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Query: UMLS:C0024141 (
systemic lupus erythematosus
)
44,322
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In a multicenter study more than 300 central European
systemic lupus erythematosus
(
SLE
) patients were examined for HLA-B, HLA-DR, and complement C4 phenotypes. For 174
SLE
patients MHC haplotypes were determined by family segregation analysis, and for 155 patients C4 gene deletions were determined by TaqI restriction fragment length polymorphism. Two haplotypes, B8-C4AQ0-C4B1-DR3 and B7-
C4A3
-C4B1-DR2, were identified as risk factors for
SLE
. These findings were confirmed by applying the haplotype frequency difference (HFD) method, which uses nontransmitted haplotypes from the family study as internal controls. Furthermore, only HLA-DR2, but not DR3, B7, or B8, was significantly increased in
SLE
patients independently of the two risk haplotypes. C4A gene deletions, but not silent C4AQ0 alleles, were increased in
SLE
patients and neither C4BQ0 alleles nor C4B gene deletions were increased. The observed frequencies of homozygosity and heterozygosity for the two haplotypes and the frequencies of homozygotes for C4AQ0 and C4A deletions did not differ from the expected values, indicating that the risk for
SLE
is conveyed by single allele effects. In conclusion, there are two MHC-linked susceptibility factors for Caucasian
SLE
patients carried by the haplotypes B7-DR2 and B8-DR3. The results argue against C4Q0 alleles being the decisive factors increasing susceptibility to
SLE
.
...
PMID:Major histocompatibility complex haplotypes and complement C4 alleles in systemic lupus erythematosus. Results of a multicenter study. 140 Oct 69
In 1982 we reported that among Caucasians with
systemic lupus erythematosus
(
SLE
) there is an increased frequency of C4A null. As this allele occurs on the HLA-A1,B8,BfS, C4AQO,B1,DR3 (8.1) supratype, we suggested this accounted for the reported association of B8 and DR3. Since then we have shown that many supratypes including 8.1 identify unique segments of DNA conserved from a common but remote ancestor. Many of these ancestral haplotypes (AH), including 8.1, carry disease genes and some bear C4 null. We have therefore tested the hypothesis that in
SLE
C4 null alleles are directly involved by examining (1) whether all or only some AH bearing C4 null alleles are increased, (2) whether C4 null is increased in all racial groups examined, and (3) whether C4 null is associated with the presence of antinuclear antibodies (ANA) in the absence of
SLE
. We performed HLA and complement allotyping on 62 Australian Caucasians and 9 Australian aborigines with
SLE
and on the 10 out of 133 healthy individuals with 7 or more international units of ANA. Our data confirm an association of C4A null in Australian Caucasians (gene frequency 0.30 versus 0.15 in controls) and show an increased frequency of C4B null in Australian aborigines (gene frequency 0.33 versus 0.22). A review of an extensive literature shows C4A and/or C4B null are increased in all racial groups examined. On the other hand, the HLA-A3,B7,BfS,
C4A3
,B1,DR2 (7.1) AH rather than C4 null is associated with ANA in health. Our data indicate that while C4 nulls contribute to MHC susceptibility, other genes are likely to be involved.
...
PMID:Major histocompatibility complex (MHC) complement deficiency, ancestral haplotypes and systemic lupus erythematosus (SLE): C4 deficiency explains some but not all of the influence of the MHC. 175 37
The metabolism of the C4 allotypes
C4A3
,B1 and
C4A3
,BO was studied in five healthy control subjects and six patients with active immunological disease (five with
systemic lupus erythematosus
and one with rheumatoid arthritis). The specific aim was to identify any differences in the metabolism of C4A and C4B gene products that may be linked to their documented functional differences in vitro. The fractional catabolic rate of
C4A3
,B1 in patients was significantly greater than that of
C4A3
,BO (3.98 +/- 1.37 versus 3.31 +/- 0.85%/h; mean +/- s.d.; P less than 0.05) but there was no difference in control subjects (1.95 versus 1.99%/h). The extravascular:intravascular (EV:IV) distribution ratio of
C4A3
,B1 was also greater in both patients (1.19 +/- 0.36 versus 0.97 +/- 0.35; P less than 0.01) and controls (0.43 +/- 0.11 versus 0.31 +/- 0.13; P = 0.01). We conclude that C4B1 was catabolized more rapidly than
C4A3
in patients with pathological complement activation but not in control subjects. This difference could reflect the relatively greater extravascular distribution (i.e. EV:IV ratio) of C4B at sites of immune complex deposition or, alternatively, different rates of catabolism of inactive C4 isotypes (iC4b).
...
PMID:Differences in the metabolism of C4 isotypes in patients with complement activation. 253 15
The inhibition of immune precipitation is mediated by the classical complement pathway. We report here that the rate of precipitate formation depends on the genetic form of human C4 present during immune precipitation.
C4A3
is more effective than C4B1 in its capacity to inhibit the rate of immune precipitate formation in serum and in serum-free reaction mixtures containing C1 and C4. Immune precipitates form within seconds after antigen is mixed with antibody, and the activation of the classical pathway is known to occur within seconds after C1 binds to antibody molecules. The covalent deposition of C4b on immune complexes is an essential step in the inhibition of immune precipitate formation, and if any of the reactions that lead to covalent C4b deposition become limiting, the rate of immune precipitation could exceed the complement system's inhibitory capacity. Hence, the inhibition of this rate may be an important function underlying the complement-mediated processing of immune complexes, and a decreased ability of the complement system to mediate this process in the presence of C4B1, in contrast to
C4A3
, could explain, at least in part, the association between the C4A-null phenotype and autoimmune diseases such as
systemic lupus erythematosus
.
...
PMID:C4-mediated inhibition of immune precipitation and differences in inhibitory action of genetic variants, C4A3 and C4B1. 318 Jul 39
The finding of dramatically depressed levels of C4 in a 17-year old patient with severe
systemic lupus erythematosus
(
SLE
) prompted a genetic study of her family. This study revealed the existence of a partial C4 deficiency; we found the presence of a
C4A3
,C4BQo haplotype which was transmitted by the mother to each of her children. This patient possessed, in her serum, an autoantibody with anti-C4 specificity. The immunochemical characterization of this autoantibody revealed that it was IgM and belonged to the immunoconglutinin family. We have studied the effects of this autoantibody on the formation and dissociation kinetics of classical C3-convertase.
...
PMID:Partial deficiency of the fourth component of human complement (C4) and autoantibody directed against C4 in a patient with SLE. 655 49
Complement component C4 is an important protein of the classical, or antibody-mediated pathway of complement activation. Human C4 is located within the central region of the major histocompatibility complex on chromosome 6. Partial C4 deficiency has been associated with an increased susceptibility to immune complex disease. The strongest association with partial C4 deficiency is with
systemic lupus erythematosus
(
SLE
) and has been shown in most racial groups studied. Interestingly, Caucasian population studies have demonstrated an increased prevalence of C4A null alleles in
SLE
patients, in particular in association with the haplotype HLA-A1, B8, BfS, C4AQ0, C4B1, DR3. To investigate whether the C4 gene on this haplotype had any structural irregularities which may explain disease association, we sequenced the entire C4B gene from this haplotype. The results revealed that the gene encoded on the disease-associated haplotype carried major structural differences (when compared to
C4A3
) at the exonic level only in the C4d region. A high degree of conservation in both the 5' and 3' untranslated regions imply that disease associations will not be due to differential C4 expression as a result of regulatory differences between C4 genes. It appears likely that protein clearance mechanisms may account for the altered levels of C4 seen between different isotypes.
...
PMID:Comparative analysis of the disease-associated complement C4 gene from the HLA-A1, B8, DR3 haplotype. 885 88
