Antibodies to laminin in Chagas' disease.

We have found that sera from humans with Chagas' disease and Rhesus monkeys infected with Trypanosoma cruzi contain IgM and IgG antibodies, which react with structures in a variety of connective tissues. These antibodies react with laminin but not with various other purified connective tissue components like collagen types I, III, IV, and V, fibronectin, heparan sulfate (BM-1) proteoglycan, or chondronectin. The tissue-reacting antibodies were isolated by absorption to a laminin-Sepharose column. The bound fraction contained all the tissue-reacting antibodies. These antibodies strongly stained trypomastigotes and amastigotes, but weakly stained epimastigotes. These studies show that sera from T. cruzi-infected primates contain antilaminin antibodies, which may be produced by those host in response to a laminin-like molecule present in the parasite.

The NC1 domain of type IV collagen promotes axonal growth in sympathetic neurons through interaction with the alpha 1 beta 1 integrin.

We have examined the effects of collagen IV on the morphological development of embryonic rat sympathetic neurons in vitro. In short-term (less than or equal to 24 h) culture, collagen IV accelerated process outgrowth, causing increases in the number of neurites and total neuritic length. Analysis of proteolytic fragments of collagen IV indicated that the NC1 domain was nearly as active as the intact molecule in stimulating process outgrowth; in contrast, the 7S domain and triple helix-rich fragments of collagen IV were inactive. Moreover, anti-NC1 antiserum inhibited neuritic outgrowth on collagen IV by 79%. In long-term (up to 28 d) cultures, neurons chronically exposed to collagen IV maintained a single axon but failed to form dendrites. Thus, the NC1 domain of collagen IV can alter neuronal development by selectively stimulating axonal growth. Comparison of collagen IV's effects to those of laminin revealed that these molecules exert quantitatively different effects on the rate of initial axon growth and the number of axons extended by sympathetic neurons. Moreover, neuritic outgrowth on collagen IV, but not laminin, was blocked by cycloheximide. We also observed differences in the receptors mediating the neurite-promoting activity of these proteins. Two different antisera that recognize beta 1 integrins each blocked neuritic outgrowth on both collagen IV and laminin; however, an mAb (3A3) specific for the alpha 1 beta 1 integrin inhibited collagen IV but not laminin-induced process growth in cultures of both sympathetic and dorsal root neurons. These data suggest that immunologically distinct integrins mediate the response of peripheral neurons to collagen IV and laminin.

Multiple mechanisms of dissociated epidermal cell spreading.

To test the possibility that epidermal cells use a common basement membrane protein whenever they spread, in vitro experiments were conducted using trypsin-dissociated guinea pig epidermal cells and the following proteins: human serum, bovine serum albumin, serum fibronectin, Type IV collagen, laminin, and epibolin (a recently described serum glycoprotein which supports epidermal cell spreading; Stenn, K.S., 1981, Proc. Natl. Acad. Sci. U.S.A. 78:6907.). When the cells were added to media containing the specific proteins, all the tested proteins, except for serum albumin, supported cell spreading. Added to protein-coated substrates in defined media, the cells spread on fibronectin, epibolin, and laminin-Type IV collagen, but not on albumin or whole serum. In none of these experiments were the results qualitatively affected by the presence of cycloheximide. Antibodies to a specific protein blocked cell spreading on that protein but not on the other active proteins, e.g. whereas antibodies to epibolin blocked cell spreading on epibolin, they did not affect spreading on fibronectin, collagen, or laminin. In a second assay in which the cells were allowed to adhere to tissue culture plastic before the protein-containing medium was added, the cells spread only if the medium contained epibolin. Moreover, under these conditions the spreading activity of whole serum and plasma was neutralized by antiepibolin antibodies. These results support the conclusion that dissociated epidermal cells possess multiple spreading modes which depend, in part, on the proteins of the substrate, proteins of the medium, and the sequence of cell adhesion and protein exposure.

Human endothelial cells are chemotactic to endothelial cell growth factor and heparin.

The response of human endothelial cell migration to various extracellular matrix components and growth factors has been assessed. Human endothelial cells demonstrate increased chemotaxis and chemokinesis when placed in a modified Boyden chamber with endothelial cell growth factor (ECGF) used at a concentration of 10(-9) M. Anti-ECGF antibody inhibits the chemotactic response. Heparin (10(-8) to 10(-10) M) was also chemotactic and was shown to potentiate the chemotactic activity of ECGF. Although laminin, fibronectin, the polypeptide (epidermal, fibroblast, and nerve) growth factors, and collagen types I, II, III, IV, and V demonstrate a chemotactic response, these activities were one third to one half less than observed with ECGF. These data suggest that ECGF and heparin may play a significant role as response modifiers of human endothelial cell migration which may be relevant to tumor metastasis, wound healing, and atherogenesis.

Modulation of the metastatic activity of melanoma cells by laminin and fibronectin.

Metastatic mouse melanoma cells have a high affinity for the basement membrane and the ability to degrade it; these properties may allow tumor cells to invade the membrane and disseminate. In this study it was found that the metastatic potential of mouse melanoma cells varied when the cells were exposed in culture to fibronectin or laminin. After removal of fibronectin or exposure to laminin, the cells had an increased affinity for basement membrane collagen, were more invasive of basement membranes in vitro, and produced more lung colonies in vivo. These changes are correlated with and may be due to an increase in the laminin-binding capacity of the tumor cell surface.

Laminin promotes rabbit neutrophil motility and attachment.

Polymorphonuclear neutrophils (PMN) traverse basement membrane to reach sites of infection. We have studied the role of laminin, a specific basement membrane component, in this process using three assay systems. In the Boyden chamber, laminin was found to stimulate chemotaxis of neutrophils while fibronectin did not. Co-incubation of cells with antibody to laminin blocked this chemotaxis, while antibody to fibronectin was without effect. In the human amnion system, neutrophils were shown to penetrate through the tissue when the peptide chemoattractant f-Met-Leu-Phe was placed on the opposing side. Antibody to laminin, but not to fibronectin, blocked this penetration. In an attachment assay system, laminin, but not fibronectin, was found to increase dispase-treated neutrophil attachment to type IV (basement membrane) collagen-coated plastic and to a plastic substrate itself. Electrophoretic analysis of PMN extract indicated the presence of laminin, and indirect immunofluorescence suggested that laminin is localized on the surface of the neutrophils. These data suggest that PMN can bind laminin on their cell surfaces, use laminin to attach to basement (type IV) membrane collagen, and migrate toward a gradient of laminin. These properties may be important for the passage of neutrophils from the circulation to sites of infection.

Basement membrane and the invasive activity of metastatic tumor cells.

Many, but not all, metastatic tumor cells have a similar phenotype. These are transformed cells with a high affinity for basement membranes and the ability to produce basement membrane degrading enzymes. Such characteristics help the cells traverse this critical barrier. Traversal may be a rather rare event unless the cells respond to local factors that amplify the numbers of cells recruited to the site and induce the cells to invade. These factors may include tissue-specific attractants and matrix molecules such as laminin. Understanding the specific steps involved in the invasion process should allow development of antimetastatic regimens directed at those activities specific to metastatic tumor cells. Due to the heterogeneity of tumor cells, other mechanisms for metastasis undoubtably exist.

Migration of tumor cells to organ-derived chemoattractants.

Certain tissues contain unique factors which are chemotactic for metastatic tumor cell lines. Extracts of bone, brain, liver, and lung were tested for their ability to promote either the migration or the chemoinvasion, i.e., their penetration through a reconstituted basement membrane barrier, of various metastatic tumor cells. Using a modified Boyden chamber assay for chemotaxis, B16-Br2 melanoma cells, which metastasize to brain, migrated most actively to brain extract. Lung-directed T241-PM2 fibrosarcoma cells migrated selectively to lung extract. Further, murine M50-76 reticulum cell sarcoma cells, which metastasize to liver and ovaries, were preferentially attracted to liver extract, and MCF-7 breast adenocarcinoma cells with high bone and brain colonization potential were found to migrate most actively to bone and brain extracts. Partial purification of tissue extracts showed that the factors in brain and liver are of different molecular weights. These data suggest that tissue-specific factors in different target tissues attract tumor cells which home to those sites.

Directed migration of murine and human tumor cells to collagenases and other proteases.

Tumor cell motility and the passage of tumor cells through various tissue matrices, including basement membrane, are important components of the metastatic process. Proteolytic enzymes, including a type IV collagen-specific collagenase, have been demonstrated to play a significant role in extracellular matrix and basement membrane degradation. In addition, exogenous collagenase has been shown to enhance the motility of some tumor cells independent of its effect on collagen-containing material. Previous studies have also indicated that collagen fragments are chemotactic for many tumor cells. We therefore studied the effect of type I and type IV collagen-specific collagenases, other enzymes involved in collagenase activation and connective tissue degradation, and subsequent collagen degradation products on the directed migration of tumor cells. We report that type I and type IV collagen-specific mammalian collagenases were potent chemoattractants as were native type I and type IV collagens and collagen fragments. Collagenase inhibitor SC44483 inhibited the type IV collagenase-stimulated migration. Collagenase pretreatment of the tumor cells potentiated the migratory response of the tumor cells to collagen and collagen fragments. The plasminogen activator, urokinase, as well as plasminogen itself also enhanced the directed migration of tumor cells in concentrations that suggest involvement of the appropriate cell surface receptor. The chemotactic response of tumor cells to the proteases studied extends the prior report of a role for collagenases and other matrix-active enzymes in tumor cell behavior in addition to matrix degradation.

Role of laminin in the attachment and metastasis of murine tumor cells.

We have studied the attachment of two murine metastatic cell lines and of a transformed, nonmetastatic sarcoma cell line to type IV (basement membrane) collagen. The metastatic cells attached preferentially to type IV collagen, whereas the nonmetastic cells attached best to type I collagen. Laminin increased both the rate and the number of metastatic cells attaching to type IV collagen, while fibronectin had no effect. Antibodies to laminin prevented the attachment of metastatic cells to type IV collagen, while antibodies to fibronectin prevented the attachment of the nonmetastatic cells. The number of pulmonary metastases which formed after i.v. injection of cells into C57BL mice was used to measure the metastatic propensity of these cell lines. A subpopulation of the metastatic cells selected for by their ability to attach to type IV collagen in the presence of laminin produced more metastases than did unattached cells or cells attached with fibronectin. In addition, incubation of metastatic cells with antibody to laminin prior to injection into mice markedly reduced the number of lung metastases. These data suggest that laminin promotes the attachment of metastatic tumor cells to basement membrane during the metastaatic process.

Tumor cell metastasis.

Local tissue invasion and the formation of metastatic lesions are characteristic properties of many malignant tumors. The formation of metastases is a complex process involving the passage of tumor cells from the site of the primary bulk tumor through successive connective tissue barriers, ultimately resulting in the growth of secondary tumor cell colonies in distinct target organ locations. At many stages in the metastatic process, tumor cells interact with multiple components of the extracellular matrix. Recently, the importance of basement membrane as a barrier to invasive cells has been recognized. In the course of the transition from in situ to invasive carcinoma, normal or dysplastic epithelial cells residing on a basement membrane are replaced by neoplastic cells which subsequently invade the basement membrane and enter the underlying stroma. Once in the stroma, tumor cells can then penetrate the walls of blood vessels or the lymphatic system and enter into the circulation. Circulating tumor cells next arrest in the lumina of small vessels, invade the vessel wall, and leave the circulation. These cells are now directly exposed to the extracellular matrix of a target organ where they may grow to form secondary tumors. Throughout the metastatic process tumor cells are thus in contact with, and are potentially responsive to, various components of the extracellular matrix. This review provides a survey of the recent advances in our understanding of the interactions of metastatic tumor cells with the extracellular matrix. Specifically, the role of basement membrane as a barrier to metastatic tumor cells is examined.

Comparative study of the chemotactic responses of periodontal ligament cells and gingival fibroblasts to polypeptide growth factors.

Selective recruitment of periodontal ligament cells to a previously exposed root surface is believed to enhance periodontal regeneration. It has been hypothesized that competition from gingival fibroblasts may reduce the potential of periodontal regeneration. We compared the migratory responses of PDL cells and gingival fibroblasts to a variety of biologicals. Parallel experiments designed to examine the directed migration responses of both periodontal ligament cells (PDL cells) and gingival fibroblasts (GF) isolated from the same donors were conducted using Platelet Derived Growth Factor (PDGF), Insulin Like Growth Factor-I, -II (IGF-I, -II), Epidermal Growth Factor (EGF), Transforming Growth Factor-beta (TGF-beta), and the chemotactic factor derived from the conditioned culture media of PDL cells (termed PDL-CTX) as attractants. Both PDL cells and GF exhibited dose-dependent migratory responses when challenged with PDGF, IGF-I, IGF-II, EGF, and TGF-beta. However, when these cells were challenged with PDL-CTX, only PDL cells migrated in a specific dose-dependent manner, while GF were refractive to PDL-CTX stimulation. Additionally, concentrated conditioned culture media from cultures of gingival fibroblasts did not stimulate PDL cell migratory responses. In other experiments, antibody directed against PDGF, FGF, TGF-beta, IGF-I, IGF-II, NGF, and EGF did not inhibit the PDL-CTX-elicited response in PDL cells. Previous studies have suggested that success of periodontal therapy depends on the specific attachment, migration, and proliferation of selected periodontal ligament cells. The data presented in this manuscript suggest that both PDL cells and gingival fibroblasts respond to a multitude of growth factors. PDL-CTX was found to be PDL-cell-specific for directed migration. Thus, we conclude that any biological therapeutic regime for periodontal regeneration should include PDL-cell-specific agents.

Periodontal ligament cells are chemotactic to fibroblast collagenase.

Periodontal ligament (PDL) cell motility and the passage of PDL cells along a root surface are important components of tissue remodeling during periodontal regeneration. Proteolytic enzymes, including fibroblast collagenase, have been demonstrated to play an important role in tissue remodeling. Previous studies have shown that PDL cells chemotactically respond to a variety of matrix and growth factors. We therefore studied the effects of type I collagen fragments and fibroblast collagenase on PDL cell migration, since PDL cells have been shown to adhere preferentially to partially demineralized root surfaces with exposed type I collagen. Gingival epithelial cells were used as a control cell population. We report that PDL cells but not gingival epithelial cells preferentially migrate in a dose-dependent manner to both fibroblast collagenase and to type I collagen degradation products. Epithelial cell migration to fibroblast collagenase and type I collagen fragments was observed. Antibody to type I collagen inhibited the type I collagen fragment-mediated migration. Collagenase pre-treatment of PDL cells enhanced PDL cell migration to type I collagen fragments. In other assays, enzyme inhibitors were shown to decrease the collagenase-mediated PDL cell motility. Epithelial cells were shown to migrate preferentially to 92-kDa type IV collagenase and type IV collagen degradation products. Antibody to type IV collagen inhibited type IV collagen-induced epithelial cell migration. Taken together, these data suggest a role for collagenase in the fine control of PDL cell migration in tissue remodeling during periodontal regeneration.

Isolation and characterization of epithelial and connective tissue cells from rat palate.

Epithelial and connective tissue cells were isolated from rat palate by sequential enzymatic digestion. Differences between the two populations were noted with respect to proline uptake and incorporation, % collagen synthesized, effects of parathyroid hormone and metabolism of D-valine. From these studies it can be concluded that the cell populations are viable and distinct with respect to the biochemical parameters examined.

Isolation, purification, and partial characterization of an autocrine periodontal ligament cell chemotactic factor.

Periodontal ligament (PDL) cells are believed to play a critically important role in the regeneration of the periodontium. We have suggested that polypeptide growth factors can enhance periodontal regeneration by stimulating PDL cell chemotaxis and mitogenesis. This manuscript describes the identification of a novel chemotactic factor isolated from human PDL cells which we named PDL-CTX. PDL-CTX induces the directed migration of human PDL cells in vitro and was found to be a more potent chemotactic agent than other known growth factors. Additionally, PDL-CTX has no chemotactic effect on gingival fibroblasts or gingival epithelial cells. Both tryptic digestion and boiling abolished PDL-CTX's biological activity. The designed purification method included Mono-S cation exchange, heparin-sepharose affinity, and microbore reverse-phase HPLC. The purified factor has a relative molecular weight of approximately 7000 daltons based on sodium dodecyl sulfate (SDS) gel analysis. The amino acid composition and partial amino acid sequence were determined from HPLC-purified material. These were determined to be unique. Further investigation of the biological functions of PDL-CTX on PDL cells and other ligament cells should help improve our understanding of ligament repair.

Migration inhibitory factor related protein-8 (MRP-8) is an autocrine chemotactic factor for periodontal ligament cells.

Previous studies have suggested that human periodontal ligament (PDL) cells secrete a chemotactic factor which stimulates motility in an autocrine manner. Here we report the partial amino acid sequence of a purified factor which shows 100% homology with human migration inhibitory factor related protein-8 (MRP-8). In addition, reverse-transcription polymerase chain-reaction (RT-PCR) analysis revealed that mRNA encoding MRP-8 was expressed in cultured human PDL cells. To confirm that MRP-8 is chemotactic for PDL cells, we synthesized 25 mer peptides overlapped by 5 amino acids covering the entire MRP-8 protein and tested them for their chemotactic activities. The data indicated that amino acid residues 21-45 showed chemotactic activity for cultured human PDL cells. The maximum chemotactic response was observed at the concentration of 10(-15) mol/mL for human PDL cells. The chemotactic activity was estimated to be approximately 1000-fold higher than that of platelet-derived growth factor (PDGF), insulin-like growth factors-I and -II (IGF-I, -II), and epidermal growth factor (EGF) when compared on a molar basis. Since MRP-8 is reported to be produced mainly by neutrophils and monocytes, the result of the current study may suggest another important role of MRP-8 in human PDL cells.

Mitogenic and chemotactic responses of human periodontal ligament cells to the different isoforms of platelet-derived growth factor.

A major focus of studies that center on regeneration of the periodontium is to determine the efficacy of the use of polypeptide growth factors. Platelet-derived growth factor has been reported to be a possible agent for clinical use. PDGF has various isoforms. Therefore, we decided to study the mitogenic and chemotactic responses of human periodontal ligament (PDL) cells to recombinant human PDGF-AB, AA, and BB. Addition of each isoform of PDGF to in vitro mitogenesis assays induced PDL cell proliferation in a dose-dependent manner. The maximum mitogenic effect was evident at the concentration of 100 ng/mL. In these assays, PDGF-BB was found to be the most potent mitogen. PDGF-AB elicited an intermediate response, and PDGF-AA was the least effective. The results of chemotaxis assays closely parallel those of the mitogenesis assays. PDGF-BB exhibited the most potent chemotactic effect. The maximal effect was observed at 10 ng/mL. The findings of these experiments indicate that PDGF-BB is more effective than the other isoforms in promoting mitogenesis and chemotaxis of PDL cells in vitro, and may therefore be a suitable ethical pharmaceutical for use in periodontal regeneration procedures.

Extracellular matrices and polypeptide growth factors as mediators of functions of cells of the periodontium. A review.

This is a review of the interactions between cells and their extracellular matrices and polypeptide growth factors. The review not only attempts to provide a basic understanding of the functions of extracellular matrices and polypeptide growth factors but, in addition, suggests the role these biological molecules may play in periodontal regeneration. It is conceivable that future periodontal therapy will include the treatment of a scaled root with biological response modifiers to predictably attain a true new connective tissue attachment.

Chemotaxis of human gingival epithelial cells to laminin. A mechanism for epithelial cell apical migration.

Laminin, a large glycoprotein (Mr = 10(6)) and a major component of basement membrane, is shown here to be a potent chemoattractant for human gingival epithelial cells. Laminin stimulated chemotaxis and chemokinesis of gingival epithelial cells in the modified Boyden chamber assay. This effect appeared to be laminin receptor mediated. Gingival epithelial cells were shown to bind laminin (Kd = 2.0 nM) with 10,000 to 30,000 binding sites per cell. Antilaminin antibody, which inhibited laminin binding, inhibited the chemotactic response of epithelial cells to laminin, while antifibronectin was without effect. Fibronectin was not as potent a chemoattractant as laminin. Other biological response modifiers were also tested; of these, Type IV collagen and epidermal growth factor were active as chemoattractants, although not as effective in inducing chemotaxis as laminin. The data indicate that laminin and other components of basement membrane may be important in regulating the migration and growth of gingival epithelial cells.

Repopulation of dentin surfaces by periodontal ligament cells and endothelial cells. Effect of basic fibroblast growth factor.

The regeneration of connective tissue attachment is a major goal of clinical periodontics. Recent investigations on biochemically mediated periodontal regeneration have attempted to define the various biological response modifiers which may provide a mechanism for periodontal regeneration. Fibronectin and endothelial cell growth factor have been shown to selectively enhance periodontal ligament (PDL) cell adhesion, migration, and proliferation. In addition, dentin preconditioned with tetracycline HCl (TTC) or citric acid (CA) supports PDL cell adhesion, presumably by exposing collagen fibers. We have now extended these studies to include basic fibroblast growth factor (b-FGF) as a potential meditor of periodontal regeneration. Using AFSCM (assays for specific cell migration), b-FGF in concentrations as low as 10 ng per dentin block significantly stimulated PDL cell chemotaxis, while the antibody against b-FGF inhibited both the chemotactic and proliferative characteristics of the mitogen. We also found that 5 ng and above of b-FGF per dentin block significantly stimulated human endothelial cell migration and proliferation. Using 125I-b-FGF, we demonstrated that the factor binds to native dentin. This binding was increased when the dentin blocks were preconditioned by TTC or CA and reduced when the dentin was subsequently treated with collagenase. 125I-b-FGF also bound with moderate affinity to a type I collagen affinity column whereas the binding to a hydroxylapatite affinity column was negligible. The combination of FN and b-FGF was a marginally more potent chemo-attractant than b-FGF alone for PDL cells.(ABSTRACT TRUNCATED AT 250 WORDS)