Repurposing the antipsychotic drug amisulpride for targeting synovial fibroblast activation in arthritis
Dimitra Papadopoulou, Fani Roumelioti, Christos Tzaferis, Panagiotis Chouvardas, Anna-Kathrine Pedersen, Filippos Charalampous, Eleni Christodoulou-Vafeiadou, Lydia Ntari, Niki Karagianni, Maria C. Denis, Jesper V. Olsen, Alexios N. Matralis, George Kollias
Dimitra Papadopoulou, Fani Roumelioti, Christos Tzaferis, Panagiotis Chouvardas, Anna-Kathrine Pedersen, Filippos Charalampous, Eleni Christodoulou-Vafeiadou, Lydia Ntari, Niki Karagianni, Maria C. Denis, Jesper V. Olsen, Alexios N. Matralis, George Kollias
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Research Article Therapeutics

Repurposing the antipsychotic drug amisulpride for targeting synovial fibroblast activation in arthritis

Abstract

Synovial fibroblasts (SFs) are key pathogenic drivers in rheumatoid arthritis (RA). Their in vivo activation by TNF is sufficient to orchestrate full arthritic pathogenesis in animal models, and TNF blockade proved efficacious for a high percentage of patients with RA albeit coinducing rare but serious side effects. Aiming to find new potent therapeutics, we applied the L1000CDS2 search engine, to repurpose drugs that could reverse the pathogenic expression signature of arthritogenic human TNF–transgenic (hTNFtg) SFs. We identified a neuroleptic drug, namely amisulpride, which reduced SFs’ inflammatory potential while decreasing the clinical score of hTNFtg polyarthritis. Notably, we found that amisulpride function was neither through its known targets dopamine receptors D2 and D3 and serotonin receptor 7 nor through TNF–TNF receptor I binding inhibition. Through a click chemistry approach, potentially novel targets of amisulpride were identified, which were further validated to repress hTNFtg SFs’ inflammatory potential ex vivo (Ascc3 and Sec62), while phosphoproteomics analysis revealed that treatment altered important fibroblast activation pathways, such as adhesion. Thus, amisulpride could prove beneficial to patients experiencing RA and the often-accompanying comorbid dysthymia, reducing SF pathogenicity along with its antidepressive activity, serving further as a “lead” compound for the development of novel therapeutics against fibroblast activation.

Authors

Dimitra Papadopoulou, Fani Roumelioti, Christos Tzaferis, Panagiotis Chouvardas, Anna-Kathrine Pedersen, Filippos Charalampous, Eleni Christodoulou-Vafeiadou, Lydia Ntari, Niki Karagianni, Maria C. Denis, Jesper V. Olsen, Alexios N. Matralis, George Kollias

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Figure 5

Amisulpride targets’ identification on hTNFtg SFs.

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Amisulpride targets’ identification on hTNFtg SFs. (A) Structure of the ...
(A) Structure of the amisulpride and the synthesized click compounds, based on amisulpride chemical form, bearing an alkyne in a different position. (B) Volcano plots with highlighted candidates, combining differences (Student’s 2-tailed t test difference > 1) for proteins identified in each active probe sample versus the DMSO or the respective competition control (n = 3). (C) Venn diagram of the proteins identified in volcano graphs of B, resulting in 6 common candidates targeted by both click 1 and click 2. (D) CCL20 and CCL5 quantification in supernatants derived from hTNFtg SFs upon shRNA-mediated silencing of Ascc3, Sec62, Romo2, Kif5c, and Cdc42 when compared with the scramble-treated sample (n = 6–20) (* P value < 0.05; all data are shown as mean ± SEM; statistics are performed using 1-way ANOVA, followed by Dunnett’s multiple comparisons test). ASCC3, activating signal co-integrator 1 complex subunit 3; SEC62, translocation protein SEC62; CDC42, cell division cycle 42; KIF5C, kinesin heavy chain isoform 5C; ROMO1, ROS modulator 1; KCT2, keratinocyte-associated transmembrane protein 2.