Free fatty acids and dialyzed serum alterations of fibroblast populated collagen lattice contraction.

Fibroblast populated collagen lattices (FPCL) have facilitated the in vitro study of wound contraction and scar contracture. Mixing fibroblasts, serum containing culture medium and soluble collagen, together and then incubating the mixture at 37 degrees C produces a FPCL. The fibroblasts elongate and spread within the collagen matrix, and by forces associated with cell locomotion they reorganize the collagen fibers. The reorganization of the collagen produces a reduction in size of the FPCL, called lattice contraction. It was also found that dialyzed fetal bovine serum did not support lattice contraction. Supplementing dialyzed serum with fatty acids accelerated lattice contraction. The fatty acid composition of the fibroblast plasma membrane influences that membrane fluidity. These studies demonstrated that lattice contraction was enhanced by the additions of saturated fatty acids in the order of laurate (C-12), palmitic (C-16), and stearate (C-18). With unsaturated fatty acids additions, the order of enhanced lattice contraction was arachidonate (4 C = C), linoleate (2 C = C) and oleate (1 C = C). The addition of dialyzed serum with or without fatty acids neither altered ATP-induced cell contraction activity nor cell proliferation. It was concluded that free fatty acid additions do not modulate FPCL contraction by enhancing microfilaments contraction or increasing cell numbers. The mechanism of action was proposed to be by altering cell membrane fluidity. This finding further supports the theory that the mechanism for lattice contraction is cell locomotion, rather than cell contraction.     

Cell coupling modulates the contraction of fibroblast-populated collagen lattices

Cultured dermal fibroblasts become notably elongated when incorporated into a fibroblast-populated collagen lattice (FPCL). With time these fibroblasts reorganize the collagen responsible for reduction in lattice size. In monolayer the microinjection of Lucifer Yellow (LY) into cultured human fibroblasts shows cell coupling through gap junctions. Human fibroblasts residing on the periphery of a FPCL are at high density and the microinjection of LY into one of those fibroblasts demonstrates cell coupling. Cells within the center of an FPCL are at low density and appear to be independent of one another; however, the microinjection of LY into selected fibroblasts again demonstrates cell coupling. Hence the microinjection of cells in both the center and the edge of a FPCL pass dye to numerous neighbors. Does cell coupling influence FPCL contraction? FPCL incubated with heptanol and octanol, aliphatic alcohols that uncouple cells, inhibits lattice contraction, whereas hexanol, an aliphatic alcohol that does not uncouple cells, did not alter lattice contraction. Fibroblasts derived from connexin 43 (a transmembrane protein responsible for gap junction structures) knockout mice were demonstrated to lack gap junctional communications. When incorporated into a FPCL these cells failed to elongate and demonstrated retarded lattice contraction. Hence, gap junctional communications between fibroblasts incorporated into collagen lattices appear to optimize FPCL contraction and suggest a role for gap junctions in the organization of collagen fibers.     

Sheep amniotic fluid has a protein factor which stimulates human fibroblast populated collagen lattice contraction.

Sutured incisional wounds made in fetal sheep and rabbits heal without scarring. Fetal sheep excisional wounds can close by contraction, but those in fetal rabbits do not. In vivo and in vitro evidence suggests that rabbit amniotic fluid inhibits wound contraction. The question arises: does sheep amniotic fluid promote wound contraction because their fetal wounds close by contraction? Sheep amniotic fluid (SAF) from 100 and 125 days gestation was tested in fibroblast populated collagen lattice (FPCL) system, an in vitro model of wound contraction. SAF stimulated FPCL contraction in a dose responsive manner. SAF from a 100 day fetus was more stimulating than a 125 day SAF. SAF enhanced FPCL contraction in the presence or absence of serum. SAF was fractionated by size, using column chromatography. It yielded a fraction with an estimated molecular weigh near 40,000 daltons, which stimulated FPCL contraction. The factor was inactivated by proteolytic digestion and heat denaturation. This protein fraction which stimulates FPCL contraction is not related to (1) actin-myosin filaments enhanced contraction by ATP-induced cell contraction, (2) promotion of fibroblast elongation on glass surface or in collagen, or (3) increased cell number by enhanced fibroblast duplication in a collagen matrix. A mechanism for SAF promotion of FPCL contraction was investigated but not identified.     

Demonstration of a direct role for myosin light chain kinase in fibroblast-populated collagen lattice contraction.

Mixing feed fibroblasts with soluble collagen and serum-supplemented culture medium at 37 degrees C results in the entrapment of cells within the polymerizing collagen matrix. This cellular-collagen complex is referred to as a fibroblast-populated collagen lattice (FPCL). In time, this FPCL undergoes a reduction in size called lattice contraction. The proposed mechanism for lattice contraction is cellular force produced by cytoplasmic microfilaments which organize collagen fibrils compacting the matrix. When the regulatory subunits of myosin, myosin light chains, are phosphorylated by myosin light chain kinase (MLCK), myosin ATPase activity is increased and actin-myosin dynamic filament sliding occurs. Elevated levels of myosin ATPase are required for maximal lattice contraction. Cholera toxin inhibits lattice contraction by increasing intracellular levels of cAMP. It is proposed that increased cytoplasmic concentrations of cAMP promote phosphorylation of MLCK, the enzyme important for maximizing myosin ATPase activity. Phosphorylating MLCK in vitro inhibits activity by decreasing its sensitivity to calcium-calmodulin complex. A decrease in MLCK activity would result in lower levels of myosin ATPase activity. MLCK, purified from turkey gizzard, was subjected to limited proteolytic digestion to produce calmodulin-independent-MLCK. The partially digested kinase does not require calcium-calmodulin for activation. Independent-MLCK is not subject to inhibition by phosphorylation. The electroporetic inoculation of independent-MLCK into fibroblasts before FPCL manufacture produced enhanced lattice contraction. Lattice contraction, in the presence of cholera toxin, was restored to normal levels by the prior electroporetic introduction of independent-MLCK. These findings support the hypothesis that increases in cAMP hinder lattice contraction by a mechanism involving inhibition of MLCK and myosin ATPase.     

Rat mast cells communicate with fibroblasts via gap junction intercellular communications

Usually mast cells (MCs) modulate other cellular activities through the release of their cytoplasmic granules. Recently, gap junctional intercellular communication (GJIC) between an established human MC cell line (HMC-1) co-cultured with human dermal fibroblasts in fibroblast populated collagen lattices (FPCLs), enhanced the rate and degree of FPCL contraction. However, HMC-1 cells were unable to generate GJIC with human neonatal fibroblasts in monolayer culture. Here freshly isolated rat peritoneal MCs are co-cultured with fibroblasts in collagen lattices and in monolayer culture in vitro and introduced into rat polyvinyl alcohol (PVA) sponge implants in vivo. Co-cultured MC-FPCL contracted faster and to a greater degree. Loading Calcein AM green fluorescent dye into red fluorescent Dil tagged MC generates MC-paratroopers. When MC-paratroopers form GJIC with fibroblasts, some green dye is passed into the fibroblast, while the MC-paratrooper retains both its red and green fluorescence. MC-paratroopers passed green fluorescent dye into both human and rat dermal fibroblasts in monolayer culture. In rats 7-day-old subcutaneous PVA sponge implants, which received an injection of MC-paratroopers, exhibited auto-fluorescent green fibroblasts, when harvested 24 h later. MC-paratroopers pretreated with a long-acting GJIC inhibitor prior to their introduction into PVA sponge implants, failed to pass dye into fibroblasts. It is proposed that GJIC between granulation tissue fibroblasts and MCs can modulate some aspects of wound repair and fibrosis.     

Dupuytren's disease: physiologic changes in nodule and cord fibroblasts through aging in vitro

The pathogenesis of the fibrotic disease Dupuytren's contracture remains unclear. The disease process includes two structurally distinct fibrotic elements, the nodule and the cord. It has been proposed that as the disease progresses, nodules develop into cords. To corroborate that hypothesis, the authors took advantage of cultured fibroblast differences found between gap junction intercellular communication and fibroblast-populated collagen lattice contraction. Paired fibroblast cell lines of nodules and cords derived from four patients with Dupuytren's disease were maintained in culture for at least eight passages. The presence of gap junction intercellular communication in nodule- and cord-derived fibroblasts was documented and reported as a coupling index. The contraction of free-floating nodule- or cord-derived collagen lattices was also documented and reported. Early passage (passage 4) cord-derived fibroblasts showed a significant increase in coupling index compared with passage 4 nodule-derived fibroblasts (4.0 +/- 0.4 versus 2.5 +/- 0.3, respectively), where p < or = 0.01. However, late passage (passage 8) nodule- and cord-derived fibroblasts were equivalent in their coupling index (4.1 +/- 0.4 versus 4.4 +/- 0.4, respectively). Early passage nodule-derived fibroblast-populated collagen lattices contracted by 64 percent, whereas late passage nodule-derived lattices showed less contraction, at only 40 percent. Early and late passage cord-derived lattices contracted 46 and 37 percent, respectively. All nodule- and cord-derived cell lines were statistically equivalent at lattice contraction by passage 8. These in vitro studies support the hypothesis that fibroblasts derived from Dupuytren's contracture nodules change their phenotype after undergoing repeated cell passage, acquiring a cord-like fibroblast phenotype. Dupuytren's nodules represent the early, active form of fibrosis in which cells are more proliferative, better at fibroblast-populated collagen lattice contraction, and display less gap junction intercellular communication. The speculation is that alterations in gap junction intercellular communication may be involved in the progression of Dupuytren's nodules to cords as the disease progresses.     

Hyaluronic acid stimulates human fibroblast proliferation within a collagen matrix

Human dermal fibroblasts suspended in a collagen matrix exhibit a 4-day delay in cell division, while the same cells in monolayer divided by day 1. The initial rates of ³H-thymidine incorporation by cells in monolayer or suspended in collagen were not significantly different. When suspended in collagen, there was a threefold increase in the proportion of cells in a tetraploidal (4N) DNA state compared to the same cells in monolayer. Flow cytometry analysis and ³H-thymidine incorporation studies identified the delay of cell division as a consequence of a block in the G2/M of the cell cycle and not an inhibition of DNA synthesis. The inclusion of 150 μ/ml of hyaluronic acid (HA) in the manufacture of fibroblast populated collagen lattices (FPCL) caused a stimulation of cell division, as determined by cell counting; increased the expression of tubulin, as determined by Western blot analysis; and reduced the proportion of cells in a 4N state, as determined by flow cytometry. HA added to the same cells growing in monolayer produced a minimal increase in the rate of cell division or DNA synthesis. HA supplementation of FPCLs stimulated cell division as well as tubulin concentrations, but it did not enhance lattice contraction. The introduction of tubulin isolated from pig brain or purchased tubulin into fibroblasts by electroporation prior to their transfer into collagen lattices promoted cell division in the first 24 hours and enhanced FPCL contraction. It is proposed that tubulin protein, the building blocks of microtubules, is limited in human fibroblasts residing within a collagen matrix. When human fibroblasts are suspended in collagen, one effect of added HA may be to stimulate the synthesis of tubulin which assists cells through the cell cycle. J. Cell. Physiol. 177:465–473, 1998. © 1998 Wiley-Liss, Inc.     

MMP-14 and MMP-2 are key metalloproteases in Dupuytren's disease fibroblast-mediated contraction

Dupuytren's disease (DD) is a common fibrotic condition of the palmar fascia, leading to deposition of collagen-rich cords and progressive flexion of the fingers. The molecular mechanisms underlying the disease are poorly understood. We have previously shown altered expression of extracellular matrix-degrading proteases (matrix metalloproteases, MMPs, and 'a disintegrin and metalloprotease domain with thrombospondin motifs', ADAMTS, proteases) in palmar fascia from DD patients compared to control and shown that the expression of a sub-set of these genes correlates with post-operative outcome. In the current study we used an in vitro model of collagen contraction to identify the specific proteases which mediate this effect. We measured the expression of all MMPs, ADAMTSs and their inhibitors in fibroblasts derived from the palmar fascia of DD patients, both in monolayer culture and in the fibroblast-populated collagen lattice (FPCL) model of cell-mediated contraction. Key proteases, previously identified in our tissue studies, were expressed in vitro and regulated by tension in the FPCL, including MMP1, 2, 3, 13 and 14. Knockdown of MMP2 and MMP14 (but not MMP1, 3 and 13) inhibited cell-mediated contraction, and knockdown of MMP14 inhibited proMMP-2 activation. Interestingly, whilst collagen is degraded during the FPCL assay, this is not altered upon knockdown of any of the proteases examined. We conclude that MMP-14 (via its ability to activate proMMP-2) and MMP-2 are key proteases in collagen contraction mediated by fibroblasts in DD patients. These proteases may be drug targets or act as biomarkers for disease progression.     

Investigating the Role of P311 in the Hypertrophic Scar

The mechanisms of hypertrophic scar formation are not fully understood. We previously screened the differentially expressed genes of human hypertrophic scar tissue and identified P311 gene as upregulated. As the activities of P311 in human fibroblast function are unknown, we examined the distribution of it and the effects of forced expression or silencing of expression of P311. P311 expression was detected in fibroblast-like cells from the hypertrophic scar of burn injury patients but not in peripheral blood mononuclear cells, bone marrow mesenchymal stem cells, epidermal cells or normal skin dermal cells. Transfection of fibroblasts with P311 gene stimulated the expression of alpha-smooth muscle actin (α-SMA), TGF-β1 and α1(I) collagen (COL1A1), and enhanced the contraction of fibroblast populated collagen lattices (FPCL). In contrast, interference of fibroblast P311 gene expression decreased the TGF-β1 mRNA expression and reduced the contraction of fibroblasts in FPCL. These results suggest that P311 may be involved in the pathogenesis of hypertrophic scar via induction of a myofibroblastic phenotype and of functions such as TGF-β1 expression. P311 could be a novel target for the control of hypertrophic scar development.     

Cyclic AMP-induced inhibition of collagen lattice contraction by fibroblasts may be attenuated by both cyclic AMP dependent and independent mechanisms

The contraction of collagen lattices made with forskin fibroblasts in medium containing 1% fetal bovine serum was inhibited by intracelluar cyclic AMP raising drugs including cholera toxin (CT), forskolin, and dibutyryl-cAMP. The inhibition by CT was attenuated by insulin, acidic fibroblast growth factor (aFGF), and transforming growth factor-β (TGF-β). All three peptide factors have previously been reported to promote collagen lattice contraction by arterial smooth muscle cells and/or fibroblasts. Incubation of cells suspended in collagen gels with CT and forskolin resulted in a transient rise of the intracellular cyclic AMP levels, which peaked at 2 hr and 30 min, respectively, after drug exposure. Cholera toxin-induced intracellular cyclic AMP increase was attenuated by TGF-β, but not by aFGF and insulin, when added simultaneously. Thus, TGF-β may attenuate CT's inhibition on collagen lattice contraction by attenuating CTinduced intracellualr cyclic AMP increse, whereas the attenuation by insulin and aFGF on the inhibition of lattice contraction may be mediated by a cyclic AMPindependent mechannism. © 1993 Wiley-Liss, Inc.     

HSP27 regulates fibroblast adhesion, motility, and matrix contraction

Heat shock protein 27 (HSP27) modulates actin-dependent cell functions in several systems. We hypothesized that HSP27 modulates wound contraction. Stably transfected fibroblast cell lines that overexpress HSP27 (SS12) or underexpress HSP27 (AS10) were established, and cell behaviors related to wound contraction were examined. First, fibroblast-populated collagen lattice (FPCL) contraction was examined because it has been studied as a wound-healing model. In floating FPCL contraction assays, SS12 cells caused increased contraction, whereas AS10 cells caused reduced contraction. Because floating matrix contraction is thought to be mediated by the tractional force of the cells, cell behaviors related to tractional force were examined. In collagen matrix, SS12 cells elongated faster and to a greater extent and contained longer stress fibers than control cells, whereas AS10 cells were slower to elongate than control cells. SS12 cells attached to the dishes more efficiently than the control, whereas AS10 cells attached less efficiently. Migration of SS12 cells on collagen-coated dishes was also enhanced, although AS10 cells did not differ from the control cells. In summary, HSP27 regulates fibroblast adhesion, elongation, and migration and the contraction of the floating matrix in a manner dependent on the level of its expression.     

Cell-mediated contraction of collagen lattices in serum-free medium: Effect of serum and nonserum factors

Summary This study was conducted to identify a defined, serum-free culture medium that supports cell dependent contraction of a collagen lattice. Collagen lattices were found to contract in cultures containing human foreskin fibroblasts (HFF) or rabbit aortic smooth muscle (RASM) cells incubated in serum-free medium. HFF and RASM cells required different supplements to contract the collagen gels. HFF cultured in Dulbecco’s modified Eagle’s (DME) medium supplemented with bovine serum albumin (BSA) and either endothelial cell growth supplement (EnGS), insulin (In), or platelet derived growth factor (PDGF) supported collagen lattice contraction. Replacement of BSA with casein without the addition of other supplements improved contraction. In contrast, RASM cells supplemented with BSA, EnGS, In, and PDGF were able to contract collagen gels only minimally. Similar to HFF, RASM cells cultured in DME medium supplemented with casein, but without the addition of other supplements, contracted collagen lattices. HFF-mediated collagen contraction was inhibited by prostaglandins E₁ or E₂, fibronectin, or ascorbic acid. The reported serum-free model provides a useful in vitro method to investigate the role of serum and nonserum factors regulating cell mediated-contraction of insoluble collagen fibrils. Presented in part as abstract 1963 in the 1985 Federation of American Societies for Experimental Biology, April 21–26, Anaheim, California, and published in Fed. Proc. (44):747; 1985.     

Fibroblast movements during contraction of collagen lattices—A quantitative study using a new three-dimensional time-lapse technique with phase-contrast laser scanning microscopy

Summary In this study we assessed the behavior of fibroblasts during contraction of collagen lattices. We applied a new technique for three-dimensional time-lapse studies of movements of living cells using phase-contrast laser scanning microscopy. Five anchored and five floating collagen lattices were studied regarding the activity of cells during a 7-h period of active contraction. Three-dimensional reconstructions of the fibroblasts and their extensions were made from datasets of 16–26 “optical sections” 5 μm apart recorded hourly during the period of measurements. The distance between fibroblast nuclei in the floating lattices decreased by a mean of 6.8 μm, but remained constant in the anchored group. Only minor variations were found in the angle between a line connecting any two nuclei and the tangent of the lattice margin. The lengths of the cellular extensions continuously changed by shortening and extending, and an increasing number of intercellular contacts were established with time. The angle between the extensions and the periphery of the lattice varied continually, and no distinct pattern of arrangement of the extensions was seen. In conclusion, we have shown in living cells in vitro that fibroblasts do not appear to move around within lattices during contraction but rather send out and withdraw cellular extensions continuously. This speaks against cellular locomotion or movement as a main feature of contraction. Time-lapse scanning laser microscopy has also been shown to be a suitable method to study cellular behavior quantitatively in three dimensions during lattice contraction.     

Alpha-smooth muscle actin expression upregulates fibroblast contractile activity

To evaluate whether alpha-smooth muscle actin (alpha-SMA) plays a role in fibroblast contractility, we first compared the contractile activity of rat subcutaneous fibroblasts (SCFs), expressing low levels of alpha-SMA, with that of lung fibroblasts (LFs), expressing high levels of alpha-SMA, with the use of silicone substrates of different stiffness degrees. On medium stiffness substrates the percentage of cells producing wrinkles was similar to that of alpha-SMA-positive cells in each fibroblast population. On high stiffness substrates, wrinkle production was limited to a subpopulation of LFs very positive for alpha-SMA. In a second approach, we measured the isotonic contraction of SCF- and LF-populated attached collagen lattices. SCFs exhibited 41% diameter reduction compared with 63% by LFs. TGFbeta1 increased alpha-SMA expression and lattice contraction by SCFs to the levels of LFs; TGFbeta-antagonizing agents reduced alpha-SMA expression and lattice contraction by LFs to the level of SCFs. Finally, 3T3 fibroblasts transiently or permanently transfected with alpha-SMA cDNA exhibited a significantly higher lattice contraction compared with wild-type 3T3 fibroblasts or to fibroblasts transfected with alpha-cardiac and beta- or gamma-cytoplasmic actin. This took place in the absence of any change in smooth muscle or nonmuscle myosin heavy-chain expression. Our results indicate that an increased alpha-SMA expression is sufficient to enhance fibroblast contractile activity.     

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. © 1996 Wiley-Liss, Inc.     

Modulation of sulfated glycosaminoglycan and small proteoglycan synthesis by the extracellular matrix

Cell culture in collagen lattice is known to be a more physiological model than monolayer for studying the regulation of extracellular matrix protein deposition. The synthesis of sulfated glycosaminoglycans (GAG) and dermatan sulfate (DS) proteoglycans by 3 cell strains were studied in confluent monolayers grown on plastic surface, in comparison to fully retracted collagen lattices. Cells were labelled with³⁵S-sulfate, followed by GAG and proteoglycan analysis by cellulose acetate and SDS-polyacrylamide gel electrophoresis, respectively. The 3 cell strains contracted the lattice in a similar way. In monolayer cultures, the major part of GAG was secreted into culture medium whereas in lattice cultures of dermal fibroblasts and osteosarcoma MG-63 cells but not fibrosarcoma HT-1080 cells, a higher proportion of GAGs, including dermatan sulfate, was retained within the lattices. Small DS proteoglycans, decorin and biglycan, were detected in fibroblasts and MG-63 cultures. They were preferentially trapped within the collagen gel. In retracted lattices, decorin had a higher M_r than in monolayer. Biglycan was detected in monolayer and lattice cultures of MG-63 cells but in lattice cultures only in the case of fibroblasts. In this last case, an up regulation of biglycan mRNA steady state level and down regulation of decorin mRNA was observed, in comparison to monolayers, indicating that collagen can modulate the phenotypical expression of small proteoglycan genes.Supported by a fellowship from the Centre National de la Recherche Scientifique     

Differences in the mechanism for high- versus moderate-density fibroblast-populated collagen lattice contraction

The free-floating fibroblast-populated collagen lattice (FPCL) model introduced by Bell contains 0.5 x 10(5) cell/ml and here is defined as a moderate-density FPCL (MD-FPCL). One modification of the model is to increase the cell density by a factor of 10, where 5 x 10(5) cells/ml defines a high-density FPCL (HD-FPCL). The initial detection of HD-FPCL contraction is 2 h, whereas MD-FPCL is later, 6 h. A contracted HD-FPCL has a doughnut-like appearance, due to the high density of cells accumulating at the periphery. A contracted MD-FPCL is a flattened disc. The compacted collagen of MD-FPCL lattice exhibits a strong birefringence pattern due to organized collagen fiber bundles. In contracted HD-FPCL, a minimal birefringence develops, indicating minimal organization of collagen fiber bundles. MD-FPCL contraction was reduced with less than 10% serum; the disruption of microtubules, uncoupling of gap junctions, inhibition of tyrosine kinases, and addition of a blocking antibody to alpha2beta1 collagen integrin. Making HD-FPCL with only 1% serum or including the inhibitory agents had only minimal affect on lattice contraction. On the other hand, platelet-derived growth factor stimulated HD-FPCL contraction but had no influence on MD-FPCL contraction. It is suggested that the mechanism for HD-FPCL contraction is limited to the process of cells spreading. HD-FPCL contraction is independent of collagen organization, microtubules, gap junctions, alpha2beta1 integrin, and tyrosine phosphorylation. MD-FPCL contraction involves collagen organization and is optimized by the involvement of microtubules, gap junctions, alpha2beta1 integrin, and tyrosine phosphorylation. When studying cell physiology in a collagen matrix, cell-density influences need to be considered.     

Minoxidil-induced changes in the contraction of collagen lattices by human skin fibroblasts.

This investigation has studied the effect of minoxidil on the contraction of hydrated collagen lattices by human dermal fibroblasts. Type I collagen was mixed with a fibroblast suspension and polymerized, and minoxidil 10 to 800 micrograms/ml (0.05 to 4 mM) was added at the time the lattices were released. Minoxidil at concentrations from 100 to 600 micrograms/ml inhibited contraction in a dose-dependent manner, whereas 800 micrograms/ml prevented contraction completely, most cells remaining rounded. Considerable inhibition was already evident within 24 hours. Visualization of living cells with MTT and cell counts showed that inhibition in the first 48 hours was not due to fibroblast death. Exchange of minoxidil to normal medium led to a resumption of contraction and a return to an elongate morphology. Minoxidil at 10 micrograms/ml had no significant effect on lattice contraction, whereas at 100 micrograms/ml it slowed contraction without affecting proliferation or morphology, as observed under the light microscope. The inhibitory effect of minoxidil should be investigated further in relation to the control of contraction of wounds in vivo.     

Fibronectin dependence of the contraction of collagen lattices by human skin fibroblasts

The role of fibronectin in the contraction of collagen lattices by human skin fibroblasts has been investigated. Incubation of lattice cultures in Dulbecco's modified Eagle's medium supplemented with increasing concentrations of non-dialysed or dialysed fetal calf serum demonstrated that the rate of contraction was dependent on non-dialysable serum components. The suppression of contraction observed when fibronectin was eliminated from serum, either by affinity chromatography on gelatin-agarose columns or by precipitation with anti-fibronectin antibodies, showed that fibronectin is critical for the contraction. When collagen lattices were incubated in a serum-free culture medium totally devoid of fibronectin, no contraction occurred. When fibronectin was added to this medium, their contraction was correlated with the concentration of fibronectin added. The contraction was inhibited by cycloheximide, tunicamycin, and monensin. These results demonstrate that the contraction of collagen lattices by human skin fibroblasts is dependent on fibronectin, and that other protein factors synthesized by the cells or contained in serum are also necessary.     

Fibroblast stimulation in schistosomiasis. IV. Isolated egg granulomas elaborate a fibroblast chemoattractant in vitro

Hepatic fibrosis complicates the chronic granulomatous inflammatory reaction to Schistosoma mansoni eggs, and is the major cause of morbidity and mortality in human schistosomiasis. We previously presented evidence that schistosomal egg granulomas secreted factors that can stimulate fibroblast proliferation and collagen synthesis in vitro. We now report that serum-free supernatants from cultures of hepatic egg granulomas isolated from S. mansoni-infected mice contained activity that stimulated the directional migration of human and guinea pig dermal fibroblasts in modified Boyden chambers. This fibroblast chemotactic activity was also detected in culture supernatants of granuloma adherent cells highly enriched for macrophages (95% latex-ingesting) but not in culture supernatants from resident peritoneal macrophages of uninfected or infected mice. This suggests that granuloma macrophages are a source of the chemotactic activity. The chemoattractant had the properties of large molecular weight (greater than 200,000 daltons; Sephadex G-200 gel filtration), pl approximately 4.5 (preparative flatbed isoelectrofocusing in granular matrix), heat stability (56 degrees C; 45 min), and trypsin sensitivity. Since preincubation of the partially purified granuloma and adherent-cell derived chemoattractants with rabbit anti-human fibronectin antibody abolished their chemotactic activity, it appears that the factor is antigenically similar to fibronectin. We propose that egg granuloma macrophages are activated in vivo to secrete a fibronectin-like molecule with activity that stimulates the directional migration of fibroblasts. This factor may therefore play a role in the local recruitment of fibroblasts and, in concert with other granuloma-derived factors, may play an important role in the pathogenesis of hepatic fibrosis in schistosomiasis.