Project description:Diabetic complications frequently arise in mechanically stressed regions, yet the molecular links between biomechanical forces and metabolic dysfunction remain unclear. Here, we demonstrate that mechanical stress induces glucose accumulation and downstream metabolic stress in keratinocytes, leading to mitochondrial injury and inflammation. Mechanistically, Piezo1 activation led to intracellular glucose overload and excessive advanced glycation end-products (AGEs) accumulation, which induced mitochondrial DNA (mtDNA) leakage into the cytosol and subsequently activated the cGAS–STINGsignaling cascade. Keratinocyte-specific Piezo1 deletion markedly reduced AGEs accumulation and preserved mitochondrial integrity, while Stimulator of interferon genes (STING) ablation reproduced similar downstream protective effects. Keratinocyte-specific deletion of the mechanosensor Piezo1 reduces advanced glycation end-products (AGEs) accumulation, preserves mitochondrial integrity, and dampens inflammatory signaling. Further, we show that this injury cascade involves cytosolic leakage of mitochondrial DNA (mtDNA) and activation of the cGAS–STING pathway. Stimulator of interferon genes (STING) ablation recapitulates the protective phenotype, confirming its downstream role. Notably, we identify Cortistatin (CST), an endogenous neuropeptide, as a previously unrecognized inhibitory ligand of Piezo1. CST binding attenuates calcium intake and glucose accumulation under mechanical stress, conferring notable protection in vitro and in diabetic ulcer (DUs) models. These findings uncover a CST–Piezo1–STING regulatory axis that integrates mechanical and metabolic cues to drive keratinocyte dysfunction in diabetes.

Project description:In China, the incidence of fracture non-unions is relatively high. Impaired endochondral ossification may lead to nonunion due to improper mechanical loading. As a mechanosensitive ion channel protein, Piezo1mediates mechanical transduction and induces calcium inward flow. Our early study showed that the osteogenic and angiogenic capacity of chondrocytes was reduced, if Piezo1 gene was knocked out on chondrocytes. Moreover, the expression of mitochondrion translation related gene LARS2 was signaling increased. Therefore, we hypothesize that the mechanical loading may cause endochondral ossification through the Piezo1- LARS2 signaling pathway. We will use conditioned gene knockout mice and Peizo1 knockdown stable cell line to support the hypothesis. Our goals include investigating the changes of Piezo1 expression during endochondral ossification of femoral fracture healing in mice under mechanical loading; investigating the response of Piezo1 channels on chondrocytes to mechanical stimulation and its role and mechanism in regulating chondrocyte osteogenesis and angiogenesis, maintaining the normal mitochondrial function in vitro; analysing the key molecular and signal network downstream of Piezo1 through the multi-omics techniques; and exploring the response mechanism of Piezo1 under vibrating stimulus. This project aims to study the molecular mechanism of Piezo1-mediated force-biological information transition and its role in endochondral ossification. We hope it provides an effective intervention target for preventing and treating fracture nonunion.

Project description:Glycation, or non-enzymatic glycosylation, has recently attracted increasing interest in the context of its impact on aging. Advanced glycation end products (AGEs) contribute to various age-related pathological conditions such as inflammation, fibrosis, stem cell aging, etc. However, the molecular mechanisms underlying the glycation-induced disruption of cell-matrix interactions during cellular senescence are not fully understood. The aim of this study was to investigate transcriptomic changes in young and senescent dermal fibroblasts (HdFbs) cultivated in post-glycated 3D collagen type I matrices after 10 and 17 days. Our findings indicate that the D-ribose-mediated glycation increases the accumulation of fluorescent AGEs and the stiffness of the matrices in a dose-dependent manner. The transcriptome alterations encompassed the modulation of age-related genes and signaling pathways, including the activation of genes related to senescence-associated secretory phenotype (SASP) in young cells. Notably, the alterations in the transcriptome profiles due to glycation were more pronounced (in terms of both the number of genes and their fold changes) on day 10 of cultivation compared to day 17 in both passages.

Project description:Macrophages play a pivotal role in mechanical force-induced inflammatory bone remodeling. Yet, how macrophages perceive mechanical stimuli and thereby modulate biological behaviors remain elusive. The orthodontic tooth movement (OTM) model was established to access the role of Piezo1 in modulating macrophage response upon mechanical stimuli. The potential functions and molecule mechanisms of Piezo1 were explored by bone marrow-derived macrophages (BMDMs) using mechanical stretch system, western blotting, immunofluorescence, flow cytometry and RNA sequencing. We first found macrophage proliferative phenotype enhanced at the later stage of force application. The biological variation mediated by mechanical force could be suppressed by Piezo1 inhibition. Furthermore, Piezo1 activated PI3K-AKT signaling was closely associated with macrophage proliferation upon mechanical stimuli. Additionally, Ccnd1 was authenticated as a critical downstream factor of PI3K-AKT signaling and conditional ablation of Ccnd1 in macrophages inhibited macrophage proliferation in mechanical force-induced bone remodeling procedure.

Project description:Chondrocytes can potentially perceive mechanical stimuli via Piezo channels. We investigated the effect of the Piezo1 agonist Yoda1 on chondrocyte-like ATDC5 cells. Chondrocytes can potentially perceive mechanical stimuli via Piezo channels. We investigated the effect of the Piezo1 agonist Yoda1 on chondrocyte-like ATDC5 cells. Chondrocytes can potentially perceive mechanical stimuli via Piezo channels. We investigated the effect of the Piezo1 agonist Yoda1 on chondrocyte-like ATDC5 cells. Chondrocytes can potentially perceive mechanical stimuli via Piezo channels. We investigated the effect of the Piezo1 agonist Yoda1 on chondrocyte-like ATDC5 cells. We used microarray analysis to detail the global gene expression of ATDC5 cells in response to 6 hours of treatment with 5µM Yoda1.

Project description:Functional complexity of the eukaryotic mitochondrial proteome is augmented by independent gene acquisition from bacteria since its endosymbiotic origins. Mammalian homologs of many ancestral mitochondrial proteins have uncharacterized catalytic activities. Recent forward genetics approaches have attributed functions to proteins in established metabolic pathways limiting the possibility of identifying novel biology which may be relevant to human disease. We undertook a bottom-up biochemistry approach to identify evolutionarily conserved mitochondrial proteins with catalytic potential. Here, we identify a Parkinson-associated DJ-1/PARK7-like protein – glutamine amidotransferase-like class 1 domain containing 3A (GATD3A), with evolutionary origins from gammaproteobacteria. We demonstrate that GATD3A localizes to the mitochondrial matrix and functions as a deglycase. Through its amidolysis domain, GATD3A removes non-enzymatic chemical modifications produced during the Maillard reaction between dicarbonyls and amines of nucleotides and amino acids. GATD3A interacts with factors involved in mitochondrial mRNA processing and translation, suggestive of a role in maintaining integrity of important biomolecules through its deglycase activity. The loss of GATD3A in mice is associated with accumulation of advanced glycation endproducts (AGEs) and altered mitochondrial dynamics. An evolutionary perspective helped us prioritize a previously uncharacterized but predicted mitochondrial protein GATD3A, which mediates the removal of early glycation intermediates. GATD3A restricts the formation of AGEs in mitochondria and is a relevant target for diseases where AGE deposition is a pathological hallmark. This dataset consists of FLAG co-immunoprecipitated GATD3A from Gatd3aFLAG/FLAG mouse heart left ventricular mitochondria.

Project description:Functional complexity of the eukaryotic mitochondrial proteome is augmented by independent gene acquisition from bacteria since its endosymbiotic origins. Mammalian homologs of many ancestral mitochondrial proteins have uncharacterized catalytic activities. Recent forward genetics approaches have attributed functions to proteins in established metabolic pathways limiting the possibility of identifying novel biology which may be relevant to human disease. We undertook a bottom-up biochemistry approach to identify evolutionarily conserved mitochondrial proteins with catalytic potential. Here, we identify a Parkinson-associated DJ-1/PARK7-like protein – glutamine amidotransferase-like class 1 domain containing 3A (GATD3A), with evolutionary origins from gammaproteobacteria. We demonstrate that GATD3A localizes to the mitochondrial matrix and functions as a deglycase. Through its amidolysis domain, GATD3A removes non-enzymatic chemical modifications produced during the Maillard reaction between dicarbonyls and amines of nucleotides and amino acids. GATD3A interacts with factors involved in mitochondrial mRNA processing and translation, suggestive of a role in maintaining integrity of important biomolecules through its deglycase activity. The loss of GATD3A in mice is associated with accumulation of advanced glycation endproducts (AGEs) and altered mitochondrial dynamics. An evolutionary perspective helped us prioritize a previously uncharacterized but predicted mitochondrial protein GATD3A, which mediates the removal of early glycation intermediates. GATD3A restricts the formation of AGEs in mitochondria and is a relevant target for diseases where AGE deposition is a pathological hallmark. This dataset consists of peptides identified following in-gel digestions of bands observed following FPLC purification of recombinant human GATD3A.

Project description:Hyperglycemia accelerates calcification of atherosclerotic plaques in diabetic patients, and the prolonged accumulation of advanced glycation end products (AGEs) induced by hyperglycemia may be closely related to the pathogenesis of aortic calcification. However, the mechanisms underlying this association remain unclear. In the current study, we investigated the role of vascular smooth muscle cell nuclear factor 90/110 (NF90/110) in mediating AGEs accumulation and accelerating diabetic atherosclerotic calcification. Using vascular smooth muscle cells (VSMCs), human samples, and mouse models, we found that hyperglycemia-mediated AGEs markedly increased VSMC NF90/110 activation both in human and mouse atherosclerotic calcified tissues with diabetes. Silencing of NF90/110 in vitro and genetic deletion of VSMC NF90/110 in mice decreased obviously AGEs-induced arteriosclerotic calcification. Mechanistically, AGEs increased the activity of NF90, which then enhanced ubiquitination and degradation of AGE receptor 1 (AGER1) by stabilizing the mRNA of E3 ubiquitin ligase, F-box, and WD repeat domain 7 (FBXW7), thus causing the accumulation of more AGEs. Furthermore, AGEs accumulation accelerated diabetic atherosclerotic calcification by inducing VSMC phenotypic changes to osteoblast-like cells, apoptosis, and matrix vesicle release. Collectively, our study demonstrated the effects of VSMC NF90 in mediating the metabolic imbalance of AGEs to accelerate diabetic arteriosclerotic calcification. These novel findings elucidate a pivotal mechanism underlying AGE-induced diabetic atherosclerotic calcification and provide a framework for potential interventions against diabetic vascular complications.

Project description:Wolff’s law and the Utah Paradigm of skeletal physiology state that bone architecture adapts to mechanical loads. These models predict the existence of a mechanostat that links strain induced by mechanical forces to skeletal remodeling. However, how the mechanostat influences bone remodeling remains elusive. Here, we find that Piezo1 deficiency in osteoblastic cells leads to loss of bone mass and spontaneous fractures with increased bone resorption. Furthermore, Piezo1-deficient mice are resistant to further bone loss and bone resorption induced by hind limb unloading, demonstrating that PIEZO1 can affect osteoblast-osteoclast crosstalk in response to mechanical forces. At the mechanistic level, in response to mechanical loads, PIEZO1 in osteoblastic cells controls the YAP-dependent expression of type II and IX collagens. In turn, these collagen isoforms regulate osteoclast differentiation. Taken together, our data identify PIEZO1 as the major skeletal mechanosensor that tunes bone homeostasis.

Project description:Non-enzymatic reactions in glycolysis lead to the accumulation of methylglyoxal (MGO), a reactive precursor to advanced glycation end-products (AGEs), which has been hypothesized to drive obesity and aging-associated pathologies. A combination of nicotinamide, lipoic acid, thiamine, pyridoxamine, and piperine (Gly-Low), was identified to lower glycation by reducing MGO and MGO-derived AGE, MG-H1, in mice. Administration of Gly-Low reduced food consumption, lowered body weight, improved insulin sensitivity, and increased survival in both leptin receptor-deficient (Leprdb) and wild-type C57B6/J mice. Unlike caloric restriction, Gly-Low modulated hypothalamic signaling by upregulating mTOR pathway signaling to inhibit ghrelin-mediated hunger response. Gly-Low also slowed hypothalamic aging and increased survival when administered as a late-life intervention, suggesting its potential benefits in ameliorating age-associated decline by inducing voluntary caloric restriction and reducing glycation.