Dysregulation of mannose-6-phosphate–dependent cholesterol homeostasis in acinar cells mediates pancreatitis
Olga A. Mareninova, … , Ilya Gukovsky, Anna S. Gukovskaya
Olga A. Mareninova, … , Ilya Gukovsky, Anna S. Gukovskaya
Published June 15, 2021
Citation Information: J Clin Invest. 2021;131(15):e146870. https://doi.org/10.1172/JCI146870.
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Research Article Cell biology Gastroenterology

Dysregulation of mannose-6-phosphate–dependent cholesterol homeostasis in acinar cells mediates pancreatitis

Abstract

Disordered lysosomal/autophagy pathways initiate and drive pancreatitis, but the underlying mechanisms and links to disease pathology are poorly understood. Here, we show that the mannose-6-phosphate (M6P) pathway of hydrolase delivery to lysosomes critically regulates pancreatic acinar cell cholesterol metabolism. Ablation of the Gnptab gene encoding a key enzyme in the M6P pathway disrupted acinar cell cholesterol turnover, causing accumulation of nonesterified cholesterol in lysosomes/autolysosomes, its depletion in the plasma membrane, and upregulation of cholesterol synthesis and uptake. We found similar dysregulation of acinar cell cholesterol, and a decrease in GNPTAB levels, in both WT experimental pancreatitis and human disease. The mechanisms mediating pancreatic cholesterol dyshomeostasis in Gnptab–/– and experimental models involve a disordered endolysosomal system, resulting in impaired cholesterol transport through lysosomes and blockage of autophagic flux. By contrast, in Gnptab–/– liver the endolysosomal system and cholesterol homeostasis were largely unaffected. Gnptab–/– mice developed spontaneous pancreatitis. Normalization of cholesterol metabolism by pharmacologic means alleviated responses of experimental pancreatitis, particularly trypsinogen activation, the disease hallmark. The results reveal the essential role of the M6P pathway in maintaining exocrine pancreas homeostasis and function, and implicate cholesterol disordering in the pathogenesis of pancreatitis.

Authors

Olga A. Mareninova, Eszter T. Vegh, Natalia Shalbueva, Carli J.M. Wightman, Dustin L. Dillon, Sudarshan Malla, Yan Xie, Toshimasa Takahashi, Zoltan Rakonczay Jr., Samuel W. French, Herbert Y. Gaisano, Fred S. Gorelick, Stephen J. Pandol, Steven J. Bensinger, Nicholas O. Davidson, David W. Dawson, Ilya Gukovsky, Anna S. Gukovskaya

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Figure 7

Gnptab ablation causes mitochondrial dysfunction in the pancreas.

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Gnptab ablation causes mitochondrial dysfunction in the pancreas. Mitoc...
Mitochondrial functional parameters were measured in mitochondria isolated from pancreas (A, D, J, and M) or liver (NP), in acinar cells (B, C, and I), and pancreatic (EH, K, and L) and liver (Q) tissues of WT and KO mice. (A and N) Activities of mitochondrial ETC complexes I, II, IV, and V. (B, C, and I) Acinar cell oxygen consumption rates (OCR), reflecting mitochondrial OXPHOS, were measured in basal conditions and after treatment with the β-oxidation inhibitor etomoxir (40 μM), and normalized to total protein in the sample. (B) Representative OCR tracings in acinar cell suspension subjected to consecutive injections of the ATP synthase inhibitor oligomycin (Oligo; 3 μM), protonophore FCCP (2.7 μM), and mitochondrial uncouplers rotenone plus antimycin A (R+A, 5 μM each; to correct for nonmitochondrial respiration). (C and I) ATP-linked respiration was calculated as the difference between basal OCR and that in Oligo-treated cells; the maximal OCR was obtained in FCCP-treated cells. (D and O) Mitochondrial membrane potential (ΔΨm) was measured with a tetraphenyl phosphonium ion (TPP+) electrode. FCCP (5 μM) was added to completely dissipate ΔΨm. (E) ATP was measured in pancreatic tissue homogenate with luciferin-luciferase assay. (F, H, L, and Q) IB analysis of the mitochondrial fission factor Fis1 and mitophagy mediator Parkin (F), mitochondrial markers (H), and MLN64/STARD3 protein (L and Q) that mediates cholesterol transfer from LE/Ly directly to mitochondria. (G) Mitochondrial fragmentation was assessed by changes in Tom20 or VDAC immunostaining pattern, from an interconnected tubular mitochondrial network in WT to a predominantly disjoined/circular one in KO pancreas. Scale bars: 10 μm. (J, M, and P) Free fatty acid (FFA) and cholesterol contents of isolated pancreatic or liver mitochondria. (K) Long-chain acylcarnitines were measured with LC-MS/GC-MS. Values are mean ± SEM; each symbol represents an individual mouse, or cell or mitochondria preparation (n = 3–8 per condition). *P < 0.05, **P < 0.01, ***P < 0.001 vs. the same parameter in WT. #P < 0.05 vs. the same condition without etomoxir (I). Significance was determined by 2-tailed Student’s t test.