Project description:Human brain structure and size requires regulated division of neural stem cells (NSCs). NSCs undergo precise divisions to self-renew and to produce intermediate neural progenitors (INPs) and neurons. The factors that regulate NSC divisions remain poorly understood, as do mechanistic explanations of how aberrant NSC division causes reduced brain size, as seen in microcephaly. Here we demonstrate that Magoh, a component of the core exon junction complex (EJC) that binds spliced RNA, controls cerebral cortical size by regulating NSC division. Magoh haploinsufficiency causes microcephaly due to INP depletion, neuronal apoptosis, and improper mitotic spindle orientation. Defective mitosis underlies these phenotypes as depletion of EJC components disrupts mitotic spindle integrity, chromosome number and genomic stability. We show that an essential function of Magoh is to regulate expression of the human microcephaly protein, LIS1, and that Lis1 addition rescues neurogenesis defects caused by Magoh knockdown, thus providing a genetic explanation for the microcephaly. This study uncovers new requirements for the EJC in brain development, NSC maintenance, mitosis and chromosome stability, thus implicating this complex in the pathogenesis of microcephaly. Mouse embryonic cortices were used for expression analysis 5 biological replicates each of control (C57BL/6) and Magoh mutant brains were analyzed

Project description:Human brain structure and size requires regulated division of neural stem cells (NSCs). NSCs undergo precise divisions to self-renew and to produce intermediate neural progenitors (INPs) and neurons. The factors that regulate NSC divisions remain poorly understood, as do mechanistic explanations of how aberrant NSC division causes reduced brain size, as seen in microcephaly. Here we demonstrate that Magoh, a component of the core exon junction complex (EJC) that binds spliced RNA, controls cerebral cortical size by regulating NSC division. Magoh haploinsufficiency causes microcephaly due to INP depletion, neuronal apoptosis, and improper mitotic spindle orientation. Defective mitosis underlies these phenotypes as depletion of EJC components disrupts mitotic spindle integrity, chromosome number and genomic stability. We show that an essential function of Magoh is to regulate expression of the human microcephaly protein, LIS1, and that Lis1 addition rescues neurogenesis defects caused by Magoh knockdown, thus providing a genetic explanation for the microcephaly. This study uncovers new requirements for the EJC in brain development, NSC maintenance, mitosis and chromosome stability, thus implicating this complex in the pathogenesis of microcephaly. Mouse embryonic cortices were used for expression analysis

Project description:Recessive mutations in RTTN, encoding centrosome associated protein Rotatin, were originally identified as cause of polymicrogyria, a cortical malformation. With time a wide variety of other brain malformations has been ascribed to RTTN mutations, such as primary microcephaly. However, the function of Rotatin is largely unknown and the molecular disease mechanism underlying these malformations has not yet been elucidated. Here, we report four novel families identified by high throughput sequencing, one of them with a novel deep intronic variant. We reviewed RTTN-related disease phenotypes and defined the spectrum which includes intellectual disability (ID), short stature, microcephaly, lissencephaly, periventricular heterotopia, polymicrogyria and other malformations. Rotatin expression, function and cellular disease phenotype were studied in cultured primary skin fibroblasts from eight unrelated affected individuals. We found that Rotatin deficiency leads to abnormal centrosome amplification during mitosis, resulting in multipolar spindle formation, mitotic failure, increased apoptosis and aneuploidy. In non-dividing healthy cells, Rotatin localizes at the primary cilium, both at basal body and axoneme during ciliogenesis. Interestingly, interphase mutant cells show aberrant ciliogenesis. Proteomics analysis reveals that exogenous Rotatin in HEK293 cells interacts with the non-muscle cellular myosin complex (MYH9-MYH10-MYH14), which is essential for nucleokinesis during neuronal migration. In hiPSC-derived neurons, endogenous Rotatin localizes to the leading edge centrosome, which pulls the perinuclear cage during nucleokinesis, suggesting a pivotal role of Rotatin in neuronal migration. This study sheds light on the pleiotropic cellular functions of Rotatin, explaining disease spectrum linked to both neuronal proliferation and migration.

Project description:BACKGROUND & AIMS: Thirty to ninety percent of hepatocytes contain whole genome duplications, making it imperative to understand the fates and functions of these polyploid cells and how they affect development of liver disease. An important question is how polyploid cells respond to chronic proliferative demands, which are characteristic of liver diseases, but a challenging situation for cells with multiple genomes. METHODS: To interrogate liver polyploidy, we employed a mouse with reversible ANLN ( Anillin actin binding protein) knockdown that drives hepatocyte polyploidization in a doxycycline inducible fashion. Diethylnitrosamine (DEN) and carbon tetrachloride (CCl4) were used to induce chronic liver damage and hepatocellular carcinoma (HCC). We performed partial hepatectomies to test regeneration and RNA-seq to assess gene expression changes. Lineage tracing was used to rule out repopulation from non-hepatocyte sources. In vivo imaging of mitotic hepatocytes estimated the frequency of aneuploidy during regeneration, and exome sequencing of 54 human cirrhotic nodules was used to quantify aneuploidy. RESULTS: Hepatocytes from mice given chronic CCl4 alone showed significant increases in ploidy. Super-polyploid mice with 97% polyploid hepatocytes, due to induced knockdown of Anln , were almost completely protected from tumorigenesis induced by DEN and chronic CCl4 . The protection was not associated with differences in regenerative capacity, tissue fitness, gene regulation, or mitotic errors. Regenerative contributions from a non-hepatocyte population were ruled out using lineage tracing, confirming that polyploids can replenish tissues during chronic damage. No lagging chromosomes or micronuclei were found in mitotic polyploid cells and there was no evidence of chromosomal copy number variations in 54 nodules, suggesting that aneuploidy is not a common outcome of polyploid cell divisions. CONCLUSION: During chronic injury, polyploid hepatocytes readily divide and regenerate while being buffered from tumor suppressor loss and tumorigenesis. Therapeutic strategies to increase numbers of polypoid hepatocytes could prevent cancer while preserving regeneration.

Project description:Neuronal activity is critical for adaptive circuit remodeling but poses an inherent risk to the stability of the genome across the long lifespan of post-mitotic neurons1-5. Whether neurons have acquired specialized genome protection mechanisms that enable them to withstand decades of potentially damaging stimuli during periods of heightened activity is not known. Here we identify an activity-dependent DNA repair mechanism via a new form of the NuA4/TIP60 chromatin modifier that assembles in activated neurons around the inducible, neuronal-specific transcription factor NPAS4. We purify this complex directly from the brain and demonstrate its functions in eliciting activity-dependent changes to neuronal transcriptomes and circuitry. By identifying the landscape of activity-induced DNA double-strand breaks in the brain, we show that the NPAS4:NuA4 complex binds to recurrently damaged regulatory elements and recruits additional DNA repair machinery to stimulate their repair. Gene regulatory elements bound by the NPAS4:NuA4 complex are partially protected from age-dependent accumulation of somatic mutations. Impaired NPAS4:NuA4 signaling leads to a cascade of cellular defects including dysregulated transcriptional responses to activity, loss of control over neuronal inhibition, and genome instability, culminating in reduced organismal lifespan. In addition, mutations in several components of the NuA4 complex are reported to lead to neurodevelopmental disorders and autism. Together, these findings identify a neuronal-specific complex that couples neuronal activity directly to genome preservation and whose disruption may contribute to developmental disorders, neurodegeneration and aging.

Project description:Robust elimination of genome-damaged cells safeguards against brain somatic aneuploidy following Knl1 deletion

Project description:Aneuploidy, a hallmark of cancer, often arises from whole-chromosomal instability (W-CIN). Many cancers exhibiting W-CIN, however, show no direct insult to the mitotic proteins that ensure proper segregation of chromosomes. This has stimulated interest in identifying defects in non-mitotic processes that might disrupt chromosome behavior in mitosis. Here we show in Saccharomyces cerevisiae that transient re-replication of centromeric DNA, due to deregulation of replication initiation proteins, greatly induces aneuploidy of the rereplicated chromosome. Some of this aneuploidy appears to arise from simple missegregation of both sister chromatids to one daughter cell, indicating that centromeric re-replication can disrupt proper centromere function during mitosis. Another source of aneuploidy appears to be the generation of an extra sister chromatid via homologous recombination, suggesting that centromeric rereplication can trigger breakage and repair events that expand chromosome numbers while preserving chromosome structure. Given the emerging connections between the deregulation of replication initiation proteins and oncogenesis, our findings offer the possibility of a new non-mitotic source of aneuploidy that may be relevant to cancer.

Project description:Cisplatin kills proliferating cells via DNA damage but also has profound effects on post-mitotic cells in tumors, kidneys, and neurons. However, the effects of cisplatin on post-mitotic cells are still poorly understood. Among model systems, C. elegans adults are unique in having completely post-mitotic somatic tissues. The p38 MAPK pathway controls ROS detoxification via SKN-1/NRF and immune responses via ATF-7/ATF2. We show that p38 MAPK pathway mutants are sensitive to cisplatin, but while cisplatin exposure increases ROS levels, skn-1 mutants are resistant. Cisplatin exposure leads to phosphorylation of PMK-1/MAPK and ATF-7 and the IRE-1/TRF-1 signaling module functions upstream of the p38 MAPK pathway to activate signaling. We identify the response proteins whose increased abundance depends on IRE-1/p38 MAPK activity as well as cisplatin exposure. Four of these proteins are necessary for protection from cisplatin toxicity, which is characterized by necrotic death. We conclude that the p38 MAPK pathway-driven proteins are crucial for adult cisplatin resilience.

Project description:We investigated how yeast cells deficient in performing homologous recombination-mediated DNA repair due to a deletion of the critical RAD52 gene respond to irreparable DNA damage inflicted by genotoxic treatment commonly applied in cancer therapy (camptothecin and irradiation). We found that upon persistence of irreparable DNA damage, yeast rad52 mutants readily undergo checkpoint adaptation accompanied by the acquisition of resistance to further genotoxic insults as well as the development of aneuploidy. Together, our findings can be used to elucidate how repair-defective cancer cells can become treatment-resistant thereby providing a way to target these resistant cell clones by tackling their aneuploidy-associated phenotypes. To investigate these characteristics commonly present in aneuploid cells in our experimental set-up, we treated yeast cells with genotoxic agents and performed whole genome sequencing. We could identify frequent whole chromosome loss events manifesting in a sensitivity of cells to aneuploidy-targeting agents.

Project description:Furfural is a potential mutagenic agent. To explore the global effect of furfural on genomic intergrity, chromosomal alterations in 14 furfural-treated isolates of JSC25-1 strain were determined by whole genome SNP microarrays at a resolution about 1kb. Our results showed furfural exposure results in striking elevations of both mitotic recombination and aneuploidy events in yeast.