Characterization of porcine plasma fibronectin and its fragmentation by porcine liver cathepsin B

Fibronectin was isolated from porcine plasma by affinity chromatography with gelatin-linked Sepharose 4B. Porcine fibronectin had a chemical composition similar to those of human and other fibronectins and reacted with antiserum raised against human fibronectin. It showed hemagglutination activity with trypsin-treated rabbit erythrocytes, though the activity was far less than that of human fibronectin. Porcine plasma fibronectin consisted of two subunit chains of about 230,000-daltons linked by disulfide bonds(s). Limited proteolysis of this protein with porcine liver cathepsin B yielded five major fragments which were investigated by affinity chromatography with gelatin- and heparin-linked Sepharose 4B. One fragment (Mr = 50,000) was bound to gelatin but not to heparin, while the remaining four were bound to heparin but not to gelatin, suggesting that plasma fibronectin takes a discrete domain structure with respect to interaction with these two macromolecules. The three larger heparin-binding fragments, Mr = 175,000, 150,000, and 130,000 were eluted with different concentrations of a mixture of NaCl and urea from the heparin-column, suggesting that they have different interactions with heparin, the 130,000-dalton fragment being the one with the strongest interaction. After reduction with 2-mercaptoethanol, the 175,000-dalton fragment was converted to the 150,000-dalton region fragment, which, together with the unchanged 150,000-dalton fragment, appeared to be equivalent in amount to the 130,000-dalton fragment. This finding suggests that the 150,000- and 130,000-dalton fragments may have originated from different subunit chains. Since the 175,000-dalton fragment was not produced by cathepsin B digestion of fibronectin which had been treated with plasmin, it was concluded that the 175,000-dalton fragment contained interchain disulfide bond(s) which had linked the native subunit chains. These results suggest that porcine plasma fibronectin has non-identical subunit chains composed of domains which differ in interaction with heparin and in susceptibility to cathepsin B.     

Localization of the cleavage sites on fibronectin following digestion by urokinase.

Urokinase (u-PA) proteolytically cleaves both human plasma (pFn) and cellular (cFn) dimeric fibronectin (M(r) 440,000) into four major polypeptides of approximately M(r) 210,000, 200,000, 25,000, and 6,000. Amino acid sequence analysis of the polypeptide fragments indicated that the enzymatic cleavage of Fn occurs at two sites: 1) between an arginine/alanine peptide bond located C-terminal to residue 259; this cleavage liberates the N-terminal M(r) 25,000 fragment and the M(r) 210,000 and M(r) 200,000 polypeptides derived from the A and B chains of Fn, respectively; and 2) between an arginine/threonine peptide bond located C-terminal to residue 2,299, thereby yielding an M(r) 6,000 dimeric fragment containing the C-terminal interchain disulfide bonds. Predigestion of Fn with u-PA increased the molecule's vulnerability to further attack by the enzymes plasmin and cathepsin D. These data provide further biochemical evidence for the proteolytic cleavage of fibronectin by plasminogen activators and substantiate that u-PA digestion of Fn may be an initial event in the local degradation of the extracellular matrix by malignant cells, possessing elevated levels of these enzymes.     

Domain structure of human plasma and cellular fibronectin. Use of a monoclonal antibody and heparin affinity to identify three different subunit chains

The domain structure of human plasma fibronectin was investigated by using heparin-binding and antibody reactivity of fibronectin and its proteolytically derived fragments. Digestion of human plasma fibronectin with a combination of trypsin and cathepsin D produced six major fragments. Affinity chromatography showed that one fragment (Mr 45 000) binds to gelatin and three fragments (Mr 31 000, 36 000, and 61 000) bind to heparin. The 31K fragment corresponds to NH2-terminal fragments isolated from other species. The 36K and 61K fragments are derived from a region near the C-terminus of the molecule and appear to be structurally related as demonstrated by two-dimensional peptide maps. A protease-sensitive fragment (Mr 137 000), which binds neither gelatin nor heparin but which has been shown previously to be chemotactic for cells [Postlethwaite, A. E., Keski-Oja, J., Balian, G., & Kang, A. H. (1981) J. Exp. Med. 153, 494-499], separates the NH2-terminal heparin- and gelatin-binding fragments from the C-terminal 36K and 61K heparin-binding fragments. A monoclonal antibody to fibronectin that recognized the 61K heparin-binding fragment was used to isolate a sixth fragment (Mr 34 000) that did not bind to heparin or gelatin and that represents a difference between the 61K and 36K heparin-binding fragments. Cathepsin D digestion produced an 83K heparin-binding, monoclonal antibody reactive fragment that contains the interchain disulfide bond(s) linking the two fibronectin chains at their C-termini. The data indicate that plasma fibronectin is a heterodimeric molecule consisting of two very similar but not identical chains (A and B). In contrast, enzymatic digestion of cellular fibronectin produced a 50K heparin-binding fragment lacking monoclonal antibody reactivity which suggests that the cellular fibronectin subunit is similar to the plasma A chain in enzyme susceptibility but contains a larger heparin-binding domain. A model relating the differences in the three fibronectin polypeptides to differences in published cDNA sequences is presented.     

Oxidation of the sulfhydryl forms of insulin A-chain and B-chain.

A modified procedure for the preparation of the S-sulfonates of the A- and B-chains of insulin and their conversion to the sulfhydryl forms by tri-n-butylphosphine is described. Air oxidation of the sulfhydryl forms of the A-chain in dilute solution (0.2 mg/ml) either in the presence or absence of urea at pH 9.0 yields primarily monomeric, intrachain disulfides. Similar treatment of the reduced B-chain yield monomeric, intrachain disulfide in 7 M urea but a large number of oligomeric, interchain disulfides in the absence of urea. Electrolytic reduction of insulin in 7 M urea of pH 8.5, followed by oxidation of the sulfhydryls in dilute solution in 7 M urea at pH 9.0 yields primarily a mixture of the monomeric, intrachain disulfides of the A-chain and of the B-chain which can be separated by chromatography on Sp-Sephadex in acidic urea. The rate of the oxidation of the sulfhydryls of the two separate chains was much slower and less complete than that reported for the two chains crosslinked by the carbonylbismethionyl residue.     

Binding of secretory component to dimers of immunoglobulin A in vitro. Mechanism of the covalent bond formation.

A complex between secretory component and an immunoglobulin A (IgA) myeloma dimer has been studied in vitro as a model to elucidate the mechanism of the formation of disulfide bonds during assembly in vivo of secretory immunoglobin A. A small amount of free thiol groups, totally about 0.4 groups per mole of protein, were shown to be present on both the heavy and light chains of the IgA dimer, but not on its J-chain, while no such groups could be demonstrated on free secretory component. The SH-groups on IgA most likely exist as a result of incomplete oxidation of some intra-or interchain disulfide bonds of the molecule, analogous to what has been suggested for IgG. Several types of evidence indicated that the disulfide bonds between secretory component and IgA are formed after the noncovalent association of the two proteins by a sulfhydryl group-disulfide bond exchange reaction, in which the small amount of free sulfhydryl groups on the IgA dimer initiate the reaction by reducing a reactive disulfide bond on secretory component. This exchange reaction, which thus proceeds by the mechanism of so-called disulfide interchange reactions, requires certain conformational features of one or both of the proteins and leads to the formation of presumably two new interchain disulfide bonds between secretory component and IgA. The reaction does not progress to completion, however, but ends in an equilibrium so that a small proportion of the secretory component molecules always are unattached by disulfide bonds.     

Structure and proteolysis of the growth hormone receptor on rat hepatocytes

125I-Labeled human growth hormone is isolated in high molecular weight (Mr) (300,000, 220,000, and 130,000) and low molecular weight complexes on rat hepatocytes after affinity labeling. The time-dependent formation of low molecular weight complexes occurred at the expense of the higher molecular weight species and was inhibited by low temperature or inhibitors of serine proteinases. Exposure to reducing conditions induced loss of Mr 300,000 and 220,000 species and augmented the amount of Mr 130,000 complexes. The molecular weight of growth hormone (22,000) suggests that binding had occurred with species of Mr 280,000, 200,000, and 100,000. Two-dimensional gel electrophoresis demonstrated that the 100,000-dalton receptor subunit is contained in both the 280,000- and 200,000-dalton species. Reduction of interchain disulfide bonds in the growth hormone receptor did not alter its elution from gel filtration columns, but intact, high molecular weight receptor constituents were separated from lower molecular weight degradation products. Digestion of affinity-labeled growth hormone-receptor complexes with neuraminidase increased the mobility of receptor constituents on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. These observations show that the growth hormone receptor is degraded by hepatic serine proteinases to low molecular weight degradation products which can be separated from intact receptor by gel filtration. Intact hormone-receptor complexes are aggregates of 100,000-dalton sialoglycoprotein subunits held together by interchain disulfide bonds and by noncovalent forces.     

Structural analysis of cGMP-dependent protein kinase using limited proteolysis

cGMP-dependent protein kinase from bovine lung is labile to specific proteolysis. Limited digestion with chymotrypsin produces a 65,000-dalton monomer and a 16,000-dalton dimer from a 150,000-dalton dimeric enzyme. The larger proteolytic fragment represents the COOH-terminal portion of the enzyme and contains the catalytic site along with the cGMP binding site. The smaller fragment representing the NH2-terminal portion of the enzyme contains the autophosphorylation site and the interchain disulfide bond(s). A model defining the functional domains of cGMP-dependent protein kinase is presented and comparisons with cAMP-dependent protein kinase regulatory subunit are discussed.     

Disulfide-bonded dimerization of fibronectin in vitro.

Human plasma fibronectin was denatured with 8 M urea and reduced with dithiothreitol. Dialysis or dilution of the solution led to formation of fibronectin dimers which migrated in non-reducing SDS/PAGE similarly to untreated control protein. When the redimerized fibronectin was reduced and re-electrophoresed it formed a doublet of alpha and beta chains of equal intensity indicating that it was a heterodimer. Low concentrations (less than 1 mM) of Fe3+ enhanced the redimerization of fibronectin, suggesting that metal ions may mediate oxidative reactions in the formation of the disulfides. Consequently, redimerization of fibronectin was completely prevented by deferoxamine, an iron chelator. Dimerization of fibronectin took place most effectively at pH greater than or equal to 8.8 but decreased strongly at lower pH, representing more unfavourable conditions for the action of the thiolate anion in the thiol/disulfide exchange reaction. Redimerized fibronectin, however, lost many of its binding properties to macromolecular ligands, suggesting that the disulfide bonding did not entirely regenerate the proper conformation of the protein. Pulse/chase experiments of fibroblast cultures showed that the initially monomeric fibronectin was rapidly and quantitatively dimerized under conditions representing natural pH and environment. SDS/PAGE analysis of the dialyzed urea-denatured/reduced thrombin and plasmin digests of fibronectin revealed that the NH2-terminal 30-kDa fragment and other fragments that contained intrachain disulfides quantitatively regained their non-reduced electrophoretic mobility. The results show that the dimerization and formation of intrachain disulfides of fibronectin may occur, in part, spontaneously, based on the amino acid sequence information of the protein. However, complete disulfide formation may also need other factors, present only in living cells, as suggested by pulse/chase experiments in fibroblasts.     

Structural disulfide bonds in the Bacillus thuringiensis subsp. israelensis protein crystal.

We examined disulfide bonds in mosquito larvicidal crystals produced by Bacillus thuringiensis subsp. israelensis. Intact crystals contained 2.01 X 10(-8) mol of free sulfhydryls and 3.24 X 10(-8) mol of disulfides per mg of protein. Reduced samples of alkali-solubilized crystals resolved into several proteins, the most prominent having apparent molecular sizes of 28, 70, 135, and 140 kilodaltons (kDa). Nonreduced samples contained two new proteins of 52 and 26 kDa. When reduced, both the 52- and 26-kDa proteins were converted to 28-kDa proteins. Furthermore, both bands reacted with antiserum prepared against reduced 28-kDa protein. Approximately 50% of the crystal proteins could be solubilized without disulfide cleavage. These proteins were 70 kDa or smaller. Solubilization of the 135- and 140-kDa proteins required disulfide cleavage. Incubation of crystals at pH 12.0 for 2 h cleaved 40% of the disulfide bonds and solubilized 83% of the crystal protein. Alkali-stable disulfides were present in both the soluble and insoluble portions. The insoluble pellet contained 12 to 14 disulfides per 100 kDa of protein and was devoid of sulfhydryl groups. Alkali-solubilized proteins contained both intrachain and interchain disulfide bonds. Despite their structural significance, it is unlikely that disulfide bonds are involved in the formation or release of the larvicidal toxin.     

Suppression of sodium dodecyl sulfate-polyacrylamide gel electrophoresis sample preparation artifacts for analysis of IgG4 half-antibody

Human IgG4 subtype antibodies have often been reported to have a significant portion (5-50%) of a heavy chain-light chain dimer ("half-antibody") on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), in which the heavy chain is not covalently linked through the hinge disulfides to another heavy chain. We demonstrate here that there can be artifactual sources of half-antibody. One occurred during SDS-PAGE sample preparation where rapid disulfide scrambling was initiated by preexisting free sulfhydryls in the monoclonal antibody (mAb) and by free sulfhydryl produced by destruction of disulfide bonds during heating. Inclusion of N-ethylmaleimide in the sample buffer prevented the disulfide scrambling. Presumably, cyclization of the flexible IgG4 hinge during this disulfide scrambling leads to the preferential separation of heavy chains. A second condition producing half-antibody was reoxidation after exposure to reductant, where 46% of the antibody was trapped in the intrachain disulfide form. The amount of half-antibody was reduced to 4% by reoxidation in the presence of a mixture of oxidized and reduced glutathione. When the improved sample preparation conditions were used, IgG4 mAb freshly isolated from cells contained 4.5-15% half-antibody, indicating that equilibration of the interchain and intrachain hinge disulfide pairing was not always attained in cells.     

The structure of human platelet thrombospondin

Two distinct murine monoclonal antibodies, designated MA-I and MA-II, and limited proteolysis with thrombin and trypsin have been used to probe the structure of human platelet thrombospondin. The results indicate that each of the constituent chains of thrombospondin comprise four distinct polypeptide segments. The production of these segments is influenced by the presence of calcium, the enzyme employed, the temperature of digestion, and the enzyme-to-substrate ratio. Thrombin digestion in the presence of calcium results in the release of a 30,000-dalton fragment, designated segment I, which contains the epitope for MA-II and the heparin-binding site. Prior EDTA treatment results in the concomitant cleavage of a 25,000-dalton fragment, designated segment IV, from the other terminus. Limited tryptic digestion in the absence of calcium produces a 47,000-dalton fragment (segment III) which is adjacent to segment IV. Segment III contains the epitope for MA-I. Segment II is an 85,000-dalton fragment which contains the interchain disulfide bonds. Calcium inhibits proteolysis at cleavage sites between segments II and III and between segments III and IV. In the presence of calcium, an 85,000-dalton fragment is produced, which is derived from portions of segments II, III, and possibly IV. Electron microscopy of platinum replicas produced by low angle rotary shadowing reveals that thrombospondin is composed of four well-defined globular regions connected by thin flexible regions. Three of the globular regions, designated globular region C, appear to be at the ends of the three thin connecting regions. The fourth globular region, designated globular region N, appears to be close to the site where the chains are cross-linked. Globular region N can be resolved into three separate smaller globular structures which are 70 +/- 7.1 A in diameter. This region is selectively removed by thrombin digestion in the presence of calcium and binds a monoclonal antibody directed against the heparin-binding peptides. These data indicate that globular region N comprises the three NH2-terminal portions (segment I) from each of the three chains of thrombospondin. Globular region C is located at the ends of each of the three thin connecting regions which are each approximately 291 +/- 46 A long. The removal of calcium results in a decrease in the size of globular region C from 118 +/- 18.6 A to 80 +/- 7.4 A and an increase in the length of the adjacent thin connecting region to 383 +/- 30 A.(ABSTRACT TRUNCATED AT 400 WORDS)     

Primary structure of human plasma fibronectin. Characterization of a 31,000-dalton fragment from the COOH-terminal region containing a free sulfhydryl group and a fibrin-binding site

The 31-kDa domain of human plasma fibronectin has been completely characterized. This fragment is located at the COOH-terminal end of the molecule immediately preceding the 3-kDa interchain disulfide-containing peptide. The 31-kDa domain was obtained after trypsin digestion of fibronectin and purified by affinity chromatography on gelatin- and heparin-Sepharose columns. The fragment eluted in the heparin-unbound fraction and was further purified by DEAE-cellulose and high performance liquid chromatography. The 31-kDa fragment contained a fibrin-binding site (fibrin II site) which was only active at physiological NaCl concentrations and therefore differed from that located in the NH2-terminal domain which also bound at lower NaCl concentrations. The 31-kDa domain bound to thiopropyl-Sepharose and was shown to contain a free sulfhydryl group located at position 35 in the sequence. To determine the complete amino acid sequence of this fragment, a trypsin digestion was performed on the reduced and alkylated 31-kDa domain, and the 17 resulting peptides were isolated by high performance liquid chromatography; their amino acid compositions and amino acid sequences have been determined, and the arrangement of peptides was achieved by comparison with the sequences deduced from human and rat cDNA clones and with a related plasmic fragment from bovine fibronectin. Comparison of these three sequences showed 23 amino acid differences between human and rat fibronectin and 16 between human and bovine fibronectin. This represents a 91 and 94% homology, respectively. An interesting finding is that the 31-kDa fragment contains a deletion of 31 residues when compared to the rat cDNA sequence. This deletion appears to represent a species difference since it is due to a shorter mRNA in the case of human fibronectin.     

Biosynthesis and processing of fibronectin in NIL.8 hamster cells.

Fibronectin is synthesized as a monomeric polypeptide chain. As early as it can be detected inside the cell, it carries carbohydrate side chains. These chains are sensitive to endoglycosidase H, suggesting that they are asparagine linked and high mannose form. The monomeric chains quickly dimerize while still inside the cell. Newly synthesized fibronectin appears as a dimer, both at the cell surface and secreted into the culture medium, about 30 min after commencement of labeling. This exported fibronectin has endoglycosidase H-resistant carbohydrate side chains, indicating processing from the high mannose form to a complex form. Exit of fibronectin to the outside of the cell follows quickly on carbohydrate processing; no large pool of endoglycosidase H-resistant fibronectin exists inside the cell. The dimeric fibronectin at the cell surface is initially deoxycholate soluble but slowly becomes deoxycholate-insoluble and also slowly forms high molecular weight aggregates which require reduction of disulfide bonds for their dissociation.     

Location of a fibronectin domain involved in newt epidermal cell migration

The interaction of migrating newt epidermal cells with the extracellular matrix protein, fibronectin, was studied. Pieces of nitrocellulose coated with intact human plasma fibronectin or proteolytically derived fragments were implanted into wounded limbs so that the coated nitrocellulose served as wound bed for migrating epidermal cells as they attempted to form a wound epithelium. Epidermal cells migrated very poorly on nitrocellulose pieces coated with (a) a 27-kD amino-terminal heparin-binding fragment, (b) a 46-kD gelatin-binding fragment, (c) a combined 33- and 66-kD carboxy-terminal heparin-binding preparation representing peptide sequences in the A and B chains, respectively, or (d) a 31-kD carboxy-terminal fragment from the A chain, containing a free sulfhydryl group. In contrast, epidermal cells readily migrated onto nitrocellulose coated with a mixture of fragments from the middle of the molecule (80-125kD) that bind neither heparin nor gelatin. Attempts to block migration on fibronectin-coated nitrocellulose using IB10, a monoclonal antibody that blocks Chinese hamster ovary cell attachment to fibronectin, were unsuccessful despite saturation of the epitope against which IB10 is directed. In contrast, a polyclonal anti-fibronectin antibody did inhibit migration. These results show that the ability of fibronectin to support newt epidermal cell migration is not shared equally by all regions of the molecule, but is restricted to a domain in the middle third. They also suggest that the site supporting migration is separate and distinct from the site mediating Chinese hamster ovary cell attachment.     

Role of the I-9 and III-1 modules of fibronectin in formation of an extracellular fibronectin matrix.

Cultured fibroblasts bind soluble protomeric fibronectin and mediate its conversion to insoluble disulfide-bonded multimers. The disulfide-bonded multimers are deposited in fibrillar pericellular matrix. Antifibronectin monoclonal antibodies were analyzed to identify domains of fibronectin required for assembly into matrix. Two antibodies, L8 and 9D2, inhibited binding and insolubilization of 125I-labeled plasma fibronectin by fibroblasts but did not inhibit binding of labeled amino-terminal 70-kDa fragment of fibronectin to matrix assembly sites. Immunoblotting of fibronectin fragments showed that the epitope for 9D2 is in the first type III homology sequence (III-1) whereas the epitope for L8 requires that the last type I sequence of the gelatin binding region (I-9) be contiguous to III-1 and is sensitive to reduction of disulfides in I-9. A 56-kDa gelatin-binding thermolysin fragment of fibronectin that contains III-1 and the L8 and 9D2 epitopes inhibited binding of fibronectin to cell layers 10-fold better than a 40-kDa gelatin-binding fragment that lacks III-1 and the antigenic sites. This 56-kDa fragment, however, did not bind specifically to cell layers. These results indicate that the I-9 and III-1 modules of fibronectin form a functional unit that mediates an interaction, perhaps between protomers, important in the assembly of fibronectin.     

Identification of disulfide-bridged substructures within human von Willebrand factor

In the course of identifying substructural domains within the homooligomeric protein von Willebrand factor [270 kilodaltons (kDa) per polypeptide chain], seven large fragments of 8-90 kDa have been generated by limited proteolysis. A monomeric fragment that binds coagulation factor VIIIc is identified as residues 1-272. A fragment that binds platelet glycoprotein Ib is identified as a homodimer containing two pairs of identical chains, i.e., residues 273-511 and 674-728. Disulfide bonds have been identified by several methods, including direct observation of the phenylthiohydantoin of cystine during Edman degradation of isolated peptides. Among half-cystine residues in the amino-terminal 1365-residue region, 52 have been paired. They place structural constraints on folding possibilities within three structural domains. Additional clusters of disulfide bonds are evident. It has been shown that at least 35 disulfides must form intrachain bridges, specifically the cystines among residues 1-272 and 906-1492. Intersubunit disulfide bonds are partially localized in an interior region (residues 283-695) and a carboxyl-terminal region (residues 1908-2050). Each of these regions appears to be linked to a corresponding region of a neighboring subunit in the network of interconnected chains. The difficulties of pairing all 169 half-cystines (per chain) and of distinguishing intrachain from interchain disulfides are evaluated.     

Free sulfhydryl in recombinant monoclonal antibodies

Monoclonal antibody (mAb) therapy applications have been growing rapidly in recent years. Like other recombinant protein drugs, therapeutic mAb's need to be well characterized to ensure their structural and functional integrity. IgG mAb's are composed of two heavy and two light chains covalently linked by interchain disulfide bonds. Each domain of the heavy or light chain contains one additional disulfide bond. Native IgG mAb's, with completely formed disulfide bonds, should not bear any free sulfhydryl. This report describes detection and quantification of free sulfhydryl in recombinant mAb's produced in Chinese hamster ovary (CHO) cells using a fluorescent technique. The method utilizes the fluorescent probe N-(1-pyrenyl)maleimide (NPM). The purified mAb's appear to be homogeneous under native conditions with approximately 0.02 mol of free sulfhydryl per mole of protein. Upon denaturation, minor species related to the mAb's are observed on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), and the free sulfhydryl level is determined to be approximately 0.1 mol/mol of protein. These results suggest that a small portion of these recombinant mAb's lack in intermolecular disulfide bonds but remain noncovalently associated under native conditions. The formation of the free sulfhydryl containing mAb species is likely to occur during the culture process and/or protein folding process in the endoplasmic reticulum (ER).     

Primary structure of human plasma fibronectin--characterization of the 6,000 dalton C-terminal fragment containing the interchain disulfide bridges

The carboxy terminal fragment of human plasma fibronectin has been isolated after tryptic digestion and separation by DEAE-cellulose chromatography and gel filtration on Sephadex G-50. It has a molecular weight of 6,000 which changes to 3,000 after reduction indicating that the fragment is a dimer. We have determined the amino acid sequence of the 6kDa fragment and showed that it contains 26 residues including two half-cystines which form two interchain disulfide bridges. The 6kDa fragment is not phosphorylated as in bovine fibronectin although its amino acid sequence is identical to that reported for bovine plasma fibronectin. When compared to the sequence deduced from a rat cDNA, one amino acid substitution can be found. It appears that the carboxyl end of fibronectin is highly conserved among species.     

Sulfhydryls of platelet tubulin: their role in polymerization and colchicine binding

Sulfhydryls and disulfides of platelet tubulin have been quantified, their accessibility and reactivity measured, and their role in polymerization and colchicine binding evaluated. Platelet tubulin isolated by two cycles of temperature-dependent polymerization--depolymerization was found to contain 12 free sulfhydryl groups per tubulin monomer all of which reacted rapidly with p-chloromercuribenzoate. One sulfhydryl was inaccessible to dithiobis(nitrobenzoic acid). Under anaerobic conditions of tubulin extraction, one intrachain disulfide bridge was found per tubulin monomer. Polymerization of tubulin reduced the number of sulfhydryls by one which were able to react with p-chloromercuribenzoate or dithiobis(nicotinic acid) but did not affect the disulfide bridge. Polymerizability of platelet tubulin was very sensitive to blocking of free sulfhydryl groups. Complete inhibition of microtubule assembly was obtained when the number of free sulfhydryls per tubulin was reduced by 3 but could be reversed by the addition of dithiothreitol. Colchicine binding, on the other hand, was only minimally influenced by blocking of sulfhydryls.     

Reactive sulfhydryl groups of the band 3 polypeptide from human erythroycte membranes. Location in the primary structure.

Human erythrocyte membranes contain a major transmembrane protein, known as Band 3, that is involved in anion transport. This protein contains a total of five reactive sulfhydryl groups, which can be assigned to either of two classes on the basis of their susceptibility to release from the membrane by trypsin. Two of the groups are located in the region COOH-terminal to the extracellular chymotrypsin-sensitive site of the protein and remain with a membrane-bound 55,000-dalton fragment generated by trypsin treatment. The three sulfhydryl groups NH2-terminal to the extracellular chymotrypsin site are released from the cytoplasmic surface of the membrane by trypsin. All three groups are present in a 20,000-dalton tryptic fragment of Band 3. Two of these groups are located very close to the sites of trypsin cleavage that generate the 20,000-dalton fragment. The third reactve group is probably located about 15,000-daltons from the most NH2-terminal sulfhydryl group. Two other well defined fragments of the protein do not contain reactive sulfhydryl groups. They are a 23,000-dalton fragment derived from the NH2-terminal end that is also released by trypsin from the cytoplasmic surface of the membrane and a 19,000-dalton membrane-bound region of the protein that is produced by treatment with chymotrypsin in ghosts. The 20,000-dalton tryptic fragment may, therefore, constitute a sulfhydryl-containing domain of the Band 3 protein.