Low-dose radiation-induced SUMOylation of NICD1 negatively regulates osteogenic differentiation in BMSCs.

Various biological effects of ionizing radiation, especially continuous exposure to low-dose radiation (LDR), have attracted considerable attention. Impaired bone structure caused by LDR has been reported, but little is known about the mechanism involved in the disruption of bone metabolism. In this study, given that LDR was found to (at a cumulative dose of 0.10 Gy) disturb the serum Mg2+ level and Notch1 signal in the mouse femur tissues, the effects of LDR on osteogenesis and the underlying molecular mechanisms were investigated based on an in vitro culture system for bone marrow stromal cells (BMSCs). Our data showed that cumulative LDR suppressed the osteogenic potential in BMSCs as a result of upregulation of Notch1 signaling. Further analyses indicated that the upregulation of NICD1 (Notch1 intracellular domain), the key intracellular domain for Notch1 signaling, under LDR was a consequence of enhanced protein stabilization caused by SUMOylation (small ubiquitin-like modification). Specifically, the downregulation of SENP1 (sentrin/SUMO-specific protease 1) expression induced by LDR enhanced the SUMOylation of NICD1, causing the accumulation of Notch1 signaling, which eventually inhibited the osteogenic potential of BMSCs. In conclusion, this work expounded on the mechanisms underlying the impacts of LDR on bone metabolism and shed light on the research on bone regeneration under radiation.

Programmable Unlocking Nano-Matryoshka-CRISPR Precisely Reverses Immunosuppression to Unleash Cascade Amplified Adaptive Immune Response.

Immune checkpoint blockade (ICB) is an attractive option in cancer therapy, but its efficacy is still less than expected due to the transient and incomplete blocking and the low responsiveness. Herein, an unprecedented programmable unlocking nano-matryoshka-CRISPR system (PUN) targeting programmed cell death ligand 1 (PD-L1) and protein tyrosine phosphatase N2 (PTPN2) is fabricated for permanent and complete and highly responsive immunotherapy. While PUN is inert at normal physiological conditions, enzyme-abundant tumor microenvironment and preternatural intracellular oxidative stress sequentially trigger programmable unlocking of PUN to realize a nano-matryoshka-like release of CRISPR/Cas9. The successful nucleus localization of CRISPR/Cas9 ensures the highly efficient disruption of PD-L1 and PTPN2 to unleash cascade amplified adaptive immune response via revoking the immune checkpoint effect. PD-L1 downregulation in tumor cells not only disrupts PD-1/PD-L1 interaction to attenuate the immunosurveillance evasion but also spurs potent immune T cell responses to enhance adaptive immunity. Synchronously, inhibition of JAK/STAT pathway is relieved by deleting PTPN2, which promotes tumor susceptibility to CD8+ T cells depending on IFN-γ, thus further amplifying adaptive immune responses. Combining these advances together, PUN exhibits optimal antitumor efficiency and long-term immune memory with negligible toxicity, which provides a promising alternative to current ICB therapy.

Electron donation characteristics and interplays of major volatile fatty acids from anaerobically fermented organic matters in bioelectrochemical systems.

Anaerobic fermentation liquid of waste organic matters (WOMs) is rich in volatile fatty acids (VFAs), which can be treated with bioelectrochemical systems for both electrical energy recovery and organics removal. In this work, four major VFAs in the fermented WOMs supernatant were selected to examine their electron donation characteristics for power output and their complicated interplays in microbial fuel cells (MFCs). Results indicated a priority sequence of acetate, propionate, n-butyrate and i-valerate when served as the sole electron donor for electricity generation. The MFC solely fed with acetate showed the highest coulombic efficiency and power density, and the longest period for electricity production. When two of the VFAs were added with equal proportion, both acids contributed positively to electricity generation, while the selective or competitive use of substrates by diverse microorganisms behaved as an antagonism effect to prolong the degradation time of each VFA. When acetate and propionate, the preferable substrates for electricity generation, were mixed in various proportions, their large concentration difference led to improved electrical performance but decreased organic removal rate.

MicroRNA-27b-3p inhibits apoptosis of chondrocyte in rheumatoid arthritis by targeting HIPK2.

BACKGROUND: Understanding the mechanism of chondrocytes degeneration could provide a new potential therapeutic idea for rheumatoid arthritis (RA) treatment. MicroRNA-27b-3p (miR-27b-3p) has been shown to regulate a variety of cell behaviors in various cell types. However, the role of miR-27b-3p in RA remains unknown. MATERIALS AND METHODS: Expression of miR-27b-3p and HIPK2 in cartilage tissues and chondrocytes was characterized using qRT-PCR and Western blot. MiR-27b-3p was overexpressed or suppressed in chondrocytes to observe the potential role of miR-27b-3p. RESULTS: We found declined miR-27b-3p and elevated HIPK2 in RA tissues and cells using qRT-PCR. Dual-luciferase reporter assay validated HIPK2 is a direct target of miR-27b-3p, confirmed by Western blot results. Pearson correlation presented that there was a significantly negative correlation between miR-27b-3p and HIPK2 mRNA. Overexpression of miR-27b-3p significantly reduced the expression of pro-apoptotic protein c-caspase3 and increased the expression of anti-apoptotic Bcl-2; however, downregulation of miR-27b-3p has a significant effect of inducing apoptosis. Furthermore, overexpression of miR-27b-3p combined with recombinant HIPK2 protein showed the inhibitory effect of miR-27b-3p was abolished by HIPK2. CONCLUSION: We found declined miR-27b-3p and elevated HIPK2 in RA tissues and cells. Further in vitro studies demonstrated that miR-27b might inhibit chondrocyte apoptosis and thus attenuate RA development by directly inhibiting HIPK2 expression.

miR-100-5p-abundant exosomes derived from infrapatellar fat pad MSCs protect articular cartilage and ameliorate gait abnormalities via inhibition of mTOR in osteoarthritis.

Osteoarthritis (OA) is the most common disabling joint disease throughout the world and its therapeutic effect is still not satisfactory in clinic nowadays. Recent studies showed that the exosomes derived from several types of mesenchymal stem cells (MSCs) could maintain chondrocyte homeostasis and ameliorate the pathological severity of OA in animal models, indicating that MSCs-derived exosomes could be a novel promising strategy for treating OA. In this study, we investigated the role and underlying mechanisms of infrapatellar fat pad (IPFP) MSCs-derived exosomes (MSCIPFP-Exos) on OA in vitro and in vivo. Our data revealed that MSCIPFP could produce amounts of MSCIPFP-Exos, which exhibited the typical morphological features of exosomes. The MSCIPFP-Exos ameliorated the OA severity in vivo and inhibited cell apoptosis, enhanced matrix synthesis and reduced the expression of catabolic factor in vitro. Moreover, MSCIPFP-Exos could significantly enhance autophagy level in chondrocytes partially via mTOR inhibition. Exosomal RNA-seq showed that the level of miR-100-5p that could bind to the 3'-untranslated region (3'UTR) of mTOR was the highest among microRNAs. MSCIPFP-Exos decreased the luciferase activity of mTOR 3'UTR, while inhibition of miR-100-5p could reverse the MSCIPFP-Exos-decreased mTOR signaling pathway. Intra-articular injection of antagomir-miR-100-5p dramatically attenuated MSCIPFP-Exos-mediated protective effect on articular cartilage in vivo. In brief, MSCIPFP-derived exosomes protect articular cartilage from damage and ameliorate gait abnormality in OA mice by maintaining cartilage homeostasis, the mechanism of which may be related to miR100-5p-regulated inhibition of mTOR-autophagy pathway. As it is relatively feasible to obtain human IPFP from OA patients by arthroscopic operation in clinic, MSCIPFP-derived exosomes may be a potential therapy for OA in the future.