Shelesa A. Brew

Cryptic Self-association Sites in Type III Modules of Fibronectin

The first type III module of fibronectin (Fn) contains a cryptic site that binds Fn and its N-terminal 29 kDa fragment and is thought to be important for fibril formation (Morla, A., Zhang, Z., and Ruoslahti, E. (1994) Nature 367, 193-196; Hocking, D. C., Sottile, J., and McKeown-Longo, P. J. (1994) J. Biol. Chem. 269, 19183-19191). A synthetic 31-mer peptide (NAPQ … TIPG) derived from the middle of domain III1 was also shown to bind Fn, but the site of its interaction was not determined (Morla, A., and Ruoslahti, E. (1992) J. Cell Biol. 118, 421-429). By affinity chromatography on peptide-agarose, we tested a set of fragments representing the entire light chain of plasma Fn. Only 40-kDa Hep-2 (III12-15) failed to bind. The concentration of urea required for peak elution of Fn and the other fragments decreased in the order Fn > 42-kDa GBF (I6II1-2I7-9) > 19-kDa Fib-2 (I10-12) > 110-kDa CBF(III2-10) > 29-kDa Fib-1 (I1-I5). Neither Fn nor any of the fragments bound immobilized intact III1, confirming the cryptic nature of this activity. In an effort to detect interactions between other Fn domains, all fragments were coupled to Sepharose, and each fragment was tested on each affinity matrix before and after denaturation. The only interaction detected was that of fluid phase III1 with immobilized denatured 110-kDa CBF and 40-kDa Hep-2, both of which contain type III domains. Analysis of subfragments revealed this activity to be dominated by domains III7 and III15. Fn itself did not bind to the denatured fragments. Thus, domain III1 contains two cryptic “self-association sites,” one that is buried in the core of the fold but recognizes many Fn fragments when presented as a peptide and another that is concealed in Fn but exposed in the native isolated domain and recognizes cryptic sites in two other type III domains. These interactions between type III domains could play an important role in assembly of Fn multimers in the extracellular matrix.

Allosteric Modulation of Ligand Binding to Low Density Lipoprotein Receptor-related Protein by the Receptor-associated Protein Requires Critical Lysine Residues within Its Carboxyl-terminal Domain

The low density lipoprotein receptor-related protein (LRP) is a large endocytic receptor that recognizes more than 30 different ligands and plays important roles in protease and lipoprotein catabolism. Ligand binding to newly synthesized LRP is modulated by the receptor-associated protein (RAP), an endoplasmic reticulum-resident protein that functions as a molecular chaperone and prevents ligands from associating with LRP via an allosteric-type mechanism. RAP is a multidomain protein that contains two independent LRP binding sites, one located at the amino-terminal portion of the molecule and the other at the carboxyl-terminal portion of the molecule. The objective of the present investigation was to gain insight into how these two regions of RAP interact with LRP and function to modulate its ligand binding properties. These objectives were accomplished by random mutagenesis of RAP, which identified two critical lysine residues, Lys-256 and Lys-270, within the carboxyl-terminal domain that are necessary for binding of this region of RAP to LRP and to heparin. RAP molecules in which either of these two lysine residues was mutated still bound LRP but with reduced affinity. Furthermore, the mutant RAPs were significantly impaired in their ability to inhibit α2M* binding to LRP via allosteric mechanisms. In contrast, the mutant RAP molecules were still effective at inhibiting uPA·PAI-1 binding to LRP. These results confirm that both LRP binding sites within RAP cooperate to inhibit ligand binding via an allosteric mechanism.

All Six Modules of the Gelatin-binding Domain of Fibronectin Are Required for Full Affinity

The gelatin-binding sites of fibronectin are confined to a 42-kDa region having four type I and two type II modules in the following order: I6-II1-II2-I7-I8-I9. To determine the relative importance of each module for recognition of gelatin, recombinant green fluorescent fusion proteins were prepared in which individual modules or groups of modules were deleted, and the resulting proteins were tested for binding to gelatin by analytical affinity chromatography. Deletion of both type II modules did not eliminate binding, confirming that at least some of the type I modules in this region are able to bind gelatin. It was found that deletion of type I module 6 tends to increase the affinity, whereas deletion of any other module decreases it. Deletion of module I9 had a large effect but only if module II2 was also present, suggesting an interaction between these two noncontiguous modules. Analysis of more than 20 recombinant fusion products led to the conclusion that all modules contribute to the interaction either directly by contacting the ligand or indirectly through module-module interactions.

Fluorescent labeling of the carbohydrate moieties of human chorionic gonadotropin and α1-acid glycoprotein

A method for covalent attachment of a fluorescent molecule to the carbohydrate moieties of glycoproteins is described. The glycoproteins were oxidized with periodate under mild conditions selective for sialic acid (Van Lenten, L. and Ashwell, G. (1971) J. Biol. Chem. 246, 1889--1894). The resulting aldehydes were condensed with either dansylhydrazine, dansylethylenediamine, or fluoresceinamine followed by reduction with NaCNBH3 and NaBH4. Conjugates prepared with dansylhydrazine were found to be insufficiently stable for spectroscopic analysis, whereas the primary amines produced stable conjugates whose fluorescence polarization (P) was constant for several hours at 37 degrees C. The degree of labeling correlated roughly with the sialic acid contents of the vaious glycoproteins. Very little covalent incorporation was observed with albumin (which is devoid of carbohydrate) or with asialo alpha 1-acid glycoprotein. Exclusion chromatography in the presence of a dissociating agent was sometimes required to remove significant amounts of noncovalently adsorbed dye. Fluorescent-labeled alpha subunits of human chorionic gonadotropin were shown to recombine normally with native beta subunits. However, the labeling procedure appeared to compromise the ability of the beta subunits to recombine. Electrophoretic analysis produced evidence of covalent cross-linking between subunits following periodate oxidation of the intact gonadotropin. The possibility that primary amine groups of the protein compete with added fluorescent amines for reaction with periodate-generated aldehydes is discussed.

Type I collagen contains at least 14 cryptic fibronectin binding sites of similar affinity.

There is uncertainty in the literature regarding the number and location of fibronectin binding sites on denatured collagen. Although most attention has focused on a single site near the collagenase-sensitive region of each alpha chain, there is evidence for additional sites in other regions. We treated bovine type I collagen with cyanogen bromide, labeled the resulting mixture with fluorescein, and separated the peptides by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Fluorescent bands were excised from the gel and dialyzed exhaustively to remove detergent. Titration of eight distinct fluorescent-labeled fragments with the 42-kDa gelatin-binding fragment of fibronectin caused increases in anisotropy that were fully reversible with unlabeled gelatin. By fitting the dose responses it was possible to calculate apparent K(d)s whose values ranged between 1 and 4 microM. The largest fragment, alpha(2)-CB3,5, composing about 2/3 of the alpha(2) chain, when further digested with endoproteinase Lys-C, yielded at least three additional subfragments that also bound with similar affinities. Thus, there appear to be at least 14 distinct fibronectin binding sites of similar affinity in bovine type I collagen, five on each of the alpha(1) chains and four on the alpha(2) chain. Experiments with several synthetic peptides failed to reveal the exact nature of the binding site.

Reversible unfolding of an isolated heparin and DNA binding fragment, the first type III module from fibronectin

Several fragments containing all or part of the first type III homology unit of fibronectin were isolated and their folding properties examined by fluorescence spectroscopy and differential scanning calorimetry. Each fragment exhibits a reversible unfolding transition when heated or titrated with guanidinium chloride. This indicates that an isolated type III module can fold independently in the absence of neighboring modules. A comparison of the specific enthalpies of unfolding of these fragments with those of well-studied globular proteins suggests that this type III unit is composed of a stable core flanked by less compact or unstructured regions. Comparison of the heparin-binding properties of these fragments revealed that removal of 12 amino acids from the amino terminus of the largest one (Ile-585 to Val-675) increased its affinity for immobilized heparin such that it now binds at physiological ionic strength.

Interaction of plasma fibronectin with gelatin and complement C1q

A variety of techniques have been used to examine the interaction of human plasma fibronectin (Fn) with complement C1q in comparison to that with gelatin in phosphate buffered saline at pH 7.4. The precipitation of 3H-Fn by polyethylene glycol (PEG) was shifted to much lower concentrations of the polymer by addition of gelatin, and to a lesser extent, by C1q. Precipitation of 3H-Fn in the presence of C1q was close to that of C1q alone under identical conditions suggesting an affinity of Fn for solid phase C1q; a similar interaction was seen with heat-insolubilized C1q. Fibronectin bound tightly to gelatin-Sepharose and C1q-Sepharose and this binding could be inhibited by gelatin but not by C1q. The presence of gelatin retarded the anodal migration of Fn during immunoelectrophoresis under physiological conditions whereas C1q had an effect only at low ionic strength. Exclusion chromatography of Fn, alone and preincubated with gelatin or C1q, was also consistent with the formation of strong complexes with gelatin but not with C1q, whereas similar mixtures of Fn and gelatin exhibited a fast-sedimenting boundary and marked depletion of the 12S Fn peak. Titration of fluorescein-labeled alpha 2 chains of type I collagen with Fn produced an increase in fluorescence polarization which could be reversed by addition of unlabeled alpha 2 chains or gelatin but not by C1q or the pepsin-derived collagen-like domain of C1q. These observations indicate that the fluid-phase interaction of Fn with C1q is much weaker than that with gelatin but that Fn does have appreciable affinity for solid-phase C1q. Such interaction could signify a role for Fn in the clearance of immune complexes from circulation.

Purification of human plasma fibronectin

A simplified procedure is described for the isolation of human plasma fibronectin by affinity chromatography on gelatin-agarose. A portion of the fibonectin can be eluted by simply lowering the pH to 5.5 and can be used immediately after neutralization. The remainder is eluted with 6M urea, and the urea removed by dialysis or rechromatography on heparin-agarose.

Interaction and thermal stability of fluorescent labeled derivatives of thrombin and antithrombin III

Derivatives of human thrombin and antithrombin III with fluorescent labels covalently attached to their carbohydrate moieties were prepared by reaction of periodate-oxidized proteins with amino derivatives of dansyl, fluorescein and pyrene. The labeled derivatives retained full biological activity, including their ability to form stable enzyme-inhibitor complexes, a reaction whose rate could be monitored by the increase in fluorescence polarization. When the dansyl-labeled derivatives were heated, they exhibited sigmoidal increases in polarization with midpoints near 50 degrees C for thrombin and 60 degrees C for antithrombin III. By contrast, a complex between antithrombin III and dansyl-thrombin showed no change in polarization up to 70 degrees C, suggesting that the individual components are more stable in the complex. These studies show that fluorescent labels attached to carbohydrate moieties of glycoproteins provide convenient probes for monitoring conformational changes and protein-protein interactions with minimum interference by the probe.