Résumé
Renal proximal tubules are a primary site of injury in metabolic diseases. In obese patients and animal models, proximal tubular epithelial cells (PTECs) display dysregulated lipid metabolism, organelle dysfunctions, and oxidative stress that contribute to interstitial inflammation, fibrosis and ultimately
end-stage renal failure. Our research group previously pointed out AMP-activated protein kinase (AMPK) decline as a driver of obesity-induced renal disease. Because PTECs display high macroautophagic/autophagic
activity and rely heavily on their endo-lysosomal system, we investigated the
effect of lipid stress on autophagic flux and lysosomes in these cells. Using a model of highly differentiated primary PTECs challenged with palmitate, our data placed lysosomes at the cornerstone of the lipotoxic phenotype. As soon as 6 h after palmitate exposure, cells displayed impaired lysosomal acidification subsequently leading to autophagosome accumulation and activation of
lysosomal biogenesis. We also showed the inability of lysosomal quality control to restore acidic pH which finally drove PTECs dedifferentiation. When palmitate-induced AMPK activity decline was prevented by AMPK activators, lysosomal acidification and the differentiation profile of PTECs were preserved. Our work provided key insights on the importance of lysosomes in PTECs homeostasis and
lipotoxicity and demonstrated the potential of AMPK in protecting the organelle from lipid stress.
end-stage renal failure. Our research group previously pointed out AMP-activated protein kinase (AMPK) decline as a driver of obesity-induced renal disease. Because PTECs display high macroautophagic/autophagic
activity and rely heavily on their endo-lysosomal system, we investigated the
effect of lipid stress on autophagic flux and lysosomes in these cells. Using a model of highly differentiated primary PTECs challenged with palmitate, our data placed lysosomes at the cornerstone of the lipotoxic phenotype. As soon as 6 h after palmitate exposure, cells displayed impaired lysosomal acidification subsequently leading to autophagosome accumulation and activation of
lysosomal biogenesis. We also showed the inability of lysosomal quality control to restore acidic pH which finally drove PTECs dedifferentiation. When palmitate-induced AMPK activity decline was prevented by AMPK activators, lysosomal acidification and the differentiation profile of PTECs were preserved. Our work provided key insights on the importance of lysosomes in PTECs homeostasis and
lipotoxicity and demonstrated the potential of AMPK in protecting the organelle from lipid stress.
langue originale | Anglais |
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Nombre de pages | 22 |
journal | Autophagy |
Les DOIs | |
Etat de la publication | Publié - 15 déc. 2024 |
Empreinte digitale
Examiner les sujets de recherche de « AMPK protects proximal tubular epithelial cells from lysosomal dysfunction and dedifferentiation induced by lipotoxicity ». Ensemble, ils forment une empreinte digitale unique.Équipement
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Microscopie optique
Renard, H.-F. (!!Manager), Forrester, A. (!!Manager), Demazy, C. (!!Other) & Ledoux, B. (!!Manager)
Plateforme technologique Morphologie, imagerieEquipement/installations: Equipement
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Spectrométrie de masse (MASUN)
Renard, P. (!!Manager)
Plateforme technologique Proteomique et spectrometrie de masseEquipement/installations: Plateforme technolgique