Molecular definition of the cellular receptor for the collagen domain of C1q has been elusive. We now report that C1q binds specifically to human CR1 (CD35), the leukocyte C3b/C4b receptor, and the receptor on erythrocytes for opsonized immune complexes. Biotinylated or radioiodinated C1q (*C1q) bound specifically to transfected K562 cells expressing cell surface CR1 and to immobilized recombinant soluble CR1 (rsCR1). *C1q binding to rsCR1 was completely inhibited by unlabeled C1q and the collagen domain of C1q and was partially inhibited by C3b dimers. Kinetic analysis in physiologic saline of the interaction of unlabeled C1q with immobilized rsCR1 using surface plasmon resonance yielded an apparent equilibrium dissociation constant (K[eq2]) of 3.9 nM. Thus, CR1 is a cellular C1q receptor that recognizes all three complement opsonins, namely, C1q, C3b, and C4b.
Previous studies have shown that human sperm that have undergone the acrosome reaction express a unique tissue-specific variant of the complement component 3 (C3)-binding molecule membrane cofactor protein (MCP, CD46) and that damaged or dead sperm activate the alternative pathway of complement and bind C3 catabolites. In this study we provide evidence that MCP on sperm that have undergone the acrosome reaction specifically binds dimeric C3b and that human sperm acrosomal proteases released during the acrosome reaction directly cleave C3, facilitating its binding to MCP. Furthermore, human and hamster oocytes can activate the alternative pathway of complement and also bind human C3 fragments. Monoclonal antibodies specific for complement receptors type 1 (CD35) and type 3 (CD11b/CD18) bind to the human oocyte plasma membrane, indicating that specific complement-binding molecules may play a role in the attachment of C3 catabolites to oocytes. Subsaturating concentrations of dimeric C3b (0.01-1 FM) promoted penetration of hamster oocytes by human sperm, whereas saturating doses (>10 FM) inhibited this process. In addition, antibodies to both MCP and C3 signiicantly inhibited penetration of hamster oocytes by human sperm. These data provide evidence that regulated gamete-induced generation of C3 fragments and the binding of these fragments by selectively expressed receptors on sperm and oocytes may be an initial step in gamete interaction, leading to membrane fusion and fertilization.Mammalian fertilization entails a complex series of events including (i) attachment of sperm to the zona pellucida of the oocyte via receptors on the sperm plasma membrane; (ii) the sperm acrosome reaction (AR), exocytosis of the acrosomal contents from the acrosome, a specialized granule containing proteases and other degradative enzymes; (iii) penetration of sperm through the zona pellucida, which occurs concurrently with the AR; (iv) attachment of sperm to the oocyte plasma membrane (oolema) via receptors exposed on the sperm surface after the AR; and (v) sperm-oocyte fusion. Receptors and ligands mediating these events are only now beginning to be identified and characterized (1).Recently, we and others have shown that human sperm that have undergone the AR express membrane cofactor protein (MCP, CD46), a complement component 3 (C3)-binding and regulatory protein, on the inner acrosomal membrane (2-4). Sperm MCP has cofactor activity for factor I-mediated cleavage of C3, and one of its apparent functions is protection of sperm from the lytic consequences of complement resulting from interactions with antisperm antibodies (5). However, sperm MCP is a tissue-specific isoform characterized by differential glycosylation (5) and deletions resulting in a shorter transmembrane region and distinctive cytoplasmic tail (6); this suggests that sperm MCP may haveThe publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. ...
Genomic research on target identification and validation has created a great need for methods that rapidly provide detailed structural information on protein-ligand interactions. We developed a suite of NMR experiments as rapid and efficient tools to provide descriptive structural information on protein-ligand complexes. The methods work with large proteins and in particular cases also without the need for a complete three-dimensional structure. We will show applications with two tetrameric enzymes of 120 and 170 kDa.
Leukotriene (LT) C4 synthase is an integral membrane protein that catalyzes the conjugation of LTA4 to reduced glutathione to form LTC4. LTC4 synthase has been cloned and characterized from transformed cell lines, but the protein has not been defined from a tissue source. LTC4 synthase was purified to homogeneity from human lung tissue, utilizing S-hexyl glutathione chromatography followed by LTC4 affinity chromatography. A greater than 100,000-fold purification with a yield of 8 to 25% (n = 4) was achieved. The purified LTC4 synthase migrated in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) as an 18-kD protein, and its 19 N-terminal amino acid sequence is identical to that of purified LTC4 synthase from KG-1 myeloid cells or from expression cloning of a KG-1 library in COS cells. Using a rabbit polyclonal IgG raised against purified LTC4 synthase, SDS-PAGE immunoblotting of LTC4 synthase from human lung tissue, eosinophils, KG-1 cells, and platelets showed an 18-kD protein. Immunofluorescence staining of alveolar macrophages in human lung sections with the anti-LTC4 synthase IgG revealed LTC4 synthase to be largely perinuclear in distribution. Thus, LTC4 synthase, the biosynthetic enzyme responsible for the formation of cysteinyl LTs, is present in lung tissue in a form apparently identical to that of hematopoietic cells.
Genomics-driven growth in the number of enzymes of unknown function has created a need for better strategies to characterize them. Since enzyme inhibitors have traditionally served this purpose, we present here an efficient systems-based inhibitor design strategy, enabled by bioinformatic and NMR structural developments. First, we parse the oxidoreductase gene family into structural subfamilies termed pharmacofamilies, which share pharmacophore features in their cofactor binding sites. Then we identify a ligand for this site and use NMR-based binding site mapping (NMR SOLVE) to determine where to extend a combinatorial library, such that diversity elements are directed into the adjacent substrate site. The cofactor mimic is reused in the library in a manner that parallels the reuse of cofactor domains in the oxidoreductase gene family. A library designed in this manner yielded specific inhibitors for multiple oxidoreductases.
SummaryMany of the autoantibodies in antiphospholipid syndrome (APS) are directed against β2-glycoprotein I (β2-GPI). Recent studies from our laboratories have indicated that the immunodominant binding epitope(s) for high titer, affinity purified antibodies from 11 APS patients are localized to the amino terminal domain (domain 1) of β2-GPI. The present study employed surface plasmon resonance to localize the immunodominant domain in serum samples from a large cohort of patients with GPL values ranging from 21 to 230 units (n = 106 patients). Eighty-eight percent of patients showed ≥ threefold selectivity for β2-GPI containing domain 1 relative to the domain deletion mutant that lacked domain 1. The domain 1 binding activity in patient serum was abolished by removing the IgG fraction from the serum and the binding activity could be fully reconstituted with the IgG fraction. Thus, analysis of serum samples from a large cohort of APS patients indicates that the immunodominant binding epitope(s) for anti- 2 antibodies are localized to the amino terminal domain of β2-GPI.
Leukotriene (LT) C4 synthase, the enzyme that catalyzes the conjugation ofLTA4 with reduced glutathione to form LTC4, was purified to homogeneity from the KG-1 myeloid cell line after solubilization of the microsomes utilizing a combination of 0.4% sodium deoxycholate and 0.4% Triton X-102. The solubilized enzyme was then applied to an S-hexylglutathione-agarose column that was eluted by the use of7.5 mM probenecid. After removal of the probenecid by sequential concentration and dilution in an Amicon concentrator, the enzyme was additionally purified and concentrated by binding to and elution from -75 mg ofS-hexyl-glutathione-agarose. The enzyme was further resolved by electrophoresis with a nondenaturing Tris-glycine gel, and the LTC4 synthase activity was localized to slices 3 and 4. When the remainder ofthe eluate from the nondenaturing gel was precipitated by acetone and analyzed by 14% SDS/PAGE with silver staining, a single protein band of 18 kDa was associated with LTC4 synthase activity and was not present in the eluates of slices lacking activity. The overall recovery was 12.5%. In a separate preliminary purification, in which the yield was only -1%, the eluates of the nondenaturing gel had also revealed a single protein of 18 kDa by SDS/PAGE, which was present only in the eluates with LTC4 synthase activity. These data identify LTC4 synthase as a protein of 18 kDa, a size consistent with its membership in the microsomal glutathione S-transferase family.
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