Project description:Cellular senescence is a hallmark of aging and the accumulation of senescent cells (SnCs) accelerates the aging process, contributing to aging-related organ disorders. The PRDF1 and RIZ1 homology domain (PRDM) protein exhibits robust transcriptional regulatory activities and governs a wide range of biological processes. However, its roles in cellular senescence remain unclear. Here, we demonstrated that PRDM16, a member of the PRDM protein family, decreased significantly in multiple organs of aged mice compared to young mice. Global Prdm16 deletion contributed to cellular senescence in various organs, including the kidneys, heart, lungs, hippocampus, stomach, and gut, leading to accelerated aging-related organ injury. Furthermore, tubular-specific Prdm16 deletion aggravated irradiation-induced kidney aging and aging-related kidney diseases in irradiated mice subjected to ischemia-reperfusion surgery. Exogenous PRDM16 gene delivery by lentivirus effectively attenuated cellular senescence in vitro and in vivo. Mechanistically, PRDM16 improved glutathione metabolism and inhibited oxidative DNA damage, which is a driving force of senescence. Specifically, PRDM16 upregulated the transcription of glutathione S-transferase mu 1 (GSTM1) by binding to its promoter region. Transfection with GSTM1 reversed PRDM16 deficiency-induced cellular senescence and kidney aging. Collectively, our results provide a potential target for the investigation of anti-aging therapies.

Project description:GSTM1 binding RNAs were analyzed by imprinting RNA-sequencing of specific antibody-retrieved complexes from peritoneal macrophage cells lysis.

Project description:To investigate the role of GSTM1, we knocked down GSTM1 expression in primary mouse astrocytes using lenvirtus vector expressing Gstm1 shRNAmir and then exposed them to TNF-alpha. Non-silencing shRNAmir and non-stimulation served as shRNA and treatment controls, respectively.

Project description:GSTM1 binding RNA RIP-seq

Project description:Introduction: Meningiomas are the most common primary central nervous system (CNS) tumor in adults, comprising one-third of all primary adult CNS tumors. Although several recent publications have identified molecular alterations in meningioma including characteristic mutations, copy number alterations, and gene expression signatures, our understanding of the drivers of meningioma recurrence is limited. Objective: To identify gene expression signatures of 1p-22q-NF2- meningioma recurrence, with concurrent biallelic inactivation of NF2 and loss of chr1p that are heterogenous but enriched for recurrent meningiomas. Methods: Transcriptomic alterations present in recurrent versus primary 1p-22q-NF2- meningiomas were identified using RNA sequencing (RNA-seq) data in a clinically annotated cohort. Results: Recurrent 1p-22q-NF2- meningiomas were enriched for a newly identified GSTM1 null genotype compared to primary meningiomas that showed variable GSTM1 expression and independent external validation was performed. Conclusions: The GSTM1 null genotype is a novel biomarker of 1p-22q-NF2- meningioma recurrence that resolves heterogeneity in existing meningioma subtypes and may be used to guide future clinical management decisions on extent of treatment to improve patient outcomes.

Project description:Kidney is a vital organ responsible for homeostasis in the body. To retard kidney aging is of great importance for maintaining body health. Whereas the therapeutic strategies targeting against kidney aging are not elucidated. Recent studies show mitochondrial dysfunction is critical for renal tubular cell senescence and kidney aging, however, the underlying mechanisms of mitochondrial dysfunction in kidney aging have not been demonstrated. Herein, we found calcium overload, and the mitochondrial calcium uniporter (MCU) was induced in renal tubular cells and aged kidney. To activate MCU not only triggered mitochondrial calcium overload, but also induced reactive oxygen species (ROS) production and cellular senescence and age-related kidney fibrosis. Inversely, to block MCU or chelate calcium diminished ROS generation, restored mitochondrial homeostasis, and retarded cell senescence and protected against kidney aging. These results demonstrate MCU plays a key role in promote renal tubular cell senescence, which provides a new insight on the therapeutic strategy for fighting against kidney aging.

Project description:Cranial neural crest (NCC)-derived chondrocyte precursors undergo a dynamic differentiation and maturation process to establish a scaffold for subsequent bone formation, alterations in which contribute to congenital birth defects. Here, we demonstrate that transcription factor and histone methyltransferase proteins Prdm3 and Prdm16 control the differentiation switch of cranial NCCs to craniofacial cartilage. Loss of either results in hypoplastic and unorganized chondrocytes due to impaired cellular orientation and polarity. We show that PRDMs regulate cartilage differentiation by controlling the timing of Wnt/β-catenin activity in strikingly different ways: prdm3 represses while prdm16 activates global gene expression, though both by regulating Wnt enhanceosome activity and chromatin accessibility. Finally, we show that manipulating Wnt/β-catenin signaling pharmacologically or generating prdm3-/-;prdm16-/- double mutants rescues craniofacial cartilage defects. Our findings reveal upstream regulatory roles for Prdm3 and Prdm16 in cranial NCCs to control Wnt/β-catenin transcriptional activity during chondrocyte differentiation to ensure proper development of the craniofacial skeleton.

Project description:This study investigates the effects of hyperbaric oxygen (HBO) on cellular senescence and aging-related phenotypes. In naturally aged mice, HBO treatment reduced systemic senescence burden and reversed aging-related transcriptomic signatures in skin, liver, and kidney tissues. Additionally, single-session HBO exposure was shown to preferentially suppress SASP propagation in human stromal cells. This dataset includes transcriptomic profiles of skin, liver, and kidney tissues from young, aged, and HBO-treated aged mice, as well as human primary prostate stromal cells (PSC27).

Project description:Autosomal dominant polycystic kidney disease (ADPKD) is one of the most common, life-threatening inherited kidney diseases. Cellular senescence regulates not only physiological and homeostatic processes, particularly during embryonic development and wound healing, but also pathological processes that contribute to aging, cancer, and other diseases in response to endogenous and exogenous stresses. However, the role of cellular senescence in ADPKD remains elusive. To determine whether D-gal induces differential senescence response in Pkd1-null vs. wild-type cells, we performed RNA-sequencing (RNA-seq) analysis.

Project description:Mice on two different ketogenic diets induce p53 and cellular senescence in multiple organs, including heart and kidney. This is mediated through inactivation of MDM2 by caspase-2 cleavage, leading to p53 accumulation and induction of p21. Ketogenic diet also induced pAMPK, suggesting that persistent activation leads to p53-dependent senescence.