Chromatin clearance in C57Bl/10 mice: interaction with heparan sulphate proteoglycans and receptors on Kupffer cells.

Chromatin is an important autoantigen in the pathogenesis of systemic lupus erythematosus (SLE) as an immunogen and as a part of nephritogenic immune complexes. Earlier studies focused on clearance of DNA. However, DNA released into the circulation from dying cells is found associated with histones in nucleosomes. The liver is the major organ involved in clearance of chromatin from the circulation of mice. Heparan sulphate proteoglycans (HSPG) have been implicated in the clearance of various charged molecules. Receptor-mediated clearance of ssDNA by the liver has also been reported. Because chromatin contains positively charged histones in addition to DNA, we wished to determine if HSPG and/or DNA receptors are involved in chromatin clearance. The rate of clearance of H1-stripped chromatin from the bloodstream of C57Bl/10 mice was markedly decreased by prior treatment of mice with Heparinase I. Clearance was also inhibited by heparin, heparan sulphate, and DNA, but not by colominic acid. DNA was the most effective inhibitor of clearance and released chromatin from sites of clearance. Depletion of Kupffer cells and splenic macrophages using liposome-encapsulated Clodronate (dichloromethylene bisphosphonate) markedly inhibited chromatin clearance. These data suggest that chromatin clearance is mediated by charge interactions with cell surface HSPG and by DNA receptors. Clearance and degradation of chromatin require functional macrophages in the liver and spleen.

The effect of acute phase proteins on clearance of chromatin from the circulation of normal mice.

The clearance of nucleosome core particles and H1-stripped chromatin from the circulation of mice was examined. Radiolabeled chromatin preparations were injected into mice, and blood samples were obtained over 60 min. The animals were then killed, and the selected organs were collected and radioactivity was measured. The acute phase response (APR) was induced by i.p. injections of casein before some clearance studies. Serum amyloid P component, the major acute phase protein in mice, increased from 27 microg/ml to 339 microg/ml during the acute phase. The rate of chromatin clearance decreased during the acute phase in C57BL/10J mice. At 5 min, 18% +/- 3% of the originally measured radioactivity remained in control animals compared with 49% +/- 2% in acute phase animals (p < 0.001). Co-injection of either serum amyloid P component or C-reactive protein, the major acute phase protein in humans, caused a decrease in the rate of chromatin clearance similar to that observed following the induction of the APR. APR induction also caused a higher percentage of the chromatin to localize in the liver compared with the spleen, with the ratio changing from 10.2 +/- 0.7 to 16.1 +/- 1.9 (p < 0.004). In addition, the APR caused a decrease in the percentage of chromatin localized in the kidney. The lack of radioactivity associated with cells in the circulation indicates that complement is not a major factor in the clearance mechanism of chromatin. These findings suggest that the APR produces major changes in the rate and path of chromatin clearance. These changes may protect against deposition of chromatin in target organs of systemic lupus erythematosus.

Expression and radiolabeling of human C-reactive protein in baculovirus-infected cell lines and Trichoplusia ni larvae.

Human C-reactive protein (CRP) is a member of the pentraxin family of proteins which are molecules composed of five identical subunits arranged in a planar configuration. In the present study a human CRP cDNA clone was ligated into the baculovirus vector pVL1393 which was used to establish a recombinant strain of BaculoGold Autographa californica multiple nuclear polyhedrosis virus containing the coding and leader sequence for human CRP (designated AcMNPV-CRP). Synthesis and secretion of CRP were studied after infection of TN5B1-4 and Sf-9 cells with AcMNPV-CRP. Accumulation of CRP but not other proteins in the medium over the course of infection suggested that CRP was actively secreted. Analysis by gel filtration chromatography and by SDS-PAGE demonstrated an intact pentamer composed of subunits of the appropriate molecular mobility. The structural integrity of the recombinant protein was further established by the ability of the product to bind to phosphocholine in a calcium-dependent manner, a property which is restricted to the intact pentamer. Functional studies of complement activation, binding to mononuclear phagocytic cells, and reactivity with a panel of monoclonal antibodies were also consistent with structural and functional integrity of the recombinant molecule. Infection of Trichoplusia ni larvae with AcMNPV-CRP also resulted in the production of functional recombinant protein. This method has the advantage of producing larger amounts of protein at lower cost than tissue culture. An additional advantage is the ability to metabolically label CRP through feeding the larvae on an [35S]methionine-containing diet.(ABSTRACT TRUNCATED AT 250 WORDS)

C-reactive protein binds to Fc gamma RI in transfected COS cells.

C-Reactive protein (CRP) is an acute phase serum protein in man that binds to certain bacterial polysaccharides and to components exposed on damaged cells. CRP is bound by receptors on phagocytic cells and functions as an opsonin for its ligands. Interactions of CRP with a specific CRP receptor (CRP-R) and with the high affinity receptor for IgG, Fc gamma RI, on monocytic cells have previously been demonstrated. It was not possible to fully characterize CRP binding to Fc gamma RI in these studies, since cells and cell lines expressing Fc gamma RI also have the CRP-R. In the present study we examined the interaction of CRP with Fc gamma RI in COS-7 cells transfected with a cDNA encoding this receptor. Expression of Fc gamma RI and specific CRP binding to transfected cells were demonstrated by flow cytometry. By two-color analysis, the cell population binding CRP was the same as the population that bound the Fc gamma RI-specific mAb 10.1 and 32.2 CRP inhibited the binding of radiolabeled IgG1 and IgG4 by up to 60%. A CRP molecule that was mutated in the amino acid sequence homologous to the IgG sequence proposed to interact with Fc gamma RI failed to bind to transfected cells, but retained the ability to bind to the CRP-R on monocytic cells. These studies confirm the binding of CRP to Fc gamma RI and identify a site on CRP that is essential for this binding.