Analysis of sequences in domain II of Pseudomonas exotoxin A which mediate translocation

Pseudomonas exotoxin (PE) contains 613 amino acids that are arranged into 3 structural domains. PE exerts its cell-killing effects in a series of steps initiated by binding to the cell surface and internalization into endocytic vesicles. The toxin is then cleaved within domain II near arginine-279, generating a C-terminal 37-kDa fragment that is translocated into the cytosol where it ADP-ribosylates elongation factor 2 and arrests protein synthesis. In this study, we have focused on the functions of PE which are encoded by domain II. We have used the chimeric toxin TGF alpha-PE40 to deliver the toxin's ADP-ribosylating activity to the cell cytosol. Deletion analysis revealed that sequences from 253 to 345 were essential for toxicity but sequences from 346 to 364 were dispensable. Additional point mutants were constructed which identified amino acids 339 and 343 as important residues while amino acids 344 and 345 could be altered without loss of cytotoxic activity. Our data support the idea that domain II functions by first allowing PE to be processed to a 37-kDa fragment and then key sequences such as those identified in this study mediate the translocation of ADP-ribosylation activity to the cytosol.     

Cell-mediated cleavage of Pseudomonas exotoxin between Arg279 and Gly280 generates the enzymatically active fragment which translocates to the cytosol.

Pseudomonas exotoxin (PE) is a three-domain toxin which is cleaved by a cellular protease within cells and then reduced to generate two prominent fragments (Ogata, M., Chaudhary, V. K., Pastan, I., and FitzGerald, D. J. (1990) J. Biol. Chem. 265, 20678-20685). The N-terminal fragment is 28 kDa in size and contains the binding domain. The 37-kDa C-terminal fragment, which translocates to the cytosol, contains the translocation domain and the ADP-ribosylation domain. Cleavage followed by reduction is essential for toxicity since mutant forms of the toxin that cannot be cleaved by cells are nontoxic. Previous results with these mutants suggest that cleavage occurred in an arginine-rich (arginine residues are at positions 274, 276, and 279) disulfide loop near the beginning of the translocation domain, but the exact site of cleavage was not determined. Since very few molecules of the 37-kDa fragment are generated within cells it was not possible to determine the site of cleavage by performing a conventional N-terminal sequence analysis of the 37-kDa fragment. Two experimental approaches were used to overcome this limitation. First, existing amino acids near the cleavage sites were replaced with methionine residues; this was followed by the addition of [35S]methionine-labeled versions of these toxins to cells. The pattern of radioactive toxin fragments recovered from the cells indicated that the toxin was cleaved either just before or just after Arg279. Second, [3H]leucine-labeled toxin was produced and added to the cells. Sequential Edman degradations were performed on the small amount of radioactive 37-kDa fragment that could be recovered from toxin-treated cells. A peak of radioactivity in the fifth fraction indicated that leucine was the 5th amino acid on the C-terminal side of the cleavage site. This result confirmed that cleavage was between Arg279 and Gly280.     

A recombinant form of Pseudomonas exotoxin directed at the epidermal growth factor receptor that is cytotoxic without requiring proteolytic processing.

Pseudomonas exotoxin A is composed of three structural domains that mediate cell recognition (I), membrane translocation (II), and ADP-ribosylation (III). Within the cell, the toxin is cleaved within domain II to produce a 37-kDa carboxyl-terminal fragment, containing amino acids 280-613, which is translocated to the cytosol and causes cell death. In this study, we constructed a mutant protein (PE37), composed of amino acids 280-613 of Pseudomonas exotoxin A, which does not require proteolysis to translocate. PE37 was targeted specifically to cells with epidermal growth factor receptors by inserting transforming growth factor-alpha (TGF-alpha) after amino acid 607 near the carboxyl terminus of Pseudomonas exotoxin A. PE37/TGF-alpha was very cytotoxic to cells with epidermal growth factor receptors. It was severalfold more cytotoxic than a derivative of full-length Pseudomonas exotoxin A containing TGF-alpha in the same position, probably because the latter requires intracellular proteolytic processing to exhibit its cytotoxicity, and proteolytic processing is not 100% efficient. Deletion of 2, 4, or 7 amino acids from the amino terminus of PE37/TGF-alpha greatly diminished cytotoxic activity, indicating the need for a proper amino-terminal sequence. In addition, a mutant containing an internal deletion of amino acids 314-380 was minimally active, indicating that other regions of domain II are also required for the cytotoxic activity of Pseudomonas exotoxin A.     

Reduction of furin-nicked Pseudomonas exotoxin A: an unfolding story

Upon entering mammalian cells, Pseudomonas exotoxin A (PE) is proteolytically processed by furin to produce an N-terminal fragment of 28 kDa and a C-terminal fragment of 37 kDa. Cleavage is followed by the reduction of a key disulfide bond (cysteines 265-287). This combination of proteolysis and reduction releases the 37 kDa C-terminal fragment, which then translocates to the cytosol where it ADP-ribosylates elongation factor 2 and inhibits protein synthesis. To investigate toxin reduction, furin-nicked PE or a hypercleavable mutant, PEW281A, was subjected to various treatments and then analyzed for fragment production. Reduction was evident only when unfolding conditions and a reducing agent were applied. Thermal unfolding of PE, as evidenced by changes in alpha-helical content and increased sensitivity to trypsin, rendered nicked toxin susceptible to protein disulfide isomerase- (PDI-) mediated reduction. When subcellular fractions from toxin-sensitive cells were incubated with nicked PE, toxin unfolding and reducing activities were present in the membrane fraction but not the soluble fraction. These data indicate that PE reduction is a two-step process: unfolding that allows access to the Cys265-287 disulfide bond, followed by reduction of the sulfur-sulfur bond by PDI or a PDI-like enzyme. With regard to cellular processing, we propose that the toxin's three-dimensional structure retains a "closed" conformation that restricts solvent access to the Cys265-287 disulfide bond until after a cell-mediated unfolding event.     

Functional analysis of two processed fragments of Bacillus thuringiensis Cry11A toxin

The 70-kDa protoxin of Cry11A, a dipteran-specific insecticidal protein, was processed by trypsin into 36- and 32-kDa fragments. To investigate the potent function of the two processed fragments, a GST (Glutathione-S-transferase) fusion protein of each polypeptide was constructed. While neither the 36- nor the 32-kDa fragment was toxic to Culex pipiens larvae, coexpression of the two fragments restored the insecticidal activity. Furthermore, the coprecipitation experiment demonstrated that the 36-kDa fragment was associated with the 32-kDa fragment. It was, therefore, shown that the coexistence of the two processed fragments of Cry11A was essential for the toxicity. The mutant of the 36-kDa fragment lacking the region from Gly(257) to Arg(360) bound to the 32-kDa fragment but the coexpression with the 32-kDa fragment resulted in no toxicity, suggesting that this region was involved in insecticidal activity.     

Localization of phosphorylation sites with respect to the functional domains of the mouse L cell glucocorticoid receptor

Digestion of the rat liver glucocorticoid receptor with chymotrypsin results in the generation of a 42-kDa fragment which contains the steroid-binding and DNA-binding domains and the antigenic site for the BuGR anti-glucocorticoid receptor monoclonal antibody, while digestion with trypsin generates a 15-kDa receptor fragment containing only the DNA-binding function and the BuGR epitope (Eisen, L.P., Reichman, M.E., Thompson, E.B., Gametchu, B., Harrison, R. W., and Eisen, H.J. (1985) J. Biol. Chem. 260, 11805-11810). In this paper, glucocorticoid receptor of mouse L cells that were grown in the presence of [32P]orthophosphate was digested with trypsin or chymotrypsin (either before or after immune purification with BuGR antibody) and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, autoradiography, and Western blotting. The receptor is endogenously phosphorylated only on serine residues. Chymotrypsin digestion results in a 32P-labeled 42-kDa receptor fragment which contains steroid-binding, DNA-binding, and BuGR-reactive sites. Trypsin digestion generates a 27-kDa steroid-bound fragment (meroreceptor) which is not labeled with 32P and a 32P-labeled 15-kDa fragment which contains both the DNA-binding domain and the BuGR epitope. We have calculated that there are 4 times as many phosphate residues in the intact receptor than in the 42-kDa chymotrypsin fragment. From examination of 32P-labeled receptor fragments, we have deduced that one phosphate is located between amino acids 398 and 447, a region containing the BuGR epitope and about one-third of the DNA-binding domain, and the remaining three phosphates appear to be clustered just to the amino-terminal side of the BuGR epitope in a region defined by amino acids 313 to 369. Treatment of intact 32P-labeled receptor in cytosol with alkaline phosphatase removes these three phosphates, but it does not remove the phosphate from the DNA-binding-BuGR-reactive fragment and it does not affect the ability of the transformed receptor to bind to DNA-cellulose.     

Immunochemical detection of unique proteolytic fragments of the chick 1,25-dihydroxyvitamin D3 receptor. Distinct 20-kDa DNA-binding and 45-kDa hormone-binding species

We have characterized proteolytic fragments of the chick intestinal 1,25-dihyroxyvitamin D3 (1,25-(OH)2D3) receptor, produced through either exogenous or endogenous protease action, utilizing a variety of physical and functional assays coupled to immunoblot detection methodology. Treatment of intestinal cytosol with increasing concentrations of trypsin resulted in a progressive diminishment of the 60-kDa receptor concomitant with the appearance of a 20-kDa fragment reactive by Western blot analysis to an anti-1,25-(OH)2D3 receptor monoclonal antibody. Cleveland analysis supported the receptor-origin of this 20-kDa fragment: a common immunoreactive species of 12 kDa could be generated by Staphylococcus aureus V8 protease treatment of the intact 60-kDa receptor as well as the 20-kDa proteolytic product. The 20-kDa fragment did not bind hormone but was capable of interacting with DNA-cellulose in a fashion identical to that of the 60-kDa receptor and, therefore, may contain the functional DNA-binding domain of the chick 1,25-(OH)2D3 receptor. Thus, this fragment likely represents the complement of a larger hormone-bound fragment that we have previously described (Allegretto, E. A., and Pike, J.W. (1985) J. Biol. Chem. 260, 10139-10145). In contrast to the exogenous effect of trypsin, incubation of cytosol resulted in the time-dependent formation of an endogenous protease-derived fragment of 45 kDa. Cleveland analysis was consistent with the 60-kDa receptor derivation of the 45-kDa fragment. This species retained the hormone-binding site and the antibody determinant but was devoid of DNA-binding activity. Moreover, it generated neither the trypsin-dependent 20-kDa fragment nor the V8 protease-dependent 12-kDa species and, therefore, was derived from the opposite end of the receptor molecule. These data have facilitated the construction of a schematic model of the chick receptor in which the immunoreactive epitope is located between the functional domains for hormone binding and DNA binding.     

Cellular uptake of Clostridium difficile toxin B. Translocation of the N-terminal catalytic domain into the cytosol of eukaryotic cells

Clostridium difficile toxin B (269 kDa) is one of the causative agents of antibiotic-associated diarrhea and pseudomembranous colitis. Toxin B acts in the cytosol of eukaryotic target cells where it inactivates Rho GTPases by monoglucosylation. The catalytic domain of toxin B is located at the N terminus (amino acid residues 1-546). The C-terminal and the middle region of the toxin seem to be involved in receptor binding and translocation. Here we studied whether the full-length toxin or only a part of the holotoxin is translocated into the cytosol. Vero cells were treated with recombinant glutathione S-transferase-toxin B, and thereafter, toxin B fragments were isolated by affinity precipitation of the glutathione S-transferase-tagged protein from the cytosolic fraction of intoxicated cells. The toxin fragment (approximately 65 kDa) was recognized by an antibody against the N terminus of toxin B and was identified by matrix-assisted laser desorption ionization time-of-flight mass spectrometry analysis as the catalytic domain of toxin B. The toxin fragment located in the cytosol possessed glucosyltransferase activity that could modify RhoA in vitro, but it was not able to intoxicate intact cells. After treatment of Vero cells with a radiolabeled fragment of toxin B (amino acid residues 547-2366), radioactivity was identified in the membrane fraction of Vero cells but not in the cytosolic fraction of Vero cells. Furthermore, analysis of cells by fluorescence microscopy revealed that the C terminus of toxin B was located in endosomes, whereas the N terminus was detected in the cytosol. Protease inhibitors, which were added to the cell medium, delayed intoxication of cells by toxin B and pH-dependent translocation of the toxin from the cell surface across the cell membrane. The data indicate that toxin B is proteolytically processed during its cellular uptake process.     

Turnover of the transferrin receptor is not influenced by removing most of the extracellular domain

We treated intact cells with trypsin to remove most of the external domain of the transferrin receptor and investigated what effect the absence of the external domain had on the turnover of the fragment that remained associated with the cells. To detect the cell-associated tryptic fragment, which contains a small amount of the external domain, the transmembrane domain, and the cytoplasmic domain, we prepared an anti-peptide antibody against a segment of the cytoplasmic domain. This antibody specifically immunoprecipitated the intact transferrin receptor as well as a 21-kDa peptide from trypsin-treated HeLa cells. Several lines of evidence indicated that the 21-kDa peptide was the cell-associated tryptic fragment of the transferrin receptor. The fragment was only present in trypsin-treated cells; the fragment migrated as a dimer in nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis, as it should if it were derived from the transferrin receptor; a goat antibody prepared to the purified human transferrin receptor also precipitated the 21-kDa peptide from trypsinized cells. In addition, treating the tryptic fragment with neuraminidase increased the electrophoretic mobility in sodium dodecyl sulfate-polyacrylamide gels, suggesting the fragment contained O-linked carbohydrate. When cells were trypsinized and then incubated at 37 degrees C, the half-life of the tryptic fragment (15 +/- 4 h) was not significantly different than the half-life of the intact receptor (19 +/- 6 h). This indicates that removing 95% of the external domain of the transferrin receptor has little effect on processes operating in the turnover of the receptor.     

Latent fibronectin-degrading serine proteinase activity in N-terminal heparin-binding domain of human plasma fibronectin

The N-terminal 70-kDa fragment of human plasma fibronectin, purified from a cathepsin D digest, is characterized by lack of stability. It is processed proteolytically during incubation in the presence of Ca2+ into 27-kDa N-terminal heparin-binding and 45-kDa collagen-binding domains. The N-terminal residue in the 27-kDa fragment was blocked as in native fibronectin. The 45-kDa fragments began with the sequences AAVYQP, AVYQP and VYQP (residues 260, 261, 262-265 of fibronectin) that correspond to the beginning of the collagen-binding domain. In the presence of Ca2+ the purified 27-kDa fragment underwent further processing finally leading to the cleavage of the bond K85-D86 and to the simultaneous appearance of a specific proteolytic activity. Inhibition studies suggests that the newly generated enzyme is a Ca(2+)-dependent serine proteinase. Among all assayed matrix proteins, the newly generated enzyme cleaves native fibronectin and its fragments. It is proposed that this fibronectinase may originate from the N-terminal domain of fibronectin.     

Thrombin cleavage analysis of a novel antihaemophilic factor variant, factor VIII delta II

Factor VIII delta II is a genetically engineered deletion variant of factor VIII expressed by recombinant Chinese hamster ovary cells, in which a major portion of the central (B) domain and a part of the light chain (Pro771-Asp1666) are missing. After immunoaffinity purification, the kinetics of thrombin cleavage of the novel molecule was analysed by SDS/PAGE, Western blotting and N-terminal amino acid sequencing. Thrombin first cleaves factor VIII delta II at Arg740-Ser741 to generate the 90-kDa heavy chain and an 80-kDa fusion polypeptide consisting of the remaining portion of the B domain and the 73-kDa light chain. The 90-kDa fragment is further cleaved, giving rise to 50-kDa and 40-kDa fragments while the 80-kDa fragment generates a 71/73-kDa doublet. The 71/73-kDa doublet, 50-kDa and 40-kDa fragments were further analysed by N-terminal amino acid sequencing and found to correspond to the predicted amino acid sequences. Our study shows that, in spite of the 900 amino acid deletion present in factor VIII delta II, the essential structural elements required for thrombin activation are conserved.     

Production of chymotrypsin-resistant Bacillus thuringiensis Cry2Aa1 delta-endotoxin by protein engineering.

Cleavage of the Cry2Aa1 protoxin (molecular mass, 63 kDa) from Bacillus thuringiensis by midgut juice of gypsy moth (Lymantria dispar) larvae resulted in two major protein fragments: a 58-kDa fragment which was highly toxic to the insect and a 49-kDa fragment which was not toxic. In the midgut juice, the protoxin was processed into a 58-kDa toxin within 1 min, but after digestion for 1 h, the 58-kDa fragment was further cleaved within domain I, resulting in the protease-resistant 49-kDa fragment. Both the 58-kDa and nontoxic 49-kDa fragments were also found in vivo when (125)I-labeled toxin was fed to the insects. N-terminal sequencing revealed that the protease cleavage sites are at the C termini of Tyr49 and Leu144 for the active fragment and the smaller fragment, respectively. To prevent the production of the nontoxic fragment during midgut processing, five mutant proteins were constructed by replacing Leu144 of the toxin with Asp (L144D), Ala (L144A), Gly (L144G), His (L144H), or Val (L144V) by using a pair of complementary mutagenic oligonucleotides in PCR. All of the mutant proteins were highly resistant to the midgut proteases and chymotrypsin. Digestion of the mutant proteins by insect midgut extract and chymotrypsin produced only the active 58-kDa fragment, except that L144H was partially cleaved at residue 144.     

Adipocyte insulin receptor. Generation of a cryptic domain of the alpha-subunit during internalization of hormone-receptor complexes.

The dynamics of the internalization of photoaffinity-labelled insulin-receptor complexes was investigated in isolated rat adipocytes by using tryptic proteolysis to probe both the orientation and cellular location of the labelled complexes. In cells that were labelled at 16 degrees C and not prewarmed, 150 micrograms of trypsin/ml rapidly degraded the labelled 125 kDa insulin-receptor subunit into a major proteolytic fragment of 70 kDa and minor amounts of 90- and 50-kDa fragments. With milder trypsin treatment conditions (100 micrograms of trypsin/ml, 15 s at 37 degrees C), the 90 kDa peptide (different from the 90 kDa beta-subunit of the insulin receptor) appeared as a major intermediate proteolytic product, but this species was rapidly and completely converted into the 70- and 50-kDa fragments with continued exposure to trypsin, such that it did not accumulate to appreciable amounts in cells that were not prewarmed before trypsin exposure. By contrast, trypsin treatment of cells prewarmed to 37 degrees C for various times showed that: first, a proportion of the labelled 125 kDa receptors was internalized (became trypsin-insensitive); secondly, the 90 kDa tryptic peptide was formed in large amounts, with proportionate decreases occurring in the amounts of the 70- and 50-kDa tryptic peptides. The increased accumulation of the 90 kDa tryptic peptide from cells preincubated at 37 degrees C, but not at 16 degrees C, indicated that trypsin cleavage sites within the 90 kDa segment of the insulin-receptor alpha-subunit that were exposed at 16 degrees C were made inaccessible by incubation at 37 degrees C, a finding that is consistent with generation of a cryptic domain of the receptor subunit. The tryptic generation of the 90 kDa peptide at 37 degrees C was rapid, becoming half-maximal in 4.4 +/- 0.6 min and maximal in 15-20 min, preceded the intracellular accumulation of labelled receptors (half-maximal in 12.6 +/- 0.7 min and maximal in 30-40 min), was highly correlated with receptor internalization, and was not observed in cultured IM-9 lymphocytes, a cell line in which photolabelled insulin receptors are primarily lost by shedding into the incubation media. These results show that, in adipocytes incubated at 37 degrees C, rapid masking of a previously (at 16 degrees C) accessible domain of the insulin-receptor alpha-subunit occurs and that this dynamic process happens at an early stage in the internalization of insulin-receptor complexes.     

Coordinate induction of collagenase-1, stromelysin-1 and urokinase plasminogen activator (uPA) by the 120-kDa cell-binding fibronectin fragment in fibrocartilaginous cells: uPA contributes to activation of procollagenase-1.

Specific fibronectin (Fn) fragments found in synovial fluid of arthritic joints potentially contribute to the loss of cartilage proteoglycans by inducing matrix metalloproteinase (MMP) expression. However, whether or not the Fn fragment-modulated changes in expression of MMPs result in a net increase in matrix-degradative activity through alterations in the balance between MMP activation and inhibition has not been established. To understand the mechanisms by which proteolytic Fn fragments may contribute to joint degeneration, conditioned medium from fibrocartilaginous cells exposed to Fn, its 30-kDa fragment containing the collagen/gelatin-binding domain, its 120-kDa fragment containing the central cell-binding domain, and the RGD peptide were assayed for MMPs, and MMP activators and inhibitors. We found that the 120-kDa fragment of Fn (but not intact Fn), the 30-kDa fragment, and the RGD peptide, dose-dependently induced procollagenase-1 and prostromelysin-1 and decreased levels of the tissue inhibitor of metalloproteinases (TIMPs) -1 and -2. The alpha5beta1 integrin was implicated in the induction of collagenase by the 120-kDa Fn fragment, since collagenase induction was abrogated in the presence of blocking antibody to this integrin. Conditioned medium from cells exposed to the 120-kDa Fn fragment also demonstrated increased levels of the activated collagenase-1, which resulted in significantly elevated collagen degradative activity. That the urokinase plasminogen activator (uPA) was involved in the activation of procollagenase-1 was suggested by findings that the 120-kDa Fn fragment induced uPA coordinately with procollagenase-1, and the activation of procollagenase-1 was dose-dependently inhibited in the presence of plasminogen activator inhibitor-1. These data demonstrate that the 120-kDa cell-binding fragment of Fn induces a net increase in matrix-degradative activity in fibrocartilaginous cells by concomitantly inducing MMPs and their activator, uPA, while decreasing TIMPs.     

A Ca2+-dependent tryptic cleavage site and a protein kinase A phosphorylation site are present in the Ca2+ regulatory domain of scallop muscle Na+-Ca2+ exchanger

Digestion of scallop muscle membrane fractions with trypsin led to release of soluble polypeptides derived from the large cytoplasmic domain of a Na(+)-Ca(2+) exchanger. In the presence of 1 mm Ca(2+), the major product was a peptide of approximately 37 kDa, with an N terminus corresponding to residue 401 of the NCX1 exchanger. In the presence of 10 mm EGTA, approximately 16- and approximately 19-kDa peptides were the major products. Polyclonal rabbit IgG raised against the 37-kDa peptide also bound to the 16- and 19-kDa soluble tryptic peptides and to a 105-110-kDa polypeptide in the undigested membrane preparation. The 16-kDa fragment corresponded to the N-terminal part of the 37-kDa peptide. The conformation of the precursor polypeptide chain in the region of the C terminus of the 16-kDa tryptic peptide was thus altered by the binding of Ca(2+). Phosphorylation of the parent membranes with the catalytic subunit of protein kinase A and [gamma-(32)P]ATP led to incorporation of (32)P into the 16- and 37-kDa soluble fragments. A site may exist within the Ca(2+) regulatory domain of a scallop muscle Na(+)-Ca(2+) exchanger that mediates direct modulation of secondary Ca(2+) regulation by cAMP.     

Production of Chymotrypsin-Resistant Bacillus thuringiensis Cry2Aa1 δ-Endotoxin by Protein Engineering

Cleavage of the Cry2Aa1 protoxin (molecular mass, 63 kDa) from Bacillus thuringiensis by midgut juice of gypsy moth (Lymantria dispar) larvae resulted in two major protein fragments: a 58-kDa fragment which was highly toxic to the insect and a 49-kDa fragment which was not toxic. In the midgut juice, the protoxin was processed into a 58-kDa toxin within 1 min, but after digestion for 1 h, the 58-kDa fragment was further cleaved within domain I, resulting in the protease-resistant 49-kDa fragment. Both the 58-kDa and nontoxic 49-kDa fragments were also found in vivo when ¹²⁵I-labeled toxin was fed to the insects. N-terminal sequencing revealed that the protease cleavage sites are at the C termini of Tyr49 and Leu144 for the active fragment and the smaller fragment, respectively. To prevent the production of the nontoxic fragment during midgut processing, five mutant proteins were constructed by replacing Leu144 of the toxin with Asp (L144D), Ala (L144A), Gly (L144G), His (L144H), or Val (L144V) by using a pair of complementary mutagenic oligonucleotides in PCR. All of the mutant proteins were highly resistant to the midgut proteases and chymotrypsin. Digestion of the mutant proteins by insect midgut extract and chymotrypsin produced only the active 58-kDa fragment, except that L144H was partially cleaved at residue 144.     

Cell-binding domain of endothelial cell thrombospondin: localization to the 70-kDa core fragment and determination of binding characteristics.

Endothelial and other cell types synthesize thrombospondin (TSP), secrete it into their culture medium, and incorporate it into their extracellular matrix. TSP is a large multifunctional protein capable of specific interactions with other matrix components, as well as with cell surfaces, and can modulate cell adhesion to the extracellular matrix. With the aim of understanding the mechanism by which TSP exerts its effect on cell adhesion, we studied the interaction of endothelial cell TSP (EC-TSP) with three different cell types: endothelial cells, granulosa cells, and myoblasts. We find that endothelial cells specifically bind radiolabeled EC-TSP with a Kd of 25 nM, and the number of binding sites is 2.6 X 10(6)/cell. Binding is not inhibitable by the cell-adhesion peptide GRGDS, indicating that the cell-binding site of EC-TSP is not in the RGD-containing domain. Localization of the cell-binding site was achieved by testing two chymotryptic fragments representing different regions of the TSP molecule, the 70-kDa core fragment and the 27-kDa N-terminal fragment, for their ability to bind to the cells. Cell-binding capacity was demonstrated by the 70-kDa fragment but not by the 27-kDa fragment. Binding of both intact [125I]EC-TSP and of the 125I-labeled 70-kDa fragment was inhibited by unlabeled TSP, heparin, fibronectin (FN), monoclonal anti-TSP antibody directed against the 70-kDa fragment (B7-3), and by full serum, but not by heparin-absorbed serum or the cell-adhesion peptide GRGDS. The 70-kDa fragment binds to endothelial cells with a Kd of 47 nM, and the number of binding sites is 5.0 x 10(6)/cell.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for a cryptic lectin site in the cell-binding domain of plasma fibronectin

Various proteolytic fragments from the central region of the fibronectin subunit chains containing the main cell-affinity site were applied in cell binding studies using peritoneal macrophages of guinea pigs. A 125I-labelled 23-kDa peptide was relatively well bound by the cells. Attachment to cells was partially inhibited by wheat germ lectin, suggesting a lectin-like site in the cell-binding domain which recognizes oligosaccharide groups with terminal N-acetylglucosamine or N-acetylneuraminic acid. Binding was inhibited by N-acetylneuraminic acid with half-maximal effect at 2 X 10(-3) M. Other inhibitors were a sialic acid rich ganglioside preparation and fetuin, a sialic acid-containing glycoprotein. In contrast to the 23-kDa peptide a 125I-labelled 125-kDa fragment was only weakly bound, although it included the sequence of the 23-kDa peptide on its C-terminus. The residual binding was weakly inhibited by low concentrations of wheat germ lectin and was remarkably improved by higher concentrations. The behavior of the peptide was explained by the presence of a sialic acid-containing oligosaccharide side chain localized outside of the 23-kDa region and interacting with the lectin-like site in the cell-binding sequence. In accord with this suggestion a 95-kDa fragment representing the oligosaccharide-containing part of the 125-kDa peptide was capable of inhibiting at least partially the cell attachment of the 23-kDa piece. The results indicate a lectin-like affinity site in the cell-binding region of fibronectin which is accessible in the 23-kDa peptide, but is masked in the 125-kDa fragment and in fibronectin by a sialic acid-containing oligosaccharide moiety.     

Structural relationships of the three stimulatory factors of RNA polymerase II from Ehrlich ascites tumor cells

The structural relationships of S-II, S-II', and S-I(b) stimulatory proteins of RNA polymerase II purified from Ehrlich ascites tumor cells were investigated. From analysis of the amino acid compositions and tryptic peptide maps of these proteins labeled with radioiodinated Bolton-Hunter reagent, it was concluded that S-I(b) is a part of S-II located at either the amino- or carboxyl-terminal and that only this region mainly contains radioiodinatable amino acid residues when labeled using 125I. On chymotryptic digestion, S-II was cleaved to 21- and 18-kDa fragments in the presence of DNA. The 21-kDa fragment was found to be sufficient for stimulation of RNA polymerase II. It was suggested that S-II' is formed by phosphorylation of S-II in the domain containing the 18-kDa fragment.     

Mammalian DNA polymerase beta: characterization of a 16-kDa transdomain fragment containing the nucleic acid-binding activities of the native enzyme.

The 39-kDa DNA polymerase beta (beta-Pol) molecule can be readily converted into two constituent domains by mild proteolysis; these domains are represented in an 8-kDa N-terminal fragment and a 31-kDa C-terminal fragment [Kumar et al. (1990a) J. Biol. Chem. 265, 2124-2131]. Intact beta-Pol is a sequence-nonspecific nucleic acid-interactive protein that binds both double-stranded (ds) and single-stranded (ss) polynucleotides. These two activities appear to be contributed by separate portions of the enzyme, since the 31-kDa domain binds ds DNA but not ss DNA, and conversely, the 8-kDa domain binds ss DNA but not ds DNA [Casas-Finet et al. (1991) J. Biol. Chem. 266, 19618-19625]. Truncation of the 31-kDa domain at the N-terminus with chymotrypsin, to produce a 27-kDa fragment (residues 140-334), eliminated all DNA-binding activity. This suggested that the ds DNA-binding capacity of the 31-kDa domain may be carried in the N-terminal segment of the 31-kDa domain. We used CNBr to prepare a 16-kDa fragment (residues 18-154) that spans the ss DNA-binding region of the 8-kDa domain along with the N-terminal portion of the 31-kDa domain. The purified 16-kDa fragment was found to have both ss and ds polynucleotide-binding capacity. Thermodynamic binding properties for these activities are similar to those of the intact enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)