| Literature DB >> 23874339 |
Sonja Krohn1, Alexandre Garin, Cem Gabay, Amanda E I Proudfoot.
Abstract
The CC chemokine ligand 18 (Entities:
Keywords: BBXB motif; CCL18; Evasin; chemokines; glycosaminoglycan; synovial fluid
Year: 2013 PMID: 23874339 PMCID: PMC3711072 DOI: 10.3389/fimmu.2013.00193
Source DB: PubMed Journal: Front Immunol ISSN: 1664-3224 Impact factor: 7.561
Figure 1. Chemotactic responses of (A) CD4+ T lymphocytes, (B) CD8+ T lymphocytes, (C) NK cells, and (D) B lymphocytes induced by CCL18 (○) or mediated by potent receptor agonists. (A,B) CXCL12α, (C) extracellular domain of CX3CL1, and (D) CXCL13. Medium was used as a control (Δ). Increase in scale and exclusion of chemotactic response induced by the potent receptor agonists (right panel). Data are expressed as chemotaxis index ± SEM. Data points are in triplicate. One out of two independent experiments is shown.
Figure 2Ability of CCL18 to induce signal transduction pathways and influence cell proliferation. One out of three independent experiments from separate donors is shown. (A) In vitro chemotactic responses of PBL mediated by CCL18 imply Giα-protein-coupled signal transduction mechanism. Chemotactic responses of PBL induced by CCL18 (○). Influence of PTX (200 ng/ml) on CCL18-mediated (●) chemotactic responses (upper panel). Chemotactic response mediated by CXCL12α (◊) and influence of PTX on CXCL12α-mediated responses (♦) (lower panel). Medium was used as a control (Δ). Data are expressed as chemotaxis index ± SEM. Data points are in triplicate. (B) ERK-1/2 phosphorylation analysis in T lymphocytes after stimulation with CCL18. Western Blot analysis using an anti-phosphor p44/42 MAPK (ERK-1/2) antibody. Time course for ERK-1/2 phosphorylation in T lymphocytes stimulated with 100 nM CCL18 or CXCL12α. Detection of actin was used as a loading control. (C) CCR3 cell surface expression after CCL18 stimulation of human eosinophils. Human eosinophils were stimulated with 12.5 nM CCL18 (○), CCL5 (▲), CCL11 (Δ), or 125 nM CCL18 (●) for 15 or 60 min. Ligand-induced CCR3 internalization was measured by Flow cytometry. Surface expression of CCR3 was compared with CCR3 expression of unstimulated eosinophils. Results are expressed in % of CCR3 surface expression. (D) T lymphocyte proliferation analysis after CCL18 stimulation. T lymphocytes were stimulated or not with anti-CD3/CD28 antibodies in the presence or absence of an increasing concentration of CCL18 (1 nM, 10 nM, 100 nM, or 1 μM). The division of cells was measured by CFSE and flow cytometry. Data points are in triplicate. Data are expressed in % of divided cells ± SEM.
Figure 3Characterization of Δ2-CCL18 and Δ3-CCL18. (A) Equilibrium competition binding assay using 125I-CCL18 on PBL. Binding of 125I-CCL18 was competed using an increasing concentration of CCL18 (IC50: 6.44 nM), CCL18-6His (IC50: 7.89 nM), Δ2-CCL18-6His (IC50: 1.14 nM), Δ3-CCL18-6His (IC50: 9.04 nM) with equal potency. Data are expressed in cpm ± SEM. Data points are in triplicate. The graph represents a single experiment. (B) In vitro chemotactic response of PBL to CCL18 and the N-terminal truncated forms Δ2-CCL18-6His and Δ3-CCL18-6His. Medium (Δ) was used as a control. Data are expressed as chemotaxis index ± SEM. Data points are in triplicate. One representative experiment out of three is shown.
Figure 4Detection and identification of processed CCL18 isoforms in the synovial fluid of RA and OA patients by SELDI-TOF MS. (A) MS spectra of recombinant CCL18 determined using NP20 ProteinChips. Recombinant CCL18 (100 ng) was applied onto a NP20 ProteinChip Array and mass analyses were performed by SELDI-TOF MS. (B) Standard curve of recombinant CCL18 with RS100 ProteinChips. Dilutions of recombinant CCL18 ranging from 0.15 to 10 ng were applied onto RS100 ProteinChip Arrays containing immobilized polyclonal anti-CCL18 antibodies. (C) Increase in scale at 0.31 ng. (D) Peak height displayed according to amount of recombinant CCL18. (E) RS100 ProteinChips were coated with polyclonal anti-human CCL18 antibodies and incubated with synovial fluid from RA (Sample number 402 and 8) or OA (Sample number 1573) patients. Mass spectra were generated by SELDI-TOF MS. Spectra are representative for four RA and OA patient samples analyzed.
Summary of the mass detected in the synovial fluid samples of RA and OA patients by SELDI-TOF MS.
| Sample number | ng/ml | MW (Da) | Δ To full length CCL18 | ||
|---|---|---|---|---|---|
| 8 | 41.1 | 7644.0 + H | 7614.5 + H | −185.4 | −185.3 |
| 7760.7 + H | 7729.6 + H | −68.7 | −70.2 | ||
| 8036.9 + H | 8011.3 + H | +207.5 | +211.5 | ||
| 385 | 389.5 | 7764.6 + H | 7766.5 + H | −69.8 | −73.0 |
| 8041.2 + H | 8046.0 + H | +206.8 | +206.5 | ||
| 402 | 92.01 | − | |||
| 7765.9 + H | 7766.3 + H | −69.3 | −72.2 | ||
| 8040.8 + H | 8043.9 + H | +205.6 | +205.4 | ||
| 2282 | 609.7 | 7747.9 + H | 7739.8 + H | −72.4 | −71.8 |
| 8029.1 + H | 8026.9 + H | +208.8 | +215.3 | ||
| 669 | 54.0 | 7766.6 + H | 7765.5 + H | −71.3 | −71.2 |
| 8001.6 + H | 7999.5 + H | +163.7 | +162.8 | ||
| 8046.6 + H | 8042.8 + H | +208.7 | +206.1 | ||
| 1201 | 58.7 | 7761.0 + H | 7761.9 + H | −70.6 | −70.1 |
| 7993.1 + H | 7994.9 + H | +161.5 | +162.9 | ||
| 8034.7 + H | 8036.7 + H | +203.1 | +204.7 | ||
| 1573 | 37.0 | 7762.7 + H | −71.6 | ||
| 7996.9 + H | +162.6 | ||||
| 8040.6 + H | +206.3 | ||||
| 2076 | 591.0 | 7719.5 + H | −72.4 | ||
| 8002.9 + H | +211.0 | ||||
The concentration of CCL18 in each sample is indicated in ng/ml, as well as the mass obtained from each sample [MW (Da)] and the discrepancy of mass to full length CCL18 which is highlighted in bold (Δ to full length CCL18).
Figure 5Analysis of complex formation of Evasin-1, -3, and -4 with CCL18 by SEC. CCL18 was incubated with an equimolar amount of (A) Evasin-1, (B) -4, and (C) -3 and injected onto an analytical Superdex 75 Prepgrade 10/300GL Tricorn column. The elution profile of CCL18 (blue), Evasins (green), and the mixture of CCL18 and Evasins (red) is shown in milliabsorbance units (mAU). The elution volume and corresponding molecular weight are indicated for each peak. The elution volume of each protein used for calibration is indicated on the top according to their molecular weights. (A,B) SDS-PAGE analyses were performed with the fractions corresponding to the peak elution fractions. SDS-PAGE stained with silver. One representative experiment out of two is shown.
Figure 6Evasin-1 neutralizes the antagonistic effect of CCL18 on CCR3. (A) Equilibrium competition binding assay of 125I-CCL18 on L1.2/CCR3 transfectants using an increasing concentration of CCL11 and the CCL18-binding proteins Evasin-1, -3, and -4. Data are expressed in cpm ± SEM. Data points are in triplicate. Inhibitory activity of CCL11 (IC50: 4.99 nM), Evasin-1 (IC50: 7.94 nM), and -4 (IC50: 0.03 nM) on 125I-CCL18 binding to CCR3. (B) Inhibition of chemotaxis using L1.2/CCR3 transfectants. Migration of L1.2/CCR3 transfectants to a constant concentration of 1 nM CCL11 was inhibited by an increasing concentration of CCL18 (IC50: 556.8 nM). The effect of Evasin-1 on the antagonistic activity of CCL18 on CCR3 was assessed by the incubation of CCL18 with a twofold access of Evasin-1. Evasin-3 (IC50: 421 nM) was used as a control. Data are expressed as chemotaxis index ± SEM. Data points are in triplicate. One representative experiment out of two is shown.
Figure 7Determination of the PITPNM3/Nir1 mRNA expression level in CCL18 responsive cells. Analysis of PITPNM3/Nir1 mRNA expression by qPCR with (A) 1.25 ng and (B) 3.13 ng cDNA per well. Universal Human Reference RNA (Control) and MDA-MB-231 were used as positive controls. CCL18: PBL upon migration to 10 nM CCL18; CXCL12α: PBL upon migration to 10 nM CXCL12α and medium: PBL collected in the lower chemotaxis well without the addition of chemokine. Data are expressed in % expression of HKG (GAPDH, actin, 18S rRNA) ± SEM. The graphs represent a single experiment.
Figure 8Equilibrium competition binding assays of . The binding of 125I-CCL18 to PBL was competed with Heparin (heparin-3393) (IC50: 97.43 nM) and CCL18 (IC50: 24.37 nM). Data are expressed in cpm ± SEM. Data points are in triplicate. One representative experiment out of six is shown.
Figure 9Identification of the BBXB GAG-binding motif in the 40s loop of CCL18. (A) Prediction of the BBXB GAG-binding motif of CCL18 by a sequence alignment of CCL18 with CCL3, CCL4, and CCL5. Basic residues, which are part of the BBXB motif, are highlighted in bold and the conserved cysteine residues in gray. (B) Comparison of the ability of CCL18 and 44AAGA47-CCL18 to bind to heparin immobilized on Epranex plates. Immobilization of a dilution series of CCL18 and 44AAGA47-CCL18 (44AAGA47) onto a heparin coated (+) or uncoated (−) heparin binding plate. Wells containing no chemokine were used as a control (■). Data are expressed in optical absorbance at 450 nm. Data points are in duplicate. One representative experiment out of three is shown. The capacity of 44AAGA47-CCL18 to bind to heparin is reduced. (C) The binding of 125I-CCL18 and 125I-44AAGA47-CCL18 (125I-44AAGA47) to PBL was competed with Heparin (heparin-3393) and CCL18. Data points are in triplicate. The mutation of the basic amino acids in the BBXB motif of CCL18 into alanine residues considerably abrogates binding to PBL.