Analysis of the role of microfilaments and microtubules in acquisition of bipolarity and elongation of fibroblasts in hydrated collagen gels

An in vitro comparison of human flexor and extensor tendon cells

This study examined the in vitro phenotype of cells cultured from both flexor and extensor tendons. Matrix proteins secreted by tendon cells were examined, together with their response to mechanical strain, using cells from the two types of tendon. Immunocytochemical staining using specific antibodies to matrix proteins demonstrated that flexor tendon cells synthesised only three of the five proteins stained for, whilst extensor tendon cells synthesised all five. Gel electrophoresis (used to separate mixtures of proteins) demonstrated that protein secretion was similar for both cell types. Both cell types showed similar patterns of synthesis for total collagen and total protein over time. No difference was found in the response to cyclical strain of cells from the two types of tendon; both cell proliferation and collagen synthesis were stimulated. The study demonstrated that cells obtained from two different types of tendon behave similarly when exposed to identical environmental conditions in vitro.

Cytochalasin D induces edema formation and lowering of interstitial fluid pressure in rat dermis

The increased capillary fluid filtration required to create a rapid edema formation in acute inflammation can be generated by lowering the interstitial fluid pressure (P(IF)). The lowering of P(IF) appears to involve dynamic beta(1)-integrin-mediated interactions between dermal cells and extracellular matrix fibers. The present study specifically investigates the role of the cell cytoskeleton, i.e., the contractile apparatus of cells, in controlling P(IF) in rat skin as the integrins are linked to both the cytoskeleton and the extracellular matrix. P(IF) was measured using a micropuncture technique in the dorsal skin of the hind paw at a depth of 0.2--0.5 mm and following the induction of circulatory arrest with the intravenous injection of KCl in pentobarbital anesthesia. This procedure prevented the transcapillary flux of fluid and protein leading to edema formation in acute inflammation, which in turn can increase the P(IF) and therefore potentially mask a decrease of P(IF). Control P(IF) (n = 42) averaged -0.8 +/- 0.5 (means +/- SD) mmHg. In the first group of experiments, subdermal injection of 2 microl cytochalasin D, a microfilament-disrupting drug, lowered P(IF) to an average of -2.8 +/- 0.7 mmHg within 40 min postinjection (P < 0.05 compared with control). Subdermal injection of vehicle (10% DMSO in PBS or PBS alone) did not change the P(IF) (P > 0.05). Lowering of the P(IF) was not observed after the injection of colchicine or nocodazole, which specifically disrupts microtubuli in cultured cells. In the second group of experiments, 2 microl of cytochalasin D injected subdermally into rats with intact circulation increased the total tissue water (TTW) and albumin extravasation rate (E(ALB)) by 0.7 +/- 0.2 and 0.4 +/- 0.3 ml/g dry wt, respectively (P < 0.05 compared with vehicle). Nocodazole and colchicine did not significantly alter the TTW or E(ALB) compared with the vehicle (P > 0.05). Taken together, these findings strongly suggest that the connective tissue cells can participate in control of P(IF) via the actin filament system. In addition, the observation that subdermal injection of cytochalasin D lowered P(IF) indicates that a dynamic assembly and disassembly of actin filaments also occurs in the cells of dermal tissues in vivo.

Effect of telmisartan on angiotensin II-mediated collagen gel contraction by adult rat cardiac fibroblasts

The possible contributions of the angiotensin receptor subtypes 1 and 2 on the angiotensin II-induced collagen gel contraction by adult rat cardiac fibroblasts were studied using the specific angiotensin receptor type 1 and 2 antagonists telmisartan and P-186, respectively. Cardiac fibroblasts (from normal male adult rats) from passage 2 were cultured to confluency and added to a hydrated collagen gel, with or without angiotensin II, angiotensin II plus telmisartan, or angiotensin II plus P-186 in Dulbecco's Modified Eagle's Medium containing 5% fetal bovine serum for 1, 2, or 3 days. Control gels containing adult rat cardiac fibroblasts showed a significant amount of contraction after 3 days of incubation, causing a contraction to 67.9 +/- 7.1% of the area after 1 day. Angiotensin II (10(-7) M) stimulated (p < or = 0.05) the contraction of collagen mediated by cardiac fibroblasts after 1, 2, or 3 days. Telmisartan (10(-7) M) completely blocked the angiotensin II-induced collagen contraction by cardiac fibroblasts. P-186 (10(-7) M) had no effect on the angiotensin II-induced collagen contraction by cardiac fibroblasts. Addition of telmisartan and P-186 alone did not affect the collagen gel contraction by cardiac fibroblasts. Our data demonstrate that the effects of angiotensin II on the collagen gel contraction by adult rat cardiac fibroblasts are angiotensin II type 1 receptor mediated because they were abolished by the specific angiotensin II type 1 receptor antagonist telmisartan but not by the specific angiotensin II type 2 receptor antagonist P-186.

Transfer of platelet-derived growth factor-BB gene by gene gun increases contraction of collagen lattice by fibroblasts in diabetic and non-diabetic human skin

We have used an in vitro model of wound contraction, the fibroblast-populated collagen lattice, to examine the effect of platelet-derived growth factor BB (PDGF-BB) and PDGF-BB gene transfer by gene gun on the contraction of lattices composed of either diabetic or non-diabetic human fibroblasts. The area of collagen lattice and DNA synthesis were measured in 12 specimens. There were significant increases in lattice contraction with increasing doses of PDGF-BB and fibroblasts transfected with the PDGF-BB gene compared with control (p < 0.01). DNA synthesis of the non-diabetic and diabetic fibroblast lattices showed significantly increased incorporation of tritiated thymidine with increasing doses of PDGF-BB and fibroblasts transfected with the PDGF-BB compared with controls (p < 0.05). The effect of PDGF-BB gene transfer on diabetic and non-diabetic fibroblasts was similar to that of 20 ng/ml or less of PDGF-BB.

Major role for active extension in the formation of processes by ras-transformed fibroblasts

Expression of constitutively active Ras protein in fibroblasts results in enhanced cell motility, invasion competence and morphological changes including the formation of elongate cellular processes. These processes have been shown to resemble retraction tails formed passively behind nontransformed cells by movement relative to sites of cell-substrate attachment. However, analysis presented here reveals that active extension mechanisms also play a role in the formation of these processes. Extension of distal process ends occurs at 0.42+/-0.44 microm/min in ras-transformed fibroblasts and accounts for 63.6+/-27.5% of observed process lengths. Active process extension by ras-transformed fibroblasts also persists in the presence of cell-cell contacts. Studies conducted using actin or microtubule antagonists, and correlation of process behavior followed by fixation and immunostaining reveal that process extension requires intact actin and microtubule networks. Other analyses reveal that active extension plays a significantly smaller role in the formation of processes by non-transformed control fibroblasts. These observations demonstrate that constitutively active Ras enhances process extension in fibroblasts and is a causal factor in process extension by fibroblasts in the presence of cell-cell contacts. Moreover, these studies demonstrate that process extension by ras-transformed fibroblasts is accomplished through mechanisms similar to those thought to drive active extension of processes by other cell types including neurons. These findings suggest that extension of cellular processes could play an important role in the metastatic behavior of ras-transformed fibroblasts as well as the response of untransformed fibroblasts to receptor mediated signal transduction events.

Immunohistochemical localization of collagen types I, III, and IV, laminin, fibronectin, and keratin in the endolymphatic sac

We have employed immunohistochemistry to obtain baseline information on the molecular constituents of the extracellular matrix (ECM) of the endolymphatic duct (ED) and endolymphatic sac (ES) of the chinchilla. The results demonstrated that collagen types I and III were distributed in the subepithelial layer in the ED and ES, type IV collagen and laminin in the basement membranes, and fibronectin in the subepithelial layer and partly in the conglomerated cells in the ES. Collagen type III was diffusely distributed in the whole subepithelial layer of the ES, whereas collagen type I was concentrated densely in the deep layer of the interstitium, although gradually, the cuboidal epithelium in the ES was transformed into a flatter type in the ED. The epithelial cells of the ED and ES were clearly positive for keratin. This study deals, in particular, with the normal distribution of ECM components of the ED and ES of the chinchilla.

Human neutrophil elastase augments fibroblast-mediated contraction of released collagen gels

In the present study, we tested the hypothesis that neutrophil elastase (NE) might mediate remodeling of extracellular matrix by affecting fibroblast-mediated contraction of three-dimensional collagen gels. Human lung fibroblasts were cast into type I collagen gels containing NE. After gelation, the gels were released into medium and the area was measured by image analyzer. NE augmented gel contraction (p < 0.001). This was not due to cell proliferation or to degradation to soluble collagen fragments because the amounts of DNA and hydroxyproline were not altered. alpha1-Protease inhibitor and the synthetic inhibitor of NE, L-680,833, when added in sufficient amount to inhibit free elastase activity, blocked the contraction induced by NE. Furthermore, neutrophil granulocytes (PMN) in coculture, as well as conditioned media from PMN, resulted in an increased contractility (p < 0.001 for both). Bronchoalveolar lavage fluid (BALF) from patients with increased PMN in their lower respiratory tract and free elastase activity had augmentive activity for gel contraction which could be partially blocked by the inhibitors. We conclude that NE augments fibroblast-mediated contraction of collagen gels. The findings support the notion that products secreted by PMN in inflammatory disorders may lead to rearrangement of extracellular matrix and could subsequently lead to tissue dysfunction.

A fibrin or collagen gel assay for tissue cell chemotaxis: assessment of fibroblast chemotaxis to GRGDSP

Fibroblast chemotaxis is implicated in many physiological processes, including wound healing and morphogenesis. We present a novel assay for chemotaxis of fibroblasts (and other slow-moving tissue cells) in a direct-viewing chamber containing a physiologically relevant three-dimensional fibrin or collagen gel in which long-lasting, spatially continuous gradients have been sustained for at least 24 h, long enough for significant fibroblast migration. This combination of features is not available in any alternative assay of comparable setup simplicity. Using a putative fibroblast chemotactic factor, the fibronectin peptide GRGDSP, we measured human foreskin fibroblast alignment in the direction along the gradient, which followed a biphasic dependence on GRGDSP concentration with an optimal concentration of about 10 nM. Time-lapse video microscopy revealed that cell migration was up the soluble GRGDSP gradient, confirming positive chemotaxis to GRGDSP and rejecting the possibility of dominant haptotaxis down the soluble GRGDSP gradient, that is, up a putative gradient of integrin-mediated adhesion induced by the soluble GRGDSP gradient.

Morphometric studies of collagen and fibrin lattices contracted by human gingival fibroblasts; comparison with dermal fibroblasts

Cell shape variations and substratum re-organization during contraction of floating collagen and fibrin lattices seeded with human gingival fibroblasts were determined by computerized image analysis of light and scanning electron microscopic images. Data were compared with those obtained with lattices populated with human dermal fibroblasts. The extent of collagen lattice contraction was similar with both cell types, resulting in a two-fold decrease in the area fractions occupied by collagen fibers. Fibroblasts exhibited a rounded shape (form factors equal to 0.8 and 0.7 for gingival and dermal cells, respectively) at day 1 of culture; they possessed a more elongated appearance (with form factors equal to 0.3 and 0.15 for gingival and dermal cells, respectively) at day 7. Continuous (gingival) and discontinuous (dermal) layers of cells were evidenced at the cortex of lattices. Contractions were associated with a significant reduction of the diameters of collagen fibers. Re-organization of substratum, as analyzed by the "Rose of Directions" technique, was evidenced only at the vicinity of filopodia where fibers ran parallel to these protrusions. Several lysed matrix cavities were observed when fibrin lattices were populated with gingival but not dermal fibroblasts at day 5 of culture. Although cells in fibrin lattices exhibited morphometric parameters comparable with those in collagen lattices, no fibroblast layers could be demonstrated at gel peripheries. Fibrin matrices consisted of an isotropic network of entangled fibrin filaments from the start of culture, and only a slight reduction of the diameters of fibrin fibers could be evidenced in dermal fibroblast-populated lattices. Fibrinolysis at the vicinity of gingival fibroblasts led to an entire re-organization of substratum toward the formation of larger fibers. The differential behavior of gingival vs. dermal fibroblasts inside fibrin but not collagen matrices could therefore partly explain the increased rate of remodeling of gingiva as compared with dermis.

Fibroblast responses to mechanical forces

The repair and maintenance of connective tissues is performed predominately by a mesenchymal cell known as a fibroblast. The activity of this cell is regulated, in part, by changes in the mechanical environment in which it resides. The authors have addressed some of the questions related to the fibroblast and how it responds to mechanical stimulation. An in vitro model, the 'culture force monitor', and its derivative, the tensioning culture force monitor have been developed enabling quantitative investigations to be performed on fibroblasts in a collagen lattice. Results have shown that a fibroblast can generate a force of approximately 10(-10) N, as a result of change in cell shape and attachment, while in a three-dimensional collagen lattice. Application of a physiologically similar mechanical load has shown that fibroblasts have the ability to maintain a tensional homeostasis of approximately 40-60 x 10(-5) N per million cells, change cellular morphology in a predictable manner and biochemically modify their resident environment.

Tensional homeostasis in dermal fibroblasts: mechanical responses to mechanical loading in three-dimensional substrates

Many soft connective tissues are under endogenous tension, and their resident cells generate considerable contractile forces on the extracellular matrix. The present work was aimed to determine quantitatively how fibroblasts, grown within three-dimensional collagen lattices, respond mechanically to precisely defined tensional loads. Forces generated in response to changes in applied load were measured using a tensional culture force monitor. In a number of variant systems, resident cells consistently reacted to modify the endogenous matrix tension in the opposite direction to externally applied loads. That is, increased external loading was followed immediately by a reduction in cell-mediated contraction whilst decreased external loading elicited increased contraction. Responses were cell-mediated and not a result of material properties of the matrices. This is the first detailed characterisation of a tensional homeostatic response in cells. The maintained force, after 8 h in culture, was typically around 40-60 dynes/million cells). Maintenance of an active tensional homeostasis has widespread implications for cells in culture and for whole tissue function.

Lattices of type I collagen select invasive variants of K-ras oncogene-transfected NIH3T3 with less cellular fibronectin

A clone of NIH3T3 transformant (H3) can yield subcutaneous tumors and experimental pulmonary metastasis in nude mice. Compared to H3 in culture, the cells after in vivo tumor growth (H3-N) acquired enhanced tumorigenicity and metastatic ability. Also, indirect immunofluorescence revealed that cellular fibronectin (c-FN) of H3-N was decreased remarkably. We have studied the interactions between H3 and extracellular matrices to elucidate these phenomena. In the present study, we observed the effect of NIH3T3, H3, and H3-N cultured in type I collagen gel. Morphologically in the collagen gel, NIH3T3 assumed an extensive elongated fiber-like shape, H3 assumed a moderately elongated shape, and H3-N assumed a round or spindle shape with short pseudopodia. Compared to conventional cultures on dishes, cell proliferation of all three types was suppressed in collagen gel, but the degree of the suppression was least in H3-N. As a result, H3-N grew fastest in collagen gel. The variants which acquired growth advantage in the subcutaneum of mice also kept it in collagen gel. H3 cells were cultured in type I collagen gel for 4 weeks, a period comparable to that of tumor formation in nude mice. The cells after this long-term culture (H3-C) acquired enhanced tumorigenicity and metastatic ability nearly equal to that of H3-N. FACS analysis revealed that the c-FN of H3-C had decreased to a value comparable to that of H3-N. This means that type I collagen gel as well as subcutaneous tissues could select variants of H3 with less c-FN through proliferation. Moreover, it is suspected that lattices of type I collagen regulate cell proliferation of fibroblast via c-FN.

Human bronchial epithelial cells modulate collagen gel contraction by fibroblasts

Connective tissue contraction is an important aspect of both normal wound healing and fibrosis. This process may contribute to small airway narrowing associated with certain airway diseases. Fibroblast-mediated contraction of a three-dimensional collagen gel has been considered a model of tissue contraction. In this study, the ability of primary cultured human bronchial epithelial cells (HBEC) obtained by bronchial brushings to modulate fibroblast gel contraction was evaluated. Human lung fibroblasts (HFL1) were cast into type I collagen gels. The gels were floated both in dishes containing a monolayer of HBEC or in dishes without HBEC. Contraction assessed by measuring the area of gels was increased at all time points from 24 h up to 96 h of coculture. At 48 h, coculture of HBEC with fibroblasts resulted in significantly more contraction than fibroblasts alone (36.6 +/- 1.2 vs. 20.4 +/- 1.7%, P < 0.05). Lipopolysaccharide (LPS, 10 micrograms/ml) stimulation of the HBEC augmented the contraction (44.9 +/- 1.0%, P < 0.05 vs. HBEC). In the presence of indomethacin, the augmentation by LPS was increased further (52.2 +/- 4.3%, P < 0.05 vs. HBEC with LPS), suggesting that prostaglandins (PGs) are present and may inhibit contraction. Consistent with this, PGE was present in HBEC-conditioned medium. Bronchial epithelial cell conditioned medium had an effect similar to coculturing. SG-150 column chromatography revealed augmentive activity between 20 and 30 kDa and inhibitory activity between 10 and 20 kDa. Measurement by enzyme-linked immunosorbent assay confirmed the presence of the active form of transforming growth factor (TGF)-beta 2. The stimulatory activity of conditioned medium was blocked by adding anti-TGF-beta antibody. These data demonstrate that, through the release of factors including TGF-beta 2 which can augment and PGE which can inhibit, HBEC can modulate fibroblast-mediated collagen gel contraction. In this manner, HBEC may modulate fibroblast activities that determine the architecture of bronchial tissue.

An in vitro force measurement assay to study the early mechanical interaction between corneal fibroblasts and collagen matrix

An in vitro force measurement assay has been developed to quantify the forces exerted by single corneal fibroblasts during the early interaction with a collagen matrix. Corneal fibroblasts were sparsely seeded on top of collagen matrices whose stiffness was predetermined by micromanipulation with calibrated fine glass microneedles. The forces exerted by individual cells were calculated from time-lapse videomicroscopic recordings of the 2-D elastic distortion of the matrix. In additional experiments, the degree of permanent reorganization of the collagen matrices was assessed by lysing the cells with 1% Triton X-100 solution at the end of a 2-hour incubation and recording the subsequent relaxation. The data suggest that a cell can exert comparable centripetal force during either extension of a cell process or partial retraction of an extended pseudopodia. The rates of force associated with pseudopodial extension and partial retraction were 0.180 +/- 0.091 (x 10(-8)) N/min (n = 8 experiments) and 0.213 +/- 0.063 (x 10(-8)) N/min (n = 8 experiments), respectively. Rupture of pseudopodial adhesion associated with cell locomotion causes a release of force on the matrix and a complete recoil of the pseudopodia concerned; a simultaneous release of force on the matrix was also observed at the opposite end of the cell. Lysis of cells resulted in 84 +/- 18% relaxation of the matrix, suggesting that little permanent remodeling of matrix is produced by the actions of isolated migrating cells.

Gelatinase A activation is regulated by the organization of the polymerized actin cytoskeleton

Gelatinase A (GL-A) is a matrix metalloproteinase (MMP) involved in both connective tissue remodeling and tumor invasion. GL-A activation is mediated by a membrane-type MMP (MT-MMP) that cleaves the GL-A propeptide. In this study, we examined the role of the actin cytoskeleton in regulating GL-A activation and MT-MMP-1 expression. Human palmar fascia fibroblasts and human fetal lung fibroblasts were cultured on a planar substratum or within different types of collagen lattices. Fibroblasts that formed stress fibers, either on a planar substratum or within an attached collagen lattice, showed reduced GL-A activation compared with fibroblasts lacking stress fibers, within either floating or stress-released collagen lattices. To determine whether changes in the organization of the actin cytoskeleton could promote GL-A activation, fibroblasts with stress fibers were treated with cytochalasin D. Within 24 h after treatment, GL-A activation was dramatically increased. Associated with this GL-A activation was an increase in MT-MMP-1 mRNA as determined by Northern blot analysis. Treatment with nocodazole, which induced microtubule depolymerization and cell shape changes without affecting stress fibers, did not promote GL-A activation. These results suggest that the extracellular matrix and the actin cytoskeleton transduce signals that modulate GL-A activation and regulate tissue remodeling.

AP-1-mediated invasion requires increased expression of the hyaluronan receptor CD44

Fibroblasts transformed by Fos oncogenes display increased expression of a number of genes implicated in tumor cell invasion and metastasis. In contrast to normal 208F rat fibroblasts, Fos-transformed 208F fibroblasts are growth factor independent for invasion. We demonstrate that invasion of v-Fos- or epidermal growth factor (EGF)-transformed cells requires AP-1 activity. v-Fos-transformed cell invasion is inhibited by c-jun antisense oligonucleotides and by expression of a c-jun dominant negative mutant, TAM-67. EGF-induced invasion is inhibited by both c-fos and c-jun antisense oligonucleotides. CD44s, the standard form of a transmembrane receptor for hyaluronan, is implicated in tumor cell invasion and metastasis. We demonstrate that increased expression of CD44 in Fos- and EGF-transformed cells is dependent upon AP-1. CD44 antisense oligonucleotides reduce expression of CD44 in v-Fos- or EGF-transformed cells and inhibit invasion but not migration. Expression of a fusion protein between human CD44s and Aequorea victoria green fluorescent protein (GFP) in 208F cells complements the inhibition of invasion by the rat-specific CD44 antisense oligonucleotide. We further show that both v-Fos and EGF transformations result in a concentration of endogenous CD44 or exogenous CD44-GFP at the ends of pseudopodial cell extensions. These results support the hypothesis that one role of AP-1 in transformation is to activate a multigenic invasion program.

Collagen gel-embedding culture of conjunctival epithelial cells

BACKGROUND

Collagen has effects on cell morphology, differentiation characteristics and function. Using collagen gel culture, several studies about cell differentiation were reported. In this study, the differentiation of rabbit conjunctival epithelial cells in a collagen gel-embedding culture system was investigated by electron microscope and lectin labeling.

METHODS

Rabbit bulbar conjunctival epithelial cells were cultured in type I collagen gel. After 1 and 2 weeks of culture, some of these cells were stained with PAS and seven kinds of lectins, and others were examined by transmission electron microscopy.

RESULTS

The conjunctival epithelial cells cultured within collagen gel formed stratified cell layers and globules with cavities. The inner layer cells facing the cavities showed PAS and lectin staining patterns similar to those of conjunctival goblet cells in vivo, whereas the staining patterns of the outer layer cells on the collagen matrices resembled the patterns of non-goblet epithelial cells. Microvilli on the surface of the innermost cells, basement membranes beneath the outermost cells, tight junctions, adherent junctions, interdigitating folds and desmosomes between cells were identified on electron microscopic examination.

CONCLUSION

These results indicate that cell junction structures of the conjunctival epithelial cells are well developed in collagen gel-embedding culture systems, and that the inner layer cells have carbohydrates similar to those of conjunctival goblet cells. Culture of conjunctival epithelial cells within collagen gel is a useful model for examining differentiation of these cells.

Balanced mechanical forces and microtubule contribution to fibroblast contraction

Fibroblast locomotion is thought to generate tractional forces which lead to contraction and reorganisation of collagen in tissue development and repair. A culture force monitor device (CFM) was used to measure changes in force in fibroblast populated collagen lattices, which resulted from cytoskeletal reorganisation by cytochalasin B, colchicine, vinblastine, and taxol. Microfilament disruption abolished contraction forces, microtubule disruption elicited a new peak of contraction, while taxol stabilisation of microtubules produced a gradual fall in measured force across the collagen gel. Based on these measurements, it is suggested that the cell can be viewed as an engineering structure in which residual intracellular forces, from contractile microfilaments, exert compressive loading on microtubular elements. This microtubular structure appears to act as a "balanced space frame" (analogous to an aeroplane chassis), maintaining cell shape and consequently storing a residual internal tension (RIT). In dermal fibroblasts this hidden RIT was up to 33% of the measurable force exerted on the collagen gel. Phenotypic differences between space frame organisation and RIT levels could explain site and pathological variations in fibroblast contraction.

1alpha,25-dihydroxyvitamin D3 rapidly inhibits fibroblast-induced collagen gel contraction

1alpha,25-Dihydroxyvitamin D3 (1,25-D3) inhibits the proliferation of fibroblasts in vitro in monolayer culture. We investigated the effect of 1,25-D3 on normal murine and human fibroblasts cultured in collagen type I gels, which more closely resembles the in vivo situation in the dermis. In this culture system 1,25-D3 had no effect on fibroblast proliferation; however, the fibroblast-induced collagen gel contraction was inhibited in a time- and concentration-dependent manner in the nanomolar concentration range. 25-Hydroxyvitamin D3 and 24,25-dihydroxyvitamin D3 were inactive. 1,25-D3 had no effect in fibroblasts lacking a functional vitamin D receptor. Pretreatment of fibroblasts in monolayer culture for 5 min was sufficient to trigger the inhibition of collagen gel contraction. Nifedipine increased collagen gel contraction and counteracted the effect of 1,25-D3. The inhibition of collagen gel contraction by 1,25-D3 is supposed to be mediated by the vitamin D receptor because a functional vitamin D receptor is required, and vitamin D metabolites with low affinity to the vitamin D receptor were inactive. Brief pretreatment of fibroblasts was sufficient to trigger the inhibitory effect of 1,25-D3, suggesting a nongenomic effect. A genomic mode of action could not be ruled out, however, because the inhibition was first measured after 24 h. The antagonism of the calcium channel antagonist nifedipine probably represents the sum of two opposite effects rather than supporting evidence for a nongenomic mode of action of 1,25-D3. In conclusion, 1,25-D3 has a specific and rapidly triggered inhibitory effect on fibroblast-induced collagen gel contraction.

Stimulation of beta1 integrins on fibroblasts induces PDGF independent tyrosine phosphorylation of PDGF beta-receptors

We report that integrin-mediated signaling induces a rapid and transient tyrosine phosphorylation of platelet-derived growth factor (PDGF) beta-receptors in human diploid foreskin AG 1518 fibroblasts. A transient tyrosine phosphorylation of PDGF beta-receptors was evident one and two hours after cells had been plated on collagen type I and fibronectin, as well as on immobilized anti-integrin subunit IgG, but not on poly-L-lysine. In contrast EGF or PDGF alpha-receptors were not phosphorylated on tyrosine residues under these conditions. Tyrosine phosphorylation of PDGF beta-receptors induced by plating on collagen type I was inhibited by cytochalasin D and herbimycin A, unaffected by cycloheximide and enhanced by orthovanadate. Furthermore, a transient phosphorylation of PDGF beta-receptors occurred when AG 518 fibroblasts were cultured in three-dimensional collagen lattices or exposed to external strain exerted through centrifugation. The latter effect was evident already after two minutes. Clustering of cell surface beta1 integrins led to PDGF beta-receptor phosphorylation both in suspended and firmly attached AG 1518 fibroblasts. Plating of cells on collagen type I, fibronectin, and anti-beta1-integrin IgG resulted in the formation of PDGF beta-receptor aggregates as detected by immunofluorescence. Suramin or anti-PDGF-BB IgG had no effect on the plating-induced tyrosine phosphorylation of PDGF beta-receptors. PDGF-B chain mRNA, or protein, were not detected in AG 1518 fibroblasts. Our data suggest that a ligand-independent PDGF beta-receptor activation during cell adhesion and early phases of cell spreading is involved in integrin-mediated signaling in fibroblasts, and constitutes parts of a mechanism for cells to respond during the dynamic phases of externally applied tension as well as fibroblast-mediated tension during cell adhesion and collagen gel contraction.

Electric fields and proliferation in a chronic wound model

A wound model for decubitus and leg ulcers consisting of human dermal fibroblasts in type I collagen dermal "equivalent" matrix (DEM) was exposed in vitro to electric fields similar to postulated endogenous fields in wounds. After an 8-10 day maturation period, conductivity of DEM samples was determined. Then, DEM samples were mounted in oval windows equidistant between Ag/AgCl agar electrodes in exposure chambers containing serum-free medium. A known low-frequency sinusoidal current was then applied for 12 h, and the average electric field amplitude was calculated in the region of the cells. After a 6 h hiatus, 3H-thymidine was introduced for 6 h. This was followed by assay. Over a series of trials, field amplitude ranged from 18 to 1,000 mV/m at frequencies of 10 and 100 Hz. Proliferation was measured by total DNA and 3H-thymidine incorporation. Results indicated that a narrow amplitude window between 37 and 50 mV/meter at 10 Hz yielded increases in proliferation: At maximum (41 mV/m), there was a 70% increase in total DNA (P < .01). Increases occurred in 3H-thymidine incorporation at 41-50 mV/m but not at other amplitudes (P < .05). Increases in total DNA at 41 mV/m occurred at 10 Hz but not 100 Hz (P < .01). 3H-thymidine incorporation was in agreement (P < .05). Response was also a function of cell density within matrix. Proliferation occurred in the same amplitude and frequency ranges in which endogenous fields are expected to occur.

Quantitative analysis of collagen gel contractile forces generated by dermal fibroblasts and the relationship to cell morphology

The force generated in granulation tissue during wound contraction is thought to be cell mediated; however, it is unclear whether contractile forces are generated by fibroblast locomotion or contraction of myofibroblasts. To help clarify this question the force of this contraction can now be determined accurately in a human dermal fibroblast collagen lattice system using a novel instrument known as a Culture Force Monitor. Three distinct phases of contraction of such collagen gels could be identified over the first 24 hours. Most of the force generated by human dermal fibroblasts was produced during the first stage in parallel with cell attachment and associated changes in cell shape, and the appearance of cell processes. During this initial 24 hours no evidence could be found for the presence of myofibroblasts, but stereoscopic and electron microscopic analysis at a range of time points indicated that migratory fibroblasts were present in the system. Comparison of the contraction profiles of cells extracted from other tissues (tendon and articular cartilage), and extracted by different means from the same tissue specimen, indicated that different populations of fibroblasts can be distinguished on the basis of their pattern of contractions. It would seem that most of the force generated in this model is a result of fibroblast attachment and movement within the collagen lattice. Furthermore, different groups of fibroblasts, even within the same tissue, may vary in their contraction (hence locomotory) activity.

Effects of electroporation on the tubulin cytoskeleton and directed migration of corneal fibroblasts cultured within collagen matrices

Electroporation provides a useful method for loading fibroblasts with fluorescent probes for the cytoskeleton, but the possible deleterious effects of this loading technique on cell motility are unknown. We have used conventional and confocal microscopy of living cells and immunohistochemistry to examine the migration and cytoskeleton of chick embryo corneal fibroblasts electroporated while cultured within collagen gels. Fibroblasts cultured in collagen (1 mg/ml) are successfully electroloaded (0.5-1.0 kVcm-1/960 microF in DMEM/F12/20 mM Hepes, pH 7.2) with dextran (4-150 kDa) and immunoglobulin, but subsequently display uncoordinated pseudopodia and hence are unable to migrate effectively in any one direction. The lack of directed movement is due to depolymerization of microtubules and/or a perinuclear collapse of vimentin filaments, seemingly caused by millimolar levels of Ca2+ ions derived from culture medium following electroporation. Fibroblasts loaded in a buffer which resembles intracellular fluid (< or = 10 microM Ca2+) maintain their cytoskeleton and continue to migrate, when returned to culture medium within 10 min. Using this novel approach, we have loaded fibroblasts migrating through extracellular matrix (ECM) with rhodamine phalloidin and monitored the behavior of the labeled actin cortex by confocal microscopy. During migration phalloidin-actin accumulates near the base of pseudopodia and at the rear of the cell where it is subsequently left behind. We conclude that electroporation is a valuable technique for loading fibroblasts to study migration within ECM, provided that the conditions used support stability of the tubulin cytoskeleton.

Microtubules can modulate pseudopod activity from a distance inside macrophages

Microtubules are thought to influence cell shape as structural components of an integrated cytoskeletal matrix. Here we show that microtubules can affect the dynamics of macrophage pseudopodia without being integrated into their structure. Macrophages landing on glass surfaces spread within 15 min into flattened circular cells with radial symmetry, and the radial distribution of microtubules reflected this symmetry. Depolymerization of microtubules using nocodazole, colchicine, or vinblastine did not inhibit macrophage spreading or the early establishment of radial symmetry. Shortly after spreading, however, macrophages without microtubules gradually became asymmetric, assuming irregular, lobed profiles. The asymmetry resulted from exaggerated protrusion and retraction of pseudopodia, with net retraction overall. This loss of radial symmetry could be inhibited by treatment of initially spread cells with cytochalasin D, indicating that the change in cell shape was mediated by the actin cytoskeleton. Intact microtubules suppressed the exaggerated pseudopod movements, even when they were separated by a distance from the cell margin. In cells treated with taxol, microtubules remained clustered near the cell center after spreading, yet the dynamics of pseudopodia at the cell margin were reduced and cells maintained a circular profile. Similarly, in cells treated with low concentrations of nocodazole, a much reduced microtubule cytoskeleton nonetheless suppressed pseudopod dynamics. We propose that microtubules act to stabilize cell shape at a distance from the cell edge via a biochemical intermediate that affects the structure or function of the microfilament system.

Induction of tissue inhibitor and matrix metalloproteinase by serum in human heart-derived fibroblast and endomyocardial endothelial cells

To understand the regulatory mechanisms of extracellular matrix (ECM) turnover and proteinase expression in human cardiovascular tissue, we have isolated and characterized human heart fibroblast (HHF) and human heart endothelial (HHE) cells from endomyocardial biopsy specimens. HHE cell in culture exhibited the typical cobblestone growth pattern and positive immunofluorescent staining for factor VIII related antigen. HHF demonstrated the typical spindle shape during culture and were positive for vimentin. Both cell types were negative for alpha-actin, indicating that these cells were of nonmuscle origin. Cell growth studies revealed significant growth when maintained in limiting serum concentration, suggesting mitogenic activity of these cells, and demonstrated growth inhibitory activity when grown in serum-free medium. Serum-dependent matrix metalloproteinases (MMPs) and tissue inhibitor of metalloproteinases (TIMPs) expression was measured by zymography, immunoblot, and Northern blot analysis. Results indicated that serum induces both the MMP and TIMP expression at the mRNA and protein levels in a dose-dependent manner. This induction was inhibited by actinomycin D and cycloheximide, suggesting transcriptional and translational regulation of MMP and TIMP. Indirect immunofluorescence labeling indicated expression of MMP and TIMP in HHF and HHE cells. These results suggested that the serum induces proliferation as well as expression of MMP and TIMP in HHE and HHF cells. The growth inhibitory activity of these cell cultures will enable us to explore further the nature of this response and compare this phenomenon with other growth inhibitors and growth promoters identified in other normal and transformed cells.

Biological specificity and measurable physical properties of cell surface receptors and their possible role in signal transduction through the cytoskeleton

It is proposed that the binding specificities of cell adhesion molecules are manifested in their measurable physical properties. A method specifically designed to measure the interfacial tension of cell aggregates is described. With the introduction of a statistical mechanical model, the measured values of tensions for aggregates consisting of genetically engineered cells with controlled adhesive properties are used to obtain information on the strength of individual receptor-ligand bonds. The strength of binding must depend on the receptor and its ligand and reflects the amino acid sequence of the binding proteins. Many of the cell surface receptors, being transmembrane proteins, are attached to the various macromolecular networks of the cytoskeleton; therefore, it is suggested that their ligation and ensuing conformational change may substantially affect the mechanical state of the cytoskeletal assemblies. Since these assemblies are believed to actively participate in intracellular signaling by transmitting signals from the cell membrane into the nucleus, the cell adhesion molecules may influence signaling in a predictable way through their measurable physical characteristics. In particular, varying bond strength at the cell surface may lead to differential gene regulation.

Topographic compensation: guidance and directed locomotion of fibroblasts on grooved micromachined substrata in the absence of microtubules

Fibroblasts cultured on grooved substrata align themselves and migrate in the direction of the grooves, a phenomenon called contact guidance. Microtubules have been deemed important for cell polarization, directed locomotion, and contact guidance. Because microtubules were the first cytoskeletal element to align with the grooves when fibroblasts spread on grooved substrata, we investigated the consequences of eliminating the influence of microtubules by seeding fibroblasts onto smooth and grooved micromachined substrata in the presence of colcemid. Fibroblasts were examined by time-lapse cinematography and epifluorescence or confocal microscopy to determine cell shape and orientation and the distribution of cytoskeletal or associated elements including actin filaments, vinculin, intermediate filaments, microtubules, and kinesin. As expected, cells spreading on smooth surfaces in the presence of colcemid did not polarize or locomote. Surprisingly however, by 24 hours, cells spread on grooves in the presence of colcemid were morphologically indistinguishable from controls spread on grooves. Both groups were aligned and polarized with the direction of the grooves and demonstrated directional locomotion along the grooves. In the absence of microtubules, kinesin localized to some of the aligned stress fibers and to leading edges of cells spreading on grooves. The grooved substratum compensated for the microtubule deficiency by organizing and maintaining an aligned actin filament framework. Thus, microtubules are not required to establish or maintain stable, polarized cell shapes or directed locomotion, provided an alternate oriented cytoskeletal component is available.

In vitro reconstruction of hybrid arterial media with molecular and cellular orientations

A hybrid medial tissue composed of a type I collagen gel, into which smooth muscle cells (SMCs) derived from bovine aortic media were 3-dimensionally (3D) embedded, was constructed around an elastomeric silicone tube (outer diameter: 8 mm). Subsequently, hybrid tissues thus prepared were subjected to three modes of mechanical stimulation in the medium: one was subjected to flotation with no disturbance (isotonic control), the second was kept isometrically (static stress) and the third was subjected to continuous periodic stretch by inflation of the embedded silicone tube which stimulated arterial pulsation (dynamic stress, amplitude: 5% in inner diameter; frequency: 60 RPM). After a 5-day culture period, hybrid tissues were morphologically investigated. In control gels, polygonal SMCs and extracellular collagen fiber bundles were randomly oriented. On the other hand, upon static or dynamic stress loading, bipolar spindle-shaped SMCs and dense collagen fiber bundles were aligned circumferentially around the silicone tube, which proceeded with time. The orientations of SMCs and collagen fibers were more prominent in dynamically stressed hybrid tissues than those in statistically stressed ones. The pulsatile stress-loaded hybrid medial tissue mimicked the media of native muscular arteries in terms of cellular and molecular orientations.

Mechanical stress-induced orientation and ultrastructural change of smooth muscle cells cultured in three-dimensional collagen lattices

The effect of tensile stress on the orientation and phenotype of arterial smooth muscle cells (SMCs) cultured in three-dimensional (3D) type I collagen gels was morphologically investigated. Ring-shaped hybrid tissues were prepared by thermal gelation of a cold mixed solution of type I collagen and SMCs derived from bovine aorta. The tissues were subjected to three different modes of tensile stress. They were floated (isotonic control), stretched isometrically (static stress) and periodically stretched and recoiled by 5% above and below the resting tissue length at 60 RPM frequency (dynamic stress). After incubation for up to four wk, the tissues were investigated under a light microscope (LM) and a transmission electron microscope (TEM). Hematoxylin and eosin-stained LM samples revealed that, irrespective of static or dynamic stress loading, SMCs in stress-loaded tissues exhibited elongated bipolar spindle shape and were regularly oriented parallel to the direction of the strain, whereas those in isotonic control tissues were polygonal or spherical and had no preferential orientation. In Azan-stained samples, collagen fiber bundles in isotonic control tissues were somewhat retracted around the polygonal SMCs to form a random network. On the other hand, those in statically and dynamically stressed tissues were accumulated and prominently oriented parallel to the stretch direction. Ultrastructural investigation using a TEM showed that SMCs in control and statically stressed tissues were almost totally filled with synthetic organelles such as rough endoplasmic reticulums, free ribosomes, Golgi complexes and mitochondria, indicating that the cells remained in the synthetic phenotype. On the other hand, SMCs in dynamically stressed tissues had increased fractions of contractile apparatus, such as myofilaments, dense bodies and extracellular filamentous materials equivalent to basement membranes, that progressed with incubation time. These results indicate that periodic stretch, in concert with 3-D extracellular collagen matrices, play a significant role in the phenotypic modulation of SMCs from the synthetic to the contractile state, as well as cellular and biomolecular orientation.

Integrin-mediated collagen gel contraction by cardiac fibroblasts. Effects of angiotensin II

Angiotensin II (Ang II), a vasoactive octapeptide, has been implicated in cardiac growth and the development of hypertrophy and fibrosis secondary in hypertensive disease. These consequences of Ang II imply an effect on the function and morphology of cardiac interstitial cells (fibroblasts). The present investigation was designed to (1) determine whether neonatal heart fibroblasts (NHFs) possess functional Ang II receptors on their plasma membrane and (2) examine the effects of Ang II on NHFs in vitro using three- and two-dimensional (3D and 2D, respectively) cultures. Several analytic techniques were used to test the specific questions of the present study. Since cardiac fibroblast phenotype can be influenced by culture conditions, both 2D and 3D cultures were used in the present investigations. Reverse-transcriptase polymerase chain reaction and radioligand binding analysis were used to test for the presence of Ang II receptors on NHFs. Both revealed that NHFs in 2D culture possess Ang II receptor mRNA and Ang II receptors. When isolated NHFs were cultured in 3D collagen gels and treated with Ang II, gel contraction was stimulated by NHFs. This effect was attenuated by the specific Ang II receptor antagonist [Sar1,Ala8]Ang II. Ang II-stimulated gel contraction was completely inhibited by extracellular matrix receptor (beta 1-integrin) antibodies (P < .05), supporting previous studies indicating that collagen gel contraction is mediated via the integrins. Immunofluorescent staining was used to test the localization of cell-surface integrins. A more intense staining pattern for beta 1-integrin in Ang II-treated versus control cells was observed.(ABSTRACT TRUNCATED AT 250 WORDS)

Dissociation of actin microfilament organization from acquisition and maintenance of elongated shape of human dermal fibroblasts in three-dimensional collagen gel

Actin microfilaments of the fibroblasts cultured in a collagen gel were distributed along the inner surface of the entire cell membrane, in either spherical shape at an initial stage of culture or elongated shape at a later stage. The distribution was quite different from that of the fibroblast cultured on a two-dimensional surface, where actin microfilaments were found to be aligned essentially along the inner membrane which is in contact with a flat surface. Timing of morphological change from spherical shape to spread shape or elongated shape was also greatly affected by contact with substrates whether in two-dimension or in three-dimension: distinct morphological change was observed within 6 h on glass or on the collagen gel, and at 30 h or later within the collagen gel. The retardation of cell elongation in the gel was antagonized by a low dose (0.2 microM) of cytochalasin D, although the drug kept the cells in round shape at a concentration of 2 microM. Since a low concentration of cytochalasin was reported to induce actin polymerization in vitro, the organization of actin microfilaments was examined by rhodamine-phalloidin staining. It was found that actin filaments in elongated cells by low cytochalasin D were disrupted. These results suggest that accelerated acquisition of elongated shape by the treatment of a low dose of cytochalasin D might be initiated by destabilization of the actin microfilaments that may scaffold the spherical shape of the cell in the collagen gel. The elongated shape thus formed returned to spherical upon washing of the added free cytochalasin D.(ABSTRACT TRUNCATED AT 250 WORDS)

Impaired regulation of collagen pro-alpha 1(I) mRNA and change in pattern of collagen-binding integrins on scleroderma fibroblasts

We explored the hypothesis that dermal fibroblasts isolated from patients suffering from systemic sclerosis are disturbed in their ability to interact functionally with native collagen fibers. Additionally, we investigated the expression of one collagen-binding integrin matrix receptor, alpha 1 beta 1 on those cells. Two populations of primary dermal fibroblasts were established, one from patients with systemic sclerosis and one from normal subjects. When cultured for 24 h in free-floating collagen gels, both types of fibroblasts down-regulated the cellular content of collagen pro-alpha 1(I) messenger ribonucleic acid, the systemic sclerosis fibroblasts less markedly than the normals. In normal, but not in systemic sclerosis fibroblasts, the kinetics of collagen gel contraction were directly proportional to the extent of the down-regulation. Fetal bovine serum stimulated collagen gel contraction in both populations. When grown in collagen gels in the presence of fetal bovine serum, no difference between systemic sclerosis and normal fibroblasts in capacity to down-regulate pro-alpha 1(I) was observed. Collagen-binding beta 1 integrins mediate the functional interactions between fibroblasts and the collagen fibers. To assess the cell surface expression of collagen-binding beta 1 integrins on fibroblasts, we labeled cells with 125I and subjected Triton X-100 extracts from them to immunoprecipitation with anti-beta 1 integrin immunoglobulin G. Among the systemic sclerosis fibroblasts, a larger number of isolates expressed low amount of alpha 1 beta 1 than did the fibroblasts isolated from normal individuals. Our data are compatible with the hypothesis that systemic sclerosis fibroblasts have a disturbed interaction with collagen fibers; this disturbance may in part be the result of an aberrant expression of collagen-binding beta 1 integrins.

Endocardial endothelium in the rat: cell shape and organization of the cytoskeleton

The cytoskeleton in endocardial endothelium of rat heart was examined by en face confocal scanning laser microscopy. In the ventricular cavity, endocardial endothelial cells had a polygonal shape and F-actin staining was generally restricted to the peripheral junctional actin band. Central F-actin bundles, or stress fibers, in endocardial endothelial cells were found on the tendon end of papillary muscles, especially in the right ventricle, and frequently in the outflow tract of both ventricles; elsewhere, stress fibers were scarce. Many endocardial endothelial cells were elongated in areas of endothelium with stress fibers, but no correlation was found between cell elongation and the number of stress fibers. An inverse correlation was found between the number of stress fibers and the surface area of endocardial endothelial cells. Shear stress as well as mechanical deformation of the surface of the ventricular wall during the cardiac cycle may affect cell shape and the organization of actin filaments in endocardial endothelial cells. Vimentin in endocardial endothelial cells formed a filamentous network with some distinct cytoplasmic and juxtanuclear vimentin bundles. No perinuclear ring of vimentin filaments was observed in endocardial endothelium. Microtubules in endocardial endothelial cells were, in contrast to endothelial cells of rat aorta, not aligned, less closely packed and originated from randomly distributed centriolar regions. The cytoskeleton has been suggested to play an important role in cellular functions of vascular endothelial cells. Accordingly, differences in the cytoskeletal organization between endocardial and vascular endothelial cells may relate to differences in functional properties.

Mechanisms and dynamics of mechanical strengthening in ligament-equivalent fibroblast-populated collagen matrices

We have measured the dynamics of extracellular matrix consolidation and strengthening by human dermal fibroblasts in hydrated collagen gels. Constraining matrix consolidation between two porous polyethylene posts held rigidly apart set up the mechanical stress which led to the formation of uniaxially oriented fibroblast-populated collagen matrices with a histology resembling a ligament. We measured the mechanical stiffness and tensile strength of these ligament equivalents (LEs) as a function of age at biweekly intervals up to 12 weeks in culture using a mechanical spectrometer customized for performing experiments under physiologic conditions. The LE load-strain curve changed as a function of LE age, increasing in stiffness and exhibiting less plastic-like behavior. At 12 weeks, LEs had acquired up to 30 times the breaking strength of 1-week-old LEs. Matrix strengthening occurred primarily through the formation of BAPN-sensitive, lysyl oxidase catalyzed crosslinks. Sulfated glycosaminoglycan (GAG) content increased monotonically with LE age, reaching levels that are characteristic of ligaments. Cells in the LEs actively incorporated [3H]proline and [35S]sulfate into the extracellular matrix. Over the first three weeks, DNA content increased rapidly but thereafter remained constant. This data represent the first documentation of strengthening kinetics for cell-assembled biopolymer gels and the results suggest that this LE tissue may be a valuable model for studying the cellular processes responsible for tissue growth, repair, and remodeling.

Age-related changes in collagen gel contraction by cultured human lung fibroblasts resulting in cross-over of contraction curves between young and aged cells

We examined the effects of population doubling levels on collagen gel contraction by human lung fibroblasts (TIG-1). The sizes of gels at day 4 of culture, when the number of cells was the same as the initial number, were smaller with young cells than with aged cells. Therefore, retractive force had decreased with in vitro cellular aging. On the other hand, the lag time until gel contraction began became shorter with aging, resulting in the cross-over of contraction curves of young and aged cells. Morphological changes, such as pseudopodia protrusion, were suppressed in collagen gel. The surrounding collagen fibrils prevented young cells from moving more than aged cells. The weakened omnidirectional interaction with collagen fibrils on the entire surface of aged cells might result in an earlier occurrence of morphological change and, thereby, gel contraction.

Primary and secondary chick heart fibroblasts: fast and slow-moving cells show no significant difference in microtubule dynamics

Highly motile chick heart fibroblasts in primary culture (1 degree CHFs) gradually convert into much slower-moving secondary (2 degrees) cells. The polarized movement of the latter, but not the former, cell type has been found to be dependent on an intact microtubule (MT) network [Middleton et al., 1989, J. Cell Sci. 94:25-32]. To investigate the comparative stability of the MT networks of 1 degree s and 2 degrees s, turnover was investigated by microinjection of biotin-labeled brain tubulin to act as a reporter. MTs in both cell types were found to be very dynamic, with the MT networks effectively disassembled by about 30 min in 1 degree CHFs and 60 min in 2 degrees CHFs, with mainly MT fragments remaining beyond these times. All MTs and fragments were found to have turned over by 1 h in 1 degree CHFs and 80 min in 2 degrees s. Because 2 degrees CHFs were found to be on average six times larger than 1 degree s, the difference in MT turnover time was considered largely due to the size difference. For both 1 degree and 2 degrees cells, the more slowly turning over MTs were generally curly and perinuclear in distribution, resembling stable MTs in other systems, but they appeared significantly earlier in CHFs. However, no discrete subpopulations of slower turning over MTs were found to be associated with either the leading edges or the processes of either cell type. In addition, no major differences were identified in the patterns of modified alpha-tubulin along the MTs or of MT cold or drug stability. It is concluded that MTs do not have a direct structural or skeletal function in maintaining a polarized 2 degrees CHF cell shape, but rather play an ancillary role.

Fibroblast-mediated collagen gel contraction does not require fibronectin-alpha 5 beta 1 integrin interaction

Fibroblasts cultured within free-floating collagen gels can bind to and reorganize the surrounding collagen fibrils into a more dense and compact arrangement. Collagen gel contraction provides an in vitro model for studying fibroblast-collagen interactions important in wound healing, fibrosis, scar contraction, and connective tissue morphogenesis. We have assessed the role of fibronectin and its interaction with the alpha 5 beta 1 "high affinity" fibronectin-specific integrin receptor in collagen gel contraction. A variety of agents, which specifically inhibit fibronectin-alpha 5 beta 1 interactions, were tested for their abilities to inhibit fibroblast-mediated collagen gel contraction. These included anti-alpha 5 beta 1 monoclonal antibodies, the synthetic peptide GRGDSP, the cell adhesive fragment of fibronectin, and an antibody against the cell adhesive region of fibronectin. None of these agents inhibited collagen gel contraction. Therefore, it is concluded that fibronectin-alpha 5 beta 1 interactions are not necessary for collagen gel contraction. However, collagen gel contraction is dependent on a member or members of the beta 1 subfamily of integrin matrix receptors. A polyclonal antiserum and a monoclonal antibody, both directed against the beta 1 subunit of integrin matrix receptors, inhibited the spreading of fibroblasts in the collagen gel and inhibited collagen gel contraction. This study demonstrates that fibroblast-mediated collagen gel contraction is independent of fibronectin-alpha 5 beta 1 interactions but dependent on an interaction of beta 1 integrin matrix receptors with collagen fibers.

Fibroblast contraction occurs on release of tension in attached collagen lattices: dependency on an organized actin cytoskeleton and serum

The generation of tension in granulation tissue undergoing contraction is believed to be a cell-mediated event. In this study we used attached collagen lattices as a model system for studying the cellular mechanisms of tension generation by fibroblasts in an extracellular matrix. Fibroblasts in attached collagen lattices developed stress fibers, surface associated fibronectin fibrils, and a fibronexus-like transmembrane association interconnecting the two structural components. Release of the attached collagen lattice from its points of attachment resulted in a rapid, symmetrical contraction of the collagen lattice. Rapid contraction occurred within the first 10 minutes after release of the lattice from the substratum, with greater than 70% of the contraction occurring within the first 2 minutes. Rapid contraction resulted in a shortening of the elongate fibroblasts and compaction of the stress fibers with their subsequent disappearance from the cell. Cytochalasin D treatment prior to release disrupted the actin cytoskeleton and completely inhibited rapid contraction. The removal of serum prior to release inhibited rapid contraction, while the re-addition of serum restored rapid contraction. These results demonstrate that fibroblasts can develop tension in an attached collagen lattice and that upon release of tension the fibroblasts undergo contraction resulting in a rapid contraction of the collagen lattice. Fibroblast contraction is dependent upon an organized actin cytoskeleton and is promoted by the presence of serum.

A new technique to study the mechanical properties of collagen lattices

A new technique to study the mechanical properties of collagen lattices or dermal equivalents is described. With the help of the load-extension curve obtained with a uniaxial traction apparatus, a stiffness modulus varying from 0.06 to 1 MPa is calculated from the studied parameters (duration of culture, collagen and fibroblast concentration). The technique is presented as a new tool for testing the effect of pharmacological agents on the mechanical properties of the skin.

Substratum-growth factor collaborations are required for the mitogenic activities of activin and FGF on embryonal carcinoma cells

When P19 mouse embryonal carcinoma cells are grown in a serum-free N2 medium on surfaces of tissue culture plastic, they die within two days. The death of these P19 cells is prevented by activin A and basic FGF (bFGF). The cells do not divide under these conditions. However, when P19 cells are cultured on substrata of extracellular matrix proteins such as laminin and fibronectin, activin A and bFGF are potent mitogens. These data show that the substratum to which cells are exposed can regulate their mitogenic response to growth factors.

Nucleokinesis: distinct pattern of cell translocation in response to an autocrine motility factor-like substance or fibronectin

Human lung adenocarcinoma cells develop bipolar shape with prominent pseudopodia (greater than or equal to 200 microns) when cultured in the presence of autocrine motility factor (AMF)-like substance or on fibronectin-coated substrata. AMF was partially purified from a human lung adenocarcinoma cell line and has a peak biological activity at a molecular mass of 67 kDa. Using time-lapse photography, we observed that during AMF- or fibronectin-induced cell translocation, the nuclei of some bipolar cells are transported to the opposite end of the cell, while gross cell shape and position remain unchanged. Following this nuclear movement, which we call "nucleokinesis," the posterior pseudopodium is retracted behind the nucleus. Thus, extension of a pseudopodium followed by nucleokinesis in the same direction and retraction of the cell body behind the nucleus is a normal motile sequence in translocating bipolar cells. This suggests that nucleokinesis is a distinct step in whole-cell translocation of bipolar cells on biological substrata and that pseudopodia can be used as nuclear transport organs. In contrast, adenocarcinoma cells cultured on artificial substrata and in the absence of AMF display a fibroblast-like motility pattern with the nucleus centrally located within the migrating cell.

Response to growth factors of human dermal fibroblasts in a quiescent state owing to cell-matrix contact inhibition

Mitogenic responses to various growth factors were compared for quiescent human dermal fibroblasts cultured under three different conditions; serum depletion, cell-cell contact inhibition and cell-matrix contact inhibition. The non-dividing fibroblasts cultured under a low serum condition (0.2% fetal bovine serum, FBS) or in a confluent culture with 10% FBS resumed multiplying upon exposure to any one of or any combination of the growth factors examined; epidermal growth factor (EGF), basic fibroblast growth factor (b-FGF), platelet-derived growth factor (PDGF) and transforming growth factor beta (TGF-beta). The only exception was the lack of effect of TGF-beta on the cell under a low serum condition. In contrast, the proliferation of fibroblasts which were growth-arrested in contracted collagen gel by cell-matrix contact inhibition was not stimulated by any of the growth factors examined except for PDGF. It is currently accepted that the mechanism of growth stimulation or signal transduction after binding of each growth factor to the specific receptor depends on the kind of growth factor. The results suggest that the signal transductions delivered by EGF, b-FGF or TGF-beta are inactivated by a high level of interaction of collagen fibrils with the cell membrane (under the condition of cell-matrix contact inhibition); whereas the signal transduction by PDGF is unaffected. The finding supports the existence of a specific growth stimulation pathway for PDGF.

Role of cell-matrix contacts in cell migration and epithelial-mesenchymal transformation

Epithelial cells make contact with extracellular matrix via receptors on the basal surface that interact with the basal actin cortex. In 3D matrix, the mesenchymal cell makes contact with matrix all around its circumference via similar receptors. When moving, the fibroblasts is constantly constructing a new front end. We postulate in a 'fixed cortex' theory of cell motility that the circumferential actin cortex is firmly attached to matrix and that the myosin-rich endoplasm slides past it into the continually forming new front end. During epithelial-mesenchymal transformation, the presumptive mesenchymal cell seems to turn on the new front end mechanism as a way of emigrating from the epithelium into the underlying matrix with which it makes 'fixed' contacts. Master genes may exist that regulate the expression of epithelial genes on the one hand, and mesenchymal genes on the other.