TY - JOUR
T1 - Defective Lipid Droplet-Lysosome Interaction Causes Fatty Liver Disease as Evidenced by Human Mutations in TMEM199 and CCDC115
AU - Larsen, Lars E.
AU - van den Boogert, Marjolein A. W.
AU - Rios-Ocampo, Wilson A.
AU - Jansen, Jos C.
AU - Conlon, Donna
AU - Chong, Patrick L. E.
AU - Levels, J. Han M.
AU - Eilers, Roos E.
AU - V. Sachdev, Vinay
AU - Zelcer, Noam
AU - Raabe, Tobias
AU - He, Miao
AU - Hand, Nicholas J.
AU - Drenth, Joost P. H.
AU - Rader, David J.
AU - Stroes, Eric S. G.
AU - Lefeber, Dirk J.
AU - Jonker, Johan W.
AU - Holleborn, Adriaan G.
N1 - Funding Information:
The authors thank the involved patients, Mayda Hernandez, Dr Deepti Abbey, and Dr Wenli Yang for helpful discussions and technical advice regarding the iPS cell culture. They thank Albert Gerding, Christoff Odendaal, and Prof. Barbara Bakker for technical advice regarding the oroboros experiments. Lars Elmann Larsen, MSc (Conceptualization: Equal; Formal analysis: Equal; Investigation: Equal; Methodology: Equal; Project administration: Equal; Visualization: Equal; Writing ? original draft: Equal; Writing ? review & editing: Equal), Marjolein van den Boogert, MD (Conceptualization: Equal; Formal analysis: Equal; Investigation: Equal; Methodology: Equal; Project administration: Equal; Visualization: Equal; Writing ? original draft: Lead; Writing ? review & editing: Equal), Wilson Alfredo Rios-Ocampo, PhD (Methodology: Supporting), Jos Jansen, MD (Formal analysis: Supporting; Methodology: Supporting; Writing ? original draft: Supporting), Donna Conlon, PhD (Data curation: Supporting; Methodology: Supporting), Patrick Chong, BSc (Formal analysis: Supporting), Han Levels, PhD (Formal analysis: Supporting), Roos E. Eilers (Methodology: Supporting), Vinai V. Sachdev (Methodology: Supporting), Noam Zelcer, Prof (Methodology: Supporting), Tobias Raabe, PhD (Conceptualization: Supporting; Methodology: Supporting), Miao He (Formal analysis: Supporting; Methodology: Supporting), Nicholas Hand, PhD (Conceptualization: Supporting; Formal analysis: Supporting; Investigation: Supporting; Methodology: Supporting; Supervision: Supporting; Writing ? review & editing: Supporting), Joost Drenth, MD, PhD (Methodology: Supporting), Daniel Rader, Prof, MD (Supervision: Supporting; Writing ? review & editing: Supporting), Erik Stroes, Prof, MD, PhD (Conceptualization: Supporting; Supervision: Supporting; Writing ? review & editing: Supporting), Dirk Lefeber, PhD (Methodology: Equal; Supervision: Equal; Writing ? original draft: Equal; Writing ? review & editing: Equal), Johan Jonker, Prof, PhD (Supervision: Equal; Writing ? original draft: Equal; Writing ? review & editing: Equal), Adriaan G. Holleboom, MD, PhD (Conceptualization: Equal; Methodology: Equal; Supervision: Equal; Writing ? original draft: Equal; Writing ? review & editing: Equal) Funding AGH is supported by the Amsterdam UMC Fellowship grant, Health?Holland TKI-PPP grants and the Gilead Research scholarship. JWJ is supported by grants from The Netherlands Organization for Scientific Research (VICI grant 016.176.640 to JWJ) and European Foundation for the Study of Diabetes (award supported by EFSD/Novo Nordisk). DJR was supported by U01 HG006398/HG/NHGRI and RC2 HL101864/HL/NHLBI, NIH. DJL is supported by grants from the Dutch Organisation for Scientific Research (ZONMW-NWO) (Medium Investment Grant 40-00506-98-9001 and VIDI Grant 91713359 to DJL).
Funding Information:
Funding AGH is supported by the Amsterdam UMC Fellowship grant, Health∼Holland TKI-PPP grants and the Gilead Research scholarship. JWJ is supported by grants from The Netherlands Organization for Scientific Research (VICI grant 016.176.640 to JWJ) and European Foundation for the Study of Diabetes (award supported by EFSD/Novo Nordisk). DJR was supported by U01 HG006398/HG/NHGRI and RC2 HL101864/HL/NHLBI, NIH. DJL is supported by grants from the Dutch Organisation for Scientific Research (ZONMW-NWO) (Medium Investment Grant 40-00506-98-9001 and VIDI Grant 91713359 to DJL).
Publisher Copyright:
© 2021 The Authors
PY - 2022
Y1 - 2022
N2 - BACKGROUND & AIMS: Recently, novel inborn errors of metabolism were identified because of mutations in V-ATPase assembly factors TMEM199 and CCDC115. Patients are characterized by generalized protein glycosylation defects, hypercholesterolemia, and fatty liver disease. Here, we set out to characterize the lipid and fatty liver phenotype in human plasma, cell models, and a mouse model.METHODS AND RESULTS: Patients with TMEM199 and CCDC115 mutations displayed hyperlipidemia, characterized by increased levels of lipoproteins in the very low density lipoprotein range. HepG2 hepatoma cells, in which the expression of TMEM199 and CCDC115 was silenced, and induced pluripotent stem cell (iPSC)-derived hepatocyte-like cells from patients with TMEM199 mutations showed markedly increased secretion of apolipoprotein B (apoB) compared with controls. A mouse model for TMEM199 deficiency with a CRISPR/Cas9-mediated knock-in of the human A7E mutation had marked hepatic steatosis on chow diet. Plasma N-glycans were hypogalactosylated, consistent with the patient phenotype, but no clear plasma lipid abnormalities were observed in the mouse model. In the siTMEM199 and siCCDC115 HepG2 hepatocyte models, increased numbers and size of lipid droplets were observed, including abnormally large lipid droplets, which colocalized with lysosomes. Excessive de novo lipogenesis, failing oxidative capacity, and elevated lipid uptake were not observed. Further investigation of lysosomal function revealed impaired acidification combined with impaired autophagic capacity.CONCLUSIONS: Our data suggest that the hyperchole-sterolemia in TMEM199 and CCDC115 deficiency is due to increased secretion of apoB-containing particles. This may in turn be secondary to the hepatic steatosis observed in these patients as well as in the mouse model. Mechanistically, we observed impaired lysosomal function characterized by reduced acidification, autophagy, and increased lysosomal lipid accumulation. These findings could explain the hepatic steatosis seen in patients and highlight the importance of lipophagy in fatty liver disease. Because this pathway remains understudied and its regulation is largely untargeted, further exploration of this pathway may offer novel strategies for therapeutic interventions to reduce lipotoxicity in fatty liver disease.
AB - BACKGROUND & AIMS: Recently, novel inborn errors of metabolism were identified because of mutations in V-ATPase assembly factors TMEM199 and CCDC115. Patients are characterized by generalized protein glycosylation defects, hypercholesterolemia, and fatty liver disease. Here, we set out to characterize the lipid and fatty liver phenotype in human plasma, cell models, and a mouse model.METHODS AND RESULTS: Patients with TMEM199 and CCDC115 mutations displayed hyperlipidemia, characterized by increased levels of lipoproteins in the very low density lipoprotein range. HepG2 hepatoma cells, in which the expression of TMEM199 and CCDC115 was silenced, and induced pluripotent stem cell (iPSC)-derived hepatocyte-like cells from patients with TMEM199 mutations showed markedly increased secretion of apolipoprotein B (apoB) compared with controls. A mouse model for TMEM199 deficiency with a CRISPR/Cas9-mediated knock-in of the human A7E mutation had marked hepatic steatosis on chow diet. Plasma N-glycans were hypogalactosylated, consistent with the patient phenotype, but no clear plasma lipid abnormalities were observed in the mouse model. In the siTMEM199 and siCCDC115 HepG2 hepatocyte models, increased numbers and size of lipid droplets were observed, including abnormally large lipid droplets, which colocalized with lysosomes. Excessive de novo lipogenesis, failing oxidative capacity, and elevated lipid uptake were not observed. Further investigation of lysosomal function revealed impaired acidification combined with impaired autophagic capacity.CONCLUSIONS: Our data suggest that the hyperchole-sterolemia in TMEM199 and CCDC115 deficiency is due to increased secretion of apoB-containing particles. This may in turn be secondary to the hepatic steatosis observed in these patients as well as in the mouse model. Mechanistically, we observed impaired lysosomal function characterized by reduced acidification, autophagy, and increased lysosomal lipid accumulation. These findings could explain the hepatic steatosis seen in patients and highlight the importance of lipophagy in fatty liver disease. Because this pathway remains understudied and its regulation is largely untargeted, further exploration of this pathway may offer novel strategies for therapeutic interventions to reduce lipotoxicity in fatty liver disease.
KW - V-ATPase assembly defects
KW - Lipophagy
KW - Lipid droplet
KW - Fatty liver disease
KW - NAFLD
KW - Hyperlipidemia
KW - Mutations in TMEM199 and in CCDC115
U2 - 10.1016/j.jcmgh.2021.09.013
DO - 10.1016/j.jcmgh.2021.09.013
M3 - Article
C2 - 34626841
SN - 2352-345X
VL - 13
SP - 583
EP - 597
JO - Cellular and molecular gastroenterology and hepatology
JF - Cellular and molecular gastroenterology and hepatology
IS - 2
ER -