A collagen/gelatin-binding decapeptide derived from bovine propolypeptide of von Willebrand factor.

Propolypeptide of von Willebrand factor (pp-vWF) binds to type I collagen, and we have reported that a binding domain exists in a 21.5/21-kDa fragment originated from the C-terminal portion [Takagi, J., Fujisawa, T., Sekiya, F., & Saito, Y. (1991) J. Biol. Chem. 266, 5575-5579]. The collagen-binding property of the 21.5/21-kDa fragment was compared with that of the intact pp-vWF. Although pp-v WF preferentially binds to native type I collagen fibrils, the isolated fragment no longer has this specificity and binds well to collagen of other types in the native and heat-denatured states. In order to determine the critical site that mediates this collagen/gelatin binding, several peptides were synthesized based on the primary structure of the 21.5/21-kDa fragment. Among these, a 25-residue peptide strongly inhibited the binding of the 125I-labeled 21.5/21-kDa fragment to collagen. Using this inhibitory effect as an index, the binding site was defined to the sequence as follows: WREPSFCALS. Furthermore, a decapeptide of this sequence bound to collagen and gelatin, indicating that this sequence is responsible for the binding of the 21.5/21-kDa fragment to collagen/gelatin.     

Use of recombinant and synthetic peptides as attachment factors for cells on microcarriers

Polystyrene culture dishes and polystyrene microcarriers were coated with Pronectin-F and poly-l-lysine (polylysine), either alone or in combination. Pronectin-F is a recombinant peptide containing repeats of the RGD cell-attachment sequence from fibronectin. Polylysine is a polymer ofl-lysine. Pronectin-F supported attachment of Madin-Darby Canine Kidney (MDCK) cells at concentrations as low as 0.025 g/cm² of surface area. The cells rapidly spread after attachment. Polylysine at concentrations of 0.05–0.5 g/cm² also supported cell attachment but cells did not rapidly spread after attachment to this substrate. Higher concentrations of polylysine could not be used because of toxicity. When the two peptides were used in conjunction, MDCK cells attached and spread at lower peptide concentrations than they did when either substrate was used alone. These findings suggest that recombinant Pronectin-F alone or in conjunction with a cationic polymer could be a useful replacement for materials such as gelatin or collagen which are currently used as microcarrier surfaces.     

The identification and characterization of collagen receptors involved in HeLa cell-substratum adhesion

Four proteins of molecular mass 102, 87, 45, and 38 kDa were isolated from plasma membrane preparations by affinity chromatography. The 102-, 87-, and 38-kDa proteins were shown to be collagen receptors involved in the adhesion of HeLa cells to a gelatin substratum. All four proteins were eluted by high salt from affinity columns made of either types I or IV collagen or type I gelatin. Generally, a total of six major proteins were found in the high salt eluates, although the relative amounts of each varied among experiments. Immunoprecipitation, immunoblotting, and limited peptide mapping indicated that the 102-kDa protein was most sensitive to proteolysis leading to the formation of proteins of molecular mass 58 and 54 kDa. Even in the presence of a mixture of protease inhibitors the 58-kDa fragment was usually the more abundant species. Lectin binding indicated that the 102-, 87-, and 38-kDa proteins contain carbohydrate. Phase-partitioning with Triton X-114 and the need to solubilize the proteins in Triton X-100 indicated that the 102-, 87-, 45-, and 38-kDa proteins have a hydrophobic domain. The 87-kDa protein partitioned exclusively with the detergent-rich phase, suggesting that it is the most hydrophobic. Cell surface labeling with 125I indicated that the four proteins have an extracellular domain. Four criteria were used to determine which of the four proteins are collagen receptors mediating cell-substrate adhesion: 1) during HeLa cell adhesion, proteins with Mr values similar to all four proteins or their peptide fragments were cross-linked to a gelatin substratum derivatized with a photoactivatable probe; 2) a pentapeptide containing the Arg-Gly-Asp cell recognition sequence eluted the same four proteins as those found by high salt elution of collagen affinity columns; 3) monospecific antibodies to the 102-, 87-, and 38-kDa proteins, but not the 45-kDa protein, inhibited the spreading of HeLa cells on a gelatin substratum; 4) monospecific antibodies to the 102-, 87-, and 38-kDa proteins, but not the 45-kDa protein, bound to culture dishes substituted for gelatin in mediating the spreading of HeLa cells. Taken together, the data suggest that the 102-, 87-, and 38-kDa proteins are collagen receptors involved in HeLa cell adhesion. Although the 45-kDa protein has two of the characteristics of a collagen receptor defined here, it does not fit the criteria for one involved in cell-substratum adhesion.     

Collagen binding properties of the membrane type-1 matrix metalloproteinase (MT1-MMP) hemopexin C domain. The ectodomain of the 44-kDa autocatalytic product of MT1-MMP inhibits cell invasion by disrupting native type I collagen cleavage

Up-regulation of the collagenolytic membrane type-1 matrix metalloproteinase (MT1-MMP) leads to increased MMP2 (gelatinase A) activation and MT1-MMP autolysis. The autocatalytic degradation product is a cell surface 44-kDa fragment of MT1-MMP (Gly(285)-Val(582)) in which the ectodomain consists of only the linker, hemopexin C domain and the stalk segment found before the transmembrane sequence. In the collagenases, hemopexin C domain exosites bind native collagen, which is required for triple helicase activity during collagen cleavage. Here we investigated the collagen binding properties and the role of the hemopexin C domain of MT1-MMP and of the 44-kDa MT1-MMP ectodomain in collagenolysis. Recombinant proteins, MT1-LCD (Gly(285)-Cys(508)), consisting of the linker and the hemopexin C domain, and MT1-CD (Gly(315)-Cys(508)), which consists of the hemopexin C domain only, were found to bind native type I collagen but not gelatin. Functionally, MT1-LCD inhibited collagen-induced MMP2 activation in fibroblasts, suggesting that interactions between collagen and endogenous MT1-MMP directly stimulate the cellular activation of pro-MMP2. MT1-LCD, but not MT1-CD, also blocked the cleavage of native type I collagen by MT1-MMP in vitro, indicating an important role for the MT1-MMP linker region in triple helicase activity. Similarly, soluble MT1-LCD, but not MT1-CD or peptide analogs of the MT1-MMP linker, reduced the invasion of type I collagen matrices by MDA-MB-231 cells as did the expression of recombinant 44-kDa MT1-MMP on the cell surface. Together, these studies demonstrate that generation of the 44-kDa MT1-MMP autolysis product regulates collagenolytic activity and subsequent invasive potential, suggesting a novel feedback mechanism for the control of pericellular proteolysis.     

Mg2+ mediates the cell-substratum interaction of Arg-Gly-Asp-dependent HeLa cell collagen receptors

Three HeLa cell surface collagen receptors of apparent molecular mass 102/58, 87, and 38/33 kDa were eluted from gelatin-Sepharose with salt gradients or Arg-Gly-Asp-containing peptides. To understand how the collagen receptors are involved in HeLa cell spreading on collagen we investigated the effects of divalent cations and Arg-Gly-Asp-containing peptides on adhesion to gelatin, since HeLa cells behave similarly on both native type I collagen and gelatin substrata and also whether Arg-Gly-Asp-containing substrata would substitute for gelatin in facilitating cell spreading. Gly-Arg-Gly-Asp-Ser-containing peptides in solution inhibited HeLa cell spreading onto gelatin and promoted only partial HeLa cell spreading when bound to tissue culture plastic. Both partial spreading of HeLa cells on the Gly-Arg-Gly-Asp-Ser substratum and full spreading on gelatin was dependent on Mg2+, but not on Ca2+. Binding of the 102/58-, 87-, and 38/33-kDa collagen receptors to gelatin-Sepharose was increased fourfold in the presence of Mg2+, and subsequent elution of the collagen receptors and a 45-kDa collagen-binding protein not thought to be involved in HeLa cell spreading was achieved with EDTA. In contrast, affinity chromatography on Gly-Arg-Gly-Asp-Ser-Sepharose eluted predominantly the 45-kDa collagen-binding protein and the 38/33-kDa collagen receptor. In summary, the Mg2(+)-dependent interaction of the collagen receptors with the Arg-Gly-Asp sequence in collagen appears to be essential for the initial events in HeLa cell spreading but is not sufficient for full cell spreading.     

The effect of a collagen tripeptide fragment (GER) on fibroblast adhesion and spreading depends on properties of an adhesive surface

The effect of collagen tripeptide fragment GER on the adhesion and spreading of mouse embryonic fibroblasts STO to different substrates (polystyrene plastic, poly-L-lysine, fibronectin, gelatin) has been studied. It was found that tripeptide GER was involved in fibroblast adhesion and spreading. The cell response depended both on the mode of tripeptide addition to culture medium and the substrate type. Coincubation of fibroblasts with tripeptide stimulated the cell attachment and spreading to untreated plastic and plastic coated with fibronectin or gelatin but did not change cell adhesion to immobilized poly-L-lysine. Preincubation of cells with tripeptide resulted in partial inhibition of fibroblast adhesion and spreading on fibronectin- and gelatin-coated substrata. It was shown that activation and inhibition of adhesive processes after tripeptide treating was higher on fibronectin than gelatin. The data obtained support the assumption about concerted action of tripeptide GER (activity was dependent both on the used concentration of the tripeptide and the mode of tripeptide addition to culture medium) and chemical characteristics of substrate (polymers of styrene and L-lysine, ECM proteins in native (fibronectin) or partly denatured (gelatin) form) on the cell adhesion and spreading. The main targets that GER peptide may affect during the formation of cell-substrate interactions are discussed.     

Cell-surface charge and cell-surface hydrophobicity of collagen-bindingAeromonas andVibrio strains

Partitioning in aqueous polymer two-phase systems of polyethylene glycol and dextran was used to detect and compare cell-surface charge and cell-surface hydrophobicity of Aeromonas hydrophila, A. caviae, A. sobria, Vibrio cholerae, and V. anguillarum strains. These strains have cell-surface components that bound either native or thermally denatured type I collagen (i.e., a mixture of the α1+α2 chains) and gelatin immobilized on latex beads. Our goals were: (1) to compare the possible relationship between the cell-surface charge/hydrophobicity and binding to collagen and (2) to evaluate the influence of the culture media on the expression of surface properties. There was no apparent relationship between cell-surface charge, cell-surface hydrophobicity, and binding to collagen. The expression of surface properties was dependent on the culture media. There was no relationship between binding to immobilized collagen and binding to soluble ¹²⁵I-labeled collagen. Particle-agglutination reactivity differed when using various collagen-coated microbead preparations. There were general differences in the particle-agglutination reactivity when collagen-coated latex beads were prepared using different coating procedures. The negative charge and hydrophobicity of the various collagen-coated microbead preparations were also studied by partitioning in the two-phase system of polyethylene glycol and dextran. Under these conditions, the α1+α2 collagen-chain mixture covalently immobilized on carboxy-modified latex beads was less hydrophobic and negatively charged than gelatin and native collagen immobilized on the same kind of latex beads. For latex beads passively coated with collagen preparations, the α1+α2 collagen-chain mixture was more hydrophobic than gelatin and native collagen. We suggest that for screening collagen-binding among Vibrio and Aeromonas strains, a reliable and sensitive particle-agglutination assay should consider the collagen preparation and the coating procedure for the immobilization of collagen onto the latex beads. In this regard, carboxy-modified latex beads coated with an α1+α2 collagen-chain mixture gave the best results. Received: 9 January 1995 / Accepted: 30 May 1995     

Purification and characterization of recombinant porcine prorelaxin expressed in Escherichia coli.

In this report we describe the purification and characterization of recombinant porcine prorelaxin expressed in Escherichia coli. Nucleotide sequence encoding porcine prorelaxin was inserted into an E. coli expression vector, pOTS, and the recombinant plasmid was transformed into the E. coli host (AR120). Upon induction with nalidixic acid, the 19-kDa recombinant porcine prorelaxin was produced at a level of approximately 8% of the total accumulated cell protein. The recombinant prorelaxin was purified to homogeneity by CM-cellulose chromatography and reversed-phase HPLC, after refolding in the presence of reduced and oxidized glutathione and a low concentration of guanidine-HCl. The identity of the recombinant prorelaxin was confirmed by the correct size, immunoreactivity with antibodies against native porcine relaxin, and direct amino-terminal sequence analysis. Furthermore, the purified recombinant prorelaxin could be converted to the 6-kDa relaxin by limited digestion with trypsin. Trypsin was shown to cleave at the carboxyl side of Arg29 and Arg137 residues of the recombinant prorelaxin, producing the des-ArgA1-B29-relaxin, and degrade the 13-kDa connecting peptide into small peptides. Both the recombinant prorelaxin and converted relaxin were found to be biologically active in an in vitro bioassay for relaxin.     

Molecular cloning of the extracellular endodextranase of Streptococcus salivarius.

We report the cloning in Escherichia coli of the gene encoding an extracellular endodextranase (alpha-1,6-glucanhydrolase, EC 3.2.1.11) from Streptococcus salivarius PC-1. Recombinants from a S. salivarius PC-1-Lambda ZAP II genomic library specifying dextranase activity were identified as plaques surrounded by zones of clearing on blue dextran agar. One such clone, PD1, had a 6.3-kb EcoRI fragment insert which encoded a 190-kDa protein with dextranase activity. The recombinant strain also produced two lower-molecular-mass polypeptides (90 and 70 kDa) that had dextranase activity. Native dextranase was recovered from concentrated culture fluids of S. salivarius as a single 110-kDa polypeptide. PD1 phage lysate and PC-1 culture supernatant fluid extract were used to measure substrate specificity of the recombinant and native forms of dextranase, respectively. Analysis of these reaction products by thin-layer chromatography revealed the expected isomaltosaccharide products yielded by the recombinant-specified enzyme but was unable to resolve the larger polysaccharide products of the native enzyme. Furthermore, S. salivarius utilized neither the substrates nor the products of dextran hydrolysis for growth.     

Collagen-induced proMMP-2 activation by MT1-MMP in human dermal fibroblasts and the possible role of alpha2beta1 integrins

Culture of human dermal fibroblasts within a three-dimensional matrix composed of native type I collagen fibrils is widely used to study the cellular responses to the extracellular matrix. Upon contact with native type I collagen fibrils human skin fibroblasts activate latent 72-kDa type IV collagenase/ gelatinase (MMP-2) to its active 59- and 62-kDa forms. This activation did not occur when cells were cultured on plastic dishes coated with monomeric type I collagen or its denatured form, gelatin. Activation could be inhibited by antibodies against MT1-MMP, by the addition of TIMP-2 and by prevention of MT1-MMP processing. MT1-MMP protein was detected at low levels as active protein in fibroblasts cultured as monolayers. In collagen gel cultures, an increase of the active, 60-kDa MT1-MMP and an additional 63-kDa protein corresponding to inactive MT1-MMP was detected. Incubation of medium containing latent MMP-2 with cell membranes isolated from fibroblasts grown in collagen gels caused activation of the enzyme. Furthermore, regulation of MT1-MMP expression in collagen cultures seems to be mediated by alpha2beta1 integrins. These studies suggest that activation of the proMMP-2 is regulated at the cell surface by a mechanism which is sensitive to cell culture in contact with physiologically relevant matrices and which depends on the ratio of proenzyme and the specific inhibitor TIMP-2.     

Identification and distribution of a novel, collagen-binding protein in the developing subepicardium and endomysium.

A protein doublet (M(r) = 68,000) that copurifies with chicken cardiac collagen types I and III is purified and characterized in the present study. Peptide mapping and amino terminus sequencing for both 68-kDa polypeptides show they have similar structures. This is supported by amino terminus sequencing of a 39-kDa proteolytic fragment of each polypeptide. The 68-kDa polypeptides appear at pI 6.7-6.8 in two-dimensional gels. Under nonreducing, electrophoretic conditions, the doublet appears as a large multimer or aggregate. Amino acid sequencing of the protein shows that its amino terminus contains a heptapeptide (VCLXXGK) that appears in the heparin/fibrin-binding domain of fibronectin and the collagen-binding domain of laminin. Cardiac myocytes synthesize and secrete the protein in vitro onto cell surfaces and onto the substratum. Indirect immunofluorescence shows the protein first appears in the chicken subepicardium at approximately 10 days following fertilization. As collagen accumulates in the subepicardium and the volume of the subepicardial space increases, the 68-kDa protein is found predominantly at the interface between myocardial cells and the connective tissue and between epicardial cells and the connective tissue. In adult hearts, the protein is also present at lower concentrations in endomysial connective tissue. The 68-kDa protein is also present in the skeletal muscle endomysium of embryonic chickens. Electron microscopic immunocytochemistry shows the 68-kDa protein is located at the surface of subepicardial collagen fibers. In addition, a direct interaction between the 68-kDa protein and collagen are indicated by: 1) equilibrium gel filtration of the 68-kDa protein in the presence of gelatin, 2) gelatin affinity chromatography of the 68-kDa protein, and 3) comigration of type I collagen and the 68-kDa protein during gel filtration under reducing conditions. The 68-kDa protein exhibits no collagenase activity under native conditions or in zymograms. Together, the data indicate that the 68-kDa protein is a novel collagen-associated protein appearing in late epicardial development.     

人基质金属蛋白酶-9在酵母Pichia pastoris中的表达

基质金属蛋白酶 - 9( MMP- 9)可促进恶性肿瘤的侵袭、转移 ,并在组织重建、胚胎发育以及伤口愈合等生理过程中发挥重要作用 .为研究这一蛋白的性质 ,并以之为靶标筛选抗肿瘤转移药物 ,在酵母 Pichia pastoris中实现了重组人 MMP- 9蛋白的高效、高活性、分泌表达 .首先用 PCR扩增了 MMP- 9基因编码区 (不含信号肽序列 ) ,经测序证实后 ,将其插入 p PIC9质粒中 ,构建表达载体 .用 Li C1 - PEG法转化酵母后 ,采用明胶 -酶谱法筛选获得 5株高效分泌表达 MMP- 9的克隆 ,经PCR证实 MMP- 9基因整合在阳性克隆的染色体中 .重组蛋白分子量为 93k D,表达量为 1 0 mg/L.重组蛋白可水解明胶及 型胶原 ,并可经有机汞 APMA诱导发生自剪切 ,转换成 85k D的激活形式 ,表明重组蛋白具有与天然人 MMP- 9蛋白相似的底物水解活性和自剪切激活特性 .     

Inhibition of fibronectin binding to platelets by proteolytic fragments and synthetic peptides which support fibroblast adhesion

To define regions within fibronectin (Fn) recognized by platelet binding sites, inhibition of Fn binding by an Fn fragment and synthetic peptides has been analyzed. A highly purified 120-kDa chymotryptic fragment, which has cell attachment activity but did not bind to insolubilized heparin or gelatin, inhibited Fn binding to platelets with an ID50 approximately 3 microM. Previous work indicates that fibroblasts attach to an 11.5-kDa subfragment of this 120-kDa fragment, and that one of four 30-residue synthetic peptides containing sequences from this region supports cell attachment. Only the peptide containing the COOH terminus of the 11.5-kDa fragment inhibited Fn binding to platelets, with an ID50 approximately 10 microM and is the peptide which supports fibroblast attachment. Of the smaller peptides studied from this sequence, all peptides containing the Arg-Gly-Asp-Ser sequence, including the tetrapeptide itself, were active in inhibiting Fn binding to platelets (ID50 values approximately 10-20 microM). The same peptides support fibroblast attachment. Those which lacked this sequence including Gly-Asp-Ser-Pro and Thr-Gly-Arg-Gly (immediately adjacent tetrapeptides) lacked both activities. Further evidence for specificity of inhibition was provided by structurally modified peptides in which substitution of a Glu for Asp abolished inhibitory activity and substitution of Lys for Arg or Ala for Gly reduced activity 6- and 8-fold, respectively. In addition, Arg-Gly-Asp-Ser-containing peptides inhibited the rate and extent of thrombin-induced platelet aggregation. These data suggest that the Arg-Gly-Asp-Ser tetrapeptide contains a recognition specificity involved in the binding of Fn to platelets and that platelets share features of this recognition specificity with fibroblasts.     

Type X collagen contains two cleavage sites for a vertebrate collagenase

Type X collagen was cleaved at two sites by a purified human skin collagenase. Two experimental approaches were used to identify the location of the cleavage sites. First, native type X collagen was digested with the enzyme, and the rotary-shadowed products were visualized in the electron microscope. The major collagenase fragment of type X contained the epitope recognized by a monoclonal antibody (X-AC9). The antibody was used as a point of reference to locate the position of the cleavage fragment within the native molecule. Second, the digestion of radiolabeled type X collagen substrates was analyzed by gel electrophoresis. The complete cleavage of type X generated three products with 32-, 18-, and 9-kDa chains. The 32-kDa peptides were present in a triple-helical conformation and demonstrated a midpoint denaturation temperature of 43 degrees C in CD experiments. The 18-kDa peptide contained the tyrosine-rich globular domain of the molecule. The 9-kDa peptide was derived from the triple-helical end of the native molecule. Type X collagen was cleaved more rapidly by the vertebrate collagenase than was type II collagen in in vitro solution studies.     

Molecular mechanisms of avian neural crest cell migration on fibronectin and laminin

We have examined the molecular interactions of avian neural crest cells with fibronectin and laminin in vitro during their initial migration from the neural tube. A 105-kDa proteolytic fragment of fibronectin encompassing the defined cell-binding domain (65 kDa) promoted migration of neural crest cells to the same extent as the intact molecule. Neural crest cell migration on both intact fibronectin and the 105-kDa fragment was reversibly inhibited by RGD-containing peptides. The 11.5-kDa fragment containing the RGDS cell attachment site was also able to support migration, whereas a 50-kDa fragment corresponding to the adjacent N-terminal portion of the defined cell-binding domain was unfavorable for neural crest cell movement. In addition to the putative "cell-binding domain," neural crest cells were able to migrate on a 31-kDa fragment corresponding to the C-terminal heparin-binding (II) region of fibronectin, and were inhibited in their migration by exogenous heparin, but not by RGDS peptides. Heparin potentiated the inhibitory effect of RGDS peptides on intact fibronectin, but not on the 105-kDa fragment. On substrates of purified laminin, the extent of avian neural crest cell migration was maximal at relatively low substrate concentrations and was reduced at higher concentrations. The efficiency of laminin as a migratory substrate was enhanced when the glycoprotein occurred complexed with nidogen. Moreover, coupling of the laminin-nidogen complex to collagen type IV or the low density heparan sulfate proteoglycan further increased cell dispersion, whereas isolated nidogen or the proteoglycan alone were unable to stimulate migration and collagen type IV was a significantly less efficient migratory substrate than laminin-nidogen. Neural crest cell migration on laminin-nidogen was not affected by RGDS nor by YIGSR-containing peptides, but was reduced by 35% after addition of heparin. The predominant motility-promoting activity of laminin was localized to the E8 domain, possessing heparin-binding activity distinct from that of the N-terminal E3 domain. Migration on the E8 fragment was reduced by greater than 70% after addition of heparin. The E1' fragment supported a minimal degree of migration that was RGD-sensitive and heparin-insensitive, whereas the primary heparin-binding E3 fragment and the cell-adhesive P1 fragment were entirely nonpermissive for cell movement.(ABSTRACT TRUNCATED AT 400 WORDS)     

Metal ion stabilization of the conformation of a recombinant 19-kDa catalytic fragment of human fibroblast collagenase.

A recombinant 19-kDa human fibroblast collagenase catalytic fragment modeled on a naturally occurring proteolytic product was purified from E. coli inclusion bodies. Following renaturation in the presence of zinc and calcium, the fragment demonstrated catalytic activity with the same primary sequence specificity against small synthetic substrates as the full-length collagenase. Unlike the parent enzyme, it rapidly cleaved casein and gelatin but not native type I collagen. Intrinsic fluorescence of the three tryptophan residues was used to monitor the conformational state of the enzyme, which underwent a 24-nm red shift in emission upon denaturation accompanied by quenching of the fluorescence and loss of catalytic activity. Low concentrations of denaturant unfolded the fragment while the full-length enzyme displayed a shallow extended denaturation curve. Calcium remarkably stabilized the 19-kDa fragment, zinc less so, while together they were synergistically stabilizing. Among divalent cations, calcium was the most effective stabilizer, EC50 approximately 60 microM, and similar amounts were required for substrate hydrolysis. Catalytic activity was more sensitive to denaturation than was tryptophan fluorescence. Least sensitive was the polypeptide backbone secondary structure assessed by CD. These observations suggest that the folding of the 19-kDa collagenase fragment is a multistep process stabilized by calcium.     

Reversible unfolding of the gelatin-binding domain of fibronectin: structural stability in relation to function

Fibronectin, a large multidomain glycoprotein, binds denatured collagen (gelatin) and mediates cell attachment and spreading on collagen-coated surfaces. Despite the high affinity, binding to gelatin is disrupted by relatively mild conditions. We have examined the effects of denaturants on the structure and function of a 42-kDa gelatin-binding fragment (GBF) isolated from chymotryptic and thermolytic digests of the parent protein. Application of linear gradients to GBF-loaded gelatin-agarose columns resulted in peak elution of the fragment at pH 5.2 or 10.2, at 0.4 M dimethylformamide, 0.9 M GdmCl, or 2.0 M urea, conditions far short of those required to induce structural changes detectable by fluorescence or circular dichroism. Solvent perturbation, fluorescence quenching, and chemical modification experiments indicate that about half of the 8 tryptophans, one-third of the 21 tyrosines, and all of the 9 lysine residues are solvent-exposed in the native protein and that 1 or more of the latter are directly involved in binding to gelatin, most likely through a hydrogen-bonding mechanism. Titration with GdmCl produced a single unfolding transition centered near 2.5 M GdmCl as monitored by changes in fluorescence and circular dichroism. This transition was fully reversible with complete recovery of structural parameters and gelatin binding. Treatment with disulfide reducing agents caused rapid irreversible changes in structure similar to those produced by GdmCl with concomitant loss of gelatin binding. Thus, tertiary and secondary structures are important for binding, but binding can be disrupted without perturbing those structures.     

Heparin inhibits the attachment and growth of Balb/c-3T3 fibroblasts on collagen substrata.

In investigating the role of cell-extracellular matrix interactions in cell adhesion and growth control, the effects of heparin on cell-collagen interactions were examined. Exponentially growing Balb/c-3T3 fibroblasts were radiolabelled with 3H-thymidine and detached from tissue culture surfaces using EDTA, and cell attachment to various types of collagen substrata was assayed in the presence or absence of heparin or other glycosaminoglycans (GAGs) or dextran sulfate (40 K). Cells attached readily (70-90%) to films of types I and V, but not to type III collagen. The number of cells bound to types I and V collagen films was inhibited by 10-50% when heparin was present from 0.1-100 micrograms/ml. Cell-collagen attachment was also inhibited by dextran sulfate, and to a lesser extent by dermatan sulfate, but chondroitin sulfates A and C and hyaluronic acid showed no effect. Heparin was active even at early time points in the adhesion assay, suggesting it may disrupt cell-collagen attachment. To study the effects of heparin in modulating cell growth on collagen, growth arrested cells cultured on type I collagen films were serum stimulated in the presence of heparin or other GAGs for 3 days. Growth was inhibited (greater than 40%) only by heparin and dextran sulfate. Interaction of heparin fragments (Mr less than or equal to 6KD) with type I collagen was analyzed by affinity co-electrophoresis (Lee and Lander, 1991) and showed higher affinity heparin binding to native as compared with denatured collagen. These data suggest that sites within native collagen may mediate Balb cell-collagen and heparin-collagen interactions, and such interactions may be relevant towards understanding heparin's antiproliferative activity in vivo and in vitro.     

A collagen-binding protein involved in the differentiation of myoblasts recognizes the Arg-Gly-Asp sequence

We had earlier demonstrated that a 46-kDa glycoprotein is involved in the differentiation of rat skeletal myoblasts. We now show that the binding of this glycoprotein to collagen and gelatin is disrupted by Arg-Gly-Asp (RGD) containing peptide but not by Arg-Gly-Glu (RGE). The former peptide also selectively elutes the 46-kDa glycoprotein bound to gelatin-Sepharose. Since all other proteins which bind RGD sequences have been found at the cell surface, we attempted to localize the 46-kDa glycoprotein by means of immuno fluorescent staining and radioiodine labeling. Surprisingly, the majority of the protein was found to be localized in the endoplasmic reticulum. Protease treatment of a microsomal fraction revealed that the protein is in the interior of the reticulum. Immunoprecipitation experiments, using a polyclonal antibody against the 46-kDa protein, demonstrated that no closely related proteins exist in myoblasts and also confirmed that the protein was not a fragment of a cell-surface localized protein. These findings suggest that the RGD sequence is also used in protein recognition within the cell.     

Magnesium-dependent attachment and neurite outgrowth by PC12 cells on collagen and laminin substrata

We report a study of the substratum and medium requirements for attachment and neurite outgrowth by cells of the pheochromocytoma-derived PC12 line. In attachment medium containing both Ca2+ and Mg2+, more than 50% of cells attached within 1 hr to petri dishes coated with native collagen Types I/III or II, native or denatured collagen Type IV, laminin, wheat germ agglutinin (WGA), or poly-L-lysine; attachment to dishes coated with nerve growth factor (NGF) was only about 20% and attachment to uncoated dishes or to dishes coated with fibronectin or gelatin was almost nil. Neither prior culturing in the presence of NGF nor addition of NGF to the attachment medium significantly affected the extent of attachment to collagen or laminin. With Ca2+ (1 mM) as the sole divalent cation, cells attached normally to WGA, polylysine, and NGF, but failed to attach to collagen or laminin. With Mg2+ (1 mM) as the only divalent cation, attachment to all substrata was about the same as in medium with both Ca2+ and Mg2+. Like the ionic requirements, the kinetics of attachment, insensitivity to protease treatment of the cells, and inhibition by low temperature and sodium azide were similar for PC12 attachment to collagen and laminin, suggesting that a common molecular mechanism may underlie attachment to these substrata. The only significant difference observed was that addition of WGA (30 micrograms/ml) to the attachment medium inhibited attachment to collagen but promoted attachment to laminin. Finally, PC12 cells extended neurites on laminin, on native collagens I/III, II, and IV, and on denatured collagen IV; they did not extend neurites on denatured collagens I/III or II, NGF, or WGA. Neurite outgrowth on collagen and laminin occurred with Mg2+ as the sole divalent cation. These results suggest that the same Mg2+-dependent adhesion mechanism operates at the cell body and at the growth cone.