UMLS:C0024141 - FACTA Search

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Query: UMLS:C0024141 (systemic lupus erythematosus)
44,322 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The allotypic forms of the C3b/C4b receptor (CR1, CD35) differ in length, in the number of expressed C3b binding sites and thus in their ability to mediate the processing of circulating C3- and C4-bearing immune complexes. We have used a combination of three informative restriction fragment length polymorphisms (RFLPs) to assess the frequencies of the F (most frequent allele comprised of four long homologous repeats (LHR)), S (five LHR) and F' (three LHR) alleles of the C3b/C4b receptor (CR1, CD35) in a French population of patients with systemic lupus erythematosus (SLE) (n = 63) and healthy controls (n = 158). A significantly higher frequency of the S phenotype was observed among patients (51%) as compared with controls (26%). The F' allele was found in 2/61 patients and 1/85 healthy controls, indicating the rare occurrence of the short CR1 allele in SLE. This allele is also extremely rare in the normal population. The overrepresentation of the S long allele among patients is indicative of a genetic linkage between CR1 and susceptibility to SLE.
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PMID:Increased frequency of the long (S) allotype of CR1 (the C3b/C4b receptor, CD35) in patients with systemic lupus erythematosus. 135 46

Previous studies of erythrocyte CR1 levels in systemic lupus erythematosus (SLE) and other diseases with in vivo complement activation have led to the conclusion that CR1 levels fall because of loss of CR1 from erythrocytes by proteolysis--predominantly in the liver. In order to measure the existence of proteolysed CR1 remnants on erythrocytes an antibody was raised to a peptide corresponding to the CR1 sequence between the proximal standard consensus repeat (SCR) and the transmembrane segment. This antipeptide antibody recognizes a neo-antigen found on trypsinized erythrocytes which has been demonstrated to represent the 'CR1-stump'. The anti-'CR1-stump' antiserum detects proteolysed CR1 on the ex vivo erythrocytes of a patient with cold haemolytic antibody disease (CHAD). However, higher affinity antibodies will be needed to make anti-CR1-stump a satisfactory diagnostic reagent.
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PMID:An anti-peptide antibody that recognizes a neo-antigen in the CR1 stump remaining on erythrocytes after proteolysis. 137 Jul 72

The present study investigated the rate of catabolism of CR1 (the C3b receptor, CD35) on erythrocytes (E) in vivo, in relationship with the expressed number of CR1/E, the CR1.1 HindIII quantitative CR1 polymorphism, and cell age. The relationship between the number of CR1/E and cell age was analysed by measuring G6PDH activity in E that had been sorted according to high or low expression of CR1 (CD35), by assessing the expression of CR1 (CD35) on E separated according to cell density, and by comparing the number of CR1 (CD35) antigenic sites on reticulocytes and on E. A physiological catabolism of CR1 (CD35) manifested by a reduction in the number of CR1 (CD35) antigenic sites/E with cell ageing was consistently observed in healthy individuals. The number of CR1/E decreased with ageing of E according to a complex pattern that associated an exponential decay and an offset. Calculated half-lives of CR1 (CD35) ranged between 11 and 32 days in healthy individuals. A more rapid loss of CR1 (CD35) with cell ageing occurred on cells from individuals expressing high numbers of CR1/E. In patients with systemic lupus erythematosus (SLE), half-lives of CR1 (CD35) on E were in the same range as those of healthy individuals with a similar quantitative CR1 genotype; the number of CR1 (CD35) on reticulocytes was reduced and linearly related to the number of CR1/E, independently of the patients' quantitative CR1 genotype. Transfusion experiments with E bearing high or low amounts of CR1/E indicated the lack of preferential removal of E bearing high numbers of CR1 (CD35) in patients with SLE. These results indicate that the rate of loss of CR1 (CD35) from E with cell ageing is directly related to the quantitative CR1 phenotype and suggest that enhanced peripheral catabolism is not the sole mechanism of the acquired loss of CR1 (CD35) on E in patients with SLE.
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PMID:Peripheral catabolism of CR1 (the C3b receptor, CD35) on erythrocytes from healthy individuals and patients with systemic lupus erythematosus (SLE). 153 48

Erythrocyte complement receptors (CR) are unique to primates and play a role in the clearance of immune complexes from the circulation. Immune complex-mediated diseases (e.g., systemic lupus erythematosus, SLE) cause decreased erythrocyte CR levels, resulting in decreased capacity of the erythrocytes to bind immune complexes that form in the circulation. Thus, raising erythrocyte CR levels might benefit patients with immune complex-mediated diseases. Because young erythrocytes express more CR than old erythrocytes, increasing erythropoiesis should increase the average number of CR expressed per erythrocyte. The present study was undertaken to test that hypothesis. Erythropoiesis was stimulated in nine cynomolgus monkeys (CYN) by weekly phlebotomy (30% of blood volume was removed, erythrocytes were discarded, and leukocytes were returned to the animal) for 8 weeks. Sham phlebotomy (30% of blood removed, then all components returned to the animal) was carried out weekly in four additional CYN for a period of 4 to 8 weeks. Sham phlebotomy did not change any of the parameters measured. However, phlebotomy resulted in a progressive increase in the mean number of CR expressed per erythrocyte (CR/erythrocyte): 2780 +/- 700 to 4230 +/- 820, P less than 0.0005. The increase in erythrocyte CR was first detected at about 2 weeks after the start of phlebotomy and was sustained through the course of phlebotomy. The increase in CR/erythrocyte included an increase in the percentage of erythrocyte expressing CR in clusters (37.9 +/- 6.4 vs 50.8 +/- 8.7%, P less than 0.01) as demonstrated by a flow cytometry study of the binding of fluorescent beads coated with anti-CR1 antibody. No significant change in leukocyte or platelet counts were observed. We conclude that stimulating erythropoiesis causes an increase in CR/erythrocyte. The magnitude of the increase suggests that it could be biologically significant.
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PMID:Stimulating erythropoiesis increases complement receptor expression on primate erythrocytes. 154 Oct 55

Sixty six patients with systemic lupus erythematosus (SLE) were genotyped using a HindIII restriction fragment length polymorphism identified by CR1.1 cDNA, then were followed up for an average of 50 months to evaluate the stability of their CR1 activities. The gene frequencies for the two alleles which correlate with the numeric expression of CR1 on the erythrocytes were not significantly different between 66 patients with SLE and 52 normal controls. A discrepancy between homozygosity for a high allele and a negative CR1 activity was found in many patients. These patients, however, had significantly lower concentrations of serum complement than did patients with a positive CR1, and some were in an active state of the disease. Furthermore, there were several patients in whom the CR1 activities changed from negative to positive together with an increase in serum complement. Our results suggest that the decreased expression of CR1 on erythrocytes in patients with SLE is not inherited, rather it is a consequence of the disease processes.
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PMID:Distribution of the HindIII restriction fragment length polymorphism among patients with systemic lupus erythematosus with different concentrations of CR1. 168 10

A systematic study has been carried out to investigate the role of immunoglobulin isotype, epitope density, and antigen/antibody ratio on the capacity of immune complexes to activate the classical and alternative pathways of human complement and for the complexes subsequently to bind to erythrocyte C3b-C4b receptors (CRI). For this purpose, a series of chimaeric monoclonal anti-NIP antibodies was used, which all shared the same combining site but had different human constant domains. Antigen epitope density was varied by coupling different numbers of NIP hapten molecules to bovine serum albumin. All three parameters affect complement fixation. In general, complement activation is better in antibody excess and at equivalence than it is in antigen excess, and better at high epitope density than at low epitope density, although the effects are variable for different immunoglobulin isotypes and for the two pathways. It has been confirmed that IgG1 and IgG3 are good activators of the classical pathway and are tolerant to variations in both epitope density and antigen/antibody ratio. IgG4 and IgA do not activate the classical pathway in any circumstances. IgG2 activates the classical pathway only at high epitope density and at equivalence or antibody excess. IgM activates the classical pathway well only at the higher epitope densities and at equivalence or antibody excess but, in addition, shows an interesting and unexpected prozone phenomenon where immune complex in antibody excess inhibits complement activation by the classical pathway. The results of the alternative pathway activation are strikingly different. IgA is by far the best activator of the alternative pathway and is relatively tolerant to epitope density and to antigen/antibody ratio. IgM, IgG1 and IgG3 do not significantly activate the alternative pathway in any circumstances. IgG2 is the best IgG subclass for alternative pathway activation but requires high epitope density and equivalence or antibody excess. Binding to CR1 in general parallels the amount of complement fixed independent to the pathway by which it is fixed. However, IgG1 and IgG3 complexes in antigen excess activate complement well but bind poorly to CR1. Nascently formed complexes seem to bind complement in a way that is similar to that bound by preformed complexes, but are then less able to bind to red cell CR1. These observations help to explain the pathogenesis of complement activation in various autoimmune and immune complex diseases such as systemic lupus erythematosus, autoimmune thyroiditis and others.
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PMID:The effect of antibody isotype and antigenic epitope density on the complement-fixing activity of immune complexes: a systematic study using chimaeric anti-NIP antibodies with human Fc regions. 170 67

C3b-coated immune complexes adhere to the complement receptor 1 (CR1, CD35) on human erythrocytes. This multi-valent binding might be favoured by the known clustering of CR1 and by the multiple C3b-binding sites on each CR1. The size of the CR1 clusters correlates directly with the number of CR1/erythrocytes, and the different structural CR1 alleles bear between two and five C3b-binding sites. Using radiolabelled hepatitis B surface antigen-antibody complexes, we investigated whether CR1 numbers and structural alleles modulate the ability of erythrocytes to bind immune complexes, and assessed if any reorganization of immune complexes takes place at the erythrocyte surface after the initial binding reaction. The binding efficiency (immune complexes/CR1) correlated with CR1 number as determined by the maximal binding at 4 degrees C, the kinetics of binding at 37 degrees C, and the binding in the presence of excess immune complexes and of immune complexes of small size. Binding efficiencies were similar for erythrocytes with low CR1 from normal subjects and patients with AIDS or SLE. A monoclonal antibody blocking the C3b-binding sites (3D9) of CR1 interfered with binding efficiency at a lower concentration on cells bearing low CR1 numbers, suggesting that CR1 clustering is essential. The larger alleles of CR1 (DD and BB) were more efficient than AA alleles. The distribution of immune complexes, visualized by immunofluorescence, was heterogeneous on erythrocytes: about two out of three cells bore between one and 12 immune complexes. No visible immune complex reorganization took place after initial binding, as prefixed erythrocytes displayed the same immune complex distribution and number/erythrocytes as unfixed erythrocytes. The contribution of CR1 alleles in immune complex binding efficiency was confirmed by morphological analysis. These results demonstrate that immune adherence efficiency is the resultant of the CR1 clustering, as well as the particular alleles carried by erythrocytes. Moreover, there is little or no immune complexes surface reorganization after the initial binding reaction.
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PMID:Immune complex binding efficiency of erythrocyte complement receptor 1 (CR1). 182 50

Our aim was to assess whether the amount of complement C3b/C4b receptors (CR1) on erythrocytes shows a correlation to disease activity in various connective tissue diseases such as systemic lupus erythematosus (SLE), rheumatoid arthritis (RA) and essential mixed cryoglobulinemia (EMC). Using an anti-CR1 monoclonal antibody, 26 patients with SLE, 34 with RA and 22 patients with EMC were investigated for erythrocyte CR1 expression. The control group consisted of 30 healthy individuals. The mean number of CR1/erythrocyte in the control group was 568 +/- 197 (range 174-1060), significantly higher than studied (EMC:379 +/- 248; p = 0.0005;SLE 147 +/- 56, p less than 0.0001; RA 298 +/- 177, p less than 0.0001). In patients with RA and in SLE, but not in patients with EMC, the number of CR1 numbers and anticardiolipin antibody (aCl) titers (r2 = 0.493; p = 0.034). A statistically significant correlation between CR1 numbers and CH50 values was found in patients with SLE, while in 3 patients with RA 4 months of therapy with cyclosporine A led to a further 30% reduction in CR1 number. Our conclusions are that (a) the decreased expression of erythrocyte CR1 is apparently a common feature of patients with various connective tissue diseases; (b) several acquired factors such as disease activity, complement activation, aCl and drugs may contribute to the loss of CR1 from erythrocytes; (c) in patients with RA and SLE, but not in patients with EMC, CR1 enumeration on erythrocytes may serve as a variable for clinical monitoring.
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PMID:Low number of complement C3b/C4b receptors (CR1) on erythrocytes from patients with essential mixed cryoglobulinemia, systemic lupus erythematosus and rheumatoid arthritis: relationship with disease activity, anticardiolipin antibodies, complement activation and therapy. 183 42

The role of classical pathway complement components in systemic lupus erythematosus (SLE) is reviewed. Their importance in maintaining immune complexes (IC) in soluble form and in enhancing clearance of IC through binding to red cell CR1 is such that deficiency, complete or partial, of these components or some of their controlling enzymes can lead to IC mediated disease like SLE. C2 and C4 are encoded within the class III region of the major histocompatibility complex (MHC). There are certain well described associations between class II MHC genes and the occurrence of SLE and the relative importance of the two sets of gene products and their potential interactions are discussed. Complement C4 plays a role in drug induced lupus as many of the lupus associated drugs bind to C4 and interfere with its protective functions. Classical genetic studies provide clear evidence that non MHC genes are important in the aetiopathogenesis of SLE. Non MHC encoded complement deficiencies and functional deficits may well represent some of these other genetic factors and is clearly a fertile area for future research.
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PMID:The role of complement in the aetiopathogenesis of systemic lupus erythematosus. 183 81

There are two isotypes of C4--C4A and C4B--, encoded within the major histocompatibility complex with quite different properties. In this study we have compared purified C4A and C4B with regard to their ability to prevent immune complex precipitation and to enhance the binding of both preformed and nascent immune complexes to the receptor CR1 on red cells. C4A was modestly more effective than C4B at inhibiting immunoprecipitation, particularly in antibody excess. In the CR1 binding assay C4A was markedly more effective than C4B in enhancing binding to CR1. This difference was seen with both preformed and nascent immune complexes at equivalence and antibody excess. Thus the major differences between C4A and C4B in regard to immune complex handling is at the level of CR1 binding. Given the strong association of C4A* QO alleles with immune complex-mediated diseases like systemic lupus erythematosus, these findings have important pathogenetic implications.
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PMID:Differences between C4A and C4B in the handling of immune complexes: the enhancement of CR1 binding is more important than the inhibition of immunoprecipitation. 213 67

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