Fluorometric and mass spectrometric analysis of nonenzymatic glycosylated albumin.

Albumin is the major transport protein in blood and intramolecular movement contributes to this function. Nonenzymatic glycosylation (NEG) of albumin occurs in diabetes and, in this study, fluorometric methods were used to determine the effect of increasing levels of NEG upon intramolecular movement in human serum albumin. Low levels of NEG significantly reduced and left-shifted Trp fluorescence, reduced quenching by acrylamide and inhibited penetration of bis-ANS, while these changes became only modestly more pronounced at higher levels of NEG. Mass spectrometry of tryptic and CNBr NEG-HSA fragments identified potential glycosylation sites and demonstrated only late glycosylation of the C- and N-terminal regions of the protein. Similar changes in diabetes may contribute to altered transport function in these patients.

pH-dependent changes in the in vitro ligand-binding properties and structure of human clusterin.

Clusterin is a glycoprotein which is locally overexpressed at sites of tissue damage or stress, leading to the proposal that it may be a cytoprotective protein. It has been shown that clusterin has chaperone-like activity, being able to protect proteins against precipitation under stress conditions. It has also been shown that local acidosis is common at sites of tissue damage or stress. We asked whether acidic pH induces structural changes in clusterin and enhances its ability to bind to other proteins. We found by affinity chromatography and ELISA that the binding of clusterin to glutathione-S-transferase, IgG, apolipoprotein A-I, and complement protein C9 was enhanced at mildly acidic compared to physiological pH. Analytical ultracentrifugation and gel filtration studies revealed that clusterin exists in different polymerization states with monomer occurring preferentially at pH 5.5 and multimeric species at pH 7.5. Although circular dichroism showed little difference in the alpha-helical and beta-sheet contents of clusterin at pH 5 compared to pH 7.5, evidence for pH-dependent structural changes in clusterin was obtained from fluorescence experiments. pH titrations showed reversible changes in the fluorescence of tryptophan residues in clusterin. There was a reversible 2-fold increase in the fluorescence of the extrinsic probe 4, 4'-bis(1-anilinonaphthalene-8-sulfonate) bound to clusterin at pH 5. 5 compared to pH 7.5. There was also a 3.5-fold increase in fluorescence resonance energy transfer from tryptophan residues in clusterin to 4,4'-bis(1-anilinonaphthalene-8-sulfonate) at pH 5.5 compared to pH 7.5. These data suggest that pH-induced changes in the structure of clusterin are responsible for its enhanced ability to bind protein ligands at mildly acidic pH.

A reexamination of the role of clusterin as a complement regulator.

Clusterin is a highly conserved glycoprotein which has been proposed to protect host cells against complement-mediated cytolysis. We tested the hypothesis that clusterin is a complement regulator using erythrocytes and cells which had been stably transfected with a membrane-anchored form of clusterin as targets for complement-mediated cytolysis. Clusterin gave dose-dependent protection of antibody-coated sheep erythrocytes against complement-mediated lysis by diluted normal human serum. There was a linear relationship between the concentration of clusterin giving 50% protection and the concentration of serum; extrapolation of this to the case of undiluted human serum showed that a clusterin concentration at least two orders of magnitude greater than its physiological plasma concentration would be needed to confer protection against complement-mediated cytolysis under physiological conditions. Physiological concentrations of clusterin did not protect rabbit erythrocytes against alternative complement pathway-mediated lysis using dilute human serum. Exogenous clusterin had no effect on lysis of human erythrocytes triggered by the addition of inulin to autologous human serum. Induction of cell-surface clusterin expression by L929 (murine fibroblast) cells which had been stably transfected with cDNA for human clusterin linked to DNA coding for the 44 C-terminal amino acid residues of CD55 did not protect the cells against complement-mediated lysis by either normal or clusterin-depleted human serum. These data suggest that clusterin may not be a physiologically relevant regulator of complement activation.

Apolipoprotein J (clusterin) induces cholesterol export from macrophage-foam cells: a potential anti-atherogenic function?

Apolipoprotein J (apo J) is a secreted glycoprotein of which the exact function remains a matter for speculation. Apo J has been implicated in such diverse processes as sperm maturation, regulation of complement activation, programmed cell death, tissue remodelling and lipid transport. In this study a possible role for apo J in lipid transport was explored. Mouse peritoneal macrophages were incubated with acetylated low-density lipoprotein (AcLDL) to produce foam cells containing cholesterol and cholesteryl esters. Incubation of the foam cells with physiological concentrations of purified apo J led to a dose-dependent export of cholesterol. The appearance of cholesterol in the medium was associated predominantly with a decline in intracellular cholesteryl esters rather than intracellular free cholesterol. The kinetics of cholesterol release to apo J were similar to apo A-I, an established promoter of cholesterol efflux. Apo J was also shown to induce phospholipid efflux from cells, whereas the cholesterol exported to the medium was associated with the apo J. Studies using foam cells from apo E-null mice showed that the cholesterol exported to the medium was independent of apo E production by the cells. These results present the first evidence that apo J can promote cholesterol efflux from foam cells and indicates that it might have a function in cellular cholesterol homoeostasis in both normal and pathological situations.

Effects of clusterin overexpression on TNFalpha- and TGFbeta-mediated death of L929 cells.

Clusterin is a widely distributed and highly conserved protein for which many functions have been proposed. We used transfected L929 cells to study the effect of clusterin expression on the regulation of cell death signals. We showed that high levels of clusterin expression, about 0.2 pg clusterin secreted per cell per 48 h period, specifically protected L929 cells from TNFalpha-mediated cytotoxicity, while low expression (about 4 fg/cell/48 h) had no effect. However, clusterin expression did not provide transfected L929 cells with protection against death mediated by colchicine, staurosporine or azide. High level expression of clusterin in transfected L929 cells also potentiated the cytotoxicity of TGFbeta. It had previously been shown that exposure of L929 cells to TGFbeta provides protection against TNFalpha. We showed that this protective effect is not additive to that of clusterin expression. One interpretation of this data is that it suggests that clusterin and TGFbeta may act via a common mechanism to provide protection against the cytotoxicity of TNFalpha. Our results indicate that an intracellular action of clusterin protein is responsible for protection against TNFalpha cytotoxicity. Exposure to TNFalpha induces an increase in the level of cell-associated clusterin and specifically in the level of a novel clusterin molecule, which when analyzed under reducing conditions by SDS/PAGE and immunoblotting appears as two closely spaced bands at about 36 and 38.5 kDa. When analyzed under the same conditions, the normal form of intracellular clusterin, which is present with or without exposure to TNFalpha, appears as two poorly resolved bands at about 43-45 kDa. Since the novel form of clusterin is also expressed in cells exposed to TGFbeta, colchicine, staurosporine, and azide, it may result from toxin-induced disruption of processes of normal cellular protein production.

Alleles of highly homologous rat T cell receptor beta-chain variable segments 8.2 and 8.4: strain-specific expression, reactivity to superantigens, and binding of the mAb R78.

This study addresses the molecular basis of a Tcrb-V polymorphism in the reactivity to the superantigens staphylococcus enterotoxin B (SEB) and the mtv-7 sag (MIs1a) of T cells recognized by the mAb R78, which reacts with the T cell receptor beta-chain variable segment 8.2 (Tcrb-V8.2) of Lewis (LEW) rats. Tcrb-V8.2-like sequences were isolated from liver DNA of the responder strain LEW (I) and the nonresponder strain DA (a) and alleles of the Tcrb-V8.2 and the highly homologous Tcrb-V8.4 were identified. Their expression was analyzed by RNase protection studies and cDNA clones were characterized. A comparison of thymocytes, activated R78+ cells, Con A-stimulated and SEB-stimulated cells allows the following conclusions: the newly identified Lewis allele of Tcrb-V8.4 (Trcb-V8.4I) is nonfunctional due to a frame shift induced by deletion of one nucleotide. The R78 epitope is expressed by Tcrb-V8.2I and Tcrb-V8.4a but not by Tcrb-V8.2a. The implication of this finding for mapping of the R78 epitope and the study of V region usage in experimental autoimmune encephalitis are discussed. Finally, the expression of both Tcrb-V8.2 alleles but not of Tcrb-V8.4a in SEB-stimulated cells defines a polymorphism of the CDR2 and/or CDR4 as the molecular basis of the differential superantigen reactivity.

Control of the rat T cell response to retroviral and bacterial superantigens by class II MHC products and Tcrb-V8.2 alleles.

The in vitro response of unprimed rat T cells to retroviral and bacterial superantigens (SAg) was analyzed with TCR V beta 8.2-, 8.5-, 10-, and 16-specific mAbs. Specific stimulation of V beta 8.2 and 8.5 CD4 cells was observed in the response to Mls1a, the retroviral SAg encoded by integrated provirus Mtv-7 (Mtv-7 SAg), which was presented by mouse B cells or mouse fibroblasts transfected with DR1 genes and the Mtv-7 SAg. Additionally, a strong response of V beta 16 CD4 cells to an as yet unidentified mouse SAg was found. Only some of the bacterial SAg known to stimulate mouse and human T cells also activated rat lymph node cells. SEA, SEE, and TSST-1 stimulated rat T cells well; SEB, SEC1, and SED did not. This defect was apparently a result of weak binding to rat MHC class II molecules because presentation by human MHC class II molecules restored T cell activation. Under these conditions, SEB stimulated V beta 8.2+ and 8.5+ CD4 and CD8 cells from Lewis rats. A comparison of several rat strains revealed an unresponsiveness to SEB or Mtv-7 SAg for V beta 8.2 cells from F344 and DA rats. Determination of the nucleotide sequences of the Tcrb-V8.2 of these strains revealed differences between SAg-responsive and SAg-unresponsive Tcrb-V8.2 in seven amino acids, four of them located in the putative SAg contact site. The significance of these findings for the evolution of TCR-SAg interactions is discussed.