Identification of a Missense Variant in the EIF2B3 Gene Causing Vanishing White Matter Disease with Antenatal-Onset but Mild Symptoms and Long-Term Survival.

Vanishing white matter disease (VWM) is a rare autosomal recessive leukodystrophy caused by a mutation in any of the five gene encoding subunits of the translation initiation factors eIF2B1 to eIF2B5. Whole-exome sequencing was performed on a 7-year-old boy with prenatal symptoms, including intrauterine-growth retardation, decreased movements, and oligohydramnios as well as mild intellectual disability, optic atrophy, macrocephaly, mild ataxia, and white matter lesions after birth. Analysis of WES data revealed a homozygous missense variant, c.C590T (p.Thr197Met) in the EIF2B3 gene (NM_0203650). The candidate variant was confirmed by Sanger sequencing and found to co-segregate with disease in family members. Pathogenicity analysis, 3D protein modeling, and stability assessment showed the deleterious effects of this nucleotide change. Previous studies suggest a direct relationship between the onset of symptoms and the progression rate and severity of the disease. All described cases of EIF2B deficiency with antenatal-onset led prenatal death; if they were born, they experienced clinical exacerbation, seizure, severe encephalopathy, and consequent infantile death (< 1 year). The patient of this study had never had seizure, which could be a potential explanation for the observed mild clinical picture, chronic state, and long-term survival until the age of seven. This study reported the first VWM due to EIF2B gene deficiency with antenatal-onset but mild symptoms and long-term survival. The result of this study showed that stressor factors, particularly seizure, could have a substantial role in poor prognosis and early neonatal death.

Homozygous TFG gene variants expanding the mutational and clinical spectrum of hereditary spastic paraplegia 57 and a review of literature.

In recent years, the tropomyosin-receptor kinase fused gene (TFG) has been linked to diverse hereditary neurodegenerative disorders, including a very rare complex hereditary spastic paraplegia, named spastic paraplegia type 57 (SPG57). Until now, four pathogenic homozygous variants of the TFG gene have been reported associated with SPG57. Two consanguineous Iranian families (1 and 2), the first one with two affected members and the second one with one, all with an early-onset progressive muscle weakness, spasticity, and several neurological symptoms were examined via the whole-exome sequencing. Two homozygous missense variants including c.41A>G (p.Lys14Arg) and c.316C>T (p.Arg106Cys) have been found in the related families. The candidate variants were confirmed by Sanger sequencing and found to co-segregate with the disease in families. The bioinformatics analysis showed the deleterious effects of these nucleotide changes and the variants were classified as pathogenic according to ACMG guidelines. A comparison of the clinical presentation of the patients harboring c.41A>G (p.Lys14Arg) with previously reported SPG57 revealed variability in the severity state and unreported clinical presentation, including, facial atrophy, nystagmus, hyperelastic skin, cryptorchidism, hirsutism, kyphoscoliosis, and pectus excavatum. The affected member of the second family carried a previously reported homozygous c.316C>T (p.Arg106Cys) variant and displayed a complex HSP including optic atrophy. Remarkable clinical differences were observed between the family 1 and 2 harboring the c.41A>G (p.Lys14Arg) and c.316C>T (p.Arg106Cys) variants, which could be attributed to the distinct affected domains (PB1 domains and coiled-coil domains), and therefore, SPG57 might have been representing phenotype vs. variant position correlation.