Selective screening for amino acid disorders.

The analysis of amino acids is the most frequently applied technique in the selective screening of inborn errors of metabolism. When urine is used as a starting material, simple techniques such as thin-layer chromatography or high-voltage electrophoresis is preferred as a first approach. The quantitative analysis requires instrumentation, usually an amino acid analyser. Both plasma and urine are needed for establishing renal transport defects. Apart from the accumulation of the 'usual' amino acids, the presence of unusual amino acids may be of diagnostic significance. Furthermore the finding of decreased plasma concentrations of specific amino acids may pinpoint several inherited defects. No amino acid screening procedure is complete without the availability of an organic acid and a purine/pyrimidine analytical system, both yielding important additional diagnostic information. Considerable clinical problems may occur in subjects with a decreased tolerance to protein amino acids without being homozygous for any inherited defect. Examples of these disorders that need further studies are homocysteinaemia associated with vascular disease and carriers of ornithine transcarbamylase deficiency.

O-phosphohydroxylysinuria: a new inborn error of metabolism?

An abnormal ninhydrin positive compound was observed in the urine of two unrelated patients with neurological abnormalities. The compound was isolated by cation exchange followed by preparative paper chromatography and finally purified via cation exchange column chromatography. Its identification as O-phosphohydroxylysine resulted from FAB mass spectrometry and NMR spectroscopy. Chemical synthesis confirmed the structure. It was tentatively postulated that these patients had a defect of the metabolism of hydroxylysine, viz., a deficiency of the enzyme O-phosphohydroxylysine phospholyase.

Prenatal diagnosis of purine nucleoside phosphorylase deficiency in the first and second trimesters of pregnancy.

Prenatal diagnosis was performed in two successive pregnancies of a mother with a previous child with purine nucleoside phosphorylase (PNP) deficiency. In one pregnancy, an affected fetus was diagnosed in the 18th week of gestation after the demonstration of PNP deficiency in cultured amniotic fluid cells. Also an abnormal purine nucleoside profile was found in the amniotic fluid. The diagnosis of an affected fetus was confirmed by the analysis of cultured fetal skin fibroblasts and placental villi. The complete deficiency of PNP activity in placental villi confirms that the prenatal diagnosis of this disorder is possible by the direct investigation of chorionic villi. In the subsequent pregnancy, a heterozygous fetus was predicted in the tenth week of pregnancy by using chorionic villi.

Fast-atom bombardment tandem mass spectrometry of phosphohydroxylysine and related phosphohydroxy amino acids.

Phosphohydroxylysine a compound found in the urine of two patients with a possible inborn error of hydroxylysine metabolism, and related phosphohydroxycompounds were investigated with fast-atom bombardment tandem mass spectrometry techniques. This resulted in a reliable and quick identification method for phospho amino acids in general.

Diagnosis of inherited adenylosuccinase deficiency by thin-layer chromatography of urinary imidazoles and by automated cation exchange column chromatography of purines.

Patients with inherited adenylosuccinase deficiency excrete large quantities of succinyloaminoimidazolecarboxamide riboside (SAICAR) and succinyloadenosine (SAdo). A two-dimensional thin-layer chromatography method for the detection of SAICAR is described. The method consists of isolation of imidazoles with a cation exchange resin; TLC on cellulose plates, solvent I, isopropanol-ammonia 10% (4:1) and II, butanol-acetic acid-water (4:1:1); detection with Pauly reagent. SAICAR gives rise to an isolated spot with a characteristic bluish color. Also a simple one-dimensional thin-layer chromatography method using urine without any pretreatment for screening of high risk populations is given. Four new cases could be diagnosed. Clinical and chemical data, including concentrations of SAICAR and SAdo in urine, plasma and cerebrospinal fluid, determined by cation exchange column chromatography, are presented.

Detection of inherited adenylosuccinase deficiency by two dimensional thin layer chromatography of urinary imidazoles.

Patients with inherited adenylosuccinase deficiency excrete large quantities of succinyloaminoimidazolecarboxamide riboside (SAICAR) and succinyloadenosine (SAdo). A two dimensional thin layer chromatography method for the detection of SAICAR is described. The method consists of 1: isolation of imidazoles with a cation exchange resin; 2: tlc on cellulose plates, solvent I: isopropanol-ammonia 10% (4:1) and II: butanol-acetic acid-water (4:1:1); detection with Pauly reagent. SAICAR gives rise to an isolated spot with a characteristic bluish color. Also a simple one dimensional thin layer chromatography method for screening of high risk populations is given. Four new cases could be diagnosed. Clinical and chemical data, including concentrations of SAICAR and SAdo in urine, plasma and cerebrospinal fluid, determined by column chromatography, are presented.

Dihydropyrimidine dehydrogenase deficiency leading to thymine-uraciluria. An inborn error of pyrimidine metabolism.

Three unrelated patients with excessive thymine-uraciluria due to dihydropyrimidine dehydrogenase deficiency are described. Excretory values (mmol/g creatinine) were: uracil 2.0-10.5, thymine 2.3-7.5, 5-hydroxymethyluracil 0.2-0.9. Orally administered (index patient) uracil and thymine were excreted for the greater part whilst dihydrouracil and S-dihydrothymine were mainly metabolised. Dihydropyrimidine dehydrogenase activities (nmol X h-1 X mg-1 protein) in leucocytes were 0.04, 0.01 and less than 0.01 in the patients, 0.31-1.66 in their parents, and 1.01-4.46 in controls (n = 4). The patients presented with a non-specific clinical picture of cerebral dysfunction.

Azetidine-2-carboxylic acid contaminated dietary proline as a cause of urinary excretion of 4-amino-2-(S-cysteinyl)butyric acid in patients on oral treatment with a synthetic diet.

Three children with branched-chain ketoaciduria (maple syrup urine disease) were found to excrete an abnormal amino acid when they were on an artificial diet. This substance was identified as 4-amino-2-(S-cysteinyl)butyric acid with the use of column liquid chromatography, gas chromatography--mass spectrometry of various derivatives, and 360 MHz 1H-NMR spectroscopy. The same compound was detected in urine samples from subjects undergoing an oral loading test with L-proline. The chromatographic analysis of commercial proline from two sources indicated that one of the batches was contaminated (less than 1%) with L-azetidine-2-carboxylic acid (the homologue of proline with a four-membered ring). The latter compound is probably metabolized by the human via ring-opening and addition of a cysteine moiety. It is highly probable that the artificial diet given to the patients contained the impure proline and that the L-azetidine-2-carboxylic acid in the proline gave rise to the excretion of the 4-amino-2-(S-cysteinyl)butyric acid.

A case of formiminoglutamic aciduria. Clinical and biochemical studies.

We describe a boy who excreted massive amounts of formiminoglutamic acid and hydantoin-5-propionic acid in his urine. He was mildly mentally retarded and epileptic, whereas his twin-brother was completely normal. Loading with L-histidine enhanced the excretion of both metabolites. Treatment was attempted with high doses of folic acid and methionine, but both were without effect on the excretion levels.

2-Mercaptoethanesulfonate-cysteine disulfide excretion following the administration of 2-mercaptoethanesulfonate--a pitfall in the diagnosis of sulfite oxidase deficiency.

In the urine of a neonate with respiratory insufficiency and convulsions a positive sulfite reaction was found, which is suggestive of sulfite oxidase deficiency. The nitroprusside reaction also was positive. More detailed investigations showed that both tests were positive due to the administration of 2-mercaptoethanesulfonate, a mucolytic drug. The patient's urine contained an acidic amino acid with a column chromatographic behaviour like S-sulfocysteine. The high-voltage electrophoretic mobility was slightly different. This compound was isolated from the urine and identified as the mixed disulfide of 2-mercaptoethanesulfonate and cysteine. Its identity was proven with field desorption mass spectrometry, a technique which is suitable for the analysis of sulfonic acid derivatives.

Chromatographic determination and mass spectrometric identification of gamma-glutamylphenylalanine, a urinary constituent in phenylketonuria.

The occurrence of gamma-glutamylphenylalanine in the urine of patients with phenylketonuria could be demonstrated using chromatographic techniques and mass spectrometry. Concentrations ranged up to 35 mg/l. Only a weak correlation between the urinary excretion of this compound and phenylalanine was seen. The ages of the patients investigated ranged from 2 weeks to 18 years. The origin of the dipeptide is discussed.

Urinary excretion of orotic acid, orotidine and other pyrimidines in a patient with purine nucleoside phosphorylase deficiency.

Urinary orotidine and orotic acid have been determined in a patient with purine nucleoside phosphorylase (PNP) deficiency under various dietary therapeutic conditions. For this purpose a new procedure for the analysis of both compounds has been developed, consisting of prefractionation with Dowex 1X8, followed by two HPLC steps on a micro Bondapak NH2 and a micro Bondapak C18 column. With this method normal as well as slightly elevated excretions of orotic acid have been found in our patient. No evidence was obtained for inhibition of OPRT by purine (deoxy)nucleosides as a cause of pyrimidine starvation. A significant increase of urinary orotidine was found after loading with allopurinol. For comparison excretory values in a patient with ornithine transcarbamylase deficiency and also in a patient with orotic aciduria type I are shown. The possible cause of the slight increase in urinary orotic acid in our patient has been discussed.

Attempted dietary treatment of a boy with hyperammonemia due to ornithine transferase deficiency.

Dietary treatment of a male patient suffering from the delayed-onset type of OCT deficiency was attempted. Control of the hyperammonemia was attempted by restriction of protein intake, guided by monitoring the plasma ammonia and regular checking of the serum amino acid levels. The influence of supplementary citric acid or lactulose therapy on the plasma ammonia level was investigated and found to be negligible. The therapeutic effect of supplying ornithine and arginine (an essential amino acid in urea cycle disorders) is described. Despite intensive dietary treatment over two and a half years, a incorrigible hyperammonemic crisis resulted in the sudden death of our patient.

Two-dimensional thin-layer chromatography for the screening of disorders of purine and pyrimidine metabolism.

A method is presented for the two-dimensional thin-layer chromatographic screening of purines, pyrimidines and their nucleosides in the urine. Prior to chromatography, isolation of these substances from the urine is performed by anion-exchange column chromatography. Purines and pyramidines are quantitatively eluted with formic acid 0.01 M and 4 M respectively. The results of recovery and stability experiments are given. Normal excretory patterns are presented. Also results in patients with various diseases are shown: ornithine transcarbamylase deficiency, adenosine deaminase deficiency, purine nucleoside phosphorylase deficiency, adenine phosphoribosyltransferase deficiency, xanthine oxidase deficiency and hypoxanthine-guanine phosphoribosyltransferase deficiency. Finally the pattern of a patient on treatment with allopurinol is given.

Combined deficiency of xanthine oxidase and sulphite oxidase: a defect of molybdenum metabolism or transport?

A child is described who presented in the neonatal period with feeding difficulties, severe neurological abnormalities, lens dislocation of the eyes and dysmorphic symptoms of the head. Routine laboratory investigations revealed a decreased serum urate and a positive sulphite reaction of the urine. Subsequent chromatographic examinations showed xanthinuria and increased excretion of S-sulphocysteine and taurine to be present. In addition, high thiosulphate and low sulphate excretions in the urine were observed. Xanthine oxidase deficiency was demonstrated in a jejunal biopsy specimen, whereas the excretion of sulphur containing substances was considered to be characteristic of sulphite oxidase deficiency. This new combination of defects may be the result of malfunctioning of both enzymes, possibly caused by alterations in the essential molybdenum containing active centre of the enzymes, which they share in common.