论文信息 - Association Between Invisible Basal Ganglia and ZNF335 Mutations: A Case Report

Association Between Invisible Basal Ganglia and ZNF335 Mutations: A Case Report

ZNF335 was first reported in 2012 as a causative gene for microcephaly. Because only 1 consanguineous pedigree has ever been reported, the key clinical features associated with ZNF335 mutations remain unknown. In this article, we describe another family harboring ZNF335 mutations. The female proband was the first child of nonconsanguineous Japanese parents. At birth, microcephaly was absent; her head circumference was 32.0 cm (−0.6 SD). At 3 months, microcephaly was noted, (head circumference, 34.0 cm [−4.6 SD]). Brain MRI showed invisible basal ganglia, cerebral atrophy, brainstem hypoplasia, and cerebellar atrophy. At 33 months, (head circumference, 41.0 cm [−5.1 SD]), she had severe psychomotor retardation. After obtaining informed consent from her parents, we performed exome sequencing in the proband and identified 1 novel and 1 known mutation in ZNF335, namely, c.1399T>C (p.C467R) and c.1505A>G (p.Y502C), respectively. The mutations were individually transmitted by her parents, indicating that the proband was compound heterozygous for the mutations. Her brain imaging findings, including invisible basal ganglia, were similar to those observed in the previous case with ZNF335 mutations. We speculate that invisible basal ganglia may be the key feature of ZNF335 mutations. For infants presenting with both microcephaly and invisible basal ganglia, ZNF335 mutations should be considered as a differential diagnosis.

[1] T. Mihara,et al. Anaesthesia and orphan disease: primary autosomal recessive microcephaly-10 caused by a mutation in the ZNF335 gene. , 2016, European journal of anaesthesiology.

[2] A. Vanderver,et al. Hypomyelination with atrophy of the basal ganglia and cerebellum: further delineation of the phenotype and genotype-phenotype correlation. , 2014, Brain : a journal of neurology.

[3] C. Walsh,et al. Microcephaly Gene Links Trithorax and REST/NRSF to Control Neural Stem Cell Proliferation and Differentiation , 2012, Cell.

[4] Andrea Crotti,et al. Huntingtin interacts with REST/NRSF to modulate the transcription of NRSE-controlled neuronal genes , 2003, Nature Genetics.

[5] David J. Anderson,et al. Silencing is golden: negative regulation in the control of neuronal gene transcription , 1995, Current Opinion in Neurobiology.

[6] Gail Mandel,et al. REST: A mammalian silencer protein that restricts sodium channel gene expression to neurons , 1995, Cell.

[7] J. Deuchars,et al. Distinct profiles of REST interactions with its target genes at different stages of neuronal development. , 2005, Molecular biology of the cell.