Distinguishing primary from secondary Δ(4) -3-oxosteroid 5ß-reductase (SRD5B1, AKR1D1) deficiency by urinary steroid analysis.

OBJECTIVE: Deficiency of Δ(4) -3-oxosteroid 5ß-reductase (5ß-reductase), a bile acid synthesis disorder, presents findings of neonatal cholestasis and hyper-3-oxo-Δ(4) bile aciduria. The 5ß-reductase enzyme participates in not only bile acid synthesis but also hepatic steroid metabolism. Deficiency of 5ß-reductase includes 2 types: primary deficiency, with an SRD5B1 gene mutation; and secondary deficiency, lacking a mutation. Secondary deficiency is caused by fulminant liver failure from various aetiologies including neonatal hemochromatosis (NH). Distinguishing primary from secondary deficiency based on γ-glutamyltransferase (GGT), serum total bile acids (TBA), and urinary bile acid analysis using gas chromatography-mass spectroscopy (GC-MS) is very difficult. SRD5B1 gene analysis is the only reliable method. We examined urinary steroid analysis as a way to distinguish primary from secondary 5ß-reductase deficiency. DESIGN, PATIENTS AND MEASUREMENTS: We examined 12 patients with cholestatic jaundice, normal or slightly elevated GGT, and hyper-3-oxo-Δ(4) bile aciduria using urinary steroid analysis by GC-MS of both cortisol and cortisone compounds, such as 5ß-tetrahydrocortisol (5ß-THF) and 5ß-tetrahydrocortisone (5ß-THE). Patients previously were diagnosed with primary 5ß-reductase deficiency (n = 3), deficiency secondary to NH (n = 3) and deficiency secondary to other liver disorders (n = 6). RESULTS: Urinary steroid analysis in 3 primary deficiency and 3 NH patients showed low 5ß-THE and elevated 5α/5ß-THE ratios, making distinction difficult without also considering the clinical course and abdominal magnetic resonance imaging (MRI) findings, such as a very low signal intensity in liver and/or pancreas, especially in T2 -weighted images. In the six patients with other secondary deficiencies, urinary 5ß-THF and 5α/5ß-THF differed from those in primary deficiency (P < 0·05). CONCLUSIONS: Urinary steroid analysis can distinguish primary and NH-related deficiencies from other secondary deficiencies.

Neonatal cholestasis with increased 3ß-monohydroxy-Δ5 bile acids in serum and urine: not necessarily primary oxysterol 7α hydroxylase deficiency.

BACKGROUND: Inborn errors of bile acid synthesis are rare genetic disorders that can present with cholestatic liver disease. Recently we encountered 3 infants with neonatal cholestasis and excessive 3ß-monohydroxy-Δ5-C24 bile acids in serum and urine. We investigated whether identification of 3ß-hydroxy-5-cholestenoic acid and 27-hydroxycholesterol in serum and urine of cholestatic patients is necessary for diagnosis of primary oxysterol 7α-hydroxylase deficiency. METHODS: These 3 patients initially led us to suspected oxysterol 7α-hydroxylase deficiency. However, sequence analysis of genomic DNA resulted in diagnosis of 2 patients with oxysterol 7α-hydroxylase deficiency and 1 patient with 3ß-hydroxy-Δ5-C27-steroid dehydrogenase/isomerase deficiency. We examined identification of 3ß-hydroxy-5-cholestenoic acid and 27-hydroxycholesterol by gas chromatography-mass spectrometry after diagnosis. RESULTS: Interestingly, we detected a peak for 3ß-hydroxy-5-cholestenoic acid in serum and 27-hydroxycholesterol of the neutral sterol in urine from 2 patients who were diagnosed with primary oxysterol 7α-hydroxylase deficiency. CONCLUSION: In evaluating infants with cholestasis and excessive 3ß-monohydroxy-Δ5-C24 bile acids in infancy, one needs to conduct C24 bile acid analysis serially. Results can guide performance and interpretation of genomic DNA analysis. Moreover, identification of 3ß-hydroxy-5-cholestenoic acid in serum and 27-hydroxycholesterol in urine is highly important for diagnosis of oxysterol 7α-hydroxylase deficiency as is genomic DNA analysis.

Successful heterozygous living donor liver transplantation for an oxysterol 7α-hydroxylase deficiency in a Japanese patient.

Only 2 patients with an oxysterol 7α-hydroxylase deficiency caused by mutations of the cytochrome P450 7B1 (CYP7B1) gene have been reported; for both, the outcome was fatal. We describe the clinical and laboratory features, the hepatic and renal histological findings, and the results of bile acid and CYP7B1 gene analyses for a third patient. This Japanese infant presented with progressive cholestatic liver disease and underwent successful heterozygous living donor liver transplantation. Sources of relevant data included medical records, hepatic and renal histopathological findings, gas chromatography/mass spectrometry analyses of bile acids in serum and urine samples, and analyses of the CYP7B1 gene in the DNA of peripheral blood lymphocytes. Large excesses of 3ß-hydroxy-5-cholen-24-oic acid were detected in the patient's serum and urine. Cirrhosis and polycystic changes in the kidneys were documented. The demonstration of compound heterozygous mutations (R112X/R417C) of the CYP7B1 gene led to the diagnosis of an oxysterol 7α-hydroxylase deficiency. After liver transplantation with an allograft from a heterozygous living donor (the patient's mother), the features of decompensated hepatocellular failure abated, and the renal abnormalities were resolved. In conclusion, we report the first Japanese patient with an oxysterol 7α-hydroxylase deficiency associated with compound heterozygous mutations of the CYP7B1 gene; in this patient, liver transplantation with an allograft from a parental donor was effective.

Molecular genetic and bile acid profiles in two Japanese patients with 3beta-hydroxy-DELTA5-C27-steroid dehydrogenase/isomerase deficiency.

We report definitive diagnosis and effective chenodeoxycholic acid (CDCA) treatment of two Japanese children with 3[beta]-hydroxy-[DELTA]5-C27-steroid dehydrogenase/isomerase deficiency. Findings of cholestasis with normal serum [gamma]-glutamyltransferase activity and total bile acid concentration indicated the need for definitive bile acid analysis. Large amounts of 3[beta]-hydroxy-[DELTA]5 bile acids were detected by gas chromatography-mass spectrometry. HSD3B7 gene analysis using peripheral lymphocyte genomic DNA from the patients and their parents identified four novel mutations of the HSD3B7 gene in the patients. One had a homozygous mutation, 314delA; the other had compound heterozygous mutations: V132F, T149I, and 973_974insCCTGC. Interestingly, the second patient's mother had V132F and T149I mutations in one allele. Excessive 3[beta]-hydroxy-[DELTA]5-bile acids such as 3[beta],7[alpha]-dihydroxy- and 3[beta],7[alpha],12[alpha]-trihydroxy-5-cholenoic acids were detected in the first patient's urine; the second patient's urine contained large amounts of 3[beta]-hydroxy-5-cholenoic acid. Liver dysfunction in both patients decreased with ursodeoxycholic acid treatment, but unusual bile acids were still detected. Normalization of the patients' liver function and improvement of bile acid profiles occurred with CDCA treatment. Thus, we found mutations in the HSD3B7 gene accounting for autosomal recessive neonatal cholestasis caused by 3[beta]-hydroxy-[DELTA]5-C27-steroid dehydrogenase/isomerase deficiency. Early neonatal diagnosis permits initiation of CDCA treatment at this critical time, before the late cholestatic stage.

SRD5B1 gene analysis needed for the accurate diagnosis of primary 3-oxo-Delta4-steroid 5beta-reductase deficiency.

BACKGROUND AND AIM: We encounter hyper-3-oxo-Delta(4) bile aciduria in patients with severe cholestatic liver disease or fulminant liver failure during the neonatal period. However, simply by bile acid analysis, it is difficult to distinguish hyper-3-oxo-Delta(4) bile aciduria from primary 3-oxo-Delta(4)-steroid 5beta-reductase deficiency. METHODS: To determine whether 3-oxo-Delta(4)-steroid 5beta-reductase (SRD5B1) gene analysis is required for the accurate diagnosis of 3-oxo-Delta(4)-steroid 5beta-reductase deficiency, we evaluated the laboratory data, bile acid analysis and SRD5B1 gene analysis from six patients with hyper-3-oxo-Delta(4) bile aciduria. RESULTS: Based upon the results, four patients who had developed neonatal liver failure were diagnosed as having neonatal hemochromatosis. Two patients with chronic cholestasis were diagnosed as having primary 3-oxo-Delta(4)-steroid 5beta-reductase deficiency by SRD5B1 gene analysis. The SRD5B1 gene in these two patients had a heterozygous mutation, G737A (Gly 223 Glu) in one patient and C217T (Arg 50 stop) in the other. CONCLUSIONS: Based upon our limited data, we conclude that SDR5B1 gene analysis is required for the accurate diagnosis of 3-oxo-Delta(4)-steroid 5beta-reductase deficiency. Moreover, we think that it is important to elucidate whether there is a heterozygous or a compound heterozygous mutation of the SRD5B1 gene in our two patients.

Paternal transmission and slow elimination of mutant alleles associated with late-onset ornithine transcarbamylase deficiency in male patients.

In ten families with late-onset ornithine transcarbamylase (OTC) deficiency in male patients, three mutant alleles-R40H, R277W, and Y55D-were identified. In a total of 20 informative parent-offspring pairs, father-to-daughter transmission and mother-to-offspring transmission occurred in five (25%) and 15 (75%), respectively, indicating that paternal transmission contributes substantially to the pool of these mutant alleles. Relative reproductive fitness of males and females carrying the mutant alleles was calculated to be 0.49 and 0.89, respectively. Comparison of the life span of the mutant alleles, estimated on the basis of these fitness values with those associated with classic phenotype (neonatal onset) in which reproductive fitness of male patients was nil, revealed that mutant alleles associated with the late-onset phenotype were eliminated more slowly. This would allow the late-onset phenotype mutant alleles to be retained more frequently in a population than those associated with classic phenotype. Although heterozygous females carrying the late-onset phenotype mutant alleles were generally asymptomatic, one female carrying the R40H allele died after a hyperammonemic episode at the age of 18 years. Such heterozygous females should be alerted to possible hyperammonemic crisis.

Mitochondrial tRNA gene mutations in patients having mitochondrial disease with lactic acidosis.

Lactic acidosis has been associated with a variety of clinical conditions and can be due to mutation in nuclear or mitochondrial genes. We performed mutations screening of all mitochondrial tRNA genes in 44 patients who referred as hyperlactic acidosis. Patients showed heterogeneous phenotypes including Leigh disease in four, MELAS in six, unclassified mitochondrial myopathy in 10, cardiomyopathy in five, MERRF in one, pure lactic acidosis in six, and others in 12 including facio-scaplo-femoral muscular dystrophy (FSFD), familial cerebellar ataxia, recurrent Reye syndrome, cerebral palsy with mental retardation. We measured enzymatic activities of pyruvate dehydrogenase complex, and respiratory chain enzymes. All mitochondrial tRNA genes and known mutation of ATPase 6 were studied by single strand conformation polymorphism (SSCP), automated DNA sequence and PCR-RFLP methods. We have found one patient with PDHC deficiency and six patients with Complex I+IV deficiency, though the most of the patients showed subnormal to deficient state of respiratory chain enzyme activities. We have identified one of the nucleotide changes in 29 patients. Single nucleotide changes in mitochondrial tRNA genes are found in 27 patients and one in ATPase 6 gene in two patients. One of four pathogenic point mutations (A3243G, C3303T, A8348G, and T8993G) was identified in 12 patients who showed the phenotype of Leigh syndrome, MELAS, cardimyopathy and cerebral palsy with epilepsy. Seventeen patients have one of the normal polymorphisms in the mitochondrial tRNA gene reported before. SSCP and PCR-RFLP could detect the heteroplasmic condition when the percentage of mutant up to 5, however, it cannot be observed by direct sequencing method. It is important to screen the mtDNA mutation not only by direct sequence but also by PCR-RFLP and the other sensitive methods to detect the heroplasmy when lactic acidosis has been documented in the patients who are not fulfilled the criteria of mitochondrial disorders.

Increased mitochondrial processing intermediates associated with three tRNA(Leu(UUR)) gene mutations.

Accumulation of RNA 19 has been associated with mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes. We analyzed total RNA in muscle specimens from six patients who had one of three pathogenetic point mutations in the mitochondrial tRNA(Leu(UUR)) gene, including A3243G, T3271C, and T3303C. Mitochondrial processing intermediates were identified and quantitated by Northern blotting. The percentage of DNA with the mutation also was determined in each patient. The intermediate (RNA 19) was significantly increased in all patients. The proportion of mutation-carrying RNA in processing intermediates was always higher than in the DNA fraction, suggesting that these mutations may have dominant-negative effects on mitochondrial RNA processing events at the tRNA(Leu(UUR)) gene boundary.