Reduced late endosome/lysosome function promotes SLE through chronic PI3K activity and SHP-1/SHIP-1 defects
SunAh Kang, Andrew J. Monteith, Liubov Arbeeva, Karissa Grier, Shruti Saxena Beem, Anthony C. Trujillo, Xinyun Bi, Kai Sun, Rebecca E. Sadun, Mithu Maheswaranathan, Megan E.B. Clowse, Saira Z. Sheikh, Jennifer L. Rogers, Barbara J. Vilen
SunAh Kang, Andrew J. Monteith, Liubov Arbeeva, Karissa Grier, Shruti Saxena Beem, Anthony C. Trujillo, Xinyun Bi, Kai Sun, Rebecca E. Sadun, Mithu Maheswaranathan, Megan E.B. Clowse, Saira Z. Sheikh, Jennifer L. Rogers, Barbara J. Vilen
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Research Article Immunology

Reduced late endosome/lysosome function promotes SLE through chronic PI3K activity and SHP-1/SHIP-1 defects

Abstract

Degradation of cellular waste from phagocytosis, endocytosis, and autophagy occurs through hydrolases that become activated during acidification of late endosomes and lysosomes (LELs). In our cross-sectional study, we showed diminished LEL acidification and the accumulation of surface-bound nucleosome on monocytes, dendritic cells, B cells, neutrophils, and T cells from patients with systemic lupus erythematosus (SLE). Diminished acidification and exocytosis of undegraded IgG-immune complexes were evident in active, but not inactive, disease. This was supported by our murine study in which LEL acidification was diminished, promoting exocytosis and the accumulation of cell surface IgG-immune complexes. Mechanistically, LEL dysfunction was induced by chronic PI3K activation in lupus-prone MRL/lpr mice. We also showed that on a non-autoimmune C57BL/6 background, deficiency in SHP-1 and inhibition of SHIP-1 activity were sufficient to recapitulate LEL dysfunction found in MRL/lpr mice. Non-acidic LELs were evident in the majority of patients and associated with SLEDAI arthritis, rash, and nephritis. The high frequency of LEL dysfunction in SLE suggests that it could serve as a biomarker identifying a specific disease endotype.

Authors

SunAh Kang, Andrew J. Monteith, Liubov Arbeeva, Karissa Grier, Shruti Saxena Beem, Anthony C. Trujillo, Xinyun Bi, Kai Sun, Rebecca E. Sadun, Mithu Maheswaranathan, Megan E.B. Clowse, Saira Z. Sheikh, Jennifer L. Rogers, Barbara J. Vilen

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Figure 4

Highly active SLE patients (SLEDAI ≥ 12) show elevated levels of surface nucleosome and circulating immune complexes.

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Highly active SLE patients (SLEDAI ≥ 12) show elevated levels of surface...
(AG) Unfractionated blood Mo (A), B cells (B), DCs (C), and rNAV (D), aNAV (E), DN2 (F), and DN1 (G) cells were analyzed for surface nucleosome by flow cytometry. Representative histograms show the cell distribution with varying disease activities (gray: isotype control). (H) Plasma circulating immune complex (CIC) levels were measured by IC-mediated internalization of FcγRIIA on neutrophils using flow cytometry and a standard curve. N = 11–41 per disease group; 3 experiments. (IM) Trends were assessed on B cells (circles), Mo (squares), and DCs (triangles) using the Cochran-Armitage test to compare the proportion of patients in each disease group with high CIC (I), high surface nucleosome (J), low [H+] and high surface nucleosome (K), high CIC and surface nucleosome (L), and low [H+] and high CIC (M). In AC: HC, N = 48; SLE patient, N = 72; in DG: HC, N = 19; SLE patient, N = 8–15; 8–48 experiments. Statistical analysis used Kruskal-Wallis (AH). Adjusted P values with significance are shown. Bars, median; boxes, 25th–75th percentiles; whiskers, minimum and maximum values.