TAF1C (TATA box-binding protein-associated factor, RNA polymerase I subunit C) is an essential component of the RNA polymerase I transcription machinery responsible for ribosomal RNA synthesis and nucleolar function. Variants in TAF1C have recently emerged as rare genetic causes of early-onset neurological syndromes characterized by nucleolar stress and impaired ribosome biogenesis, leading to developmental delay and brain atrophy. Here, we report a novel homozygous missense variant (c.1766C>T; p.Ser589Leu) in TAF1C in a 3-year 8-month-old boy who exhibited normal development until age two, followed by generalized seizures and progressive neurodevelopmental regression, spasticity, microcephaly, and cerebellar atrophy. MRI revealed asymmetric diffusion restriction and diffuse cerebellar atrophy. Although the mutant TAF1C transcript and protein were expressed at normal levels in peripheral blood cells, immunofluorescence analysis revealed a loss of nucleolar localization and the formation of abnormal thread-like aggregates within the nucleoplasm. These findings suggest that the p.Ser589Leu variant causes disease through functional mislocalization rather than loss of expression. Our case expands the phenotypic and mechanistic spectrum of TAF1C-related disorders and highlights the importance of proper subnuclear localization for maintaining neuronal function and development.

Despite major progress in understanding the impact of the triplicated chromosome 21 on the brain and behaviour in Down syndrome, our knowledge of the underlying neurobiology in humans is still limited. We sought to address some of the pertinent questions about the drivers of brain structure differences and their associations with cognitive function in Down syndrome. To this aim, in a pilot magnetic resonance imaging (MRI) study, we monitored brain anatomy in individuals with Down syndrome receiving pulsatile gonadotropin-releasing hormone (GnRH) therapy over 6 months in comparison with typically developed age- and sex-matched healthy controls. We analysed cross-sectional (Down syndrome/healthy controls n  = 11/27; Down syndrome-2 females/9 males, age 26.7 ± 5.0 years old; healthy controls-8 females/19 males, age 24.1 ± 2.5 years old) and longitudinal (Down syndrome/healthy controls n  = 8/13; Down syndrome-1 female/7 males, age 26.4 ± 5.3 years old; healthy controls-4 females/9 males, 24.7 ± 2.2 years old) relaxometry and diffusion-weighted MRI data alongside standard cognitive assessment. The statistical tests looked for cross-sectional baseline differences and for differential changes over time between Down syndrome and healthy controls. The post hoc analysis confined to the Down syndrome group, tested for potential time-dependent interactions between individuals' overall cognitive performance and associated brain anatomy changes. The brain MRI statistical analyses covered both grey and white matter regions across the whole brain allowing for investigation of regional volume, macromolecular/myelin and iron content, additionally to diffusion tensor and neurite orientation and dispersion density characterization across major white matter tracts. The cross-sectional analysis showed reduced frontal, temporal and cerebellar volumes in Down syndrome with only the cerebellar differences remaining significant after adjustment for the presence of microcephaly (P family-wise-corrected < 0.05). The volume reductions were paralleled by decreased cortical and subcortical macromolecular/myelin content confined to the cortical motor system, thalamus and basal ganglia (P family-wise-corrected < 0.05). All major white matter tracts showed a ubiquitous mean diffusivity and intracellular volume fraction reduction contrasted with no differences in magnetization transfer saturation metrics (P family-wise-corrected < 0.05). Compared with healthy controls over the same period, Down syndrome individuals under GnRH therapy showed cognitive improvement (Montreal Cognitive Assessment from 11.4 ± 5.5 to 15.1 ± 5.6; P < 0.01) on the background of stability of the observed differential neuroanatomical patterns. Despite the lack of adequate Down syndrome control group, we interpret the obtained cross-sectional and longitudinal findings in young adults as evidence for predominant neurodevelopmental neuronal loss due to dysfunctional neurogenesis without signs for short-term myelin loss.

Rett syndrome is a genetic neurodevelopmental disorder that predominantly affects girls. While microcephaly is a common feature, there is limited information on the detailed structural changes in the brain. This study aimed to identify regional brain volume abnormalities and explore the correlation between brain volume and clinical characteristics. We compared the regional brain volumes of 20 female children with Rett syndrome to those of 25 healthy female children. Additionally, we assessed the correlation between regional brain volume, Clinical Severity Scores, and epilepsy status. Significantly smaller volumes were observed in all brain regions, including the cerebral cortex, cerebral white matter, subcortical gray matter, cerebellum, and brainstem. Within the cortical regions, volume reduction was prominent in the left precentral, right lateral occipital, left precuneus, left inferior parietal, and right medial orbitofrontal cortices. After correcting for intracranial volumes, volume reduction was more prominent in the cerebral cortices than in the cerebral white matter. Small volumes were consistently observed, regardless of age. Negative correlations were observed between the volumes of multiple regions and the Clinical Severity Scores. There were no correlations among regional brain volume, seizure control, or duration of epilepsy. The mechanism underlying the cortical-dominant volume reduction remains unclear; however, it may be caused by altered synapse development associated with methyl-CpG-binding protein 2 gene abnormalities. Characteristic impairments in visual recognition and deterioration of motor function in Rett syndrome may be associated with significant volume reduction in specific cortical regions, such as the lateral occipital cortex, precuneus, and precentral gyrus.

Polo-like kinase 4 (Plk4) is a ser/thr kinase, which plays a central role in centriole duplication during the cell cycle. PLK4 gene abnormalities are responsible for autosomal recessive chorioretinopathy-microcephaly syndrome and Seckel syndrome. In this study, we performed expression analyses of Plk4 by focusing on mouse brain development. Western blotting analyses revealed that Plk4 with a molecular mass of ∼100 kDa was broadly expressed in adult mouse tissues with specific subcellular distribution. As to the central nervous system, Plk4 was expressed throughout the developmental process with drastic increase after P15, suggesting an essential role of Plk4 in differentiated neurons. In immunohistochemical analyses with mouse brain at embryonic day 14, Plk4 was detected dominantly at the cell-cell contact sites of neuronal progenitors in the ventricular zone. Plk4 was then diffusely distributed in the cell body of cortical neurons at P7, while it was enriched in the neuropil as well as soma of excitatory neurons in the cerebral cortex and hippocampus and Purkinje cells in the cerebellum at P30. Notably, biochemical fractionation analysis found an enrichment of Plk4 in the postsynaptic density fraction. Then, immunofluorescent analyses showed partial co-localization of Plk4 with excitatory synaptic markers, PSD95 and synaptophysin, in differentiated primary cultured hippocampal neurons. These results suggest that Plk4 takes part in the regulation of synaptic function in differentiated neurons.

Centrosomal protein 152 (Cep152) regulates centriole duplication as a molecular scaffold during the cell cycle. Its gene abnormalities are responsible for autosomal recessive primary microcephaly 9 and Seckel syndrome. In this study, we prepared an antibody against mouse Cep152, anti-Cep152, and performed expression analyses focusing on mouse brain development. Western blotting analyses revealed that Cep152 with a molecular mass of ∼150 kDa was expressed strongly at embryonic day (E)13 and then gradually decreased during the brain development process. Instead, protein bands of ∼80 kDa and ∼60 kDa came to be recognized after postnatal day (P)15 and P30, respectively. In immunohistochemical analyses, Cep152 was enriched in the centrosome of neuronal progenitors in the ventricular zone at E14, whereas it was diffusely distributed mainly in the cytoplasm of cortical neurons at P18. In developing cerebellum at P7, Cep152 was localized at the centrosome in the external granular layer, where neurogenesis takes place. Notably, biochemical analysis revealed that Cep152 was also present in the postsynaptic density fraction. Subsequent immunofluorescent analyses showed co-localization of Cep152 with excitatory synaptic markers, PSD95 and synaptophysin, but not with an inhibitory synaptic marker gephyrin in differentiated primary cultured hippocampal neurons. The obtained results suggest that Cep152 takes part not only in neurogenesis during corticogenesis but also in the regulation of synaptic function in differentiated neurons.