Abigail S Haka1, Rajesh K Singh1, Inna Grosheva1, Haley Hoffner1, Estibaliz Capetillo-Zarate1, Harvey F Chin1, Niroshana Anandasabapathy1, Frederick R Maxfield2. 1. From the Department of Biochemistry, Weill Cornell Medical College, New York, NY (A.S.H., R.K.S., I.G., H.H., E.C.-Z., H.F.C., F.R.M.); and Department of Dermatology, Harvard Skin Disease Research Center, Bringham and Women's Hospital, Boston, MA (N.A.). 2. From the Department of Biochemistry, Weill Cornell Medical College, New York, NY (A.S.H., R.K.S., I.G., H.H., E.C.-Z., H.F.C., F.R.M.); and Department of Dermatology, Harvard Skin Disease Research Center, Bringham and Women's Hospital, Boston, MA (N.A.). frmaxfie@med.cornell.edu.
Abstract
OBJECTIVE: Although dendritic cells are known to play a role in atherosclerosis, few studies have examined the contribution of the wide variety of dendritic cell subsets. Accordingly, their roles in atherogenesis remain largely unknown. We investigated the ability of different dendritic cell subsets to become foam cells after contact with aggregated low-density lipoprotein (LDL; the predominant form of LDL found in atherosclerotic plaques). APPROACH AND RESULTS: We demonstrate that both murine and human monocyte-derived dendritic cells use exophagy to degrade aggregated LDL, leading to foam cell formation, whereas monocyte-independent dendritic cells are unable to clear LDL aggregates by this mechanism. Exophagy is a catabolic process in which objects that cannot be internalized by phagocytosis (because of their size or association with extracellular structures) are initially digested in an extracellular acidic lytic compartment. Surprisingly, we found that monocyte-derived dendritic cells upregulate exophagy on maturation. This contrasts various forms of endocytic internalization in dendritic cells, which decrease on maturation. Finally, we show that our in vitro results are consistent with dendritic cell lipid accumulation in plaques of an ApoE(-/-) mouse model of atherosclerosis. CONCLUSIONS: Our results show that monocyte-derived dendritic cells use exophagy to degrade aggregated LDL and become foam cells, whereas monocyte-independent dendritic cells are unable to clear LDL deposits. Furthermore, we find that exophagy is upregulated on dendritic cell maturation. Thus, exophagy-mediated foam cell formation in monocyte-derived dendritic cells could play a significant role in atherogenesis.
OBJECTIVE: Although dendritic cells are known to play a role in atherosclerosis, few studies have examined the contribution of the wide variety of dendritic cell subsets. Accordingly, their roles in atherogenesis remain largely unknown. We investigated the ability of different dendritic cell subsets to become foam cells after contact with aggregated low-density lipoprotein (LDL; the predominant form of LDL found in atherosclerotic plaques). APPROACH AND RESULTS: We demonstrate that both murine and human monocyte-derived dendritic cells use exophagy to degrade aggregated LDL, leading to foam cell formation, whereas monocyte-independent dendritic cells are unable to clear LDL aggregates by this mechanism. Exophagy is a catabolic process in which objects that cannot be internalized by phagocytosis (because of their size or association with extracellular structures) are initially digested in an extracellular acidic lytic compartment. Surprisingly, we found that monocyte-derived dendritic cells upregulate exophagy on maturation. This contrasts various forms of endocytic internalization in dendritic cells, which decrease on maturation. Finally, we show that our in vitro results are consistent with dendritic cell lipid accumulation in plaques of an ApoE(-/-) mouse model of atherosclerosis. CONCLUSIONS: Our results show that monocyte-derived dendritic cells use exophagy to degrade aggregated LDL and become foam cells, whereas monocyte-independent dendritic cells are unable to clear LDL deposits. Furthermore, we find that exophagy is upregulated on dendritic cell maturation. Thus, exophagy-mediated foam cell formation in monocyte-derived dendritic cells could play a significant role in atherogenesis.
Authors: Shalin H Naik; Anna I Proietto; Nicholas S Wilson; Aleksandar Dakic; Petra Schnorrer; Martina Fuchsberger; Mireille H Lahoud; Meredith O'Keeffe; Qi-xiang Shao; Wei-feng Chen; José A Villadangos; Ken Shortman; Li Wu Journal: J Immunol Date: 2005-06-01 Impact factor: 5.422
Authors: Emmanuel L Gautier; Thierry Huby; Flora Saint-Charles; Betty Ouzilleau; John Pirault; Virginie Deswaerte; Florent Ginhoux; Elizabeth R Miller; Joseph L Witztum; M John Chapman; Philippe Lesnik Journal: Circulation Date: 2009-04-20 Impact factor: 29.690
Authors: Oliver Annacker; Janine L Coombes; Vivianne Malmstrom; Holm H Uhlig; Tim Bourne; Bengt Johansson-Lindbom; William W Agace; Christina M Parker; Fiona Powrie Journal: J Exp Med Date: 2005-10-10 Impact factor: 14.307
Authors: Andrew D Nguyen; Thi A Nguyen; Rajesh K Singh; Delphine Eberlé; Jiasheng Zhang; Jess Porter Abate; Anatalia Robles; Suneil Koliwad; Eric J Huang; Frederick R Maxfield; Tobias C Walther; Robert V Farese Journal: Atherosclerosis Date: 2018-08-30 Impact factor: 5.162
Authors: Rajesh K Singh; Valéria C Barbosa-Lorenzi; Frederik W Lund; Inna Grosheva; Frederick R Maxfield; Abigail S Haka Journal: J Cell Sci Date: 2016-01-22 Impact factor: 5.285