GTP-cyclohydrolase I gene mutations in hereditary progressive and dopa-responsive dystonia

Recently, mutations of the GTP-cyclohydrolase I (GTP-CH I) gene, which catalyzes the first step in the tetrahydrobiopterin (BH₄) biosynthesis, were discovered in Japanese patients with hereditary progressive dystonial/dopa-responsive dystonia (HPD/DRD). However, it has not been confirmed that non-Japanese patients also contain mutations in the same gene, or whether these mutations are specific to HPD/DRD. In this study, two novel nonsense mutations in exon 1 of the GTP-CH I gene and a new mutation at the splice acceptor site of intron 1 were identified in an autopsied case of English-Irish descent and 2 Japanese patients with HPD/DRD. In the latter, cerebrospinal fluid (CSF) neopterin levels (which may reflect the GTP-CH I activity in the brain) were reduced to 18% and 37% of controls. A therapeutic trial of oral BH₄ was ineffective, however, in a genetically proven patient. In contrast, no mutations in any exons of the GTP-CH I gene were found in 2 patients with early-onset parkinsonism with dystonia (EOP-D) who developed dopa-responsive parkinsonism and dystonia at 6 and 8 years old, respectively. Neopterin levels in CSF were well preserved in 6 EOP-D patients. These data suggest that, among patients of different racial backgrounds, the pathogenesis of HPD/DRD, unlike EOP-D, involves partial reduction of the brain GTP-CH I activity consequent to mutations in the GTP-CH I gene. Measurement of CSF neopterin concentration may be useful for the differential diagnosis between HPD/DRD and EOP-D.     

Early-onset autosomal dominant GTP-cyclohydrolase I deficiency: Diagnostic delay and residual motor signs

ObjectiveAutosomal dominant (AD) guanosine triphosphate cyclohydrolase 1 (GCH1) deficiency is the most common cause of dopa-responsive dystonia (DRD). Patients with GCH1 deficiency are likely to experience diagnostic delay, but its consequences have not been described thoroughly in patients with early-onset disease. We describe the diagnostic delay and residual motor signs (RMS) observed in patients with early-onset (before 15 years of age) disease.MethodsTwelve patients with early-onset AD GCH1 deficiency from a single center were included in the case series analysis. For the meta-analysis, the PubMed database was searched for articles on early-onset AD GCH1 deficiency published from 1995 to 2019.ResultsIn the case series, the mean duration of diagnostic delay was 5.6 years. Two patients exhibited RMS, and four patients underwent orthopedic surgery. The literature search yielded 137 AD GCH1 deficiency cases for review; gait disturbance was reported in 92.7% of patients, diurnal fluctuation of symptoms in 91.9%, and RMS in 39%. The mean duration of diagnostic delay was 14.6 years overall: 12.0 years in RMS-negative patients and 21.2 years in RMS-positive patients.ConclusionsDiagnostic delay in early-onset AD GCH1 deficiency is more closely associated with later RMS. Early clinical suspicion, timely diagnosis, and levodopa treatment may reduce the occurrence of RMS in patients with early-onset AD GCH1 deficiency.     

Autosomal recessive spastic ataxia of Charlevoix-Saguenay: compound heterozygotes for nonsense mutations of the SACS gene

Mutations of the SACS gene have been reported in patients with autosomal recessive spastic ataxia of Charlevoix-Saguenay from Canada (Quebec), Tunisia, Japan, Turkey, Belgium, Italy, Spain, the Netherlands, and Germany. Features that distinguish autosomal recessive spastic ataxia of Charlevoix-Saguenay from other recessive ataxias include sensory motor polyneuropathy and hypermyelinated retinal nerve fibers. We describe the clinical, electrophysiological, and radiological features in 2 white American siblings diagnosed with autosomal recessive spastic ataxia of Charlevoix-Saguenay. The 2 affected children are compound heterozygotes for nonsense mutations of the SACS gene (c. 3484 G>T, p. E 1162 X; and c. 11,707 C>T, p. R 3903 X). We have measured allele-specific SACS mRNA abundance in peripheral blood and show that these specific mutant mRNAs are not degraded. We suggest that in children with early onset cerebellar ataxia and spasticity, ophthalmological examination and nerve conduction testing may guide genetic testing.     

Amantadine for levodopa-induced choreic dyskinesia in compound heterozygotes for GCH1 mutations.

Amantadine suppressed severe levodopa-induced choreic dyskinesia, which developed at initiation of levodopa therapy, in two siblings manifesting dystonia with motor delay phenotype of GTP cyclohydrolase I deficiency caused by compound heterozygous GCH1 mutations. Our finding suggests a beneficial effect of amantadine on this type of dyskinesia frequently observed in relatively severe dopamine-deficient metabolic disorders.     

Friedreich's ataxia: Point mutations and clinical presentation of compound heterozygotes

Friedreich's ataxia is the most common inherited ataxia. Ninety-six percent of patients are homozygous for GAA trinucleotide repeat expansions in the first intron of the frataxin gene. The remaining cases are compound heterozygotes for a GAA expansion and a frataxin point mutation. We report here the identification of 10 novel frataxin point mutations, and the detection of a previously described mutation (G130V) in two additional families. Most truncating mutations were in exon 1. All missense mutations were in the last three exons coding for the mature frataxin protein. The clinical features of 25 patients with identified frataxin point mutations were compared with those of 196 patients homozygous for the GAA expansion. A similar phenotype resulted from truncating mutations and from missense mutations in the carboxy-terminal half of mature frataxin, suggesting that they cause a comparable loss of function. In contrast, the only two missense mutations located in the amino-terminal half of mature frataxin (D122Y and G130V) cause an atypical and milder clinical presentation (early-onset spastic gait with slow disease progression, absence of dysarthria, retained or brisk tendon reflexes, and mild or no cerebellar ataxia), suggesting that they only partially affect frataxin function. The incidence of optic disk pallor was higher in compound heterozygotes than in expansion homozygotes, which might correlate with a very low residual level of normal frataxin produced from the expanded allele. Ann Neurol 1999;45:200–206     

Sporadic ALS with compound heterozygous mutations in the SQSTM1 gene

Accumulating evidence suggests that heterozygous mutations in the SQSTM1 gene, which encodes p62 protein, are associated with amyotrophic lateral sclerosis (ALS). Here, we report a Japanese patient with sporadic, late-onset ALS who harbored compound heterozygous SQSTM1 mutations (p.[Val90Met];[Val153Ile]). Autopsy examination revealed that although TDP-43 pathology was rather widespread, the selective occurrence of p62-positive/TDP-43-negative cytoplasmic inclusions in the lower motor neurons (LMNs) was a characteristic feature. No Bunina bodies were found. Ultrastructurally, p62-positive cytoplasmic inclusions observed in the spinal anterior horn cells were composed of aggregates of ribosome-like granules and intermingled bundles of filamentous structures. Another feature of interest was concomitant Lewy body pathology. The occurrence of distinct p62 pathology in the LMNs in this patient indicates the pathogenic role of SQSTM1 mutations in the development of a subset of ALS.     

Hyperekplexia phenotype due to compound heterozygosity for GLRA1 gene mutations.

Hyperekplexia (MIM 149400), or startle disease, is a neurological disorder characterized by generalized stiffness during the neonatal period, excessive startle reflexes, and generalized stiffness related to the startle response. Linkage analysis mapped a major gene for this disorder to chromosome 5q33-35. Subsequently, mutations in the GLRA1 gene, encoding the alpha1 subunit of the glycine receptor, were found in hyperekplexia families with an autosomal dominant or recessive inheritance pattern. In the present study, we describe the genetic analysis of the GLRA1 gene of a family consisting of 2 children with hyperekplexia, 2 nonaffected children, and their healthy nonconsanguineous parents. Although the pedigree suggested the presence of a recessive mutation, haplotype construction showed that the 2 affected children shared the same haplotype combination in which the maternal haplotype differed from the paternal haplotype, suggesting the presence of compound heterozygosity. Mutation analysis revealed different missense mutations on the two haplotypes, changing an arginine to a histidine at amino acid positions 252 and 392, respectively. It is interesting that the hyperekplexia phenotype was only seen in individuals compound heterozygous for the two mutations, whereas family members carrying either one of the two mutations had no clinical signs.     

Two compound frame-shift mutations in succinate dehydrogenase gene of a Chinese boy with encephalopathy

Objective: To investigate respiratory chain complex II deficiency resulted from mutation in succinate dehydrogenase gene (SDH) encoding complex II subunits in China. Methods: An 11-year-old boy was admitted to our hospital. He had a history of progressive psychomotor regression and weakness since the age of 4 years. His cranial magnetic resonance imaging revealed focal, bilaterally symmetrical lesions in the basal ganglia and thalamus, indicating mitochondrial encephalopathy. The activities of mitochondrial respiratory chain enzymes I−V in peripheral leukocytes were determined via spectrophotometry. Mitochondrial DNA and the succinate dehydrogenase A (SDHA) gene were analyzed by direct sequencing. Results: Complex II activity in the leukocytes had decreased to 33.07 nmol/min/mg mitochondrial protein (normal control 71.8 ± 12.9); the activities of complexes I, III, IV and V were normal. The entire sequence of the mitochondrial DNA was normal. The SDHA gene showed two heterozygous frame-shift mutations: c.G117G/del in exon 2 and c.T220T/insT in exon 3, which resulted in stop codons at residues 56 and 81, respectively. Conclusions: We have described the first Chinese case of mitochondrial respiratory chain complex II deficiency, which was diagnosed using enzyme assays and gene analysis. Two novel, compound, frame-shift mutations, c.G117G/del in exon 2 and c.T220T/insT in exon 3 of the SDHA gene, were found in our patient.     

Juvenile-onset spinal muscular atrophy caused by compound heterozygosity for mutations in the HEXA gene

Progressive proximal muscle weakness is present both in spinal muscular atrophy (SMA) type III (Kugelberg-Welander disease) and in GM₂ gangliosidosis, diseases that segregate in an autosomal recessive fashion. The SMN gene for SMA and the HEXA gene for GM₂ gangliosidosis were investigated in a woman with progressive proximal muscle weakness, long believed to be SMA type III (Kugelberg-Welander type). She and her family underwent biochemical studies for GM₂ gangliosidosis. Analysis of SMN excluded SMA. Biochemical studies on GM₂ gangliosidosis showed deficiency in hexosaminidase A activity and increased GM₂ ganglioside accumulation in the patient's fibroblasts. The HEXA gene was first analyzed for the Gly²⁶⁹→Ser mutation characteristic for adult GM₂ gangliosidosis. Since the patient was carrying the adult mutation heterozygously, all 14 exons and adjacent intron sequences were analyzed. A novel mutation in exon 1 resulting in an A-to-T change in the initiation codon (ATG to TTG) was identified. The adult patient is a compound heterozygote, with each allele containing a different mutation. Although mRNA was transcribed from the novel mutant allele, expression experiments showed no enzyme activity, suggesting that neither the TTG nor an alternative codon serve as an initiation codon in the HEXA gene.     

Novel compound heterozygous MCOLN1 mutations identified in a Japanese girl with severe developmental delay and thin corpus callosum

Mucolipidosis type IV (MLIV) is a rare lysosomal storage disorder causing severe psychomotor developmental delay and progressive visual impairment. MLIV is an autosomal recessive disease caused by mutations in MCOLN1, which encodes for mucolipin-1. Here, we report a case of a 4-year-old Japanese girl with severe intellectual disability and motor deficits. Brain magnetic resonance imaging showed signal abnormalities in the white matter and thinning of the corpus callosum. Whole-exome sequencing was performed on the proband and her parents, and novel compound heterozygous mutations at c.936_938del (p.Phe313del) and c.1503dupC (p.Ile502Hisfs*106) in MCOLN1 (NM_020533.2) were identified in the proband. Additional biochemical examinations revealed elevated serum gastrin level and iron deficiency anemia, leading to the diagnosis of MLIV. More reports of such pathogenic mutations are expected to broaden the understanding of the channel function of mucolipin-1 and genotype-phenotype correlations.     

Early-onset ataxia with ocular motor apraxia and hypoalbuminemia: the aprataxin gene mutations

BACKGROUND: Early-onset ataxia with hypoalbuminemia is regarded as a variant form of Friedreich ataxia in Japan. Early-onset ataxia with hypoalbuminemia and ataxia with ocular motor apraxia have been considered as the same clinical entity because of the recent identification of a common mutation in the aprataxin gene. A new clinical entity named early-onset ataxia with ocular motor apraxia and hypoalbuminemia (EAOH) has been proposed to explain these two diseases. OBJECTIVE: To disclose the clinical features of EAOH and to identify the mutations in the aprataxin gene in six patients in four Japanese families with EAOH. METHODS: The clinical features, laboratory findings, sural nerve biopsy results, and brain MRI or CT findings for these patients were evaluated, and molecular analysis was performed, which involved sequencing of the aprataxin gene directly or use of the subcloning method. RESULTS: Cerebellar ataxia and peripheral neuropathy were noted in all six patients. Ocular motor apraxia was observed in five patients; two of these patients had obvious head thrust. Choreiform movements of the limbs and mental deterioration were observed in five patients. Although foot deformity was noted in five patients, kyphoscoliosis was noted only in one patient. In all patients, hypoalbuminemia and hypercholesterolemia were evident, and brain MRI or CT showed marked cerebellar atrophy. Nerve biopsy revealed depletion of large myelinated fibers in three of the five patients examined. Molecular analysis of the aprataxin gene revealed an insertion mutation (insT at nt167) and two missense mutations (A-to-G transition at nt80 and C-to-T transition at nt95, the former being novel). CONCLUSION: We found clinical heterogeneity in the patients with EAOH in this study. With the disease course, the choreiform movements tended to reduce in degree, and hypoalbuminemia became evident. Molecular analysis identified one insertion and two missense mutations including a novel missense one, which was located at a highly conserved amino acid residue in the aprataxin gene product.     

Pediatric macrophagic myofasciitis associated with motor delay

BACKGROUND: Macrophagic myofasciitis (MMF) is a rare inflammatory myopathy characterized by accumulation of perifascicular macrophages without muscle fiber necrosis. Few sporadic pediatric cases have been described, and MMF is recognized as a possible reaction to intramuscular injections of aluminum-containing vaccines. The association of MMF and motor delay is unclear in the pediatric population. We report the clinical evaluation and follow-up of 4 young children with MMF and review of 4 cases previously reported of sporadic, pediatric MMF to better determine the possible association of sporadic MMF in children presenting with motor delay. PATIENTS AND METHODS: Described our 4 case reports in which we observed children presenting for evaluation of motor delay with unrevealing clinical and laboratory evaluations for common causes of motor delay and histopathological evaluations consistent with macrophagic myofasciitis. Muscle data was obtained by quadriceps muscle biopsy. RESULTS: Clinical presentations were similar in all children and were characterized by motor delay, hypotonia, and failure to thrive with an unrevealing evaluation for central nervous system disease, congenital, and mitochondrial myopathies. CONCLUSIONS: Our cases and those previously reported in the literature demonstrate MMF should be considered in the evaluation of children with failure to thrive, hypotonia, and muscle weakness, as clinical outcome appears to be favorable.     

Early recognition of heterozygotes for the gene for dystrophia myotonica

A study has been performed on 124 first degree relatives of 38 index patients with dystrophia myotonica in order to assess means of detecting heterozygotes before neurological complaints. Some or all of the following tests have been performed on the relatives: clinical examination, electromyography, slit-lamp examination, radiography of the skull, electrocardiography, serum insulin, and serum immunoglobulin levels. There is evidence that abnormalities in symptomless heterozygotes may be detected by slit-lamp examination, electromyography, and immunoglobulin concentration, and this is probably the order of usefulness of the test in early recognition of the disease. In this study 13 previously undetected heterozygotes have been identified: six as a result of neurological examination, four by both electromyography and slit-lamp examination, and three by slit-lamp examination alone. Abnormalities detected by these tests appear to be independently manifest, so that they will probably be more useful in combination than singly. The family data give a maximum estimate for incidence of mutations among index cases of one quarter, lower than previously suggested. The estimation of immunoglobulins in 45 patients showed significant deficiency, as compared with controls, not only of IgG but also of IgM, and there was an insignificant trend for IgA to be low too. This suggests that the abnormally rapid catabolism of immunoglobulin, previously reported, is not specific for IgG.