DsbA-L ameliorates high glucose induced tubular damage through maintaining MAM integrity

Keyphrases

• High Glucose 100%
• Disulfide Bond 100%
• Tubular Injury 100%
• Oxidoreductase 100%
• Apoptosis 44%
• Kidney 33%
• Diabetic Nephropathy 33%
• Renal Injury 33%
• Overexpression 22%
• Transmission Electron Microscopy 11%
• Flow Cytometry 11%
• Mutant Mice 11%
• Molecular Biology Techniques 11%
• Pathobiology 11%
• Biological Function 11%
• Mitochondria 11%
• Protein-coding Genes 11%
• Diabetic 11%
• Antioxidant 11%
• Streptozotocin-induced Diabetic Rats 11%
• Endoplasmic Reticulum Stress (ER stress) 11%
• Beneficial Effects 11%
• Confocal Microscopy 11%
• Gene-deficient Mice 11%
• TUNEL Staining 11%
• Endoplasmic Reticulum 11%
• Ambience 11%
• Protein mutants 11%
• HK-2 Cells 11%
• Uncoupling Protein 11%
• Anti-apoptosis 11%
• In Situ Proximity Ligation Assay 11%
• National Key R&D Program of China 11%
• Mitochondria-associated ER Membranes 11%
• National Natural Science Foundation of China 11%

Biochemistry, Genetics and Molecular Biology

• Disulfide Bond 100%
• Oxidoreductase 100%
• Confocal Microscopy 11%
• Transmission Electron Microscopy 11%
• Molecular Biology 11%
• Biological Functions 11%
• Mitochondrion 11%
• Mouse Mutant 11%
• Endoplasmic Reticulum Stress 11%
• Endoplasmic Reticulum Membrane 11%
• Mutant Protein 11%
• Streptozotocin 11%
• Uncoupling Protein 11%
• TUNEL Assay 11%
• Flow Cytometry 11%

Immunology and Microbiology

• Disulfide Bond 100%
• Transmission Electron Microscopy 11%
• Proximity Ligation Assay 11%
• Mouse Mutant 11%
• Biological Functions 11%
• Mitochondrion 11%
• Endoplasmic reticulum 11%
• Endoplasmic Reticulum Stress 11%
• Endoplasmic Reticulum Membrane 11%