Regulatory Effects of Damaged Renal Epithelial Cells After Repair by Porphyra yezoensis Polysaccharides with Different Sulfation Degree on the Calcium Oxalate Crystal–Cell Interaction

Sun, Xin-Yuan; Zhang, Hui; Deng, J F; Yu, Bang-Xian; Zhang, Yihan; Ouyang, Jing

doi:10.2147/ijn.s320278

Cited by 9 publications

(4 citation statements)

References 58 publications

(68 reference statements)

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“…Injury to renal tubular epithelial cells is considered to be an important cause of the formation of renal stones [ 39 ]. Changes in cell-membrane structure and adhesion sites for stone crystals happened in damaged cells [ 40 , 41 ].…”

Section: Discussionmentioning

confidence: 99%

Dysregulated palmitic acid metabolism promotes the formation of renal calcium-oxalate stones through ferroptosis induced by polyunsaturated fatty acids/phosphatidic acid

Wang,

Zhang,

Ren

et al. 2024

Cell. Mol. Life Sci.

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The pathogenesis of renal calcium-oxalate (CaOx) stones is complex and influenced by various metabolic factors. In parallel, palmitic acid (PA) has been identified as an upregulated lipid metabolite in the urine and serum of patients with renal CaOx stones via untargeted metabolomics. Thus, this study aimed to mechanistically assess whether PA is involved in stone formation. Lipidomics analysis of PA-treated renal tubular epithelial cells compared with the control samples revealed that α-linoleic acid and α-linolenic acid were desaturated and elongated, resulting in the formation of downstream polyunsaturated fatty acids (PUFAs). In correlation, the levels of fatty acid desaturase 1 and 2 (FADS1 and FADS2) and peroxisome proliferator-activated receptor α (PPARα) in these cells treated with PA were increased relative to the control levels, suggesting that PA-induced upregulation of PPARα, which in turn upregulated these two enzymes, forming the observed PUFAs. Lipid peroxidation occurred in these downstream PUFAs under oxidative stress and Fenton Reaction. Furthermore, transcriptomics analysis revealed significant changes in the expression levels of ferroptosis-related genes in PA-treated renal tubular epithelial cells, induced by PUFA peroxides. In addition, phosphatidyl ethanolamine binding protein 1 (PEBP1) formed a complex with 15-lipoxygenase (15-LO) to exacerbate PUFA peroxidation under protein kinase C ζ (PKC ζ) phosphorylation, and PKC ζ was activated by phosphatidic acid derived from PA. In conclusion, this study found that the formation of renal CaOx stones is promoted by ferroptosis of renal tubular epithelial cells resulting from PA-induced dysregulation of PUFA and phosphatidic acid metabolism, and PA can promote the renal adhesion and deposition of CaOx crystals by injuring renal tubular epithelial cells, consequently upregulating adhesion molecules. Accordingly, this study provides a new theoretical basis for understanding the correlation between fatty acid metabolism and the formation of renal CaOx stones, offering potential targets for clinical applications.

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Section: Discussionmentioning

confidence: 99%

Dysregulated palmitic acid metabolism promotes the formation of renal calcium-oxalate stones through ferroptosis induced by polyunsaturated fatty acids/phosphatidic acid

Wang,

Zhang,

Ren

et al. 2024

Cell. Mol. Life Sci.

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“…Endocytosis is an active transport process that consumes energy. Cells in good condition have high metabolism and sufficient energy and are more likely to endocytose crystals adhering to the cell surface and reduce the harm of adhering crystals to cells (Sun et al, 2021; Taguchi et al, 2021). Taguchi et al (Borjigin et al, 2023) demonstrated that a fatty acid–binding protein promoted the development of renal CaOx stones by attenuating the phagocytosis of crystals by macrophages and renal tubular cells.…”

Section: Discussionmentioning

confidence: 99%

“…I G U R E 13 Schematic diagram of carboxymethylated desmodium styracifolium polysaccharide inhibited the adhesion of nanoCOD crystals to HK-2 cell membranes and promoted crystal endocytosis. and are more likely to endocytose crystals adhering to the cell surface and reduce the harm of adhering crystals to cells(Sun et al, 2021;Taguchi et al, 2021).Taguchi et al (Borjigin et al, 2023) demonstrated that a fatty acid-binding protein promoted the development of renal CaOx stones by attenuating the phagocytosis of crystals by macrophages and renal tubular cells. Furthermore, CDSPs promoted nanoCOD crystal endocytosis(Figures 11 and 12), inhibited the nanoCOD crystal-induced opening of mPTPs in HK-2 cells (Figure6), increased the mitochondrial membrane potential (Figure5), and promoted the cell cycle transition from the G2/M and S phases to the G1 phase (Figure2).…”

mentioning

confidence: 99%

Carboxymethylated Desmodium styracifolium polysaccharide reduces the risk of calcium oxalate kidney stone formation by inhibiting crystal adhesion and promoting crystal endocytosis

Wang,

Liu,

Zhao

et al. 2024

Journal Cellular Physiology

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The inhibition of cell surface crystal adhesion and an appropriate increase in crystal endocytosis contribute to the inhibition of kidney stone formation. In this study, we investigated the effects of different degrees of carboxymethylation on these processes. An injury model was established by treating human renal proximal tubular epithelial (HK‐2) cells with 98.3 ± 8.1 nm calcium oxalate dihydrate (nanoCOD) crystals. The HK‐2 cells were protected with carboxy (‐COOH) Desmodium styracifolium polysaccharides at 1.17% (DSP0), 7.45% (CDSP1), 12.2% (CDSP2), and 17.7% (CDSP3). Changes in biochemical indexes and effects on nanoCOD adhesion and endocytosis were detected. The protection of HK‐2 cells from nanoCOD‐induced oxidative damage by carboxymethylated Desmodium styracifolium polysaccharides (CDSPs) is closely related to the protection of subcellular organelles, such as mitochondria. CDSPs can reduce crystal adhesion on the cell surface and maintain appropriate crystal endocytosis, thereby reducing the risk of kidney stone formation. CDSP2 with moderate ‐COOH content showed the strongest protective activity among the CDSPs.

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“…Sulfated-modified polysaccharides are primarily used for antioxidant, antibacterial, antiviral, antitumor, anticoagulation, and immunomodulatory research [24][25][26]. However, less research has been conducted on their use in repairing damaged cells [27,28]. Previously, four sulfated U. pinnatifida polysaccharides (UPPs) were synthesized and their structures were characterized.…”

Section: Introductionmentioning

confidence: 99%

Sulfated Undaria pinnatifida Polysaccharide Promotes Endocytosis of Nano-Calcium Oxalate Dihydrate by Repairing Subcellular Organelles in HK-2 Cells

2023

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The clinical manifestation of primary hyperoxaluria includes hyperoxaluria and recurrent urinary calculi. In this study, an oxidative damage model was constructed based on oxalate damage to the human renal proximal tubular epithelial cells (HK-2), and a comparative study was carried out on four different sulfated levels of Undaria pinnatifida polysaccharides (UPP0, UPP1, UPP2, and UPP3 with sulfate group [–OSO3−] contents of 1.59%, 6.03%, 20.83%, and 36.39%, respectively) on the repair of oxidatively damaged HK-2 cells. The results showed that after repair by UPPs, cell viability was enhanced, healing ability was improved, the intracellular superoxide dismutase level and mitochondrial membrane potential were increased, malondialdehyde, reactive oxygen species, and intracellular Ca2+ levels were reduced, cellular autophagy was reduced; lysosomal integrity was improved, and cytoskeleton and cell morphology were restored. The ability of repaired cells to endocytose nano-calcium oxalate dihydrate crystals (nano−COD) was enhanced. The activity of UPPs was closely related to their –OSO3− content. A too high or too low –OSO3− content was not conducive to polysaccharide activity, and only UPP2 exhibited the best cell repair ability and strongest ability to promote the cell endocytosis of crystals. UPP2 may be used as a potential agent to inhibit CaOx crystal deposition caused by high oxalate concentration.

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Regulatory Effects of Damaged Renal Epithelial Cells After Repair by Porphyra yezoensis Polysaccharides with Different Sulfation Degree on the Calcium Oxalate Crystal–Cell Interaction

Cited by 9 publications

References 58 publications

Dysregulated palmitic acid metabolism promotes the formation of renal calcium-oxalate stones through ferroptosis induced by polyunsaturated fatty acids/phosphatidic acid

Dysregulated palmitic acid metabolism promotes the formation of renal calcium-oxalate stones through ferroptosis induced by polyunsaturated fatty acids/phosphatidic acid

Carboxymethylated Desmodium styracifolium polysaccharide reduces the risk of calcium oxalate kidney stone formation by inhibiting crystal adhesion and promoting crystal endocytosis

Sulfated Undaria pinnatifida Polysaccharide Promotes Endocytosis of Nano-Calcium Oxalate Dihydrate by Repairing Subcellular Organelles in HK-2 Cells

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