 3' primer PLACZ6 matched to the lacZ gene. For the second round of amplification, the 5' primer MSY70 was upstream of exon 1, and the 3' primer PLACZ7 again in the lacZ gene (MSY69: 5'-TATATGCCATCTCTGACTGACAACA-3'; MSY70: 5'-CTGTCTCTGGTTTGAGGAAGTCTCT-3'; PLACZ6: 5'-CAGTTTGAGGGGACGACGACAGTAT-3'; PLACZ7: 5'-TGCTGTTTCTGGTCTTCACCCACCG-3'). Upon additional confirmation of correct double cross-over by Southern blot analyses with an outside probe A (see Fig. 1C) or an internal probe B (not shown), positive Pts+/ ES cell sub-clones were used for injection into C57BL/6 blastocysts, generation of chimeras (derivatives of ES cell-subclone 7-E3), and breeding of homozygous Pts/ 129/Sv-C-57BL/6 hybrid mice. Screening of mouse tissue material (tail biopsies) was performed by a complex PCR with 40 cycles, 3 primers, and an annealing temperature of 53 °C. Primers were MSY107 (a), 5'-TGACTATGGGCAGAGTTGTT-3'; MSY108 (b), 5'-GATTGTTGCATTTCCCAAAC-3'; and PLACZ8 (c), 5'-GGCTCAGTTCGAGGTGCT-3' (see also Fig. 1B). {beta}-Galactosidase activity was determined with extracts from ES cells according to a published protocol (27).



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FIG. 1.
Targeted disruption of the murine Pts gene. A, genomic structure of the Pts wild-type allele containing the six exons, the targeting vector (pMSY23), and the expected targeted allele with the in-frame lacZ and the Pgk-neo insertion, replacing exons 3 and 4 plus most of exon 2. Position of the primers a–c for PCR analysis and probes for Southern analysis are indicated. E, EcoRI; H, HindIII. B, genetic analysis of F1-hybrid mice by multiplex PCR with genomic DNA as template and the three primers a–c: while primer a is upstream of exon 2 and thus present in wild-type and mutant alleles, primer b is specific for exon 2, and primer c is specific for lacZ. The multiplex PCR with primer pair a/b results in a DNA fragment of 315 bp and with primers a/c in 354 bp. C, Southern blot analyses of genomic DNA with either wild-type ES cell clone 129/Sv (wt) and the targeted ES cell clone (7-E3; hetero), or mouse tail DNA from wild-type, heterozygous or Pts-knockout mice. Genomic DNA was digested with EcoRI and hybridized with the 5'-external probe A. The endogenous wild-type fragment is 7.5 kb, whereas the targeted fragment is 6.4 kb in size.

 

Replacement Therapy
For an overview of concentrations of drugs used for treatments, see Table I. For the "low" treatment, tablets from Schircks Laboratories (Jona, Switzerland) containing 50 mg of BH4, 50 mg of ascorbic acid, and 25 mg of N-acetyl-L-cysteine were dissolved in 10 ml of H2O. For L-dopa, tablets containing 100 mg of levodopa and 25 mg of carbidopa (Sinemet MSD, Glattbrugg, Switzerland), and for 5-hydroxytryptophan, tablets containing 100 mg of oxitriptanum (Sigma-tau) were each dissolved in 20 ml of H2O. For the medium treatment, the following stock solution was prepared: 65 mg of BH4-2HCl, 50 mg of ascorbic acid, 10 mg of L-dopa, 6 mg of 5-hydroxytryptophan, 2.5 mg of carbidopa and 25 mg of N-acetyl-L-cysteine dissolved in 1 ml of H2O. For the high treatment, the following stock solution was prepared: 130 mg of BH4-2HCl, 100 mg of ascorbic acid, 10 mg of L-dopa, 6 mg of 5-hydroxytryptophan, 2.5 mg of carbidopa, and 50 mg of N-acetyl-L-cysteine dissolved in 1 ml of H2O. To determine the actual concentrations of BH4, L-dopa and 5-hydroxytryptophan, the dissolved compounds were analyzed by standard HPLC (see below). Aliquots were kept frozen, thawed before used, and buffered with sodium citrate to pH 5. The solutions were diluted with water and 10–20 µl were orally administered using yellow tips and a Gilson pipette. For the medium and high treatment protocols, the daily aliquots were divided into two daily doses.


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TABLE I
Treatment protocol for oral application of BH4 and neurotransmitter precursors

 

Preparation of Mouse Tissues
After scarifying the animals, brains and livers were withdrawn immediately for preparing tissue homogenates. Homogenizing buffer containing 50 mM Tris-HCl, pH 7.5, 0.1 M KCl, 1 mM EDTA, 1 mM dithiothreitol, 0.2 mM phenylmethylsulfonyl fluoride, 1 µM leupeptin, and 1 µM pepstatin was added to whole brain (4 µl/mg tissue), or liver (5 µl/mg tissue). Tissues were blended at 4 °C with an electric homogenizer (Kinematic GmbH, Littau-Luzern, Switzerland) and centrifuged at 15,000 x g for 20 min at 4 °C. Supernatants were kept frozen at –80 °C.

Neopterin, Biopterin, and Neurotransmitter Measurements
A volume of 50 µl of liver or 50 µl of brain tissue homogenates were adjusted to 100 µl and oxidized with 10 µl of oxidizing solution (5 g/liter iodine and 10 g/liter potassium iodide in 1 M HCl). After oxidation in the dark for 60 min, the reaction was stopped by adding 10 µl of freshly prepared ascorbic acid (20 g/liter). A total of 14 µl of 1 M NaOH was added to adjust the mixture to pH 8.5, followed by incubating with 20 µl of an alkaline phosphatase solution at 37 °C for 1 h (300 units/ml calf intestine alkaline phosphatase from Roche Applied Science in 0.1 M Tris-HCl, pH 8.0, 1 mM MgCl2, 0.1 mM ZnCl2). The mixture was adjusted to pH 2 by adding 5 µl of 2 M HCl and deproteinized through an Ultrafree-MC filter (Millipore). Neopterin and biopterin are measured from the filtrate by HPLC (28). The concentrations are expressed as picomoles per mg of protein. Monoamine neurotransmitters were determined according to a published method (46).

Enzymatic Assays
A volume of 100-µl tissue homogenates was desalted on a spin column (MicroSpinTM G-25 columns, Amersham Biosciences), and 100 µg of protein from the liver filtrate or 200 µg of protein from the brain filtrate was used for GTPCH and PTPS assays, respectively.

GTPCH Assay—A final volume of filtrate was adjusted to 50 µl and added to 148 µl of homogenizing buffer and 2 µl of 100 mM GTP (Roche Applied Science). This mixture was divided into two 100-µl portions. One portion was immediately oxidized as blank with cell extract, and the second portion was incubated for 60 min at 37 °C. The reaction was stopped by cooling the sample on ice and adding 10 µl of oxidizing solution (5 g/liter iodine and 10 g/liter potassium iodide in 1 M HCl). After oxidation in the dark for 60 min, the reaction was stopped by adding 10 µl of 20 g/liter ascorbic acid (freshly prepared). The mixture was adjusted to pH 8.5 by adding 14 µl of 1 M NaOH, and the sample was incubated with 20 µl of alkaline phosphatase solution at 37 °C for 1 h (300 units/ml calf intestine alkaline phosphatase (Roche Applied Science); see above). The mixture was adjusted to pH 2 by adding 5 µl of 2 M HCl and deproteinized through an Ultrafree-MC filter (Millipore). Neopterin was measured from the filtrate by HPLC. One unit of GTPCH produces 1 µmol of neopterin per minute at 37 °C.

PTPS Assay—A final volume of filtrate was adjusted to 50 µl and was added to 60 µl of reaction mixture (100 mM Tris-HCl, pH 7.4, 10 mM MgCl2, 1 mM NADPH, 1 mM NADH, 3 milliunits of SR, 140 milliunit of DHPR from Roche Applied Science, and 60 µmol/liter dihydroneopterin triphosphate) in a final volume of 110 µl. This mixture was divided into two portions, one 50-µl aliquot was incubated for 2 h at 37 °C, and another 50 µl was used as a blank. A blank without cell extract was incubated at the same time; it contained 50 µl of reaction buffer and 60 µl of reaction mixture. The reaction was stopped by adding 15 µl of 300 g/liter trichloroacetic acid for protein precipitation, and cooling on ice for at least 10 min, followed by oxidation with 10 µl of oxidizing solution (10 g/liter iodine and 10 g/liter potassium iodide in H2O) for 60 min in the dark. Excess iodine is destroyed by adding 15 µl of ascorbic acid (10 g/liter ascorbic acid in H2O). For the blanks, the same procedure was used. After 2 min of centrifugation at 15,000 x g, the supernatant was deproteinized through an Ultrafree-MC filter (Millipore) and analyzed by HPLC. One unit of PTPS produces 1 µmol of biopterin per minute at 37 °C.

NO Assay—The NO, which is the product of NOS, is extremely reactive and undergoes a series of reaction. Nitrite () and nitrate () are the final products. The sum of these two products (nitrite plus nitrate) was measured using a commercial Colorimetric assay kit (Cayman Chemical, Ann Arbor, MI). During this assay, nitrate was converted to nitrite utilizing nitrate reductase and measured by using the Griess reagent. Absorbance was read at 570/620 nm in a Micro-ELISA autoreader MR 530 (Dynatech, Chantilly, VA).

Phenylalanine Hydroxylase Assay—This assay was adapted from Ledley et al. (29). Liver homogenate containing 50–100 µg of total protein was used for PAH assay. For the blank, the appropriate amount of liver homogenate was adjusted to a final volume of 104 µl with water and incubated for 5 min in a 96 °C heating block. For the sample, the appropriate amount of liver homogenate was adjusted to a final volume of 77.5 µl with water. A volume of 22 µl of master mixture was added to each sample. The master mixture contained 0.6 mM phenylalanine, 3.6 units of catalase (Sigma), 0.15 M KCl in a 0.2 M potassium phosphate buffer, pH 6.8. After preincubation at room temperature, the reaction was started by adding 2 µl of 0.1 M dithiothreitol and 2 µl of 4.5 mM 6-methyltetrahydropterin (Schircks Laboratories) to the samples and incubated for 60 min at 25 °C. The reaction was stopped by incubation for 5 min in a 96 °C heating block and centrifuged for 5 min at 13,000 rpm. The supernatant was filtrated in an Ultrafree-MC filter device and centrifuged again at 5000 x g for 15 min. Phenylalanine and tyrosine were quantified with a standard amino acid analyzer (Biochrom 20 Plus, Amersham Biosciences).

Phenylalanine Concentration in the Blood
The blood from the mice was collected on filter paper cards (Guthrie card). Phenylalanine (and tyrosine) concentrations were measured using electrospray ionization tandem mass spectrometry.

Protein Measurement
Protein concentrations in homogenized tissues were determined by the spectrophotometric method described by Bradford, using {gamma}-globulin as a calibrator (30). The activities of the various enzymes are expressed as units per milligram of protein.

Immunoassays
Blood was collected from 35- and 44-day-old mice at the time animals were sacrificed.

Insulin-like Growth Factor-1—Serum IGF-1 was separated from clotted blood by centrifugation. It was measured after extraction with acid-ethanol (40 µl of serum and 160 µl of acid-ethanol). The mixture was incubated for 30 min at room temperature and centrifuged, and 100 µl of supernatant was diluted 1:6 before analysis. Serum IGF-1 was determined by radioimmunoassay (RIA) using a rat IGF-1 RIA kit (DSL-2900, Bühlmann Laboratories AG, Switzerland).

Growth Hormone—Serum GH was measured by RIA using a specific rabbit anti-rat antiserum and rat GH as standard. The rat GH RIA kit (AH R012) was obtained from Bühlmann Laboratories AG.

Blood Thyroxin—T4 was measured by fluoroimmunoassay using the mouse anti-thyroxine IgG as first antibody and the anti-mouse IgG as second antibody. The blood was dried on filter paper cards (Guthrie card). The total amount of T4 was determined in the test. The AutoDELFIATM neonatal thyroxine (T4) kit was obtained from PerkinElmer Life Sciences, Wallac-ADL AG (Switzerland).


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Targeted Deletion of the Mouse Pts Leads to Perinatal Death—A targeting construct was generated based on the previously isolated and characterized mouse gene structure Pts, encoding the 6-pyruvoyltetrahydropterin synthase (25). As shown in Fig. 1A, the pMSY32-targeting vector contained an in-frame lacZ gene fusion at exon 2 of the Pts gene, expressing a putative PTPS-{beta}-galactosidase fusion with 35 N-terminal amino acids from PTPS. Downstream of the lacZ gene, a Pgk-neo cassette was inserted in the opposite direction. Upon correct homologous recombination in ES cells, a putative mutant allele was generated with the lacZ and Pgk-neo inserted, and a deletion of exons 3 and 4, plus most of exon 2. The targeting frequency for correct double cross-over in the 129/Sv ES cells, as verified by PCR, was approximately 5% (not shown). These ES cells had a {beta}-galactosidase activity of 0.05–0.12 OD/mg (wild-type activity < 0.001 OD/mg) and a PTPS activity indistinguishable from wild-type (5.4–6.5 microunits/mg).

Upon PCR and Southern blot analyses (Fig. 1, B and C), a few Pts+/ ES cell clones were used for blastocyst injection and subsequent generation of PTPS-null mice. Homozygous mice developed with normal morphology in utero and were born at the expected Mendelian ratio (25% wild-type, 48% heterozygotes, 27% Pts-null mice; n = 159). However, most of the Pts/ mice died within the first hours after birth; at maximum we found 4 mice out of 26 surviving for 7 days. A more detailed analysis of brain development and fine structure of Pts/ mice is now in preparation.2 Southern blot analyses with genomic mouse tail DNA and a 5'-external probe (Fig. 1C), or an internal neo-probe (Probe B in Fig. 1A; results not shown) revealed correct homologous recombination at the single mouse Pts gene locus. As compiled in Table II, newborn knockout mice at day 1 had no PTPS (<0.05 microunit/mg) and normal GTPCH activity (0.1–0.3 microunit/mg). Heterozygous animals showed intermediate PTPS activity (1.5 microunit/mg) compared with normal activity in wild-type mice (8.0 microunits/mg). Liver neopterin was almost 200-fold higher than normal (59.0 pmol/mg in Pts/), and biopterin was only 4% of wild-type (0.9 pmol/mg). Furthermore, the Pts/ animals had hyperphenylalaninemia with blood values of 1352 µmol/liter phenylalanine (normal control levels were between 34 and 85 µmol/liter), and no detectable or very low brain dopamine and serotonin levels. Expression of {beta}-galactosidase was observed in heterozygous and homozygous Pts mutants (not shown). A more detailed study on developmental expression of the PTPS-LacZ fusion is now in preparation.2


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TABLE II
Mouse liver values for GTPCH and PTPS enzymes and their metabolites neopterin and biopterin

 

Treatment of Pts/ Mice Resulted in Rescue from Lethality but Severe Dwarfism—In the next step, we sought to rescue the knockout mice by applying a replacement therapy protocol based on the recommended standard concentrations for treatment of human PTPS patients (1). This included daily oral administration of BH4 to control blood phenylalanine and the neurotransmitter precursors L-dopa and 5-hydroxyptryptophan. Unexpectedly, we learned that, with this standard treatment protocol, Pts/ mice survived not longer than for about 3 weeks. We thus extended our treatment studies with three types of application levels (Table I; see also "Experimental Procedures"): standard or low treatment, a medium treatment with 2- to 5-fold higher concentrations of BH4 and neurotransmitter precursors, and a high treatment with roughly 3- to 10-fold higher concentrations. Each treatment group contained 7–14 control animals, i.e. wild-type or heterozygotes, and 3–6 Pts/ mice. The body weight of each animal was monitored daily and is depicted for each treatment group in Fig. 2.



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FIG. 2.
Growth behavior following BH4, L-dopa, and 5-hydroxytryptophan treatment of Pts/ and control mice. Growth curves of colonies with low (A), medium (B), and high (C) treatments are shown. Full lines are for Pts/ animals (3 in A, 5 in B, and 6 in C), whereas the dashed lines are for the wild-type or heterozygous animals (14 in A, 13 in B, and 7 in C). D, comparison of a 7-day-old Pts/ mouse with a heterozygous healthy littermate. Both animals were treated with the low dose. Details are described in the text.

 

As mentioned before, the Pts/ animals with the low treatment did not survive for more than 3 weeks. A similar situation was encountered with the medium treatment, where survival of the Pts/ animals was prolonged but they eventually died between day 31 and 40 after birth (at a certain point knockout animals had to be sacrificed due to progressively poor conditions and in agreement with the Rules and Guidelines for the Care and Use of Laboratory Animals of the State of Zurich). In contrast, all Pts/ animals with the high treatment survived and were in relatively good health conditions. The experiment was stopped after 6 weeks of treatment, where all animals were sacrificed for biochemical analysis (see below). As shown in Fig. 2(A–C), newborn mice regardless of the treatment mode gained weight without significant differences between genotypes for about 2 weeks and underwent pronounced growth retardation during week 3 (days 15–21). Only the Pts/ mice with low treatment seemed to be slightly different from their normal littermates, as they had reduced growth rate almost from birth (see low at day 3 in Fig. 3). This developmental difference in the low treatment group was even more pronounced later, as illustrated also in Fig. 2D, which shows a 7-day-old Pts/ animal in comparison with an age-matched heterozygous littermate. After the period of growth stagnation, the Pts/ animals stopped gaining weight independently of the treatment level, whereas all wild-type and heterozygous mice grew normally. The diminutive body size of Pts/ mice was best visible for those that survived due to high treatment, where the body weight was 34% of control at the age of 7 weeks (7.8 ± 1.5 g for Pts/ mice compared with 23.1 ± 2.4 g for combined controls; Fig. 3 medium and high at days 23, 31, and 44). Further qualitative characteristics of these otherwise healthy dwarf mice included reduced activity, hypersalivation, difficulty in swallowing, dystonia, tremor, and no signs of sexual maturation. Additional but less pronounced or steady characteristics were fair hair due to light pigmentation, hair loss, and hypothermia. In summary, treatment of Pts/ mice with BH4 and neurotransmitter precursors resulted in rescue from lethality but severe dwarfism.



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FIG. 3.
Statistical analysis of data points from growth curves with low, medium, and high treatment. Shown are mean values and standard deviations for animals with low treatment at days 3 and 23, medium treatment at days 3, 23, and 31, and high treatment at days 3, 23, 31, and 44 (ko, knockout; h, heterozygous; wt, wild-type). Significant difference is indicated by asterisks: *, p < 0.05; **, p < 0.01; ***, p < 0.005 (Student's t test).

 

Biochemical Analysis of Sacrificed Mice following Different Treatment Protocols—For enzymatic and metabolite analyses in liver, blood, and brain, all groups of treated mice were sacrificed at day 23 for low, day 31 for medium, and day 44 for high treatments. Liver analysis was also carried out with untreated mice at day 1 after birth (see above), whereas the limited brain material from newborns allowed us to measure only nitrite plus nitrate (compare with Tables II and III).


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TABLE III
Mouse brain values for GTPCH and PTPS enzymes and their metabolites, plus neurotransmitter and nitrite plus nitrate values

 

As expected, PTPS activity in liver and brain was completely abolished in the Pts-knockout mice and reduced to roughly 45% in heterozygous animals compared with wild-type. Furthermore, in liver and brain of phenotypically normal mice, i.e. wild-type and heterozygotes, PTPS activity increased with age. Independent of the treatment level, blood phenylalanine, and liver BH4 and GTPCH activity decreased in 23, 31, and 44-day-old knockout mice compared with controls. Low GTPCH activity in Pts/ mice was surprising, because it was expected that hyperphenylalaninemia and low BH4 levels, as observed in these mice, result in an increase of GTPCH activity via the stimulatory action of GFRP (6) (see also "Discussion").

Brain serotonin was severely lowered only in 23-day-old knockout mice with the low treatment, but ~50% of normal in knockouts with medium or high treatment. Instead, brain dopamine was not detectable in knockouts with the low treatment and also very low, between 3–11% of control, in the medium and high treatment. The brain metabolites for dopamine and serotonin, HVA and 5-HIAA, were only slightly reduced in Pts/ mice even under the high treatment conditions, with 52% of normal for HVA and 60% of normal for 5-HIAA (day 44 of treatment). Brain dihydroxyphenylacetic acid (DOPAC), which is the first degradation product of dopamine following the action of dopamine hydroxylase, was indistinguishable among knockout and wild-type or heterozygous animals from the medium and high treatment groups (between 30.2 and 67.9 pmol/mg; not shown).

The NOS activity in brain, as determined by measuring the sum of nitrate plus nitrite, revealed no difference among knockout and control animals and was independent of treatment levels. NOS activity in the brain of untreated Pts/ or normal mice at day 1 was severalfold higher compared with older animals but was also indistinguishable between the phenotypes (100.0–117.3 nmol/g of tissue at day 1).

The Pts/ knockout animals, independent of medium or high treatment conditions, exhibited extremely low dopamine and sub-optimal levels of BH4 and serotonin. Furthermore, the only metabolic difference we observed among these two treatment conditions, which eventually lead to the death of animals with only the medium treatment, was the intermediate HPA.

IGF-1 Is Severely Lowered in Rescued Pts/ Mice with Dwarfism—Because the phenotypic characteristics of the dwarf mice might be a consequence of abnormal feeding behavior due to low dopamine and/or of hormonal deregulation, we wondered whether the pituitary growth hormone (GH), the thyroid hormone thyroxin (T4), and the insulin-like growth factor-1 (IGF-1) in serum of knockout animals were reduced. As shown in Fig. 4, the serum IGF-1 levels in the knockout mice were reduced by a factor of 7 in comparison with age-matched controls (knockouts 79 ± 36 ng/ml; controls 541 ± 155 ng/ml). The expected sexual dimorphism between females (482 ± 170 ng/ml) and males (613 ± 113 ng/ml) is also clearly visible as published before (31). Furthermore, we also tested whether the pituitary-derived growth hormone (GH) and the thyroxin-stimulating hormone (TSH)-dependent thyroxin (T4) were also reduced in these animals. However, we found no change in GH and T4 (not shown), indicating that the pituitary gland is normally developed and thus not the primary reason for dwarfism in these treated Pts/ mice. Low IGF-1 might thus be the biochemical reason for the dwarfism, probably caused by the limiting brain dopamine, because abnormal feeding behavior was reported in dopamine-deficient mice (see "Discussion") (32).



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FIG. 4.
Serum IGF-1 levels for 44-day-old mice under high treatment. Mean values and standard deviations in nanograms/ml are shown for normal animals (wild-type and heterozygote; n = 9) and knockouts (n = 6). The first bar is IGF-1 for both sexes (f + m), whereas f is for females and m for males only.

 


    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Here we report on treatment studies with a BH4-deficient mouse that was generated by targeted disruption of the Pts locus that encodes the second enzyme in the BH4-biosynthetic pathway. This model was used to study the role of the cofactor in metabolism and treatment. The importance of BH4 for dopamine and serotonin production has been well established in patient studies, where treatment of cofactor deficiency by replacement with the precursors L-dopa and 5-hydroxytryptophan is required for neurotransmitter homeostasis and essential for survival (1). The observation that a complete knockout of BH4 biosynthesis in the mouse leads to a phenotype with perinatal death fits the expectations regarding the absolute requirement of a cofactor with central metabolic importance. The lack of biosynthetic activity for catecholamines, which includes dopamine and norepinephrine, and for serotonin must be one of the primary reasons for the perinatal death, because these neurotransmitters are essential for postnatal survival (33). However, in contrast to human patients, we were surprised to find that the mice died almost immediately after birth with no visible abnormalities, an observation that was also made by Sumi-Ichinose and co-workers, and published during the course of our study (34).

We found only a few knockout mice surviving for up to 7 days after birth, probably due to the BH4 present in mother's milk (35), while the amount of milk available is in turn dependent on the litter size and/or the mother's behavior. Data from ~250 PTPS patients, as compiled in the data base www.bh4.org, does not reveal perinatal lethality, and, although symptoms may be noted during the neonatal period, abnormalities develop typically during the first weeks of life (1). Furthermore, low birth weight and microcephaly, which are typical for PTPS deficiency in human newborns (36), were not observed in our mice. On the other hand, symptoms like hypersalivation and temperature instability are found in PTPS mice and human patients. Analysis of metabolites showed HPA and neopterin accumulation due to complete absence of PTPS activity, as expected (day 1, Table II). Brain metabolites at this age were only determined for NOS due to the limited material. However, monoamine neurotransmitters must be low as inferred from measurements of 23-day-old knockouts under low treatment that died despite initial treatment and had very low or not detectable brain serotonin and dopamine levels. Although BH4 has a central role for the function of the three NOS isoenzymes, i.e. vasorelaxation, immune response, and neurotransmission, no direct association with such pathologies in BH4-deficient patients has been made. Only recently, however, we found that patients revealed reduced NO metabolites in cerebrospinal fluids independent of treatment. Implications from this study are that, under BH4-deficient conditions NOS is uncoupled and produces by-products that are neurotoxic and thus responsible for neuronal cell pathology through peroxynitrite generation (2, 37, 38). Regarding the NOS activity in our mutant mouse presented here, we found no alterations in brain nitrate and nitrite levels, independently of treatment level or age (Table III). Also the mouse brain NOS activity was not reduced in untreated newborn knockouts, a phenomenon that may be explained by the fact that mother's milk contains high concentrations of BH4 and that all NOS have a low KD for BH4 binding compared with the aromatic amino acid hydroxylases (KD of 100–600 µM compared with KD of 0.2 µM for nNOS) (39). Despite lethality during the first days of life, which is not typical for BH4 deficiency in humans, we think that this Pts knockout is a suitable animal model for studying the pathophysiology and treatment of BH4 deficiency.

During the initial treatment study where the recommended concentration of compounds and precursors for the treatment of human patients was administered orally (low treatment), we learned that this therapy did not rescue the mice. Accordingly, we found no normalization of the metabolites that are followed today to control treatment in human patients, i.e. plasma phenylalanine, brain biopterin, HVA, and 5-HIAA (Tables II and III). Furthermore, brain dopamine and serotonin were extremely low in the knockout mice with low treatment. These neurotransmitters are below detection levels in human CSF and thus can not be determined in patients. A simple explanation for the requirement of higher doses of precursors and compounds for treatment may be the fact that mice have a much higher metabolic rate than humans. For instance, the enzymatic efficiency of PTPS is roughly ten times higher for the mouse compared with the human enzyme (kcat/Km of recombinant PTPS from mouse is 2.5 x 104 and from human 2.8 x 103) (25). This hypothesis was corroborated by the fact that we could eventually rescue the animals by increasing the treatment doses.

The biochemical parameters under high treatment conditions revealed that plasma phenylalanine was normalized, and biopterin was in the same range as in controls (Tables II and III). Serotonin and the neurotransmitter metabolites HVA and 5-HIAA were in the subnormal range (~50% of normal), whereas brain dopamine was unexpectedly low at 3% of normal (see below). Furthermore, plasma and brain neopterin remained elevated, and GTPCH was below normal activity, although hyperphenylalaninemia is expected to result in an increase of GTPCH activity. Moreover, under conditions of low BH4 levels, as in Pts/ mice with low treatment, stimulation of GTPCH by the GTPCH·GFRP complex was expected to be even more pronounced, because the inhibitory action of BH4 should also be diminished (4, 6). From the data presented here, we conclude that PTPS may have a direct or indirect effect on GTPCH expression or GTPCH·GFRP activity. Regarding hyperphenylalaninemia, increasing levels of oral BH4 lead to a gradually decrease of blood phenylalanine. Whereas the medium treatment exhibited an intermediate phenylalanine level, the high treatment conditions were required to completely normalize blood phenylalanine levels. A further observation that cannot be explained sufficiently at this point is that knockout animals under medium treatment consistently did not survive for more than 4 weeks, whereas under high treatment none of the mutants died. The only metabolic difference we observed between these two treatment procedures was the slightly elevated plasma phenylalanine levels in the animals treated with the medium dose (see Tables II and III). It is unlikely that a mild HPA has such a dramatic effect on growth and development, and additional treatment studies must be conducted to learn more about these differences.

The most remarkable observation made while treating the Pts/ mice was the consistently reduced growth starting almost from the first days of life, leading to dwarfism. Normal growth and development are largely programmed during the first weeks of postnatal life by the pituitary growth hormone (GH) and thyroxin-stimulating hormone (TSH) (40). Furthermore, somatic growth is mediated mainly by circulating IGF-I, an insulin-like hormone produced mainly in the liver but also in many other tissues. At least two examples of dwarf mice are well described: the so-called Ames and Snell dwarf mice with recessive mutations in the homeotic genes Pit-1 or Prop-1, respectively, with developmental arrest in pituitary ontogeny (40). Phenotypic characteristics are decreased growth rate post-weaning and reduced body size of adults, having approximately one-third of the weight of their normal siblings, similar to what we found in our Pts knockout mice. Further characteristics reminiscent of our dwarf mice include delayed puberty, reduction of body temperature, tendency to experience hair loss, and reduction in plasma IGF-1. This prompted us to determine these hormones in our treated mice. In contrast to the Ames and Snell dwarf mice, we found normal levels for the pituitary GH- and TSH-dependent T4, indicating that the pituitary gland developed normally and can thus be excluded as the primary reason for dwarfism of treated Pts/ mice. The IGF-1 level is influenced by GH but also by the nutritional status and food intake, which in turn is regulated by the dopamine and norepinephrine levels (4143). For instance, it was reported that a knockout mouse that does not express tyrosine hydroxylase was unable to initiate feeding, an ability that can be restored by gene delivery of tyrosine hydroxylase into the striatum (32, 33, 44, 45). As also mentioned before, we found that the brain serotonin, and the neurotransmitter metabolites HVA, DOPAC, and 5-HIAA, although slightly below normal, were not much different from control levels. This is in sharp contrast with the actual dopamine levels of 3% of normal in the brain of mice under high treatment. Furthermore, the DOPAC/dopamine ratio (and the HVA/dopamine ratio), which is an index of dopamine turnover rate, was 1.8 in the wild-type and heterozygous mice group under medium and high treatment, but was 48 in both knockout mice groups, presumably reflecting the high turnover of the small dopamine pool (not shown). The extremely low brain dopamine together with the wealth of literature on the feeding behavior in dopamine-deficient mice mentioned above supports the assumption that abnormal (hypothalamic) neurotransmission is associated in our mice with disturbance of eating behavior. Although we did not measure daily food or water intake, we consistently observed difficulties in swallowing in our knockout mice groups and conclude that control of appetite is compromised in the treated Pts/ mice, and thus chronic undernutrition is responsible for low IGF-1 and dwarfism. Such feeding difficulties have been described for BH4-deficient patients, but so far there was no indication of growth retardation or dwarfism. Nevertheless, we tested for IGF-1 in a first study with a very small group of BH4-deficient patients and found specifically reduced plasma IGF-1 levels in newborns with PTPS deficiency. Although these results are only preliminary, we believe it will be important to collect more data on IGF-1 levels and to follow growth and development in human patients with BH4 deficiency.


    FOOTNOTES
 
* This work was supported by the Rentenanstalt/Swiss Life, Stiftung für wissenschaftliche Forschung an der Universität Zürich, and the Swiss National Science Foundation (Grant 31-066953.01). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

§ Present address: European Patent Office, 80339 München, Germany. Back

|| To whom correspondence should be addressed. Tel.: 41-1-266-7622; Fax: 41-1-266-7169; E-mail: beat.thony{at}kispi.unizh.ch.

1 The abbreviations used are: BH4, tetrahydrobiopterin; NOS, nitricoxide synthase; GTPCH, GTP cyclohydrolase I; GFRP, GTPCH feedback regulatory protein; PTPS, 6-pyruvoyltetrahydropterin synthase; SR, sepiapterin reductase; PAH, phenylalanine hydroxylase; DHPR, dihydropteridine reductase; HPA, hyperphenylalaninemia; HVA, homovanillic acid; 5-HIAA, 5-hydroxyindoleacetic acid; CSF, cerebrospinal fluid; IGF-1, insulin-like growth factor-1; ES, embryonic stem; HPLC, high-performance liquid chromatography; RIA, radioimmuno-assay; GH, growth hormone; T4, thyroxine; DOPAC, dihydroxyphenylacetic acid; TSH, thyroxin-stimulating hormone; dopa, L-dihydroxyphenylalanine. Back

2 L. Elzaouk, W. Leimbacher, M. Turri, B. Ledermann, K. Bürki, N. Blau, and B. Thöny, manuscript in preparation. Back


    ACKNOWLEDGMENTS
 
We thank Dr. A. Biason-Lauber for helpful discussions, L. Kierat for HPLC analyses, Dr. O. Bodamer for performing mass spectrometry analysis on the Guthrie cards, Dr. T. Torresani for IGF-1 measurements with human samples, M. Killen for help with the preparation of the manuscript, and Prof. C. W. Heizmann for continuous support of this work. Financial support by the Rentenanstalt/Swiss Life, Stiftung für wissenschaftliche Forschung an der Universität Zürich, and the Swiss National Science Foundation is gratefully acknowledged.



    REFERENCES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 

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