Search

Your search keyword '"Li, Guangbi"' showing total 240 results
Start Over Author "Li, Guangbi"
240 results on '"Li, Guangbi"'

19. Podocyte-specific silencing of acid sphingomyelinase gene to abrogate hyperhomocysteinemia-induced NLRP3 inflammasome activation and glomerular inflammation.

Author

Huang, Dandan, Kidd, Jason M., Zou, Yao, Wu, Xiaoyuan, Li, Ningjun, Gehr, Todd W. B., Li, Pin-Lan, and Li, Guangbi

Subjects
NLRP3 protein, INFLAMMASOMES, SPHINGOMYELINASE, GENETIC overexpression, GENE silencing, PLANT gene silencing, HAZARDOUS substance release
Abstract

Acid sphingomyelinase (ASM) has been reported to increase tissue ceramide and thereby mediate hyperhomocysteinemia (hHcy)-induced glomerular nucleotide-binding oligomerization domain-like receptor containing pyrin domain 3 (NLRP3) inflammasome activation, inflammation, and sclerosis. In the present study, we tested whether somatic podocyte-specific silencing of Smpd1 gene (mouse ASM gene code) attenuates hHcy-induced NLRP3 inflammasome activation and associated extracellular vesicle (EV) release in podocytes and thereby suppresses glomerular inflammatory response and injury. In vivo, somatic podocyte-specific Smpd1 gene silencing almost blocked hHcy-induced glomerular NLRP3 inflammasome activation in Podocre (podocyte-specific expression of cre recombinase) mice compared with control littermates. By nanoparticle tracking analysis (NTA), floxed Smpd1 shRNA transfection was found to abrogate hHcy-induced elevation of urinary EV excretion in Podocre mice. In addition, Smpd1 gene silencing in podocytes prevented hHcy-induced immune cell infiltration into glomeruli, proteinuria, and glomerular sclerosis in Podocre mice. Such protective effects of podocyte-specific Smpd1 gene silencing were mimicked by global knockout of Smpd1 gene in Smpd1−/− mice. On the contrary, podocyte-specific Smpd1 gene overexpression exaggerated hHcy-induced glomerular pathological changes in Smpd1trg/Podocre (podocyte-specific Smpd1 gene overexpression) mice, which were significantly attenuated by transfection of floxed Smpd1 shRNA. In cell studies, we also confirmed that Smpd1 gene knockout or silencing prevented homocysteine (Hcy)-induced elevation of EV release in the primary cultures of podocyte isolated from Smpd1−/− mice or podocytes of Podocre mice transfected with floxed Smpd1 shRNA compared with WT/WT podocytes. Smpd1 gene overexpression amplified Hcy-induced EV secretion from podocytes of Smpd1trg/Podocre mice, which was remarkably attenuated by transfection of floxed Smpd1 shRNA. Mechanistically, Hcy-induced elevation of EV release from podocytes was blocked by ASM inhibitor (amitriptyline, AMI), but not by NLRP3 inflammasome inhibitors (MCC950 and glycyrrhizin, GLY). Super-resolution microscopy also showed that ASM inhibitor, but not NLRP3 inflammasome inhibitors, prevented the inhibition of lysosome-multivesicular body interaction by Hcy in podocytes. Moreover, we found that podocyte-derived inflammatory EVs (released from podocytes treated with Hcy) induced podocyte injury, which was exaggerated by T cell coculture. Interstitial infusion of inflammatory EVs into renal cortex induced glomerular injury and immune cell infiltration. In conclusion, our findings suggest that ASM in podocytes plays a crucial role in the control of NLRP3 inflammasome activation and inflammatory EV release during hHcy and that the development of podocyte-specific ASM inhibition or Smpd1 gene silencing may be a novel therapeutic strategy for treatment of hHcy-induced glomerular disease with minimized side effect. NEW & NOTEWORTHY: In the present study, we tested whether podocyte-specific silencing of Smpd1 gene attenuates hyperhomocysteinemia (hHcy)-induced nucleotide-binding oligomerization domain-like receptor containing pyrin domain 3 (NLRP3) inflammasome activation and associated inflammatory extracellular vesicle (EV) release in podocytes and thereby suppresses glomerular inflammatory response and injury. Our findings suggest that acid sphingomyelinase (ASM) in podocytes plays a crucial role in the control of NLRP3 inflammasome activation and inflammatory EV release during hHcy. Based on our findings, it is anticipated that the development of podocyte-specific ASM inhibition or Smpd1 gene silencing may be a novel therapeutic strategy for treatment of hHcy-induced glomerular disease with minimized side effects. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

20. Facile synthesis of polyaniline/Al2O3 micro-fibers through in situ polymerization.

Author

Hui, Zhenping, Jiao, Tianyi, Guo, Yanling, Li, Guangbi, and Wang, Xiaocong

Subjects
POLYANILINES, MICROFIBERS, FIBROUS composites, ALUMINUM oxide, ELECTRIC conductivity, POLYMERIZATION
Abstract

Since aluminum oxide (Al2O3) is easy to dissolve in acid, it is still a big challenge to prepare conductive PANI/Al2O3 fibers. In this paper, a very simple way to synthesize long PANI/Al2O3 micro-fibers using calcined-Al2O3 fibers as substrate by in situ polymerization method was reported. In contrast, PANI/Al2O3 composite fibers were synthesized using uncalcined-Al2O3 fibers as substrate. The SEM results revealed that the PANI composites from calcined-Al2O3 could keep the long fibrous form well, while the composites from uncalcined-Al2O3 fibers become short fibers due to the etching of acid. This suggested that the calcined-Al2O3 fibers had good corrosion resistance to the strong acid. FTIR results indicated the molecular structure of PANI was in conductive emeraldine state. So, PANI could be polymerized on the surface of Al2O3 fiber in acidic condition to form conductive composite PANI/Al2O3 fibers. The electrical conductivity of the composite fibers was in the order of 10–2 S/cm, and the electrical conductivity of the composite fibers increased with the increasing of aniline concentration. These conductive composite fibers could greatly reduce the electrostatic hazard caused by Al2O3 fibers. In that mean, this paper provided a feasible method for the synthesis of other conductive PANI/oxide (the oxide is soluble in strong acid like Al2O3) composite fibers. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

42. Regulation of exosome release by lysosomal acid ceramidase in coronary arterial endothelial cells: Role of TRPML1 channel

Author

Li, Guangbi, Huang, Dandan, Li, Pengyang, Yuan, Xinxu, Yarotskyy, Viktor, and Li, Pin-Lan

Subjects
Mice, Knockout, Mammals, Mice, Transient Receptor Potential Channels, Acid Ceramidase, Sphingosine, Animals, Endothelial Cells, Exosomes, Lysosomes, Article
Abstract

Lysosomal acid ceramidase (AC) has been reported to determine multivesicular body (MVB) fate and exosome secretion in different mammalian cells including coronary arterial endothelial cells (CAECs). However, this AC-mediated regulation of exosome release from CAECs and associated underlying mechanism remain poorly understood. In the present study, we hypothesized that AC controls lysosomal Ca(2+) release through TRPML1 channel to regulate exosome release in murine CAECs. To test this hypothesis, we isolated and cultured CAECs from WT/WT and endothelial cell-specific Asah1 gene (gene encoding AC) knockout mice. Using these CAECs, we first demonstrated a remarkable increase in exosome secretion and significant reduction of lysosome-MVB interaction in CAECs lacking Asah1 gene compared to those cells from WT/WT mice. ML-SA1, a TRPML1 channel agonist, was found to enhance lysosome trafficking and increase lysosome-MVB interaction in WT/WT CAECs, but not in CAECs lacking Asah1 gene. However, sphingosine, an AC-derived sphingolipid, was able to increase lysosome movement and lysosome-MVB interaction in CAECs lacking Asah1 gene, leading to reduced exosome release from these cells. Moreover, Asah1 gene deletion was shown to substantially inhibit lysosomal Ca(2+) release through suppression of TRPML1 channel activity in CAECs. Sphingosine as an AC product rescued the function of TRPML1 channel in CAECs lacking Asah1 gene. These results suggest that Asah1 gene defect and associated deficiency of AC activity may inhibit TRPML1 channel activity, thereby reducing MVB degradation by lysosome and increasing exosome release from CAECs. This enhanced exosome release from CAECs may contribute to the development of coronary arterial disease under pathological conditions.

Published
2022

Catalog

Books, media, physical & digital resources
See catalog results