Project description:Diabetic foot ulcer (DFU) is a serious complication of diabetes mellitus, which causes great health damage and economic burden to patients. The pathogenesis of DFU is not fully understood.We screened wound healing-related genes using bioinformatics analysis, and full-thickness skin injury mice model and cellular assays were used to explore the role of target genes in diabetic wound healing. SFRP2 was identified as a wound healing-related gene, and the expression of SFRP2 is associated with immune cell infiltration in DFU. In vivo study showed that suppression of SFRP2 delayed the wound healing process of diabetic mice, impeded angiogenesis and matrix remodeling, and increased macrophage infiltration in wound tissues. In addition, suppression of SFRP2 enhanced M1 polarization in both the early and later stage of wound healing, and decreased M2 polarization in the later stage, which impeded the transition of M1 to M2 polarization of wound healing. Moreover, suppression of SFRP2 affected the transcriptome signatures-related to inflammatory response and energy metabolism at the early stage of wound healing. Extracellular flux analysis (EFA) showed that suppression of SFRP2 decreased mitochondrial energy metabolism and increased glycolysis in injury-related macrophages. Furthermore, suppression of SFRP2 inhibited transcriptome signaturesrelated to carbohydrate metabolism, lipid metabolism and amino acid metabolism, which consists the three main components of energy metabolism of macrophages. In conclusions, SFRP2 may function as a wound healing-related gene in DFU, and suppression of SFRP2 impaired diabetic wound healing by compromising the M1-to-M2 transition of macrophages and modulating the balance between mitochondrial energy metabolism and glycolysis.

Project description:Diabetic foot ulcer (DFU) is a serious complication of diabetes mellitus, which causes great health damage and economic burden to patients. The pathogenesis of DFU is not fully understood.We screened wound healing-related genes using bioinformatics analysis, and full-thickness skin injury mice model and cellular assays were used to explore the role of target genes in diabetic wound healing. SFRP2 was identified as a wound healing-related gene, and the expression of SFRP2 is associated with immune cell infiltration in DFU. In vivo study showed that suppression of SFRP2 delayed the wound healing process of diabetic mice, impeded angiogenesis and matrix remodeling, and increased macrophage infiltration in wound tissues. In addition, suppression of SFRP2 enhanced M1 polarization in both the early and later stage of wound healing, and decreased M2 polarization in the later stage, which impeded the transition of M1 to M2 polarization of wound healing. Moreover, suppression of SFRP2 affected the transcriptome signatures-related to inflammatory response and energy metabolism at the early stage of wound healing. Extracellular flux analysis (EFA) showed that suppression of SFRP2 decreased mitochondrial energy metabolism and increased glycolysis in injury-related macrophages. Furthermore, suppression of SFRP2 inhibited transcriptome signaturesrelated to carbohydrate metabolism, lipid metabolism and amino acid metabolism, which consists the three main components of energy metabolism of macrophages. In conclusions, SFRP2 may function as a wound healing-related gene in DFU, and suppression of SFRP2 impaired diabetic wound healing by compromising the M1-to-M2 transition of macrophages and modulating the balance between mitochondrial energy metabolism and glycolysis.

Project description:Impaired healing of diabetic wounds causes significant morbidity and mortality. This study aimed to identify novel mechanisms of diabetic wound healing defects and test a therapeutic intervention using diabetic mouse and pig models. We found Smad7 transgene expression in mouse epidermis promoting wound healing in diabetic dbdb mice, with reductions in obesity and blood glucose. To isolate effects of Smad7 on wounds, we created a Smad7-based biologic (Tat-PYC-Smad7) that penetrates wound cells. Topical application of Tat-PYC-Smad7 to diabetic pig and mouse wounds accelerated healing compared to controls. RNAseq analysis of mouse wound samples showed reduced TGF/NFB signaling, leading to faster re-epithelialization and better extracellular matrix remodeling. Tat-PYC-Smad7 also attenuated neutrophil degranulation and NETosis by blocking histone 3 citrullination and inhibiting myeloperoxidase activities. Our study reveals that Tat-PYC-Smad7 promotes diabetic wound healing by targeting keratinocytes and neutrophils, providing insight into cellular mechanisms of diabetic wound healing defects targetable by Smad7-based therapy.

Project description:Background: Diabetic wounds are a major complication of diabetes mellitus and heal poorly due to persistent inflammation, fibroblast dysfunction, oxidative stress, mitochondrial injury, and impaired angiogenesis. Scutellarein (SCU) is a natural flavonoid with demonstrated anti-inflammatory, antioxidant, and fibroblast-relevant bioactivities, but its effects on diabetic wound repair and the underlying molecular mechanisms remain poorly defined. Methods: A streptozotocin-induced diabetic mouse cutaneous wound model was used to evaluate the effects of topical SCU treatment on wound closure, epithelial repair, and collagen deposition. In vitro, an H₂O₂-induced oxidative injury model in fibroblasts was employed to assess SCU-mediated protection on migration, viability, redox balance, and mitochondrial structure and function. Transcriptomics (RNA-seq) was performed to identify SCU-responsive molecular pathways, and SCU-P2RX1 molecular docking combined with ATP rescue experiments was used to interrogate a P2RX1–calcium axis. Results: SCU accelerated diabetic wound closure and improved epithelial gap, collagen deposition, fibroblast-like cell proliferation, and angiogenesis in vivo. In vitro, SCU promoted fibroblast migration, suppressed H₂O₂-induced cell death, reduced intracellular ROS, restored mitochondrial morphology and membrane potential, and preserved ATP production. RNA-seq revealed that SCU downregulated P2rx1 and enriched calcium-transport, mitochondrial, and wound-healing pathways. Molecular docking predicted SCU binding to P2RX1 with a docking score of ΔG = −9.2 kcal/mol, and ATP addition reversed the SCU-mediated suppression of calcium overload, mitochondrial depolarization, and inflammatory gene expression.

Project description:Chronic diabetic wounds present a critical clinical challenge due to persistent inflammation and compromised healing. Here we report a novel sprayable nanozyme hydrogel that epigenetically reprograms macrophages to suppress inflammation and coordinate regeneration. Ultrasmall copper-based nanozymes (CuNZ, ~4 nm) synthesized via an eco-friendly one-pot method demonstrated potent multi-radical scavenging activity. When integrated into gelatin methacryloyl (Gel), CuNZ@Gel exhibited excellent sprayability, conformal skin coverage, and long-term storage stability, offering substantial translatable potential. Notably, the nanozyme hydrogel induced distinct epigenetic modifications in macrophages by remodeling chromatin accessibility, effectively shifting gene expression from pro-inflammatory to anti-inflammatory profiles. This epigenetic modulation persisted under oxidative stress, actively suppressing inflammatory while facilitating regenerative responses. In diabetic wound models, CuNZ@Gel significantly accelerated healing through its coordinated antioxidant, anti-inflammatory, and pro-regenerative actions. Unlike conventional passive dressings, our sprayable nanozyme hydrogel proactively reprograms the wound microenvironment via epigenetic antioxidant mechanisms, offering novel insights and strategy for managing chronic diabetic wounds and inflammatory skin complications.

Project description:Chronic diabetic wounds present a critical clinical challenge due to persistent inflammation and compromised healing. Here we report a novel sprayable nanozyme hydrogel that epigenetically reprograms macrophages to suppress inflammation and coordinate regeneration. Ultrasmall copper-based nanozymes (CuNZ, ~4 nm) synthesized via an eco-friendly one-pot method demonstrated potent multi-radical scavenging activity. When integrated into gelatin methacryloyl (Gel), CuNZ@Gel exhibited excellent sprayability, conformal skin coverage, and long-term storage stability, offering substantial translatable potential. Notably, the nanozyme hydrogel induced distinct epigenetic modifications in macrophages by remodeling chromatin accessibility, effectively shifting gene expression from pro-inflammatory to anti-inflammatory profiles. This epigenetic modulation persisted under oxidative stress, actively suppressing inflammatory while facilitating regenerative responses. In diabetic wound models, CuNZ@Gel significantly accelerated healing through its coordinated antioxidant, anti-inflammatory, and pro-regenerative actions. Unlike conventional passive dressings, our sprayable nanozyme hydrogel proactively reprograms the wound microenvironment via epigenetic antioxidant mechanisms, offering novel insights and strategy for managing chronic diabetic wounds and inflammatory skin complications.

Project description:Chronic diabetic wounds present a critical clinical challenge due to persistent inflammation and compromised healing. Here we report a novel sprayable nanozyme hydrogel that epigenetically reprograms macrophages to suppress inflammation and coordinate regeneration. Ultrasmall copper-based nanozymes (CuNZ, ~4 nm) synthesized via an eco-friendly one-pot method demonstrated potent multi-radical scavenging activity. When integrated into gelatin methacryloyl (Gel), CuNZ@Gel exhibited excellent sprayability, conformal skin coverage, and long-term storage stability, offering substantial translatable potential. Notably, the nanozyme hydrogel induced distinct epigenetic modifications in macrophages by remodeling chromatin accessibility, effectively shifting gene expression from pro-inflammatory to anti-inflammatory profiles. This epigenetic modulation persisted under oxidative stress, actively suppressing inflammatory while facilitating regenerative responses. In diabetic wound models, CuNZ@Gel significantly accelerated healing through its coordinated antioxidant, anti-inflammatory, and pro-regenerative actions. Unlike conventional passive dressings, our sprayable nanozyme hydrogel proactively reprograms the wound microenvironment via epigenetic antioxidant mechanisms, offering novel insights and strategy for managing chronic diabetic wounds and inflammatory skin complications.

Project description:Chronic diabetic wounds present a critical clinical challenge due to persistent inflammation and compromised healing. Here we report a novel sprayable nanozyme hydrogel that epigenetically reprograms macrophages to suppress inflammation and coordinate regeneration. Ultrasmall copper-based nanozymes (CuNZ, ~4 nm) synthesized via an eco-friendly one-pot method demonstrated potent multi-radical scavenging activity. When integrated into gelatin methacryloyl (Gel), CuNZ@Gel exhibited excellent sprayability, conformal skin coverage, and long-term storage stability, offering substantial translatable potential. Notably, the nanozyme hydrogel induced distinct epigenetic modifications in macrophages by remodeling chromatin accessibility, effectively shifting gene expression from pro-inflammatory to anti-inflammatory profiles. This epigenetic modulation persisted under oxidative stress, actively suppressing inflammatory while facilitating regenerative responses. In diabetic wound models, CuNZ@Gel significantly accelerated healing through its coordinated antioxidant, anti-inflammatory, and pro-regenerative actions. Unlike conventional passive dressings, our sprayable nanozyme hydrogel proactively reprograms the wound microenvironment via epigenetic antioxidant mechanisms, offering novel insights and strategy for managing chronic diabetic wounds and inflammatory skin complications.

Project description:Impaired healing of diabetic wounds causes significant morbidity and mortality. This study aimed to identify novel mechanisms of diabetic wound healing defects and test a therapeutic intervention using diabetic mouse and pig models. We found Smad7 transgene expression in mouse epidermis promoting wound healing in diabetic db/db mice, with reductions in obesity and blood glucose. To isolate effects of Smad7 on wounds, we created a Smad7-based biologic (Tat-PYC-Smad7) that penetrates wound cells. Topical application of Tat-PYC-Smad7 to diabetic pig and mouse wounds accelerated healing compared to controls. RNAseq analysis of mouse wound samples showed reduced TGFβ/NFκB signaling, leading to faster re-epithelialization and better extracellular matrix remodeling. Tat-PYC-Smad7 also attenuated neutrophil degranulation and NETosis by blocking histone 3 citrullination and inhibiting myeloperoxidase activities. Our study reveals that Tat-PYC-Smad7 promotes diabetic wound healing by targeting keratinocytes and neutrophils, providing insight into cellular mechanisms of diabetic wound healing defects targetable by Smad7-based therapy.

Project description:MicroRNAs are powerful gene expression regulators, but their corneal repertoire and potential changes in corneal diseases remain unknown. Our purpose was to identify miRNAs altered in the human diabetic cornea by microarray analysis, and to examine their effects on wound healing in cultured telomerase-immortalized human corneal epithelial cells (HCEC) in vitro. Using microarrays, 29 miRNAs were identified as differentially expressed in diabetic samples. Two miRNA candidates showing the highest fold increased in expression in the diabetic cornea were confirmed by Q-PCR and further characterized. HCEC transfection with h-miR-146a or h-miR-424 significantly retarded wound closure, but their respective antagomirs significantly enhanced wound healing vs. controls. Cells treated with h-miR-146a or h-miR-424 had decreased p-p38 and p-EGFR staining, but these increased over control levels close to the wound edge upon antagomir treatment. In conclusion, several miRNAs with increased expression in human diabetic central corneas were found. Two such miRNAs inhibited cultured corneal epithelial cell wound healing. Dysregulation of miRNA expression in human diabetic cornea may be an important mediator of abnormal wound healing. Total RNA was extracted from age-matched human autopsy normal (n=6) and diabetic (n=6) central corneas, Flash Tag end-labeled, and hybridized to Affymetrix® GeneChip® miRNA Arrays. Select miRNAs associated with diabetic cornea were validated by quantitative RT-PCR (Q-PCR) and by in situ hybridization (ISH) in independent samples.