Structural differences in the cell binding region of human fibronectin molecules isolated from cultured normal and tumor-derived human cells

Fibronectins isolated from human plasma (pFN) and from the conditioned media of normal (N-cFN) and tumor (T-cFN) human cells were compared by cathepsin D digestion followed by immunostaining of released fragments with the monoclonal antibody 3E3, specific for the cell binding site. Two different staining patterns were obtained, one specific for pFN and N-cFN, the second common to fibronectins from the 3 different kinds of tumors studied. This indicates structural differences between N-cFN and T-cFN in the cell binding region of the fibronectin molecule.     

Differences in domain structure between pericellular matrix and plasma fibronectins as revealed by domain-specific antibodies combined with limited proteolysis and S-cyanylation: a preliminary note

Differences in domain structure between human fibronectins obtained from pericellular matrix and plasma have been revealed by limited proteolysis and S-cyanylation, followed by identification of each domain with domain-specific antibodies. Although the overall domain structure is similar between pericellular and plasma fibronectins, the fragments derived from the COOH-terminal region of these fibronectins, which were defined by specific antibodies, exhibited clear differences in their molecular weights and protease susceptibility, suggesting that the structure near the COOH-terminal region is significantly different between these two proteins.     

Studies of functional domains of the regulatory subunit from cAMP-dependent protein kinase isozyme I

Homogenous regulatory subunit from rabbit skeletal muscle cAMP-dependent protein kinase (isozyme I) was partially hydrolyzed with low (1 g/1300 g) or high (1 g/6 g) concentrations of trypsin. After treatment with low trypsin two main peptides (Mr = 35,000 and 12,000) were produced. The cAMP-binding activity (2 mol cAMP/mol of subunit monomer) was recovered in the monomeric Mr = 35,000 peptide. The ability of either fragment to inhibit catalytic subunit activity was lost. Treatment of the regulatory subunit with a high concentration of trypsin yielded three main fragments (Mr = 32,000, 16,000, and 6,000) which could be resolved by Sephadex G-75 and purified further on DEAE-cellulose columns. One of the peptides (Mr = 32,000) bound 2 mol cAMP/mol fragment. The Mr = 16,000 fragment was very labile and bound cAMP with an undetermined stoichiometry. Cyclic AMP dissociation curves for the native regulatory subunit and its Mr = 32,000 component were similar and suggested the presence of two nonidentical binding sites in each monomer. Using the same procedure, the Mr = 16,000 fragment or homogenous cGMP-dependent protein kinase appeared to contain a single type of binding site. Purified Mr = 32,000 fragment was readily converted to the Mr = 16,000 fragment using high trypsin as assessed by protein bands on SDS-disc gels or by following transfer of radioactivity from Mr = 32,000 peptide covalently labeled with 8-N3-[32P] cAMP to radiolabeled Mr = 16,000 fragment. The smallest regulatory subunit fragment (Mr = 6,000) did not bind cAMP, but was dimeric and could be part of the dimerization domain in the native protein. A model is presented to explain the possible structural-functional relationships of the regulatory subunit.     

Domain-specific distribution of carbohydrates in human fibronectins and the transformation-dependent translocation of branched type 2 chain defined by monoclonal antibody C6

Fibronectins purified from human plasma (termed pFN), spent culture media of human fibroblasts WI38 (termed cFN), and SV40 virus-transformed WI38/VA13 cells (termed tFN) and their cleavage fragments were compared with respect to their binding activities to lectins and anti-carbohydrate antibodies reacting with chemically well-defined structures. The following findings were of particular interest. About 25-35% of cFN and tFN carried a binary sialosyl type 2 chain (NeuAc alpha 2----3/or 6Gal beta 1----4GlcNAc) linked beta 1----3/beta 1----6 to the galactose residue and defined by monoclonal antibody C6. This structure was not detected in pFN. In cFN, the C6-defined structure was localized within the gelatin-binding domain, whereas in tFN the same structure was absent from this domain but was located at the NH2-terminal region of the central domain. Other carbohydrate determinants, defined by Ricinus communis lectin and concanavalin A before and after sialidase treatment, showed essentially identical domain distribution patterns among cFN, tFN, and pFN and were all located at the gelatin-binding domain (44 kDa), its precursor (60 kDa), and the Cell/Hep-2 domain (155/145 kDa). Although both cFN and tFN were reactive with lentil lectin, pFN was not. Fibronectin from transformed cells (tFN) showed much greater reactivity than cFN and pFN with wheat germ lectin before sialidase treatment and showed enhanced reactivity with R. communis lectin and peanut lectin after sialidase treatment, indicating that tFN is more highly sialylated than cFN and pFN. All fibronectins examined were strongly reactive with monoclonal antibody AH8-28, which binds to Gal beta 1----3GalNAc residues, and this reactivity was localized to both the NH2-terminal half and COOH-terminal half of the S-cyanylation-cleaved fibronectin molecule.     

Modulation of matrix adhesive responses of human neuroblastoma cells by neighboring sequences in the fibronectins

Attachment and neurite extension have been measured when Platt or La-N1 human neuroblastoma cells respond to tissue culture substrata coated with a panel of complementary fragments from the individual chains of human plasma (pFN) or cellular fibronectins (cFN) purified from thermolysin digests. A 110-kD fragment (f110), which contains the Arg-Gly-Asp-Ser sequence (RGDS)-dependent cell-binding domain but no heparin-binding domains and whose sequences are shared in common by both the alpha- and beta-subunits of pFN, facilitated attachment of cells that approached the level observed with either intact pFN or the heparan sulfate-binding platelet factor-4 (PF4). This attachment on f110 was resistant to RGDS-containing peptide in the medium. Neurite outgrowth was also maximal on f110, and half of these neurites were also resistant to soluble RGDS peptide. Treatment of cells with glycosaminoglycan lyases failed to alter these responses on f110. Therefore, there is a second "cell-binding" domain in the sequences represented by f110 that is not RGDS- or heparan sulfate-dependent and that facilitates stable attachment and some neurite outgrowth; this domain appears to be conformation-dependent. Comparisons were also made between two larger fragments generated from the two subunits of pFN-f145 from the alpha-subunit and f155 from the beta-subunit--both of which contain the RGDS-dependent cell-binding domain and the COOH-terminal heparin-binding domain but which differ in the former's containing some IIICS sequence at its COOH terminus and the latter's having an additional type III homology unit. Heparin-binding fragments (with no RGDS activity) of f29 and f38, derived from f145 or f155 of pFN, respectively, and having the same differences in sequence, were also compared with f44 + 47 having the "extra domain" characteristic of cFN. Attachment on f145 was slightly sensitive to soluble RGDS peptide; attachment on f155 was much more sensitive. There were also differences in the percentage of cells with neurites on f145 vs. f155 but neurites on either fragment were completely sensitive to RGDS peptide. Mixing of f29, f38, or PF4 with f110 could not reconstitute the activities demonstrated in f145 or f155, demonstrating that covalently linked sequences are critical in modulating these responses. However, mixing of f44 + 47 from cFN with f110 from pFN increased the sensitivity to RGDS peptide.(ABSTRACT TRUNCATED AT 400 WORDS)     

Domain structures of the dihydrolipoyl transacetylase and the protein X components of mammalian pyruvate dehydrogenase complex. Selective cleavage by protease Arg C

Treatment of the dihydrolipoyl transacetylase-protein X-kinase subcomplex (E2-X-KcKb) with protease Arg C selectively converted protein X into an inner domain fragment (Mr approximately equal to 35,000) and an outer (lipoyl-bearing) domain fragment (Mr approximately equal to 15,500). These fragments were larger and much smaller, respectively, than the inner domain and outer domain fragments derived from the E2 component, supporting the conclusion that protein X is distinct from the E2 component. Protease Arg C cleaved the Kb subunit more slowly than protein X. An increase in kinase activity correlated with this cleavage of the Kb subunits. An even slower cleavage of E2 subunits generated an inner domain fragment (Mr approximately equal to 31,500) and a lipoyl-bearing domain fragment (Mr approximately equal to 49,000) which had Mr values at least 3,000 and 10,000 larger, respectively, than the corresponding E2 fragments generated by trypsin treatment of the subcomplex. Following various extents of cleavage with protease Arg C or trypsin, residual oligomeric subcomplexes were isolated and characterized. We found that selective removal of the lipoyl-bearing domain of protein X did not alter lipoyl-mediated regulation of the kinase indicating that the lipoyl residues bound to E2 subunits are effective, that the inner domain of protein X remained associated with the inner domain of E2 subunits following the complete removal of the outer domains of both E2 and protein X, that, with only 10% of the E2 subunits intact, nearly half of the catalytic (Kc) subunits of the kinase were bound by the residual subcomplex, and that removal of the remaining outer domains from E2 subunits released the Kc subunits. Thus, protein X is unique among the subunits of the complex in binding tightly to the oligomeric inner domain of the transacetylase, and the outer domain of the transacetylase serves to bind to and facilitate the regulation of the catalytic subunit of the kinase.     

Elution of fibronectin proteolytic fragments from a hydroxyapatite chromatography column. A simple procedure for the purification of fibronectin domains

Human plasma fibronectin is composed of at least five distinct domains which we refer to as Hep-1/Fib-1, Gel, Cell, Hep-2 and Fib-2 depending on their affinity for heparin (Hep), gelatin (Gel), the cell surface (Cell) or fibrin (Fib). These domains are aligned from the NH2 to the COOH terminus in the above order and can be separated from each other by mild proteolytic digestion. We have studied the elution of fibronectin thermolysin digest from a hydroxyapatite column using a linear gradient (0.5-190 mM) of sodium phosphate buffer. The five major fibronectin domains were eluted from the hydroxyapatite chromatography column in the following order: Gel, Fib-2, Cell, Hep-1/Fib-1 and Hep-2. They were identified on the basis of their molecular mass, affinity to different macromolecules and reaction with domain-specific monoclonal antibodies. All domains except the Cell and Hep-2 domains eluted as single homogeneous peaks. The Cell domain eluted as two different peaks and the Hep-2 domain eluted as four different peaks. This is the first time that heterogeneity of these two domains has been observed. Since chromatography of a fibronectin thermolysin digest on a hydroxyapatite column provides a good separation of the five major fibronectin domains, we have elaborated a procedure in which each fibronectin domain is purified by no more than two steps; hydroxyapatite and molecular exclusion chromatography. Fractionation of fibronectin proteolytic digest on a hydroxyapatite chromatography column should be of great value in the comparative analysis of fibronectin from different sources and in the study of fibronectin heterogeneity. Its use in combination with molecular exclusion chromatography offers a simple and high-yield method for the purification of large amounts of fibronectin domains.     

Interaction of the fibronectin COOH-terminal Fib-2 regions with fibrin: further characterization and localization of the Fib-2-binding sites

Incorporation of fibronectin into fibrin clots is important for the formation of a provisional matrix that promotes cell adhesion and migration during wound healing. Previous studies revealed that this incorporation occurs through noncovalent interaction between two NH2-terminal Fib-1 regions of fibronectin (one on each chain) and the alphaC-regions of fibrin, and is further reinforced by factor XIIIa-mediated covalent cross-linking of fibronectin to the fibrin matrix. To clarify the role of another pair of fibrin-binding regions, Fib-2, located at the disulfide-linked COOH-terminal ends of fibronectin, we prepared by limited proteolysis a dimeric 140 kDa (Fib-2)2 fragment containing both Fib-2 regions and tested its interaction with recombinant fragments corresponding to the alphaC regions of fibrin(ogen). In both ELISA and surface plasmon resonance (SPR) experiments 140 kDa (Fib-2)2 bound to the immobilized Aalpha221-610 alphaC-fragment. However, the affinity of binding was substantially lower than that for Fib-1. Ligand blotting and ELISA established that the Fib-2 binding site is located in the connector part of the alphaC region including residues Aalpha221-391. Analysis of the SPR-detected binding of fibronectin to the immobilized Aalpha221-610 alphaC-fragment revealed two types of fibronectin-binding sites, one with high affinity and another one with much lower affinity. Competition experiments revealed about 30% inhibition of the Fib-2 mediated binding by increasing concentrations of Fib-1 fragment suggesting partial overlap of the two sets of binding sites. Based on these results and our previous studies we propose a mechanism of interaction of fibronectin with fibrin in which both Fib-1 and Fib-2 play a role.     

Papain fragmentation of the (Na+,K+)-ATPase beta subunit reveals multiple membrane-bound domains

Purified dog kidney (Na+,K+)-ATPase was reacted with tritiated sodium borohydride after treatment with neuraminidase and galactose oxidase. This procedure did not affect the ATPase activity of the enzyme, and all of the covalently bound radioactivity was found in the beta subunit (Mr 54 000). Papain digestion of the tritiated enzyme produced two labeled fragments of Mr 40 000 and 16 000. Further proteolysis generated an Mr 31 000 peptide from the larger fragment. Unlike the tryptic and chymotryptic sites of the alpha subunit, the sites of papain hydrolysis were insensitive to conformations of the (Na+,K+)-ATPase. Determination of the NH2-terminal sequences was used to arrange the fragments within the linear map of the beta chain. Finally, none of the labeled peptides was released from the membrane under nondenaturing conditions. These results are consistent with a model of the beta subunit containing a 40 000-dalton NH2-terminal piece and a 16 000-dalton COOH-terminal piece. Both fragments have extracellularly exposed carbohydrate and at least one membrane-bound domain.     

Characterization of the calmodulin-binding and catalytic domains in skeletal muscle myosin light chain kinase

Limited proteolysis has been utilized to study the structural organization of rabbit skeletal muscle myosin light chain kinase. The enzyme (Mr approximately 89,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis) consists of an amino-terminal, protease-susceptible region of unidentified function and a carboxyl-terminal, protease-resistant region of Mr approximately 40,000 containing the catalytic and calmodulin-binding domains. Partial digestion with trypsin produced an intermediate 56,000-dalton fragment and a stable 38,000-dalton fragment, both of which were catalytically active and calmodulin-dependent. Chymotryptic digestion yielded three catalytically active fragments of about 37,000, 36,000, and 35,000 daltons. The Mr = 37,000 fragment was calmodulin-dependent with an apparent affinity equivalent to that of the native enzyme (approximately 1 nM). The 36,000-dalton fragment was also calmodulin-dependent but had a approximately 200-fold lower apparent affinity. The Mr = 35,000 fragment was calmodulin-independent. These three chymotryptic fragments, had identical amino termini. Nineteen residues were missing from the carboxyl terminus of the calmodulin-independent chymotryptic fragment whereas only 8 or 9 carboxyl-terminal residues were missing from the calmodulin-dependent tryptic fragments. These results suggest that the 11-residue sequence (IAVSAANRFKK) in the carboxyl-terminal region of myosin light chain kinase contributes directly to the binding of calmodulin. This conclusion is in accord with data (Blumenthal, D. K., Takio, K., Edelman, A. M., Charbonneau, H., Titani, K., Walsh, K. A., and Krebs, E. G. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 3187-3191) that the carboxyl-terminal, 27-residue CNBr peptide of the native enzyme shows Ca2+-dependent, high affinity binding to calmodulin and that similar calmodulin-binding activity, although detectable in unfractionated CNBr digests of calmodulin-dependent enzyme forms, is much reduced in a CNBr digest of the calmodulin-independent, Mr = 35,000 chymotryptic fragment.     

Isolation and characterization of a heparin-binding domain from the amino terminus of platelet thrombospondin

Calcium-replete thrombospondin has been purified from outdated platelets using heparin-Sepharose affinity chromatography, gelatin-Sepharose to remove fibronectin, and gel filtration to eliminate low-molecular-weight heparin-binding proteins. Edman degradation of six different preparations revealed the amino-terminal sequence of thrombospondin (TSP) to be Asn-Arg-Ile-Pro-Glu-Ser-Gly-Gly-Asp-Asn-Ser-Val-Phe-. This sequence was obtained in initial yields as high as 85%, indicating that no blocked chains are present. Cleavage of calcium-replete TSP with thermolysin or plasmin results in the production of relatively stable fragments. Chromatography of these digests on heparin-Sepharose followed by elution with 0.6 M NaCl affords purification of an Mr 25,000 fragment from the thermolysin digest and an Mr 35,000 fragment from the plasmin digest. The binding of these fragments to heparin-Sepharose does not require divalent metal ions. Neither fragment is disulfide-bonded to other fragments present in the digests. The heparin-binding domains from both digests have similar amino acid compositions and their tryptic peptide maps on high performance liquid chromatography are identical with the exception of one peptide unique to each fragment. Automated Edman degradation in a vapor-phase sequenator of the thermolytic heparin-binding domain electroeluted from sodium dodecyl sulfate-gels indicates that the heparin-binding domain resides at the amino terminus of the Mr 180,000 TSP peptide chain.     

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.     

Identity of the protein cores of the two link proteins from bovine nasal cartilage proteoglycan complex. Localization of their sugar moieties

The cyanogen bromide (CNBr) fragments of the two link proteins (LP) were examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The observed apparent molecular weight difference between LP1 (Mr = 44,500) and LP2 (Mr = 48,500) was the reflect of a molecular weight difference between their NH2-terminal CNBr fragments (Mr = 19,000 and 24,000 for LP1 and LP2, respectively). The latter are glycosylated contrary to the COOH-terminal parts of the molecules. Fluorhydric acid/pyridine treatment suggests that LP1 and LP2 have a protein core of identical size. They differ from their common tryptic fragment (T-G200-3 fraction) by the presence of an additional short peptide. The latter was highly glycosylated in LP2 but not in LP1. Deglycosylation together with CNBr treatment corroborates the hypothesis that LP1 and LP2 possess a similar protein core.     

Structure of alpha-polymer from in vitro and in vivo highly cross-linked human fibrin.

Peptides derived from plasmic and cyanogen bromide (CNBr) cleavage of highly cross-linked fibrin were isolated and characterized by sodium dodecyl sulfate-gel electrophoresis, amino acid analyses, cyanoethylation, and NH2-terminal analyses. Extended plasmic digestions of human fibrin containing four epsilon-(gamma-glutamyl)lysine cross-links per molecule produced a peptide of alpha-chain origin (Mr congruent to 21,000) which was comprised of a small donor peptide cross-linked to the acceptor site peptide from the middle of the alpha-chain. CNBr cleavage of highly cross-linked in vitro fibrin or of fibrin from a spontaneously formed in vivo arterial embolus produced about three cross-linked species of molecular weights 30,000 to 40,000, each of which contained the largest CNBr fragment (Mr = 29,000) from the alpha-chain. The predominant cross-link-containing CNBr fragments derived their donor group from the near COOH-terminal region of the alpha-chain as judged by difference amino acid compositions and NH2-terminal analyses. Additionally, cross-linked fragments of molecular weights 68,000 to 70,000 which appeared to contain two acceptor site peptides (Mr = 29,000) were detected in minor amounts in the CNBr digests of fibrin formed from whole plasma or from purified, plasminogen-free fibrinogen. No larger polymeric cross-linked CNBr fragment was generated from any of the highly cross-linked fibrin preparations examined. A model for the predominant mode of alpha-chain polymerization is proposed.     

An amphiphilic structure of the ninth component of human complement. Evidence from analysis of fragments produced by alpha-thrombin

Purified human C9 was treated separately with three proteolytic enzymes: trypsin, plasmin, and alpha-thrombin, and the digestion products were analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Trypsin initially cleaved the Mr = 71,000 C9 to produce a Mr = 47,000 fragment plus numerous smaller fragments and prolonged digestion reduced the molecule to small polypeptides. Plasmin produced a Mr = 37,000 fragment which was stable to further digestion, plus fragments smaller than Mr = 10,000. Human alpha-thrombin cleaved C9 (7.8% carbohydrate) at a single internal site to produce a Mr = 37,000 fragment (11.3% carbohydrate) and a Mr = 34,000 fragment (3.9% carbohydrate). Statistical analysis of the amino acid compositions of the fragments and alkaline polyacrylamide gel electrophoresis showed that C9 is highly amphiphilic; the Mr = 34,000 fragment contains a majority of the acidic amino acids and migrates rapidly on alkaline gels; the Mr = 37,000 fragment is hydrophobic with a slow electrophoretic mobility. The two fragments remain noncovalently associated, but were separated by sodium dodecyl sulfate-hydroxylapatite chromatography. The NH2-terminal sequence analysis of native C9, of alpha-thrombin-cleaved C9, and for the isolated fragments showed that the acidic Mr = 34,000 fragment is the NH2-terminal C9a domain and the more hydrophobic Mr = 37,000 fragment is the carboxyl-terminal C9b domain. Hemolytic activity of C9 was unaffected by alpha-thrombin cleavage.     

Analysis of the nuclear estrogen receptor from MCF-7 cells by limited proteolysis

The proteolytic fragments of the nuclear estrogen receptor in the MCF-7 cell line were characterized following limited digestion with chymotrypsin and trypsin. Nuclei were isolated from cells previously exposed to 10 nM [3H]estradiol. The proteolytic digestion was performed either on the micrococcal nuclease hydrolysate or on intact nuclei. The molecular weights (Mr) were calculated from the sedimentation coefficients determined on a sucrose gradient and from the Stokes radii estimated by gel filtration. Digestion of the nuclei with micrococcal nuclease solubilized a receptor form of Mr = 151,000. This receptor form was degraded by chymotrypsin to a receptor of Mr = 33,000 and by trypsin to a receptor of Mr = 60,000. Digestion of intact nuclei with chymotrypsin solubilized a receptor form of Mr = 62,000 which dissociated in 0.4 M KCl to a receptor of Mr = 32,000. Digestion of intact nuclei with trypsin followed by micrococcal nuclease solubilized a receptor form of Mr = 75,000 which was further dissociated by 0.4 M KCl to a receptor form of Mr = 60,000. The ability of the receptor forms to bind DNA was tested using DNA-cellulose column chromatography. About 40% of the micrococcal nuclease solubilized receptor form, compared to about 7% of the chymotrypsin degraded receptor and to about 13% of the trypsin degraded receptor forms, all bound to the column and could be eluted by high salt concentrated buffer. We conclude that the nuclear estrogen receptor in the MCF-7 cell line can be partially degraded either in the micrococcal nuclease hydrolysate or in intact nuclei by chymotrypsin or trypsin generating protein moieties, probably receptor fragments of Mr = 33,000 and 60,000 respectively. Both fragments retain their estradiol binding domain and it may be hypothesized that the heavier fragment retains its chromatin binding domain.     

Staphylocoagulase-binding region in human prothrombin

A staphylocoagulase-binding region in human prothrombin was studied by utilizing several fragments prepared from prothrombin by limited proteolysis. Bovine prothrombin, prethrombin 1, prethrombin 2, and human diisopropylphosphorylated alpha-thrombin strongly inhibited formation of the complex ("staphylothrombin") between human prothrombin and staphylocoagulase, but bovine prothrombin fragment 1 and fragment 2 had no effect on the complex formation, indicating that the binding region of human prothrombin for staphylocoagulase is located in the prethrombin 2 molecule. To identify further the staphylocoagulase-binding region, human alpha-thrombin was cleaved into the NH2-terminal large fragment (Mr = 26,000) and the COOH-terminal fragment (Mr = 16,000) by porcine pancreatic elastase. Of these fragments, the COOH-terminal fragment, which includes Asn-200 to the COOH-terminal end of the alpha-thrombin molecule, partially inhibited the complex formation between staphylocoagulase and human prothrombin. In contrast, the NH2-terminal large fragment did not show any inhibitory effect on the staphylothrombin formation. These results suggest that the staphylocoagulase interacts with human prothrombin through the COOH-terminal region of alpha-thrombin B chain. Other plasma proteins, factor X, factor IX, protein C, protein S, protein Z, all of which are structurally similar to prothrombin, did not inhibit the staphylothrombin formation at all, indicating that a specific interaction site with staphylocoagulase is contained only in the prothrombin molecule.     

Phospholipid binding and biophysical activity of pulmonary surfactant-associated protein (SAP)-35 and its non-collagenous COOH-terminal domains

Surfactant-associated protein of Mr = 35,000, SAP-35, is the major glycoprotein present in mammalian pulmonary surfactants. In this study, canine SAP-35 and several of its COOH-terminal peptides were purified and characterized by amino acid composition and NH2-terminal sequencing analysis. These proteins were then studied in terms of their specific lipid-binding characteristics and surface activity when combined with a synthetic phospholipid mixture, SM, chosen as an approximation of lung surfactant phospholipids. Purified, delipidated SAP-35 bound SM strongly. In contrast, SAP-21 (a non-collagenous fragment generated by collagenase digestion) bound phospholipid weakly; SAP-18 (an acidic COOH-terminal fragment comprising residues Gly-118 to Phe-231) did not bind phospholipid, demonstrating the importance of hydrophobic amino acid residues Gly-81 to Val-117 and the NH2-terminal collagenous domain in interaction of the SAP-35 with phospholipids. In surface activity experiments, purified SAP-35 enhanced the adsorption of SM phospholipids in terms of both rate and overall surface tension lowering. However, the adsorption facility of the SM-SAP-35 mixture did not approach that of either whole surfactant or the surfactant extract preparations, calf lung surfactant extract or surfactant-TA, used in exogenous surfactant replacement therapy for the neonatal respiratory distress syndrome. In addition, the dynamic surface activity of the SM-SAP-35 mixture was well below that of natural surfactant or surfactant extracts. This was also true of mixtures of SM phospholipids combined with the SAP-18 and SAP-21 fragments of SAP-35.     

Bovine coagulation factor V visualized with electron microscopy. Ultrastructure of the isolated activated forms and of the activation fragments

Single chain bovine factor V (Mr = 330,000) was isolated and visualized by means of high resolution transmission electron microscopy of negatively stained samples. Both factor Va, activated by thrombin or by the factor V activator from Russell's viper venom, and the isolated fragments, D (Mr = 105,000), C1 (Mr = 150,000), and F1F2 (Mr = 72,000), were studied. Single chain factor V appeared as a multidomain structure with three globular domains of similar size (diameter approximately 80 A), and oriented around a somewhat larger central domain (diameter approximately 140 A). The distance between the center of the molecule and the center of each of the peripheral domains was 120 A and the maximum length of factor V was 300 A. The structure was essentially identical with that recently shown for human single chain factor V (Dahlb?ck, B. (1985) J. Biol. Chem. 260, 1347-1349). Isolated thrombin-activated factor Va (containing fragments D and F1F2) was composed of two domains of similar size, each of which was approximately 80 A in diameter and corresponded in size and shape to the peripheral domains seen in intact factor V. The isolated activation fragment C1 appeared as an irregular structure with an approximate diameter of 140 A and corresponded in size and shape to the larger central domain in intact factor V. The activator from Russell's viper venom only cleaves the bond(s) between C1 and F1F2, which results in two fragments, a larger fragment (Mr = 220,000) bearing the D, E, and C1 region and a smaller one corresponding to the F1F2 fragment. The venom-activated factor Va in the electron microscope demonstrated a multidomain structure similar in size and shape to that obtained with intact factor V. A model for factor V and the molecular events involved in activation is proposed.     

Differential expression of tropomyosin forms in the microfilaments isolated from normal and transformed rat cultured cells

Using a newly developed method for microfilament isolation (Matsumura, F., Yamashiro-Matsumura, S. and Lin, J. J.-C. (1983) J. Biol. Chem. 258, 6636-6644), we have analyzed protein composition of microfilaments in "normal" and transformed rat tissue culture cells. They include REF-52 (an established rat embryo cell line) cells, REF-52 transformed by DNA viruses (SV40 or adenovirus type 5), normal rat kidney cells, and normal rat kidney cells transformed by RNA viruses (Kirsten or Rous sarcoma virus). Microfilaments from normal rat culture cells contain three major tropomyosins (apparent Mr = 40,000, 36,500, and 32,400) and two relatively minor tropomyosins (apparent Mr = 35,000 and 32,000). In transformed cells the levels of one or two of the major tropomyosins (Mr = 40,000 and 36,500) are decreased and the levels of one or both of the minor tropomyosins (Mr = 35,000 and 32,000) are increased. These changes in tropomyosin patterns were also observed in temperature shift experiments with rat-1 cells transformed with a Rous sarcoma virus mutant, temperature-sensitive for transformation. Cell-free translation of whole cell mRNA generated similar tropomyosin patterns on two-dimensional gels, suggesting that changes in the pattern of tropomyosin expression were largely effected at the level of RNA rather than by post-translational modification. Such changes in the tropomyosin composition of microfilaments were consistently found to accompany the various morphological alterations associated with transformation. We suggest that alterations in the pattern of tropomyosin expression are involved in, or cause, rearrangement of stress fibers and that this may be responsible (in part) for morphological transformation.