Fig 2: Downregulation of downstream effector SOCS3 participated in visceral hypersensitivity in neonatal‐CRD or dual‐CRD rats. (A–D) The expression of Rap1 mRNA, Rap1 protein, SOCS3 mRNA, and SOCS3 protein in PVN in each group (n = 6). (E) SOCS3 double‐labeled with CRF and GFAP, rather than Iba‐1 (Scale bar = 100 μm). (F) Co‐expression of CRF with SOCS3 in PVN in each group. (G) Statistical diagram for SOCS3 and CRF co‐labeling (n = 6, scale bar = 100 μm). (H) Schema of PVN, and immunofluorescent staining of SOCS3 in PVN. Data are presented as the mean ± SD. *p < 0.05, **p < 0.01 vs. indicated group

Fig 3: PRMT7 expression is increased in COPD lungs and localized to macrophages.a Heat map of the most significantly enriched gene lists in the lungs of COPD patients following gene set enrichment analysis (GSEA) of the GO molecular function set on publicly available array data from lung tissue (GSE76925) of healthy smokers (n = 40) v COPD patients (n = 111). Nominal P value generated by the GSEA software of the enrichment score relative to the null distribution92 shown. b Expression of genes involved in N-methyltransferase activity in COPD patients relative to healthy smokers taken from GSE76925, relative fold change, and P value calculated using the GEO2R interactive web tool running limma R. PRMT genes highlighted in red. c, d Expression of PRMT7, in the lungs of healthy smokers and COPD patients, individuals are shown, expression relative to healthy smokers, taken from GSE76925 (n = 40 smokers and n = 111 COPD patients) (c) and GSE27597 (n = 16 smokers and n = 48 COPD patients) (d). e qPCR analysis of PRMT7 and TNF expression in human lung core biopsies from healthy controls (n = 8) and COPD patients (n = 18) relative to controls. f Western blot analysis of PRMT7 expression in lung core biopsies from healthy (n = 17) and COPD patients (n = 23), normalized to β-actin and shown relative to controls. g Representative images of immunofluorescence analysis for PRMT7 (Red) and the macrophage marker Galectin 3 (Green) in sections from core biopsies of healthy and COPD human lung (n = 4, scale bar 20 μm) and sections from filtered air (FA) and cigarette smoke (CS) mouse lung (n = 5, scale bar 25 μm). h Quantification of double-positive cells from (g). i, j mRNA expression levels of PRMT7 determined by qPCR in human monocytes isolated from blood of non-smokers (n = 7) vs smokers (n = 10) (i) and circulating monocytes (n = 4 for FA and CS) (i) and alveolar macrophages (n = 4 for FA and n = 3 for CS) (j) from B6 mice exposed to FA or CS for 3 days, relative to controls. k–m scRNA-Seq (Drop-Seq) analysis on the lungs of mice following exposure to FA (n = 3) and CS for 2 (n = 5) and 4 months (n = 5). AM alveolar macrophages, CS-ind MØ CS-induced macrophages, IM interstitial macrophages, cMono classical monocytes. k Dot blot depicting Prmt7 expression (log-transformed, normalized UMI counts) and percentage of cells positive for Prmt7 in the myeloid cell compartment. l RNA velocity analysis of the myeloid compartment. (1) AM; (2) CS-ind MØ; (3) Lyve1 + /Cd163 + IM; (4) Lyve1−/Cd163− IM; (5) Prg4 + IM; (6) Ly6c2 + cMono; (7) Ly6c2- non-cMono; (8) Cd103 + /Clec9a + cDC; (9) Cd209 + /Cd11b + cDC; (10) Fscn1 + DC. m Fate probability mapping towards the CS-ind MØ population utilizing CellRank. n Heat map of gene expressions of PRMT6/7, RAP1A, and ALOX5 in monocyte-like macrophages obtained from scRNA-Seq data of bronchoalveolar lavage from COPD patients (n = 9) and healthy controls (n = 6). Mean gene expression per donor is shown as a z-transformed value (across all donors). Data shown mean ± SD and individual patients or mice (c–f and h–j), P values shown in charts determined by two-tailed Mann–Whitney test (c–f), unpaired two-tailed Student’s t-test (h–j). Source data are provided as a Source Data file.

Fig 4: PLCD3 promotes aerobic glycolysis and cell growth through activation of the RAP1 pathway. A. KEGG shows significant enrichment of RAR1 pathway-related genes. B. Western blot analysis of Rap1, b-Raf, GLUT1, HK1, HK2, and PKM2 in lung cancer cells with or without PLCD3 silencing. C. Growth assay of A549 cells with and without PLCD3 induction and XIV induction. D–E. Glucose uptake and consumption assays in A549 and NCI-H1299 cells with or without PLCD3 induction and 1 μmol/L GGTI298 (Rap1 inhibitor) treatment. F-I. Detection of the mRNA expression levels of GLUT1, HK1, HK2 and PKM2 in A549 and NCI-H1299 cells transfected or not transfected with PLCD3 and GGTI298. (F) GLUT1; (G) HK1; (H) HK2; (I) PKM2. J. The effect of PLCD3 and GGTI298 on the invasion of lung cancer cells was detected by transwell assay. All data were shown as the mean ± SD, n = 3, *p < 0.05, **p < 0.01.

Fig 5: The inhibition activities of 2 and bivalent 4a‐e against prenylation of K‐Ras, HDJ‐2, and Rap1 (Change in Figure as well) were evaluated using gel shift assays. The dual FTase and GGTase I inhibitor FGTI (FGTI‐2734)[ 19 ] was used as a positive control. Miapaca‐2 cells were treated for 48 hours with vehicle (V) or the indicated compounds at 30 and 100 µM (10 and 30 µM for FGTI‐2734), harvested and processed for SDS‐PAGE Western blotting with K‐Ras, HDJ‐2, and Rap1 antibodies as described in the Methods section. The inhibition of prenylation of K‐Ras, HDJ‐2, and Rap1 was seen by the shift in bands from prenylated (P) to prenylated (U) proteins. Vinculin 1 and 2 were used loading controls.