Lactate programs CRIP1 protein lactylation to drive synovial proliferation in rheumatoid arthritis
Meican Ma, Yu Zhou, Qianlin Li, Zhao Wang, Shangqi Guan, Xiaoxue Wang, Han Zhao, Zhenke Wen, Ting Liu, Fenghong Yuan
Meican Ma, Yu Zhou, Qianlin Li, Zhao Wang, Shangqi Guan, Xiaoxue Wang, Han Zhao, Zhenke Wen, Ting Liu, Fenghong Yuan
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Research Article Metabolism

Lactate programs CRIP1 protein lactylation to drive synovial proliferation in rheumatoid arthritis

Abstract

Synovial hyperplasia is a hallmark of rheumatoid arthritis (RA), yet its mechanism remains unclear. RA synovium exhibits metabolic shift, characterized by upregulated glycolysis and enhanced lactate production. In this study, we elucidated the mechanism underlying the roles of lactate metabolism and protein lactylation in RA pathology. In patients with RA, both lactate production and protein lactylation were elevated and showed a positive correlation with clinical disease activity. These changes were further implicated in driving synovial proliferation. Among the lactylated proteins, Cysteine-rich intestinal protein 1 (CRIP1) exhibited a marked increase in modification and played a central role in promoting synovial proliferation. Mechanistically, CRIP1 underwent MOF-mediated lactylation in RA synovial fibroblasts. Lactylated CRIP1 hijacked the cell-cycle regulator p21, disrupting its interaction with cyclin-dependent kinase 2 (CDK2), thereby facilitating the G1/S phase transition. Functionally, AAV-mediated delivery of a lactylation-deficient CRIP1 K49R significantly reduced synovial proliferation compared with WT CRIP1. Peptide-based interventions targeting CRIP1 K49 lactylation effectively inhibited synovial hyperplasia and disease severity in both Collagen II–induced arthritis (CIA) and humanized NSG chimeric models. Collectively, CRIP1 protein lactylation drives synovial proliferation in RA by hijacking p21 from CDK2, thereby facilitating cell cycle progression. Targeting this pathway may serve as a promising strategy for RA.

Authors

Meican Ma, Yu Zhou, Qianlin Li, Zhao Wang, Shangqi Guan, Xiaoxue Wang, Han Zhao, Zhenke Wen, Ting Liu, Fenghong Yuan

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Figure 8

Targeting CRIP1 lactylation with a synthetic peptide suppresses RA progression in mouse models.

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Targeting CRIP1 lactylation with a synthetic peptide suppresses RA progr...
(A) Peptide treatment in CIA mice. (B) Evaluation of clinical arthritis scores in K49R peptide– or K49 peptide–treated CIA mice (n = 6). (C) Paw thickness in K49R peptide– or K49 peptide–treated CIA mice (n = 6). (D) μCT images of forepaws and knee joints from K49R peptide– or K49 peptide–treated CIA mice. Scale bar: 5 mm. (E) Histological staining of H&E and Safranin O in synovial tissues with from K49R peptide– or K49 peptide–treated CIA mice. Scale bar: 100 μm. (F and G) IHC staining and quantification of Ki67 and FAPα in synovial tissues from K49R peptide– or K49 peptide–treated CIA mice (n = 6). Scale bar: 100 μm. (HJ) Immunofluorescence staining and quantification of Ki67 (green) and FAPα (red) in synovial grafts derived from K49R peptide and K49 peptide groups (n = 6). Scale bar: 10 μm. (K) Heatmap depicting mRNA expression levels of inflammation-related genes (IL6, TNF, IL1B) and matrix-degrading enzymes (MMP1, MMP9) in synovial grafts derived from K49R peptide and K49 peptide groups (n = 6). *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001. Data are shown as mean ± SEM and P values are calculated using 2-way ANOVA with Bonferroni’s post hoc test (B and C), or unpaired 2-tailed t test (G and IK).