Project description:Current clinical approaches to promote osteoporotic fracture healing primarily target osteoclast biology, overlooking the negative regulatory role of fibroblasts in fracture healing. Perioperative bisphosphonates (BPs) used in anti-osteoporosis treatment for osteoporotic fractures have become a consensus worldwide. However, excessive fibrosis is induced simultaneously, leading to fracture non-union and atypical femur fractures. It is highly desirable to inhibit osteoclasts but block fibrosis. In this study, an magnesium ions (Mg2+)-BPs MOF-based bone adhesive material was designed to down-regulate SOST and weaken SOST/TGF-β signaling pathway through Mg2+ through transcriptome analysis, thus inhibiting fibrotic differentiation and subsequent disordered mineralization.

Project description:Comparative transcriptomic analysis of HUVECs cultured on hydroxyapatite doping with Mg2+ (HA/Mg) versus Trio-Active bone scaffold (TABS)

Project description:Comparative transcriptomic analysis of Raw264.7 cells cultured on hydroxyapatite doping with Mg2+ (HA/Mg) versus Trio-Active bone scaffold (TABS)

Project description:Comparative transcriptomic analysis of MC3T3-E1 cells cultured on hydroxyapatite doping with Mg2+ (HA/Mg) versus Trio-Active bone scaffold (TABS)

Project description:There are currently no approved therapeutic interventions to promote skeletal muscle regeneration following traumatic muscle injury, among the most common debilitating injuries. Here we developed a new therapeutic approach for severe muscle injury that significantly prevents muscle atrophy, while promoting rapid muscle repair, regeneration and regeneration of neuro-muscular junctions (NMJs), orchestrated by gene delivery of the mRNA binding protein AUF1. Key regulators of myogenesis and NMJs are encoded by mRNAs that are regulated in their stability and translation by AUF1. Using preclinical mouse models of severe muscle injury, we show that delivery of the AUF1 gene to muscle cells systemically or intramuscularly by AAV8 or lentivirus vectors, prophylactically, during or 24 hours after injury, is highly effective in reducing muscle atrophy, rapidly expanding muscle stem cells, promoting accelerated muscle repair, regeneration and maturation, while restoring NMJs. Animals receiving AUF1 therapy following severe tibialis anterior muscle injury, rapidly regained near-normal muscle strength and function by two weeks, whereas control animals showed continued significant deficit four months later. Histologic and ultrastructure electron micrographic analysis shows that AUF1 gene therapy restores normal muscle architecture and muscle mass. AUF1 therapy is a potential new approach for treating severe muscle injury.

Project description:Mg2+ is an essential cofactor for numerous enzymes, supporting fundamental cellular processes. Phosphatase of regenerating liver (PRL) protein family, inhibits cyclin M (CNNM) Mg2+ efflux transporters. To elucidate the physiological role of PRL in Mg2+ homeostasis at the cellular level, we employed combined genetic knockout and knockdown approaches. Such PRL KO + KD led to marked reduction of intracellular Mg2+ levels and triggered extensive cell death. To investigate the mechanism underlying cell death induced by PRL KO + KD, we next performed transcriptomic analysis to profile the changes in global gene expression, which revealed activation of the NF-κB pathway, and accordingly, genetic deletion of NF-κB p65 subunit abrogated cell death. Similarly, CNNM overexpression triggered intracellular Mg2+ decrease, NF-κB activation and subsequent cell death. Notably, this form of cell death exhibited unique morphological features, including actin-driven fiber-like protrusions, distinguishing it from known cell death modalities. Our findings uncover a previously unrecognized mode of NF-κB-dependent cell death triggered by intracellular Mg2+ decrease.

Project description:Tripartite resistance nodulation and cell division multidrug efflux pumps span the periplasm and are major drivers of multidrug resistance among Gram-negative bacteria. Cations, such as Mg2+, become concentrated within the periplasm and, in contrast to the cytoplasm, it’s pH is sensitive to conditions outside the cell. Here, we reveal an interplay between Mg2+ and pH in modulating the structural dynamics of the periplasmic adaptor protein, AcrA, and its function within the prototypical AcrAB-TolC multidrug pump from Escherichia coli. In the absence of Mg2+, AcrA becomes increasingly plastic within acidic conditions, but when Mg2+ is bound this is ameliorated, resulting instead in domain specific organisation. We establish a unique histidine residue directs these dynamics and is essential for sustaining pump activity across acidic, neutral, and basic regimes. Overall, we propose Mg2+ conserves AcrA structural mobility to ensure optimal AcrAB-TolC function within rapid changing environments commonly faced during bacterial infection and colonization.

Project description:TRIP4 is one of the subunits of the transcriptional coregulator ASC-1, a ribonucleoprotein complex that participates in transcriptional coactivation and RNA processing events. Recessive variants in the TRIP4 gene have been associated with spinal muscular atrophy with bone fractures as well as a severe form of congenital muscular dystrophy. Here we present the diagnostic journey of a patient with cerebellar hypoplasia and spinal muscular atrophy (PCH1) and congenital bone fractures. Initial exome sequencing analysis revealed no candidate variants. Reanalysis of the exome data by inclusion in the Solve-RD project resulted in the identification of a homozygous stop-gain variant in the TRIP4 gene, previously reported as disease-causing. This highlights the importance of analysis reiteration and improved and updated bioinformatic pipelines. Proteomic profile of the patient’s fibroblasts showed altered RNA-processing and impaired exosome activity supporting the pathogenicity of the detected variant. In addition, we identified a novel genetic form of PCH1, further strengthening the link of this characteristic phenotype with altered RNA metabolism.

Project description:Osteoporotic fractures are notoriously difficult to heal due to an imbalance between osteoblasts and osteoclasts. Current treatments often have limited efficacy or adverse side effects, highlighting the need for safer, more effective solutions. Here, we developed an injectable plant-derived phosphate coordination compound-based adhesive hydrogel to restore bone homeostasis by integrating magnesium ions (Mg2+)-phytic acid (PA) nanoparticles with aminated gelatin and aldehydated starch. The hydrogel can firmly adhere to irregular bone tissue at the fracture site and achieve achieve Mg-PA degradation in response to the osteoporotic acidic microenvironment, releasing PA and Mg2+, which modulated osteoclast and osteoblast activity, respectively. Impressively, PA inhibits osteoclastogenesis by stimulating monocyte secretion of CCN1, which competitively binds RANKL to disrupt RANKL-RANK signaling. Meanwhile, Mg2+ enhances osteoblast differentiation from bone marrow stem cells. In an ovariectomized rat model, the hydrogel significantly accelerates fracture healing (84.63% improvement over the control groups in flexural strength). This study highlights the potential of PA-based coordination compounds as a novel strategy for osteoporotic fracture treatment.

Project description:Enterococcus lactis strain:MG2-8 Genome sequencing and assembly