OBJECTIVE: To analyze the clinical manifestation and genetic mutation of a child with tyrosinemia type I but without elevated succinylacetone. METHODS: Clinical data of the patient was collected. Tandem mass spectrometry and gas chromatography mass spectrometry were used to analyze the blood amino acid and urine organic acid component of the proband. DNA was extracted from the child and his parents and used for mutation analysis. RESULTS: The proband was of acute type, with features including hepatomegaly, jaundice, anemia and tendency of bleeding. Serum levels of Tyrosine, Methionine and Phenylalanine were 397.12 μmol/L, 896.16 μmol/L and 292.52 μmol/L, respectively, which all distinctly exceeded the normal levels. The level of phenyllactic acid and 4-hydroxyphenyl-lactic acid of proband's urine were 17.4 μmol/L and 417.0 μmol/L, respectively, which also exceeded the normal levels, but the level of succinylacetone was within the normal range. Compound heterozygous mutations of the FAH gene, namely c.634delT (p.L212Wfs*20) and c.455G>A (p.W152X), were detected in the proband, which were both predicted to be pathogenic and were inherited from her father and mother, respectively. CONCLUSION For children with tyrosinemia type I, detection of urine succinylacetone by gas phase mass spectrometry can be negative. The diagnosis of tyrosinemia type I must rely on genetic testing and/or enzymatic assaying.
DNA Mutational Analysis ; Female ; Genetic Testing ; Heptanoates ; Humans ; Male ; Tyrosinemias

OBJECTIVETo establish the diagnostic method of tyrosinemia type 1 and evaluate its value, the succinylacetone levels in the blood of suspected patients with tyrosinemia were tested by tandem mass spectrometry, and the succinylacetone in the urine was tested by gas chromatography-mass spectrometry.

METHODA total of 190 patients suspected of having tyrosinemia, were tested by tandem mass spectrometry for measurement of the level of succinylacetone in the blood, and detected by gas chromatography-mass spectrometry for measurement of the level of succinylacetone and organic acid in the urine. The method of measuring the level of succinylacetone in blood by tandem mass spectrometry as follows: After the diameter of 3 mm dry blood spots were punched into wells of 96-well plate, 100 µl 80% acetonitrile were added into each well, which contained hydrazine monohydrate and the internal standard of succinylacetone. The supernatant fluid were transferred to another 96-well plate and dried under heated nitrogen, after the plate was incubated for 30 min at 65°C. The residual hydrazine reagent was removed by addition of 100 µl methanol to each well and evaporated under heated nitrogen. The mobile phase (80% acetonitrile) was added to each well and 20 µl samples were tested by tandem mass spectrometry. The diagnostic terms were the clinical manifestation and the high level of succinylacetone in both blood and urine.

RESULTEleven patients were diagnosed as tyrosinemia type 1, with 9 males and 2 females. Their ages ranged from 2 months to 6 years. The succinylacetone levels in the blood of the patients were remarkably increased (7.26-31.09 µmol/L), with an average of (14.2 ± 7.8)µmol/L. Seven patients were tested for the level of succinylacetone in the urine by gas chromatography-mass spectrometry, and 4 were positive and 3 negative. Their tyrosine levels in the blood were 190-543 µmol/L(Normal: 20 - 100 µmol/L), with an average of (327.3 ± 125.8) µmol/L. All the patients presented the symptoms of hepatomegaly. Among them, 9 patients died and 2 patients were improved after treatment.

CONCLUSIONThe higher levels of succinylacetone in the blood or urine is a remarkable evidence for the diagnosis of tyrosinemia type 1. Determination of succinylacetone in the dry blood spots using tandem mass spectrometry was a good method for diagnosis of tyrosinemia type 1. To test succinylacetone in urine by gas chromatography-mass spectrometry may yield a false-negative result for tyrosinemia type 1.

Adolescent ; Child ; Child, Preschool ; Female ; Gas Chromatography-Mass Spectrometry ; Heptanoates ; blood ; urine ; Humans ; Infant ; Infant, Newborn ; Male ; Tandem Mass Spectrometry ; Tyrosinemias ; blood ; diagnosis ; urine

OBJECTIVETo investigate the clinical features and mutations of the FAH gene.

METHODClinical records of two cases were collected, and diagnosis was made according to the diagnostic criteria of the International Organization for Rare Disorders (NORD). Genomic DNA was extracted from peripheral blood leukocytes with QIAamp DNA Mini Kit. The DNA extracts were subjected to direct sequencing for 14 exons together with adjacent fragments of FAH gene using ABI Prism 3730 Genetic Analyzer (Applied Biosystems, Foster City, CA) after PCR based on genomic DNA. The mutation source was verified by analyzing parents' exons corresponding to patients' mutation exons. The homology between human FAH enzyme and that of other species was surveyed using software Clustal X(European Bioinformatics Institute, Hinxton, Saffron Walde, UK). Polyphen (Polymorphism Phenotyping), available online, were used to predict possible impact of an amino acid substitution on structure and function of FAH enzyme. Polyphen calculates position-specific independent counts (PISC) scores for two amino acid variants in polymorphic position. A PISC scores that differ by > 2 were regarded as indicating the probability of damaging variants.

RESULTPatient 1 was a 5 months and 21 days-old boy who suffered from persistent diarrhea, hepatomegaly, ascites; Alpha-fetoprotein > 1210 µg/L, levels of tyrosine in blood and succinylacetone in urine were 110.8 µmol/L and 83.7 µmol/L. His sister suffered from tyrosinemia type 1. Direct sequencing showed a G to A transition in CDS position 455 and 1027. He was compound heterozygous for the mutation c.455G > A/c.1027G > A, which predicts a change from tryptophan to a stop codon (TGG > TAG) at position 152 (W152X) and a change from glycine to arginine (GGG > AGG) at position 343 respectively. Patient 2 was a 6 year and 1 month-old girl with late-onset rickets who had signs of hepatosplenomegaly, rachitic rosary, windswept knees. Hypophosphatemia and alkaline phosphatase 1620 IU/L were detected. Alpha-fetoprotein 412.8 µg/L, levels of tyrosine in blood and succinylacetone in urine were 835.8 µmol/L and 27.48 µmol/L. Rickets did not improve after administration of calcium and vitamine D3. She is homozygous for the mutation c.1027G > A/c.1027G > A, which predicts G343R. The parents were mutation carriers. Analysis by Clustal X on the alignment of amino acids residual reservation among different species showed that the locative amino acid was highly conserved. Polyphen software predicted G343R was probably damaging (PISC score 3.235).

CONCLUSIONChildren with tyrosinemia type 1 can have manifestations of persistent diarrhea or late-onset rickets. Physical examination can reveal hepatosplenomegaly, laboratory tests indicate markedly elevated serum concentration of alpha-fetoprotein and alkaline phosphatase in plasma and succinylacetone in urine, other members in family may have tyrosinemias or parents are consanguineous. Mutations c.455G > A and c.1027G > A can be detected in FAH gene of Chinese children.

Amino Acid Sequence ; Base Sequence ; Child ; Child, Preschool ; DNA Mutational Analysis ; Diarrhea ; etiology ; genetics ; Exons ; Female ; Heptanoates ; urine ; Humans ; Hydrolases ; genetics ; Infant ; Male ; Mutation ; Pedigree ; Polymerase Chain Reaction ; Rickets ; etiology ; genetics ; Tyrosine ; blood ; Tyrosinemias ; complications ; diagnosis ; genetics ; pathology ; alpha-Fetoproteins ; analysis