1. C-reactive protein: a physiological activator of interleukin 6 receptor shedding
S A Jones, D Novick, S Horiuchi, N Yamamoto, A J Szalai, G M Fuller J Exp Med. 1999 Feb 1;189(3):599-604. doi: 10.1084/jem.189.3.599.
The soluble interleukin 6 receptor (sIL-6R) circulates at elevated levels in various diseases. This suggests that inflammatory mediators control sIL-6R release. Through examination of human neutrophils, it was found that the acute phase reactant C-reactive protein (CRP) activates a threefold increase in sIL-6R production. Maximal release occurred after 30-60 min exposure to CRP (50 micrograms/ml), and was mimicked by peptides corresponding to amino acid residues 174- 185 and 201-206 of native CRP. A third peptide fragment (77-82) had no effect. Differential mRNA splicing did not account for the CRP-mediated release of sIL-6R, since this isoform was not detected in conditioned media. Furthermore, stimulation of neutrophils with CRP or with peptides 174-185 or 201-206 promoted a loss of membrane-bound IL-6R, suggesting release by proteolytic shedding. The metalloprotease inhibitor TAPI had only a marginal effect on CRP-mediated sIL-6R release, suggesting that shedding occurs via a mechanism distinct from that previously reported. It well established that IL-6 stimulates the acute phase expression of CRP. Our current findings demonstrate a novel relationship between these two mediators, since CRP may affect IL-6-mediated inflammatory events by enabling formation of the sIL-6R/IL-6 complex.
2. Prevention of In vitro neutrophil adhesion to endothelial cells through shedding of L-selectin by C-reactive protein and peptides derived from C-reactive protein
C Zouki, M Beauchamp, C Baron, J G Filep J Clin Invest. 1997 Aug 1;100(3):522-9. doi: 10.1172/JCI119561.
C-Reactive protein (CRP), the classic acute-phase reactant in humans, diminishes accumulation of neutrophils at inflammatory sites. To evaluate the underlying mechanisms, we have studied whether CRP and peptides derived from CRP could affect the first step of neutrophil extravasation, the L-selectin-mediated interaction of neutrophils with endothelial cells. CRP markedly attenuated attachment of human neutrophils to cultured LPS-activated human coronary artery and pulmonary microvascular endothelial cells with apparent IC50 values of 20 and 22 microg/ml, respectively. At similar concentrations, CRP rapidly downregulated the expression of L-selectin on the neutrophil surface, whereas it failed to affect expression of CD11b and CD45 or to induce granule enzyme release. The loss of L-selectin was due to cleavage and shedding of the molecule from the cell surface, as quantitated by the soluble form of L-selectin in cell-free supernatants. The effects of CRP could be prevented by an anti-CRP antiserum and by KD-IX-73-4, which inhibits shedding of L-selectin. Inhibition of adhesion with CRP was additive with function-blocking anti-E-selectin and anti-CD18 antibodies, but was not additive with anti-L-selectin antibody. Neutrophil attachment and L-selectin expression were also diminished by CRP peptides 174-185 and 201-206, but not peptide 77-82, albeit these peptides showed a weaker inhibitory effect than the parent protein. These studies indicate a specific activation-independent action of CRP and CRP peptides 174-185 and 201-206 on expression of L-selectin, and suggest that by attenuating neutrophil adhesion to the endothelium and consequently neutrophil traffic into tissues, native CRP and peptides 174-185 and 201-206 may be major mechanisms to attenuate or limit the inflammatory response.
3. Peptides derived from C-reactive protein inhibit neutrophil alveolitis
R M Heuertz, N Ahmed, R O Webster J Immunol. 1996 May 1;156(9):3412-7.
C-reactive protein (CRP) is the classic acute phase reactant in humans, with serum levels elevated up to 1000-fold after the onset of inflammation. CRP inhibits chemotaxis of complement (C5a)-, LTB4-, IL-8-, and FMLP-stimulated neutrophils in vitro, and rabbits and transgenic mice with elevated serum CRP levels exhibit diminished neutrophil infiltration and vascular permeability in models of chemotactic factor-induced alveolitis. To evaluate the mechanism of CRP inhibition on chemoattractant-induced neutrophil inflammation in vivo, experiments were performed in mice infused with peptides of human CRP shown to inhibit C5a- and FMLP-stimulated neutrophil chemotaxis in vitro. After direct tracheal instillation of FMLP, mice previously injected via the retro-orbital plexus with CRP peptide 77-82 or 201-206 showed significant reductions (up to 90%) of neutrophils in the bronchoalveolar lavage fluid compared with vehicle-treated mice. Both CRP peptides also significantly (up to 55%) inhibited the increase in alveolar total protein levels. Control injections of native rabbit CRP (3 microM) inhibited neutrophil influx by 93% and protein leak by 55% in mice intratracheally instilled with FMLP. Despite similar levels of inhibition, approximately 10-fold more peptide by weight than native CRP was required. These data suggest that CRP degradation products at sites of tissue injury, in particular CRP peptides 77-82 and 201-206, are anti-inflammatory and can diminish lung injury by a reduction in neutrophil influx and protein leakage into alveoli following FMLP-induced inflammation.