Miki Akino

Biopterin in human brain and urine from controls and parkinsonian patients: Application of a new radioimmunoassay

Total biopterin concentrations in the post-mortem human brain (caudate nucleus) and in the urine of controls and parkinsonian patients were measured by a newly developed radioimmunoassay. There was good correlation between the total biopterin level and tyrosine hydroxylase activity in the human brain. Biopterin concentrations in the caudate nucleus were greatly reduced in parkinsonian patients. In contrast, the reduction of urinary biopterin in parkinsonian patients was slight and not statistically significant, as compared with normal controls.

Radioimmunoassay for biopterin in body fluids and tissues

Specific antibodies against l-erythro-biopterin have been prepared in rabbits using the conjugates to bovine serum albumin. The antiserum against l-erythro-biopterin distinguished among l-erythro-tetrahydro- or 7,8-dihydro-biopterin, the other three stereoisomers of biopterin, d-erythro-neopterin, folic acid, and other synthetic pteridines. Using the specific antiserum against l-erythro-biopterin, a radioimmunoassay has been developed to measure the biopterin concentrations in urine, serum, cerebrospinal fluid, and tissues. The conjugate of l-erythro-biopterin with tyramine, 4-hydroxy-2-[2-(4-hydroxyphenyl)ethylamino]-6-(l-erythro-1,2-dihydroxypropyl)pteridine (BP-TYRA), was synthesized and labeled with 125I as the labeled ligand for the radioimmunoassay. BP-125I-TYRA had similar binding affinity as the natural l-erythro-biopterin and was thus permitted to establish a highly sensitive radioimmunoassay for biopterin. The limit of sensitivity of the radioimmunoassay with BP-125I-TYRA as labeled ligand was 0.5 pmol. The total concentration of biopterins, i.e., biopterin, 7,8-dihydro-, quinonoid dihydro and tetrahydrobiopterins, in the biological samples was obtained by iodine oxidation under acidic conditions prior to the radioimmunoassay, whereas iodine oxidation under alkaline conditions gave the concentration only of the former two. Biopterin in urine could be measured directly using 1 μl of urine, but a pretreatment with a small Dowex 50-H+ column was required for serum, cerebrospinal fluid, and brain tissues.

Nuclear magnetic resonance studies of some biologically active dihydropterins

Abstract An improved isolation method for biopterin and neopterin from natural sources is described. Crystalline dihydrobiopterin and dihydroneopterin were prepared by reduction with sodium dithionite and successive purification by column chromatography. The 7,8-dihydro structure of dihydrobiopterin and dihydroneopterin was established by comparing their nuclear magnetic resonance (NMR) spectra to those of authentic 7,8-dihydropteridines. The NMR spectrum of sepiapterin revealed that this compound also has the 7,8-dihydro configuration.

Dyspropterin, an intermediate formed from dihydroneopterin triphosphate in the biosynthetic pathway of tetrahydrobiopterin

The structure of dyspropterin, a new name given to an intermediate which is formed from dihydroneopterin triphosphate in the biosynthetic pathway of tetrahydrobiopterin, has been studied. Sepiapterin reductase (EC 1.1.1.153) was found to reduce dyspropterin to tetrahydrobiopterin in the presence of NADPH. Several lines of evidence showing the formation of tetrahydrobiopterin have been presented. Stoichiometric analysis revealed that there is a 1:2 relationship between the production of biopterin and the oxidation of NADPH during the reductase-catalyzed reduction of dyspropterin. The tetrahydrobiopterin production from dyspropterin was enhanced by dihydropteridine reductase (EC 1.6.99.7). Dyspropterin could also serve as a cofactor in phenylalanine hydroxylase (EC 1.14.16.1) system. These results are consistent with the view that dyspropterin is 6-(1,2-dioxopropyl)-5,6,7,8-tetrahydropterin. Based on our findings, the biosynthetic pathway of tetrahydrobiopterin from dihydroneopterin triphosphate has been discussed.

Radioimmunoassay for neopterin in body fluids and tissues

Specific antibodies against D-erythroneopterin have been prepared in rabbits using a conjugate of D-erythroneopterin to bovine serum albumin (D-erythroneopterinylcaproyl-bovine serum albumin). The antiserum distinguished D-erythroneopterin from other pteridines, i.e., three stereoisomers of neopterin, L-erythrobiopterin, folic acid, xanthopterin, and four other synthetic pteridines. Using this specific antiserum, a radioimmunoassay for D-erythroneopterin has been developed to measure the neopterin concentrations in urine and tissues. The conjugate of D-erythroneopterin with tyramine (NP-Tyra) was synthesized and labeled with 125I as the labeled ligand NP-[125I]tyra for the radioimmunoassay. The minimal detectable amount of neopterin was about 0.1 pmol. The concentration of total neopterin (neopterin, 7,8-dihydroneopterin, quinonoid dihydroneopterin, and tetrahydroneopterin) in the biological samples was obtained by iodine oxidation under acidic conditions prior to the radioimmunoassay, and that of neopterin plus 7,8-dihydroneopterin by oxidation under alkaline conditions. Total neopterin values in human urine obtained by this new radioimmunoassay showed a good agreement with those obtained by high-performance liquid chromatography with fluorescence detection. With rat tissue samples which contained very low concentrations of neopterin as compared to biopterin, biopterin was simultaneously determined by our previously reported radioimmunoassay, and neopterin values were corrected for the cross-reactivity (0.1%). The neopterin concentrations obtained by this method agreed with the values obtained by the radioimmunoassays for neopterin and biopterin after their separation by high-performance liquid chromatography. This very small amount of neopterin, as compared with biopterin, in rat tissues could not be determined by high-performance liquid chromatography-fluorometry alone due to the masking of the neopterin peak by a large biopterin peak.(ABSTRACT TRUNCATED AT 250 WORDS)

Synthesis of biopterin from dihydroneopterin triphosphate by rat tissues.

High performance liquid chromatography procedure for the analysis of pterins of biopterin synthesis from dihydroneopterin triphosphate via sepiapterin in rat tissues has been described. Sepiapterin-synthesizing enzyme 1, which catalyzes in the presence of Mg2+ the conversion of dihydroneopterin triphosphate to an intermediate designated compound X was assayed by determining pterin which is formed from compound X under acidic conditions. Sepiapterin- and biopterin-synthesizing activity were also assayed by determining sepiapterin and biopterin, respectively. Analytical results revealed the presence of these activities in most rat tissues examined and high levels were found in kidney, pineal gland and liver. Activities were also detectable in peripheral erythrocytes.

Effects of melanin on tyrosine hydroxylase and phenylalanine hydroxylase

Melanin inhibited rat liver phenylalanine hydroxylase, but activated tyrosine hydroxylase from rat brain (caudate nucleus), rat adrenal glands, and bovine adrenal medulla. Activation of tyrosine hydroxylase by melanin was demonstrated with the extensively dialyzed enzyme and in suboptimal concentrations of the substrate (tyrosine) and the cofactor (6-methyltetrahydropterin). Tyrosine hydroxylase from rat brain was activated by melanin more markedly than that from rat adrenal glands. Purified and extensively dialyzed bovine adrenal tyrosine hydroxylase had two Km values with 6-methyltetrahydropterin, depending upon its concentrations, but the melanin-activated tyrosine hydroxylase had a single Km value and showed the classical Michaelis-Menten kinetics.

A sensitive assay of GTP cyclohydrolase I activity in rat and human tissues using radioimmunoassay of neopterin

A highly sensitive and simple assay for the activity of GTP cyclohydrolase I (EC 3.5.4.16) was established using a newly developed radioimmunoassay. D-erythro-7,8-Dihydroneopterin triphosphate formed from GTP by GTP cyclohydrolase I was oxidized by iodine and dephosphorylated by alkaline phosphatase to D-erythro-neopterin, and quantified by a radioimmunoassay for D-erythro-neopterin. This method was highly sensitive and required only 0.2 mg of rat liver tissues for the measurement of the activity. It was reproducible and can be applied for the simultaneous assay of many samples. The activity of GTP cyclohydrolase I was measured in several rat tissues. For example, the enzyme activity in rat striatum (n = 5) was 13.7 +/- 1.5 pmol/mg protein per hour (mean +/- SE), and agreed well with those obtained by high-performance liquid chromatography with fluorescence detection. The activity in the autopsy human brains (caudate nucleus) was measured by this new method for the first time. The activity in the caudate nucleus from parkinsonian patients (n = 6) was 0.82 +/- 0.56 pmol/mg protein per hour which was significantly lower than the control value, 4.22 +/- 0.43 pmol/mg protein per hour (n = 10).

Occurrence of unconjugated pterins in a higher plant,Stizolobium hassjoo

3 unconjugated pterins, D-erythro-neopterin, 6-hydroxymethylpterin and isoxanthopterin, were isolated from the pericarps of a leguminous plant,Stizolobium hassjoo.

Biopterin in the Brain of Controls and Patients with Parkinson’s Disease and Related Striatal Degenerative Diseases: Application of New Biopterin Radioimmunoassay

We reported that tyrosine hydroxylase activity in the dopaminergic regions of nigro-striato-pallidal complex of the brain is greatly reduced (5–10% of controls) in all 12 cases of parkinsonian patients (Nagatsu, et al., 1977, 1979). The reduction in tyrosine hydroxylase activity in the parkinsonian brain was also reported by several groups (Lloyd, et al., 1975; McGeer and McGeer, 1976; Riederer, et al., 1979).