Glycine encephalopathy (nonketotic hyperglycinaemia) : review and update.

This article summarizes data and issues covered in the workshop on Glycine Encephalopathy using headings that cover important topics in our present knowledge of this disease.

Three novel deletions in the alanine:glyoxylate aminotransferase gene of three patients with type 1 hyperoxaluria.

We describe three novel deletions in the human AGT gene in three patients with primary hyperoxaluria type 1, an autosomal recessive disease resulting from a deficiency of the liver peroxisomal enzyme, alanine glyoxylate aminotransferase (AGT; EC 2.6.1.44). A deletion of 4 nucleotides in the exon 6/intron 6 splice junction (679-IVS6+2delAAgt) is expected to cause missplicing. It would also code for a K227E missense alteration in any mRNA successfully spliced. A 2-bp deletion in exon 11 (1125-1126del CG, cDNA) results in a frameshift. A deletion of at least 5-6 kb, EX1 EX5del, spanned exons 1-5 and contiguous upstream sequence. All three deletions are heterozygous with previously documented missense mutations; the intron 6 deletion with F152I, the exon 11 deletion with G82E, and EX1 EX5del with the common mistargeting mutation, G170R.

Nonketotic hyperglycinemia (glycine encephalopathy): laboratory diagnosis.

Nonketotic hyperglycinemia (NKH) is an autosomal recessive disorder of glycine metabolism caused by a defect in the glycine cleavage enzyme complex (GCS). GCS is a complex of four proteins encoded on four different chromosomes. In classical neonatal NKH, levels of cerebrospinal fluid (CSF) glycine and CSF/plasma glycine ratio are very high but the CSF results, in particular, may be more difficult to interpret in later-onset, milder, or otherwise atypical NKH. Enzymatic confirmation of NKH requires a liver sample. Delineation of which protein of the complex is defective is necessary to screen for mutations in the appropriate gene. Except for Finnish NKH patients, few recurrent mutations have yet been found, although analysis of the P-protein gene (the site of the defect in the majority of patients) is at an early stage. Prenatal diagnosis by GCS assay in chorionic villus biopsies is not completely reliable and will be replaced by molecular analysis in families where the mutations are known.

Recurrent mutations in P- and T-proteins of the glycine cleavage complex and a novel T-protein mutation (N145I): a strategy for the molecular investigation of patients with nonketotic hyperglycinemia (NKH).

Screening a DNA bank from 50 patients with enzymatic confirmation of their diagnosis of nonketotic hyperglycinemia gave allele frequencies of 5% for R515S of P-protein (glycine decarboxylase) and 7% for R320H of T-protein (aminomethyltransferase). In a previous report we found that 3% of the same patient alleles were positive for T-protein IVS7-1G>A. In total, testing for these three mutations identified 15% of alleles and positive results (one or two mutations) were found in 11 of the 50 patients. In addition, a novel point mutation in T-protein, N145I, was found in a single case and a PCR/restriction enzyme assay was developed for its detection.

Identification of the first reported splice site mutation (IVS7-1G-->A) in the aminomethyltransferase (T-protein) gene (AMT) of the glycine cleavage complex in 3 unrelated families with nonketotic hyperglycinemia.

A novel splice site mutation (IVS7-1G-->A) in the T-protein gene (aminomethyltransferase, or AMT) of the glycine cleavage enzyme complex was found in a patient with nonketotic hyperglycinemia (NKH). A PCR/restriction enzyme method to detect this mutation was used to screen 100 NKH alleles and identified the mutation in three unrelated families.

Biochemical and molecular investigations of patients with nonketotic hyperglycinemia.

The investigation of 14 unrelated patients with nonketotic hyperglycinemia led to the identification of mutations in 4 cases. Patients were initially categorized into probable P- or T-protein defects of the glycine cleavage enzyme complex, by the use of the glycine exchange assay without supplemental H-protein, then screened for mutations in the P-protein and T-protein genes, respectively.

Non-concordance of CVS and liver glycine cleavage enzyme in three families with non-ketotic hyperglycinaemia (NKH) leading to false negative prenatal diagnoses.

We report three false negative prenatal diagnostic results, using direct measurement of glycine cleavage enzyme activity in uncultured chorionic villus tissue from 290 pregnancies at risk for non-ketotic hyperglycinaemia (NKH). Testing was done by two centres: Vancouver, Canada and Lyon, France. One false negative result had activity near the lower limit of the normal range but two samples gave completely normal results well within the control range. All three pregnancies continued and the three children were born affected with NKH. Because of the first result, we now counsel that there is a grey zone of uninterpretable activity where affected and normal enzyme values overlap. Because of the other two results we now counsel that there is an approximately 1% chance of a pregnancy with a normal CVS activity resulting in an affected child. The clinical and biochemical findings in the three families are discussed.

Incidence of inborn errors of metabolism in British Columbia, 1969-1996.

OBJECTIVE: To determine how many children with specific types of inborn errors of metabolism are born each year in British Columbia, Canada. This population provides a relatively unique setting for collection of accurate and uniform incidence data because the diagnoses are all made through one laboratory in a population with universal access to government-funded medical care. METHODOLOGY: We used the records of the Biochemical Diseases Laboratory, Children's Hospital, Vancouver (the central referral point for all metabolic diagnoses in British Columbia) to identify all patients diagnosed with the metabolic diseases defined below. We obtained incidence figures by including only the children diagnosed with the diseases covered in this article who were confirmed as having been born within the province for the years 1969 to 1996. The diseases covered were diseases of amino acids, organic acids, the urea cycle, galactosemia, primary lactic acidoses, glycogen storage diseases, lysosomal storage diseases, and diseases involving specifically peroxisomal and mitochondrial respiratory chain dysfunction. Because the technology needed for diagnosis of specific disease groups was in place at different times our data for the different disease groups correspond to different time frames. We have also adjusted the time frames used to allow for the likelihood that some diseases may not come to medical attention for some time after birth. For instance the incidence of amino acid diseases was assessed throughout the whole of this time frame but the incidence of peroxisomal diseases was restricted to 1984 to 1996 because this was the time frame during which the technology needed for diagnosis was in place and reliable. Most disease group statistics included at least 400 000 births. RESULTS: The overall minimum incidence of the metabolic diseases surveyed in children born in British Columbia is approximately 40 cases per 100 000 live births. This includes phenylketonuria (PKU) and galactosemia which are detected by a newborn screening program. Metabolic diseases, which were not screened for at birth, ie, those with PKU and galactosemia subtracted from the total, have a minimal incidence of approximately 30 cases per 100 000 live births. This diagnostic dilemma group would present to pediatricians for diagnosis. Not all metabolic diseases have been surveyed and our data are restricted to the following metabolic disease groups. Approximately 24 children per 100 000 births (approximately 60% of the total disease groups surveyed) have a disease involving amino acids (including PKU), organic acids, primary lactic acidosis, galactosemia, or a urea cycle disease. These children all have metabolic diseases involving small molecules. Approximately 2.3 children per 100 000 births ( approximately 5%) have some form of glycogen storage disease. Approximately 8 per 100 000 births (20%) have a lysosomal storage disease; approximately 3 per 100 000 births (7%-8%) have a respiratory chain-based, mitochondrial disease and approximately 3 to 4 per 100 000 (7%-8%) of births have a peroxisomal disease. The diseases involving subcellular organelles represent approximately half of the diagnostic dilemma group. The incidence of each of the specific diseases diagnosed, including apparently rare diseases such as nonketotic hyperglycinemia, is to be found in the text. The metabolic diseases reported in this survey represent over 10% of the total number of single gene disorders in our population. CONCLUSIONS: Our data provide a good estimate of metabolic disease incidence, for the disease groups surveyed, in a predominantly Caucasian population. Incidence data for metabolic diseases are hard to collect because in very few centers are diagnoses centralized for a population with uniform access to modern health care and this has been the case for our population during the course of the study. (ABSTRACT TRUNCATED)

Atypical nonketotic hyperglycinemia with normal cerebrospinal fluid to plasma glycine ratio.

The diagnosis of nonketotic hyperglycinemia is considered to depend upon the presence of increased cerebrospinal fluid glycine and an increased cerebrospinal fluid to plasma glycine ratio. We studied two siblings who have the neurologic and peripheral biochemical features of the atypical variant of nonketotic hyperglycinemia but have normal cerebrospinal fluid glycine and cerebrospinal fluid to plasma glycine ratios. The proband had reduced liver glycine cleavage system activity of 17% and 21% of mean normal values, confirmed in two independent laboratories. Her lymphoblast glycine cleavage system activity was normal. Nonketotic hyperglycinemia can be present in the absence of increased cerebrospinal fluid glycine. Measurement of liver glycine cleavage system activity is indicated when nonketotic hyperglycinemia is suggested by clinical features and peripheral glycine levels but cerebrospinal fluid glycine is normal.

A protocol for detection of mitochondrial DNA deletions: characterization of a novel deletion.

OBJECTIVES: To develop a protocol capable of identifying deletions in mitochondrial DNA and use it to identify the breakpoints of a mtDNA deletion in a patient with chronic progressive external ophthalmoplegia (CPEO). DESIGN AND METHODS: Deletions in mtDNA were identified by a combination of long range PCR and Southern blotting. The precise breakpoints were determined by automated DNA sequencing. RESULTS: A series of DNA samples from patients with suspected mitochondrial disease was subjected to a protocol, which combines long range PCR and Southern blotting. We found a unique deletion in a patient with CPEO and we identified the precise location of this deletion through DNA sequencing. CONCLUSIONS: Long range PCR has the advantages of speed, minimal samples requirements, and sensitivity. Southern blotting is better able to evaluate heteroplasmy and detect duplications. We suggest a protocol that enables us to identify precisely the breakpoints in a unique mutation of mtDNA in a patient with CPEO.

Nonketotic hyperglycinemia: atypical clinical and biochemical manifestations.

A 16-year-old boy had intermittent chorea, delirium, and vertical gaze palsy precipitated by febrile illness. Nonketotic hyperglycinemia was confirmed by measurement of liver and lymphoblast glycine cleavage enzyme activity. Deficient but residual enzyme activity was demonstrated in both tissues, possibly accounting for the mild phenotype. Confirmation of an atypical variant of nonketotic hyperglycinemia with residual glycine cleavage enzyme activity has important implications for diagnosis and treatment.

The differential diagnosis of adult onset metachromatic leukodystrophy and early onset familial Alzheimer disease in an Alzheimer clinic population.

Clinical differentiation between forms of progressive dementia can prove difficult, particularly when relatively rare forms of dementia are involved. Factors such as family history of dementia, age at onset, presenting features such as personality change, cognitive deficits, psychiatric symptoms, and clinical course (progressive deterioration; retention of skills over time) may prove useful for directing investigations to identify underlying pathology and genetic implications. This is illustrated by two patient reports. Each patient had the onset of memory/behavioral problems at approximately age 40 years, was initially given a psychiatric, non-dementing diagnosis, and had a positive family history for early onset behavioral and memory problems. After longitudinal assessment, the diagnosis of Alzheimer disease was confirmed at autopsy in one patient and a diagnosis of familial, adult-onset metachromatic leukodystrophy in the other.

Prenatal diagnosis of non-ketotic hyperglycinaemia.

Non-ketotic hyperglycinaemia (NKH) is a devastating neurological disease for which there is no effective therapy. Consequently, most couples with a pregnancy known to be at risk for NKH request prenatal diagnosis. We have applied the combination of chorionic villus (CVS) assay for glycine cleavage enzyme activity and determination of amniotic fluid glycine concentration to increase the reliability of prenatal diagnosis for this disorder beyond that of each of these methods alone. All 15 of the at-risk pregnancies monitored had CVS glycine cleavage assay and five also had amniotic fluid glycine measurements. Two cases had no detectable cleavage activity in CVS and one gave uninterpretable enzyme results. Amniotic fluid glycine concentration was increased in all three and NKH was confirmed by abortus tissue assays for cleavage activity and amino acids. The remaining 12 case had activity in CVS (two also had normal amniotic fluid glycine levels) and delivered unaffected infants. Four of these 12 cases had cleavage activities below or at the low end of the normal range, perhaps indicating carrier status. We believe that the combination of CVS glycine cleavage assay and amniotic fluid glycine measurement is currently the best approach to the prenatal diagnosis of NKH.

Laboratory detection of metabolic disease.

This article describes the clinical signs, abnormal chemistry, histopathology, and biochemical tests that assist in the diagnosis of many inherited metabolic diseases. Small molecule diseases (for example, amino acid disorders, organic acidurias, and galactosemia) may present with acute illness and lead to unexplained death. Diagnosis of the specific enzyme defect may permit treatment by dietary changes or vitamin supplementation. Large molecule diseases are degenerative disorders due to storage of glycogen, glycoproteins, or mucopolysaccharides. Table 7 presents a compendium of laboratory investigations one should consider using when abnormalities are found in multiple organ systems. The investigation of a child with a mucopolysaccharidosis is used as an example of the use of this table. Investigating pediatricians should realize that many laboratory tests involved in the diagnosis of metabolic disease required special collection and handling by the laboratory.