Chimeric antigen receptor macrophages target and resorb amyloid plaques
Alexander B. Kim, … , Jin-Moo Lee, Carl J. DeSelm
Alexander B. Kim, … , Jin-Moo Lee, Carl J. DeSelm
Published March 22, 2024
Citation Information: JCI Insight. 2024;9(6):e175015. https://doi.org/10.1172/jci.insight.175015.
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Resource and Technical Advance Aging Therapeutics

Chimeric antigen receptor macrophages target and resorb amyloid plaques

Abstract

Substantial evidence suggests a role for immunotherapy in treating Alzheimer’s disease (AD). While the precise pathophysiology of AD is incompletely understood, clinical trials of antibodies targeting aggregated forms of β amyloid (Aβ) have shown that reducing amyloid plaques can mitigate cognitive decline in patients with early-stage AD. Here, we describe what we believe to be a novel approach to target and degrade amyloid plaques by genetically engineering macrophages to express an Aβ-targeting chimeric antigen receptor (CAR-Ms). When injected intrahippocampally, first-generation CAR-Ms have limited persistence and fail to significantly reduce plaque load, which led us to engineer next-generation CAR-Ms that secrete M-CSF and self-maintain without exogenous cytokines. Cytokine secreting “reinforced CAR-Ms” have greater survival in the brain niche and significantly reduce plaque load locally in vivo. These findings support CAR-Ms as a platform to rationally target, resorb, and degrade pathogenic material that accumulates with age, as exemplified by targeting Aβ in AD.

Authors

Alexander B. Kim, Qingli Xiao, Ping Yan, Qiuyun Pan, Gaurav Pandey, Susie Grathwohl, Ernesto Gonzales, Isabella Xu, Yoonho Cho, Hans Haecker, Slava Epelman, Abhinav Diwan, Jin-Moo Lee, Carl J. DeSelm

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Figure 1

Generation, validation, and phenotype of an aducanumab-based Aβ CAR-M.

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Generation, validation, and phenotype of an aducanumab-based Aβ CAR-M. (...
(A) Schematic diagram of Aβ CAR and control CAR constructs. scFv, single-chain variable fragment; E CAR, EphA2 scFv CAR; E(t) CAR, EphA2 truncated CAR. (B) Representative FACS plots of (left) F4/80 and CD64 surface expression on HoxB8 cells at day 0 and day 6 of differentiation with M-CSF and (right) surface CAR expression on cells at day 6 of differentiation. (C) In vitro uptake of Alexa Flour 488 fluorescent tagged Aβ (1–42 aa) by untransduced, control, or Aβ CAR-Ms after 2 or 4 hours of coincubation, depicted as percent uptake (left) or geometric mean fluorescence intensity (MFI, right). (D) Representative immunofluorescence microscopy images of Aβ CAR-Ms incubated with AF-488–tagged Aβ (1–42 aa) for 4 hours and stained for Lamp1. Scale bars: 10 μm. (E) Schematic of flow-based phenotyping of untransduced macrophages, control CAR-Ms, or Aβ CAR-Ms coincubated with amyloid-laden brain slices from aged APP/PS1 mice for 44 hours prior to flow cytometry analysis. (F) Percent change in the stated marker after coincubation of untransduced, control, or Aβ CAR-Ms on amyloid-laden brain slices from APP/PS1 mice from the expression of the same markers on the same cells incubated without brain slices. Data are represented as mean ± SEM from n = 2 independent experiments with 3–5 technical replicates for each condition (C) and 5 technical replicates (F). Statistical significance was calculated with a repeated measures 2-way ANOVA (C) or 1-way ANOVA (F) with Tukey’s multiple-comparison tests. For F, *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.