Project description:Miz1 is a zinc finger protein that regulates expression of cell cycle inhibitors as part of a complex with Myc. Cell cycle-independent functions of Miz1 are poorly understood. Here, we use a Nestin-Cre transgene to delete an essential domain of Miz1 in the central nervous system (Miz1M-NM-^TPOZNes). Miz1M-NM-^TPOZNes mice display cerebellar neurodegeneration characterized by the progressive loss of Purkinje cells. Chromatin immunoprecipitation sequencing and biochemical analyses show that Miz1 activates transcription upon binding to a non-palindromic sequence present in core promoters. Target genes of Miz1 encode regulators of autophagy and proteins involved in vesicular transport that are required for autophagy. Miz1M-NM-^TPOZ neuronal progenitors and fibroblasts show reduced autophagic flux. Consistently, polyubiquitinated proteins and p62/Sqtm1 accumulate in the cerebella of Miz1M-NM-^TPOZNes mice, characteristic features of defective autophagy. Our data suggest that Miz1 may link cell growth and ribosome biogenesis to the transcriptional regulation of vesicular transport and autophagy. ChIP-Seq with H190 and G18 on an Illumina Genome Analyzer IIx.
Project description:Miz1 is a zinc finger protein that regulates expression of cell cycle inhibitors as part of a complex with Myc. Cell cycle-independent functions of Miz1 are poorly understood. Here, we use a Nestin-Cre transgene to delete an essential domain of Miz1 in the central nervous system (Miz1ΔPOZNes). Miz1ΔPOZNes mice display cerebellar neurodegeneration characterized by the progressive loss of Purkinje cells. Chromatin immunoprecipitation sequencing and biochemical analyses show that Miz1 activates transcription upon binding to a non-palindromic sequence present in core promoters. Target genes of Miz1 encode regulators of autophagy and proteins involved in vesicular transport that are required for autophagy. Miz1ΔPOZ neuronal progenitors and fibroblasts show reduced autophagic flux. Consistently, polyubiquitinated proteins and p62/Sqtm1 accumulate in the cerebella of Miz1ΔPOZNes mice, characteristic features of defective autophagy. Our data suggest that Miz1 may link cell growth and ribosome biogenesis to the transcriptional regulation of vesicular transport and autophagy.
Project description:To isolate neuronal progenitor cells (NPCs), forebrains of E13.5 Miz1+/+ or Miz1-delta-POZ embryos were cut in small pieces, digested with trypsin and filtered through sterile gauze. Cells were cultivated in 2:1 DMEM/F12 supplemented with 1xB27 (Life technologies), 20 ng/ul EGF (Biomol), 20 ng/?l basic FGF (Biomol), 1 ug/ml fungizone (Gibco) and Penicillin/Streptomycin (PAA). NPCs were passaged every seven days. RNA expression of different genotypes was compared in sec. and quart. neurospheres.
Project description:Mice: knock-out of the Miz1 POZ-domain in brain (Miz1DPOZNes) and control mice. The RNA expression in cerebella of of old Miz1 delta POZ mice (1.5 years), old control mice (1.5 years), young Miz1 delta POZ mice (5.5 weeks) and young control mice (5.5 weeks) was compared
Project description:Autophagy plays an important role in preserving cellular homeostasis in pancreatic beta cells. However, the extent of autophagic flux induced in various physiological settings in vivo is unclear. In this study, we generated transgenic mice expressing pHluorin-LC3-mCherry reporter for monitoring systemic autophagic flux. Our findings revealed that autophagic flux in pancreatic islets enhanced after starvation, although suppression of the flux after short-term refeeding needs more prolonged restarvation in islets than in liver and skeletal muscle. Furthermore, heterogeneity of autophagic flux in beta cells manifested after increasing insulin resistance and intracellular calcium influx by glucose stimulation increased more in high- than low-flux beta cells, with differential gene expression based on the flux. Thus, our monitor mouse enables us to reveal physiological response and biological insight of heterogeneity in autophagic flux in pancreatic beta cells.
Project description:Autophagic flux is associated with chemoresistance, the leading cause of chemotherapeutic failure. Here, we showed that HAX-1 promotes chemoresistance by effectively blocking the fusion of autophagosomes with lysosomes. Mass spectrometric and functional studies demonstrated that HAX-1 recruited NEDD4 to promote Rab7a degradation and inhibited the binding of Rab7a with SNAREs by competitively binding to it. Furthermore, HAX-1 could bind to IGF2BP1 mRNA, thereby contributing to its stability and translation. Moreover, IGF2BP1 enhanced HAX-1 m6A methylation, thereby enhancing its stability. Via in vivo and in vitro experiments, we confirmed the positive role of the IGF2BP1-HAX-1 feedback loop in chemoresistance. Our data provide evidence that HAX-1, IGF2BP1, and SQSTM1 levels are useful predictors of clinical outcome and chemoresistance risk. In addition, our data provide new insights into the clinical applications of therapies related to autophagic flux and its associated molecular network in targeting cisplatin chemoresistance in nasopharyngeal carcinoma.
Project description:Medulloblastomas (MBs) are cerebellar tumors that can be classified into molecularly distinct subgroups that differ in pathology and prognosis. The mechanisms that underlie subgroup specification are largely unknown. While human SHH MBs express MYCN, Group3 (G3) MBs are associated with c-MYC (MYC) overexpression and often show metastasis that confers a poor prognosis. Although MYC proteins are thought to be functionally exchangeable, ectopic expression of Myc or N-myc in Trp53-/-;Cdkn2c-/- cerebellar granule neuron progenitors (GNPs) induces G3 and SHH MBs, respectively, demonstrating that each Myc protein has distinct biological properties. We now show that Myc and N-myc differ in their affinity to Miz1 and that Myc, but not N-myc, effectively recruits Miz1 to its target sites on chromatin. The interaction of Myc with Miz1 is required for the genesis of G3 MB. Myc suppresses ciliogenesis and “reprograms” the transcriptome of SHH-dependent GNPs to stem-like cells by repressing genes highly expressed in SHH MB via Miz1. Consistently, target genes of Myc/Miz1 are repressed in human G3 MBs but not in other MB subgroups. Collectively, the data show that the interaction of Myc with Miz1 is a defining hallmark of G3 MB development.