RNA binding proteins are key players in posttranscriptional regulation and have been implicated in neurodevelopmental and neuropsychiatric disorders. Here, we report a significant burden of heterozygous, likely gene-disrupting variants in CSDE1 (encoding a highly constrained RNA binding protein) among patients with autism and related neurodevelopmental disabilities. Analysis of 17 patients identifies common phenotypes including autism, intellectual disability, language and motor delay, seizures, macrocephaly, and variable ocular abnormalities. HITS-CLIP revealed that Csde1-binding targets are enriched in autism-associated gene sets, especially FMRP targets, and in neuronal development and synaptic plasticity–related pathways. Csde1 knockdown in primary mouse cortical neurons leads to an overgrowth of the neurites and abnormal dendritic spine morphology/synapse formation and impaired synaptic transmission, whereas mutant and knockdown experiments in Drosophila result in defects in synapse growth and synaptic transmission. Our study defines a new autism-related syndrome and highlights the functional role of CSDE1 in synapse development and synaptic transmission.
Along with the widespread development of their bioapplications, concerns about the biosafety of quantum dots (QDs) have increasingly attracted intensive attention. This study examines the toxic effect and subcellular location of cadmium telluride (CdTe) QDs with different sizes against yeast Saccharomyces cerevisiae. The innovative approach is based on the combination of microcalorimetric, spectroscopic, electrochemical, and microscopic methods, which allows analysis of the toxic effect of CdTe QDs on S. cerevisiae and its mechanism. According to the values of the half inhibitory concentration (IC(50)), CdTe QDs exhibit marked cytotoxicity in yeast cells at concentrations as low as 80.81 nmol L(-1) for green-emitting CdTe QDs and 17.07 nmol L(-1) for orange-emitting CdTe QDs. QD-induced cell death is characterized by cell wall breakage and cytoplasm blebbing. These findings suggest that QDs with sizes ranging from 4.1 to 5.8 nm can be internalized into yeast cells, which then leads to QD-induced cytotoxicity. These studies provide valuable information for the design and development of aqueous QDs for biological applications.
SHANK3 has been identified as the causative gene of 22q13.3 microdeletion syndrome phenotype. De novo mutations (DNMs) of SHANK3 were subsequently identified in patients with several neurodevelopmental disorders, including autism spectrum disorders (ASDs), schizophrenia (SCZ), a Rett syndrome-like phenotype, and intellectual disability (ID). Although broad developmental phenotypes of these patients have been described in single studies, few studies have reviewed the genotype and phenotype relationships using a relatively large cohort of patients with SHANK3 DNMs. In this study, we identified a de novo splice mutation (NM_033517.1: c.2265+1G>A) that functionally impairs mRNA splicing, produces multiple splice variants, and results in the reduction of the amounts of mRNA. To analyze the genotype and phenotype correlations for SHANK3 DNMs, we reviewed 37 previously published patients with 28 SHANK3 DNMs. Our results revealed that haploinsufficiency of SHANK3 causes a broad spectrum of neurodevelopmental phenotypes with impaired social interaction, repetitive behavior, speech impairment, ID, and regression as the most common observations. Seizures, hypotonia, global development delay, dysmorphic features, and several other features also occurred recurrently.Specific phenotypes are also observed in certain genotypes. Our study provides the frequency of the heterogeneous co-occurring conditions caused by SHANK3 DNMs, which will be beneficial for diagnosis and clinical management. K E Y W O R D SASD, de novo mutation, clinical phenotype, SHANK3, splice mutation
Autism spectrum disorder (ASD) represents a group of neurodevelopmental phenotypes with a strong genetic component. Excess of likely gene-disruptive (LGD) mutations of GIGYF1 was implicated in ASD. Here, we reported that GIGYF1 was the second most mutated gene among known ASD high-confidence risk genes. We investigated the inheritance of 46 GIGYF1 LGD variants, including the highly recurrent mutation, c.333del:p.L111Rfs*234. Inherited GIGYF1 heterozygous LGD variants were 1.8 times more common than de novo mutations. Unlike most high-confidence genes, ASD individuals with GIGYF1 LGD variants were less likely to have cognitive impairments. Using a Gigyf1 conditional knockout mouse model, we showed that haploinsufficiency in the developing brain led to social impairments without significant cognitive impairments. In contrast, homozygous mice showed more severe social disability as well as cognitive impairments. Gigyf1 deficiency in mice led to a reduction of upper layer cortical neurons accompanied by decreased proliferation and increased differentiation of neural progenitor cells. We showed that GIGYF1 regulated the recycling of IGF-1R to cell surface. Knockout of GIGYF1 led to a decreased level of IGF-1R on the cell surface disrupting the IGF-1R/ERK signaling pathway. In summary, our findings showed that GIGYF1 was a regulator of IGF-1R recycling. Haploinsufficiency of GIGYF1 was associated with autistic behaviors likely through interference with IGR-1R/ERK signaling pathway.
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