Role of ribosomal protein S19-like plasma protein in blood coagulum resorption.

Western blot analyses and monocyte chemoattraction analyses of guinea pig plasma and serum indicated the presence of a plasma protein indistinguishable from ribosomal protein S19 and the cross-linked dimerization of it gaining monocyte chemotactic capacity in association with blood coagulation as in the case of human. When coagula preformed in vitro were intraperitoneally inserted into guinea pigs, they were rapidly covered by macrophages within 24h concomitant with an intra-coagulum macrophage infiltration. Differences were observed between the surface macrophages and the penetrating macrophages in ultrastructural, histochemical and immunohistochemical analyses. The inserted coagula were resorbed by day 7. When either anti-RP S19 antibodies or Gln137Asn-RP S19, a competitive inhibitor against RP S19, was premixed into the inserted coagulum, the attachment and penetration by macrophages decreased and the coagulum resorption retarded. These results indicate the role of the plasma RP S19-like molecule in coagulum resorption via macrophage recruitment.

The role of the ribosomal protein S19 C-terminus in Gi protein-dependent alternative activation of p38 MAP kinase via the C5a receptor in HMC-1 cells.

We have demonstrated that an alternative C5a receptor (C5aR) ligand, the homodimer of ribosomal protein S19 (RP S19), contains a unique C-terminus (I(134)-H(145)) that is distinct from the moieties involved in the C5a-C5aR interaction. To examine the role of I(134)-H(145) in the ligand-C5aR interaction, we connected this peptide to the C-terminus of C5a (C5a/RP S19) and found that it endowed the second binding moiety of RP S19 (L(131)DR) with a relatively higher binding affinity to the C5aR on a human mast cell line, HMC-1. In contrast to the C5aR, the second C5aR C5L2 worked as a decoy receptor. As a result, the mitogen-activated protein kinase (MAPK) downstream of the Gi protein exchanged extracellular-signal regulated kinase for p38MAPK. This alternative p38MAPK activation could be pharmacologically suppressed not only by the downregulation of phosphoinositide 3-kinase (PI3K) by LY294002, but also by the over-activation of protein kinase C by phorbol 12-myristate 13-acetate. The activation was reproduced upon C5a-C5aR interaction by a simultaneous suppression of PI3K and phospholipase C with LY294002 and U73122 at low concentrations. Moreover, p38MAPK phosphorylation upstream of the pertussis toxin-dependent extracellular Ca(2+) entry was also suppressed by high concentrations of MgCl(2), which blocks melastatin-type transient receptor potential Ca(2+) channels (TRPMs). The active conformation of C5aR upon the ligation by C5a, at least on HMC-1 cells, is changed by the additional interaction of the I(134)-H(145) peptide, which seems to guide the alternative activation of p38MAPK. This activation is then amplified by a novel positive feedback loop between p38MAPK and TRPM.

Agonistic and antagonistic effects of C5a-chimera bearing S19 ribosomal protein tail portion on the C5a receptor of monocytes and neutrophils, respectively.

C-terminus of S19 ribosomal protein (RP S19) endows the cross-linked homodimer with a dual effect on the C5a receptor in leucocyte chemoattraction; agonistic effect on the monocyte receptor, and antagonistic effect on the neutrophil receptor. C5a exhibits the uniform agonistic effect on this receptor of both cell types. We have currently prepared a recombinant C5a-chimeric protein bearing the C-terminus of RP S19 (C5a/RP S19 chimera) to be used as a substitute of the RP S19 dimer. In vitro, this chimera similarly inhibited the intracellular Ca(2+) mobilization of neutrophils induced by C5a to the RP S19 dimer did. In the guinea pig skin, 10(-7) M C5a/RP S19 chimera exhibited an inhibitory capacity to the neutrophil infiltration induced by 3 x 10(-7) M C5a without enhancing monocyte infiltration. In reverse passive Arthus reaction, the neutrophil infiltration associated with plasma extravasation was significantly reduced by the simultaneous administration of 10(-7) M C5a/RP S19 chimera with antibodies. The C5a/RP S19 chimera is a useful tool not only to examine the molecular mechanism that underlies the functional difference of the C5a receptor between monocytes and neutrophils, but also to prevent C5a-mediated hyper-response of neutrophils in acute inflammation.

Roles of leukocytosis and cysteinyl leukotriene in polymorphonuclear leukocyte-dependent plasma extravasation.

The PMN-dependent plasma extravasation is a major mechanism of permeability enhancement in acute inflammation. To reveal the pathophysiological significance of the PMN-dependent plasma extravasation, we prepared a systemic leukocytotic guinea pig model by a daily injection of recombinant human (rh)G-CSF. The extent of the PMN-dependent plasma extravasation, regarded as the late-phase permeability induced by an intradermal injection of zymosan-activated guinea pig plasma (ZAP) or of rhC5a, clearly correlated to the circulating PMN number. The augmentation of local response following the systemic response seemed to be the characteristic feature of the PMN-dependent plasma extravasation. We then revealed the molecular mechanism of the PMN-dependent plasma extravasation. Neither the antihistaminic agent diphenhydramine, nor the bradykinin B2 receptor antagonist, HOE140, affected the ZAP-induced, late-phase extravasation. In contrast to this, pretreatment with an antagonist of cysteinyl leukotriene (cys-LT) 1 receptor, pranlukast, significantly reduced the late-phase extravasation. Similarly, it was reduced by pretreatment with a 5-lipoxygenase inhibitor, MK-886, indicating the participation of cys-LTs in the PMN-dependent plasma extravasation. Histologically, pretreatment with pranlukast or MK-886 did not affect the ZAP-induced PMN infiltration. Consistently, a combined treatment with pranlukast and diphenhydramine completely suppressed the early-phase extravasation. As pranlukast pretreatment did not affect plasma extravasation induced by mast cell degranulation, and depletion of platelets did not influence the pranlukast-inhibitable plasma extravasation induced by rhC5a injection, cys-LTs are most likely produced by transcellular biosynthesis involving PMNs and vascular wall cells.

Monocyte chemotactic S19 ribosomal protein dimer in atherosclerotic vascular lesion.

To elucidate the molecular mechanism inducing monocyte/macrophage infiltration in the atherosclerotic lesion, we measured the monocyte chemotactic capacity in the extracts of aortic lesions. Five out of seven extracts exhibited significant chemotactic activities. Immunohistochemical examination with an anti-CD68 monoclonal antibody demonstrated that the five positive lesions possessed obvious monocyte/macrophage infiltrations at the intima, whereas the two negative lesions did so at significantly lower intensities. We subjected the chemotactic extracts to immunological analyses to identify the monocyte chemoattractant in them. The monocyte chemotactic capacities of all positive extracts were removed with anti-S19 ribosomal protein (RP S19) antibody beads and antimonocyte chemoattractant protein-1 (MCP-1) antibody beads. In three of the five extracts, the anti-RP S19 antibody beads were more effective than the anti-MCP-1 antibody beads for removal, while in the remaining two extracts, the opposite was observed. A combined immunoabsorption with these beads depleted the monocyte chemotactic capacity of a representative sample of each group. Consistently, the chemotactic capacity of an apparently RP S19 dimer-predominant extract was strongly inhibited by the presence of a C5a receptor antagonist. These results suggest that the RP S19 dimer and MCP-1 play a major role in the monocyte/macrophage infiltration of the atherosclerotic vascular lesion.

Elastin peptide receptor-directed monocyte chemotactic polysaccharides derived from seaweed sporophyll and from infectious fungus.

We discovered that a seaweed sporophyll-derived polysaccharide of brown alga, Wakame (Undaria pinnatifida) bound to monocytes and attracted them in vitro and in vivo. Physicochemical properties, affinity to a lectin-bead column and sugar composition of the chemotactic polysaccharide indicated this molecule to be a highly sulfated fucogalactan. We then identified the monocyte receptor of the sulfated fucogalactan as the elastin peptide receptor by prophylactic inhibition of the binding and the chemoattraction with lactose and the synthetic elastin peptide, Val-Gly-Val-Ala-Pro-Gly. We assume that the galactose-binding lectin, which is a component of the elastin peptide receptor complex, would recognize a Gal residue of the sulfated fucogalactan. We also observed a similar chemoattracting polysaccharide in a pathogenic fungus, Candida albicans, although the content of it was much lower than in the case of seaweed sporophyll. We speculate that the chemotactic response of monocytes to the sulfated fucogalactan is part of the innate immune system to fungal infection.

Differential role of neutrophils and monocytes during subcutaneous plasma extravasation.

We examined the behavior of polymorphonuclear leukocytes (PMNs) and monocytes during subcutaneous plasma extravasation in guinea-pigs. Plasma extravasation was induced by intradermal injection of zymosan-activated plasma (ZAP). The degree of extravasation correlated logarithmically with the concentration of injected ZAP, and was composed of PMN-dependent and -independent components. The latter was mediated primarily by histamine. The former accounted for 40-50% of the total plasma extravasation, peaked within 15 min, and then rectilinearly decreased with a half-life between 30 and 40 min. Histological examination of skin at 15 min after ZAP injection demonstrated PMN attachment to the luminal surface of venule endothelial cells, without evidence of PMN extravasation. We next examined whether monocyte infiltration of subcutaneous tissue played a causal role in plasma extravasation. Monocyte-predominant infiltration was initially caused by an intradermal injection of a monocyte-specific chemotactic factor, the S19 ribosomal protein (RP S19) dimer. Monocyte infiltration did not induce plasma extravasation even in guinea-pigs with elevated peripheral blood monocyte levels following administration of a macrophage-colony stimulating factor. A simultaneous injection of prostaglandin E2, a vasodilating agent, with RP S19 dimer also did not induce plasma extravasation. In contrast, a simultaneous injection of RP S19 dimer with ZAP changed the leukocyte infiltration pattern from PMN-predominant to monocyte-predominant, and almost completely suppressed the PMN-dependent component of the ZAP-induced plasma extravasation. The lack of plasma extravasation in the monocyte-predominant pattern was reproduced when a strong monocyte infiltration was induced by an intradermal injection of apoptotic cells. We conclude that leukocyte-induced plasma extravasation is specific for PMN, and is not due to a physical leakage of plasma during leukocyte emigration. Rather, plasma extravasation is probably caused by a cognate interaction between PMNs and postcapillary venule endothelial cells.

Bacterial chaperone protein, Skp, induces leukocyte chemotaxis via C5a receptor.

C5a receptor has been identified as a leukocyte chemotactic receptor to two intrinsic chemical mediators, C5a and the S19 ribosomal protein dimer, so far. We found an Escherichia coli protein that also induced the chemotactic responses of monocytes and polymorphonuclear leukocytes via the C5a receptor. We identified the E. coli-derived chemoattractant to be Skp by the molecular size and the N-terminal amino acid sequence. Skp is a periplasmic chaperone protein widely present in gram-negative bacterial species. Immunoabsorption experiments indicated that Skp was the major leukocyte chemotactic factor in the E. coli extract. Receptor-antagonizing experiments with analogue peptides of S19 ribosomal protein and of C5a suggested that Skp induced the receptor activation by the two-step binding mechanism as in the cases of the intrinsic mediators, sharing the ligand-binding site of the receptor among them at each binding step. The C5a receptor would play a role in the host defense directly recognizing the bacteria-derived protein, besides identifying the signals of the intrinsic chemical mediators.