Project description:Cellular senescence disables the proliferation of damaged cells and it is relevant for cancer and aging. Here, we show that cellular senescence occurs during mammalian embryonic development. Specifically, we have focused on the mouse regressing mesonephros and the endolymphatic sac of the inner ear. Senescence is characterized by SAM-NM-2G activity, heterochromatinization, and proliferative arrest. Mechanistically, developmentally-programmed senescence at the mesonephros and endolymphatic sac is strictly dependent on p21, but independent of DNA damage, p53 or other cell cycle inhibitors, and it is regulated by the TGFM-NM-2/SMAD and PI3K/FOXO pathways. Developmentally-programmed senescence is followed by macrophage infiltration and clearance of senescent cells. Abrogation of senescence by p21 deletion is only partially compensated by apoptosis and originates detectable developmental abnormalities. Importantly, high levels of p21 are also associated to the regressing mesonephros and endolymphatic sac in human embryos. These findings place cellular senescence as a relevant morphogenic process during embryonic development. We microdissected mesonephric tubules from senescent (WT) and non-senescent (p21-null) embryos to get information about this new senescence that occurs during embryogenesis.

Project description:Comparison of gene expression in rat endolymphatic sac with dura tissue to pure dura tissue.

Project description:Methylation analysis of sporadic and von Hippel-Lindau syndrome associated endolymphatic sac tumors (ELST).

Project description:Methylation profiling of endolymphatic sac tumors

Project description:Single-cell RNA-seq analysis of pre- and postnatal mouse endolymphatic sac demonstrates two types of differentiated cells distinguished by their mRNA expression signatures.

Project description:The embryonic endolymphatic sac mediates fluid resorption for which anion exchangers such as SLC26A4, and its transcriptional activator FOXI1, are required. Apart from FOXI1, little is known about transcriptional regulators of this fluid balance. Altered fluid homeostasis in the inner ear is the leading cause of congenital hearing loss. Some patients with campomelic dysplasia (CD) caused by heterozygous mutations in SOX9, in addition to skeletal malformation, are deaf, with an unknown etiology. In a mouse model of CD caused by the SOX9Y440X mutation, which results in a truncated protein lacking the transactivation domain, we show severe endolymphatic dysfunction leading to deafness and vestibular problems. Adult heterozygous Sox9Y440X mice that express the mutation in the developing inner ear display sensorineural deafness combined with endolymphatic hydrops and lack of endocochlear potential. The mutant inner ear is enlarged from E15 and fewer Slc26a4-expressing cells are present in the endolymphatic epithelium. By single cell RNA sequencing of mutant and wild-type endolymphatic sacs we find marked reduction in genes important for ion transport such as Slc24a4 and Ttyh1 and gap-junctions such as Gjb2 and up-regulation of Wnt signaling and Igfbp2 that promotes progenitor proliferation. The cochlea overexpresses Aqp3, which encodes a water channel. We find by biochemical and cell-based transactivation assays and genetic interaction tests that SOX9 and SOX10 normally work co-operatively to repress Aqp3 transcription: SOX9Y440X blocks this repression by dominant interference. Our study reveals the key roles of SOXE transcription factors in the development of endolymphatic sac function, and highlight a molecular mechanism whereby the CD mutation exerts both a dominant negative and haploinsufficient mechanisms in different compartments of the inner ear to maintain fluid homeostasis. In the cochlea, SOX9 and SOX10 together repress aquaporin expression whereas in the endolymphatic sac, SOX9 controls SOX10 expression and genes for ion transport and gap-junctions. We postulate that in addition to loss of control of cell proliferation results in the exhaustion of progenitors which in turn leads to a deficit in mitochondria-rich cells. These results highlight a multifaceted mechanism for maintaining the proper fluid balance for hearing.

Project description:The embryonic endolymphatic sac mediates fluid resorption for which anion exchangers such as SLC26A4, and its transcriptional activator FOXI1, are required. Apart from FOXI1, little is known about transcriptional regulators of this fluid balance. Altered fluid homeostasis in the inner ear is the leading cause of congenital hearing loss. Some patients with campomelic dysplasia (CD) caused by heterozygous mutations in SOX9, in addition to skeletal malformation, are deaf, with an unknown etiology. In a mouse model of CD caused by the SOX9Y440X mutation, which results in a truncated protein lacking the transactivation domain, we show severe endolymphatic dysfunction leading to deafness and vestibular problems. Adult heterozygous Sox9Y440X mice that express the mutation in the developing inner ear display sensorineural deafness combined with endolymphatic hydrops and lack of endocochlear potential. The mutant inner ear is enlarged from E15 and fewer Slc26a4-expressing cells are present in the endolymphatic epithelium. By single cell RNA sequencing of mutant and wild-type endolymphatic sacs we find marked reduction in genes important for ion transport such as Slc24a4 and Ttyh1 and gap-junctions such as Gjb2 and up-regulation of Wnt signaling and Igfbp2 that promotes progenitor proliferation. The cochlea overexpresses Aqp3, which encodes a water channel. We find by biochemical and cell-based transactivation assays and genetic interaction tests that SOX9 and SOX10 normally work co-operatively to repress Aqp3 transcription: SOX9Y440X blocks this repression by dominant interference. Our study reveals the key roles of SOXE transcription factors in the development of endolymphatic sac function, and highlight a molecular mechanism whereby the CD mutation exerts both a dominant negative and haploinsufficient mechanisms in different compartments of the inner ear to maintain fluid homeostasis. In the cochlea, SOX9 and SOX10 together repress aquaporin expression whereas in the endolymphatic sac, SOX9 controls SOX10 expression and genes for ion transport and gap-junctions. We postulate that in addition to loss of control of cell proliferation results in the exhaustion of progenitors which in turn leads to a deficit in mitochondria-rich cells. These results highlight a multifaceted mechanism for maintaining the proper fluid balance for hearing.

Project description:The downstream events and target genes of p53 in senescence responses are not fully understood. Here, we report a novel function of the forkhead transcription factor Foxp3, a key player in mediating T cell inhibitory function, in p53-mediated cellular senescence. Overexpression of Foxp3 in mouse embryonic fibroblasts (MEFs) accelerates senescence, whereas Foxp3 knockdown leads to escape from p53-mediated senescence in p53-expressing MEFs. Consistently, Foxp3 expression resulted in the induction of senescence in epithelial cancer cells, including MCF7 and HCT116. Foxp3 overexpression also increased the intracellular levels of reactive oxygen species (ROS). The ROS inhibitor N-acetyl-L-cysteine rescued Foxp3 expression-induced senescence. Furthermore, the elevated ROS levels that accompanied Foxp3 overexpression were paralleled by an increase in p21 expression. Knockdown of p21 in Foxp3-expressing MEFs abrogated the Foxp3-dependent increase in ROS levels, indicating that Foxp3 acts through p21 induction and subsequent ROS elevation to trigger senescence. Collectively, these results suggest that Foxp3 is a downstream target of p53 that is sufficient to induce p21 expression and ROS production and is necessary for p53-mediated senescence. control and treated samples (human), young passage (p3) or old passage (p7) samples (mouse)

Project description:Long noncoding RNAs regulating diverse cellular processes implicate in many diseases. Here, we report the identification of a novel long intergenic noncoding RNA, Linc-ASEN, expressed in prematurely senescent cells, that associates with UPF1 and represses cellular senescence by reducing p21 production transcriptionally and post-transcriptionally. The Linc-ASEN-UPF1 complex suppressed p21 transcription by recruiting Polycomb Repressive Complex 1 (PRC1) and PRC2 to the p21 locus, and thereby preventing binding of the transcriptional activator p53 on the p21 promoter. Moreover, the Linc-ASEN-UPF1 complex repressed p21 expression post-transcriptionally by lowering p21 mRNA stability in association with DCP1A. Accordingly, Linc-ASEN levels were found inversely correlated with p21 mRNA levels in tumor tissues from patient-derived xenograft mice, in various human cancer tissues, and in aged mice tissues. Our studies reveal that Linc-ASEN prevents cellular senescence by reducing the transcription and stability of p21 mRNA in concert with UPF1, and suggest that Linc-ASEN might be a potential therapeutic target in processes influenced by senescence, including cancer.

Project description:Long noncoding RNAs regulating diverse cellular processes implicate in many diseases. Here, we report the identification of a novel long intergenic noncoding RNA, Linc-ASEN, expressed in prematurely senescent cells, that associates with UPF1 and represses cellular senescence by reducing p21 production transcriptionally and post-transcriptionally. The Linc-ASEN-UPF1 complex suppressed p21 transcription by recruiting Polycomb Repressive Complex 1 (PRC1) and PRC2 to the p21 locus, and thereby preventing binding of the transcriptional activator p53 on the p21 promoter. Moreover, the Linc-ASEN-UPF1 complex repressed p21 expression post-transcriptionally by lowering p21 mRNA stability in association with DCP1A. Accordingly, Linc-ASEN levels were found inversely correlated with p21 mRNA levels in tumor tissues from patient-derived xenograft mice, in various human cancer tissues, and in aged mice tissues. Our studies reveal that Linc-ASEN prevents cellular senescence by reducing the transcription and stability of p21 mRNA in concert with UPF1, and suggest that Linc-ASEN might be a potential therapeutic target in processes influenced by senescence, including cancer.