Project description:Glucose is an important cellular energy source, however, glucose’s function as a second messenger remains relatively unexplored. Here, we find that glucose binds directly to DDX21 to regulate its function during epidermal differentiation. Specifically, glucose binds to the ATP-binding domain of DDX21 to induce a conformational change and inhibit helicase activity. Glucose binding inhibits the dimerization of DDX21 leading to re-localization from the nucleolus to the nucleoplasm and reassembly of DDX21 into larger protein complexes, increasing its association with splicing factors. This occurs during keratinocyte differentiation, where glucose accumulation is necessary, and results in DDX21 binding to RNA processing proteins and mRNA introns. Consequently, DDX21 regulates the splicing of key differentiation factors and promotes epidermal differentiation in a glucose-dependent manner. These findings reveal a novel mechanism of glucose regulation of cell signaling.

Project description:Glucose is an important cellular energy source, however, glucose’s function as a second messenger remains relatively unexplored. Here, we find that glucose binds directly to DDX21 to regulate its function during epidermal differentiation. Specifically, glucose binds to the ATP-binding domain of DDX21 to induce a conformational change and inhibit helicase activity. Glucose binding inhibits the dimerization of DDX21 leading to re-localization from the nucleolus to the nucleoplasm and reassembly of DDX21 into larger protein complexes, increasing its association with splicing factors. This occurs during keratinocyte differentiation, where glucose accumulation is necessary, and results in DDX21 binding to RNA processing proteins and mRNA introns. Consequently, DDX21 regulates the splicing of key differentiation factors and promotes epidermal differentiation in a glucose-dependent manner. These findings reveal a novel mechanism of glucose regulation of cell signaling.

Project description:Glucose is an important cellular energy source, however, glucose’s function as a second messenger remains relatively unexplored. Here, we find that glucose binds directly to DDX21 to regulate its function during epidermal differentiation. Specifically, glucose binds to the ATP-binding domain of DDX21 to induce a conformational change and inhibit helicase activity. Glucose binding inhibits the dimerization of DDX21 leading to re-localization from the nucleolus to the nucleoplasm and reassembly of DDX21 into larger protein complexes, increasing its association with splicing factors. This occurs during keratinocyte differentiation, where glucose accumulation is necessary, and results in DDX21 binding to RNA processing proteins and mRNA introns. Consequently, DDX21 regulates the splicing of key differentiation factors and promotes epidermal differentiation in a glucose-dependent manner. These findings reveal a novel mechanism of glucose regulation of cell signaling.

Project description:Glucose is an important cellular energy source, however, glucose’s function as a second messenger remains relatively unexplored. Here, we find that glucose binds directly to DDX21 to regulate its function during epidermal differentiation. Specifically, glucose binds to the ATP-binding domain of DDX21 to induce a conformational change and inhibit helicase activity. Glucose binding inhibits the dimerization of DDX21 leading to re-localization from the nucleolus to the nucleoplasm and reassembly of DDX21 into larger protein complexes, increasing its association with splicing factors. This occurs during keratinocyte differentiation, where glucose accumulation is necessary, and results in DDX21 binding to RNA processing proteins and mRNA introns. Consequently, DDX21 regulates the splicing of key differentiation factors and promotes epidermal differentiation in a glucose-dependent manner. These findings reveal a novel mechanism of glucose regulation of cell signaling.

Project description:Glucose is an important cellular energy source, however, glucose’s function as a second messenger remains relatively unexplored. Here, we find that glucose binds directly to DDX21 to regulate its function during epidermal differentiation. Specifically, glucose binds to the ATP-binding domain of DDX21 to induce a conformational change and inhibit helicase activity. Glucose binding inhibits the dimerization of DDX21 leading to re-localization from the nucleolus to the nucleoplasm and reassembly of DDX21 into larger protein complexes, increasing its association with splicing factors. This occurs during keratinocyte differentiation, where glucose accumulation is necessary, and results in DDX21 binding to RNA processing proteins and mRNA introns. Consequently, DDX21 regulates the splicing of key differentiation factors and promotes epidermal differentiation in a glucose-dependent manner. These findings reveal a novel mechanism of glucose regulation of cell signaling.

Project description:Glucose is an important cellular energy source, however, glucose’s function as a second messenger remains relatively unexplored. Here, we find that glucose binds directly to DDX21 to regulate its function during epidermal differentiation. Specifically, glucose binds to the ATP-binding domain of DDX21 to induce a conformational change and inhibit helicase activity. Glucose binding inhibits the dimerization of DDX21 leading to re-localization from the nucleolus to the nucleoplasm and reassembly of DDX21 into larger protein complexes, increasing its association with splicing factors. This occurs during keratinocyte differentiation, where glucose accumulation is necessary, and results in DDX21 binding to RNA processing proteins and mRNA introns. Consequently, DDX21 regulates the splicing of key differentiation factors and promotes epidermal differentiation in a glucose-dependent manner. These findings reveal a novel mechanism of glucose regulation of cell signaling.

Project description:We discovered that glucose directly bind to DDX21, induced the conformation change of the proteins and inhibit its helicase activity. Glucose also inhibits the dimerization of DDX21, re-localize DDX21 from nucleolus to nucleoplasm and reassemble DDX21 to RNA splicing complex. DDX21 is essential for epidermal differentiation while with normal glucose condition, DDX21 was re-localized from nucleolus to nucleoplasm, bind to splicing factors and mRNA introns more to regulate splicing of key differentiation factors and promote epidermal differentiation.

Project description:<p>Transcription factor p63 is a key regulator of epidermal keratinocyte proliferation and differentiation. Mutations in the p63 DNA-binding domain are associated with Ectrodactyly Ectodermal Dysplasia Cleft Lip/Palate (EEC) syndrome. Underlying molecular mechanism of these mutations however remain unclear. Here we characterized the transcriptome and epigenome of p63 mutant keratinocytes derived from EEC patients. The transcriptome of p63 mutant keratinocytes deviated from the normal epidermal cell identity. Epigenomic analyses showed an altered enhancer landscape in p63 mutant keratinocytes contributed by loss of p63-bound active enhancers and by unexpected gain of enhancers. The gained enhancers were frequently bound by deregulated transcription factors such as RUNX1. Reversing RUNX1 overexpression partially rescued deregulated gene expression and the altered enhancer landscape. Our findings identify an unreported disease mechanism whereby mutant p63 rewires the enhancer landscape and affects epidermal cell identity, consolidating the pivotal role of p63 in controlling the enhancer landscape of epidermal keratinocytes.</p>

Project description:Splicing and epigenetic factors jointly regulate epidermal differentiation

Project description:We studied AES and DDX21 binding RNAs in Kasumi-1 cells stably expressing V5-tagged AES. RNA immunoprecipitation was performed with V5 antibody (for AES), DDX21 antibody and control IgG. We found that AES as well as DDX21 RIP samples showed enrichment for small nucleolar RNAs (snoRNAs) compared to control IgG. We also showed that AES and DDX21 binding snoRNAs showed significant overlap. Our studies provide mechanisms how AES regulates snoRNAs and rRNA modification.