Compound heterozygous ADAMTS9 variants in Joubert syndrome-related disorders without renal manifestation.

BACKGROUND: Ciliopathies are the outcomes of defects of primary cilia structures and functions which cause multisystemic developmental disorders, such as polycystic kidney disease, nephronophthisis, retinitis pigmentosa, Joubert syndrome (JS), and JS-related disorders (JSRD) with additional organ involvement including oral-facial-digital syndrome and so on. They often share common and unexpected phenotypic features. CASE PRESENTATION: We report a 4-year-old-boy case with compound heterozygous variants of ADAMTS9. Unlike the cases with ADAMTS9 variants in the previous report, which identified that homozygous variants of ADAMTS9 were responsible for nephronophthisis-related ciliopathies in two cases, the current case did not have nephronophthisis nor renal dysfunction, and his clinical features, such as oculomotor apraxia, hypotonia, developmental delay, bifid tongue, and mild hypoplasia of cerebellar vermis indicated JSRD. CONCLUSIONS: The case suggested a possible association between the clinical presentation of JSRD and ADAMTS9-related disease, and it shows a wide spectrum of ADAMTS9 phenotype.

Comprehensive genetic analysis confers high diagnostic yield in 16 Japanese patients with corpus callosum anomalies.

Corpus callosum anomalies (CCA) is a common congenital brain anomaly with various etiologies. Although one of the most important etiologies is genetic factors, the genetic background of CCA is heterogenous and diverse types of variants are likely to be causative. In this study, we analyzed 16 Japanese patients with corpus callosum anomalies to delineate clinical features and the genetic background of CCAs. We observed the common phenotypes accompanied by CCAs: intellectual disability (100%), motor developmental delay (93.8%), seizures (60%), and facial dysmorphisms (50%). Brain magnetic resonance imaging showed colpocephaly (enlarged posterior horn of the lateral ventricles, 84.6%) and enlarged supracerebellar cistern (41.7%). Whole exome sequencing revealed genetic alterations in 9 of the 16 patients (56.3%), including 8 de novo alterations (2 copy number variants and variants in ARID1B, CDK8, HIVEP2, and TCF4) and a recessive variant of TBCK. De novo ARID1B variants were identified in three unrelated individuals, suggesting that ARID1B variants are major genetic causes of CCAs. A de novo TCF4 variant and somatic mosaic deletion at 18q21.31-qter encompassing TCF4 suggest an association of TCF4 abnormalities with CCAs. This study, which analyzes CCA patients usung whole exome sequencing, demonstrates that comprehensive genetic analysis would be useful for investigating various causal variants of CCAs.

A female patient with a hot spot mutation of PRRT2 gene suffering from several types of epileptic seizures in infancy.

Benign familial infantile epilepsy (BFIE) is characterized by non-febrile focal seizures, which sometimes evolve to secondarily generalized seizures and are usually resolved in the second year. Proline-rich transmembrane protein 2 (PRRT2) is confirmed as the major cause of BFIE, familial paroxysmal kinesigeneic dystonia (PKD) and infantile convulsions and choreoathetosis (ICCA) syndrome. We examined a female patient with a hot spot mutation of PRRT2 gene. She had recurrent tonic seizures when she was three months old. The seizures were controlled by several kinds of anticonvulsants. Then, she had several times of focal seizures daily at nine months old. However, the seizures were stopped by small amounts of carbamazepine. Later, when she was two years old, she experienced frequent motor seizures characterized by truncal flexion and swaying the body with partially disturbed consciousness. Her father also had the same PRRT2 gene mutation and non-febrile seizures in infancy. The patient had mild to moderate mental retardation, whereas her father was mentally normal. Therefore, the patient revealed a quiet different phenotype from that of her father as a carrier of the same PRRT2 gene mutation. We speculate that the PRRT2 mutation had caused the BFIE-like seizures both in the patient and her father, whereas other unknown genetic factors specific for the patient might be associated with the atypical seizures observed only in her.

Plasticity and injury in the developing brain.

The child's brain is more malleable or plastic than that of adults and this accounts for the ability of children to learn new skills quickly or recovery from brain injuries. Several mechanisms contribute to this ability including overproduction and deletion of neurons and synapses, and activity-dependent stabilization of synapses. The molecular mechanisms for activity-dependent synaptic plasticity are being discovered and this is leading to a better understanding of the pathogenesis of several disorders including neurofibromatosis, tuberous sclerosis, Fragile X syndrome and Rett syndrome. Many of the same pathways involved in synaptic plasticity, such as glutamate-mediated excitation, can also mediate brain injury when the brain is exposed to stress or energy failure such as hypoxia-ischemia. Recent evidence indicates that cell death pathways activated by injury differ between males and females. This new information about the molecular pathways involved in brain plasticity and injury are leading to insights that will provide better therapies for pediatric neurological disorders.