Effect of strain on human dermal fibroblasts in a three-dimensional collagen sponge

Our aim was to design a simple compression system and investigate the influence of mechanical stress on skin-like structures. Many mechanical compression studies have employed intricate culture systems, so the relationship between extracellular matrix material and the response of skin cells to mechanical stress remains unknown. Our approach uses only glass vials, 6-well plates and standard laboratory equipment. We examined the influence of mechanical stress on human skin fibroblasts embedded within a collagen sponge. The results show that mechanical compression increases MMP-1 and MMP-2 release by the cells into the the cell culture. Our results suggest that pressure on the skin may affect extracellular matrix degradation through some as yet unidentified pathways and that IL-6 mRNA expression may be involved in this effect. Using our approach, the effects of static mechanical stress on protein expression by cells in the culture medium and in sponges can be easily examined, and therefore this system will be useful for further analyses of skin responses to mechanical stress.     

Hydrostatic fluid pressure promotes cellularity and proliferation of human dermal fibroblasts in a three-dimensional collagen gel/sponge

Cell constructs and culture systems are essential components of tissue engineering. Cell constructs are usually composed of a dense population of cells, for which long-term culture is required in vitro. However, the denser construct suffers from the absence of passive nutrient supply, gas exchange, and removal of degraded debris. We have developed a novel hydrostatic pressure/perfusion (HP/P) culture system that improves the quality of neo-tissues, providing an automated affordable system for clinical applications. We evaluated the effects of HP/P on cellularity, viability, and proliferation of human dermal fibroblasts seeded in a gel/sponge construct. HP/P and perfusion promoted cell migration and significantly increased proliferation and DNA content after 4 days culture compared to the static culture. HP/P culture is beneficial for building a denser three-dimensional fibroblast construct.     

Tissue form of type VII collagen from human skin and dermal fibroblasts in culture

The triple-helical domain of type VII collagen was isolated from human placental membranes by mild digestion with pepsin, and polyclonal antibodies were raised in rabbits against this protein. After affinity purification the antibodies specifically recognized type VII collagen in both the triple-helical and the unfolded state. They also reacted with the fragments P1 and P2, derived from the triple-helical domain by further proteolysis with pepsin, but did not crossreact with other biochemical components of the dermal connective tissue. In skin the presence of a fragment of type VII collagen, similar to that isolated from placenta, was demonstrated by SDS-PAGE and immunoblotting. Type VII collagen represented less than 0.001% of the total collagen extracted by pepsin digestion from newborn or adult skin. The tissue form of type VII collagen was obtained from dermis after artificial epidermolysis with strongly denaturing buffers under conditions reducing disulfide bonds. The protein was identified by immunoblotting with the antibodies. The molecule was composed of three polypeptides with an apparent molecular mass of about 250 kDa, each. Similar large-molecular-mass chains could be identified by immunoblotting in extracts of human fibroblasts in culture.     

Wound healing mediator production by human dermal fibroblasts grown within a collagen-GAG matrix for skin repair in humans

Cell and tissue therapy applications in humans are being used increasingly, particularly for tissue repair. Several reconstructed skin models have been proposed. Wound healing involves overlapping steps of inflammation, cell migration and proliferation, neovascularisation, extracellular matrix production and remodelling. This is regulated by numerous cytokines and other soluble mediators. We have prepared dermal substitutes (DS) consisting of a collagen-GAG, three-dimensional matrix colonized by human dermal fibroblasts (HDF), isolated by skin explant or enzymatic digestion of the skin for potential therapeutic use in humans. To test the functionality of these DS, we measured (ELISA) the stimulatory effect on HDF in the matrix, of serial dilutions of human serum (HS) on the production of wound healing mediators: interleukin-8 (IL-8), vascular endothelial growth factor (VEGF), keratinocyte growth factor (KGF) and tissue inhibitor of metalloproteinase-1 (TIMP-1). We observed: 1). a stimulatory effect of HS on HDF production of the different mediators tested, with a dose-dependent effect in the case of IL-8 and VEGF. 2). A matrix-potentiating effect on the production of the different mediators by HDF. 3). A decrease in the production of IL-8 and VEGF when HDF isolated by enzymatic digestion was used to colonize the matrix as compared with HDF isolated by skin explant. We conclude: 1). that the production by HDF, in a collagen-GAG matrix, of mediators involved in cutaneous wound healing is decreased when HDF are isolated by enzymatic skin digestion rather than by skin explant. 2). That measurement of the production of cytokines or other mediators could be a useful quality control to test the functionality of tissue-engineered DS for tissue repair therapy in humans and more generally of cells prepared for cell therapy.     

The contraction of collagen matrices by dermal fibroblasts

Floating collagen gel cultures containing human foreskin fibroblasts have been observed to undergo a rapid contraction process. The initial rate of contraction (i.e., within the first 2 hr) was observed to be a linear function of cell number within the concentration range of 10(5)-10(6) cells/gel. Observation of thick, deresined sections of such contracting gels in the SEM, as well as observation of thin sections in the TEM, suggest that the fibroblasts exert a tension upon the surrounding collagen fibers. These observations further indicate that the fibroblasts migrate from the interior regions of the gel matrix and eventually form a monolayer of cells encapsulating the contracted collagen disc. These observations are discussed in terms of the possible mechanisms involved in gel contraction.     

Comparison of collagen and glycosaminoglycan synthesis in attaching control and diabetic human skin fibroblasts

Summary Cultured fibroblasts derived from normal subjects and juvenile diabetics attach in the absence of serum to plastic culture dishes and secrete macromolecules, including collagenous components, hyaluronic acid, and proteoglycans into the medium and onto the plastic surface where they form a microexudate carpet. Most diabetic fibroblasts examined did not spread as well as normal cells during a 4-hr interval after the initial attachment. There were no significant differences between normal and diabetic cells with respect to proline and lysine incorporation and lysine hydroxylation. The percentage glycosylation of hydroxylysine was marginally higher in the media proteins of diabetic cells, but glycosylation in both normal and diabetic cells was elevated over that typically observed in human skin collagen. Collagenous components were estimated to constitute approximately 15–20% of the microexudate carpet fraction in both normal and diabetic cell strains. Diabetic fibroblasts exhibited a marginally lower ratio of heparan sulfate to chondroitin sulfate in the cell surface to matrix microexudate carpet fraction (trypsinate) than did normal fibroblasts. The hyaluronate and chondroitin sulfate contents of this fraction of diabetic cells were not significantly different from those of normal cells. This work was supported by Grants AM 11821 and AM 19606 from the National Institutes of Health, United States Public Health Service, by a grant from the American Diabetes Association (Leon W. Cunningham, Principal Investigator) and by the Vanderbilt Diabetes Endocrinology Center grant, AM 17026. R. E. Branson was the recipient of a research fellowship of the Juvenile Diabetes Foundation and of a National Institutes of Health Postdoctoral Fellowship AM 05636.     

A new in vitro wound model based on the co-culture of human dermal microvascular endothelial cells and human dermal fibroblasts

BACKGROUND INFORMATION: Different in vitro models, based on co-culturing techniques, can be used to investigate the behaviour of cell types, which are relevant for human wound and soft-tissue healing. Currently, no model exists to describe the behaviour of fibroblasts and microvascular endothelial cells under wound-specific conditions. In order to develop a suitable in vitro model, we characterized co-cultures comprising NHDFs (normal human dermal fibroblasts) and HDMECs (human dermal microvascular endothelial cells). The CCSWMA (co-culture scratch wound migration assay) developed was supported by direct visualization techniques in order to investigate a broad spectrum of cellular parameters, such as migration and proliferation activity, the differentiation of NHDFs into MFs (myofibroblasts) and the expression of endothelin-1 and ED-A-fibronectin (extra domain A fibronectin). The cellular response to hypoxia treatment, as one of the crucial conditions in wound healing, was monitored. RESULTS: The comparison of the HDMEC-NHDF co-culture with the respective mono-cultures revealed that HDMECs showed a lower proliferation activity when co-cultured, but their number was stable throughout a period of 48 h. NHDFs in co-culture were slightly slower at proliferating than in the mono-culture. The MF population was stable for 48 h in the co-culture, as well as in NHDF mono-culture. Co-cultures and HDMEC mono-cultures were characterized by a slower migration rate than NHDF mono-cultures. Hypoxia decreased both cell proliferation and migration in the mono-cultures, as well as in the co-cultures, indicating the general suitability of the assay. Exclusively, in co-cultures well-defined cell clusters comprising HDMECs and MFs formed at the edges of the in vitro wounds. CONCLUSIONS: On the basis of these results, the CCSWMA developed using co-cultures, including HDMECs, NHDFs and MFs, proved to be an effective tool to directly visualize cellular interaction. Therefore, it will serve in the future to evaluate the influence of wound-healing-related factors in vitro, as shown for hypoxia in the present study.     

Studies on vascular smooth muscle cells and dermal fibroblasts in collagen matrices. Effects of heparin

The incorporation of such tissue-cultured mesenchymal cells as bovine vascular smooth muscle cells (SMS) and human dermal fibroblasts (DF) in a collagen matrix results in the reorganization and distortion of that matrix. A 2 ml collagen matrix populated by 55 000 bovine SMC and having a surface area of 800 mm2 will be reduced to 226 mm2 by 48 h. Under identical conditions, a lattice populated by 55 000 DF will achieve an area of 78 mm2 at 48 h. DF are thus more efficient at reducing the size of a collagen lattice by the process of lattice contraction. Bovine SMC proliferate in a collagen matrix; human DF do not. DF in a collagen matrix have a more elongate morphology than SMC. Actin cytoplasmic filaments were studied using the specific F-actin staining reagent, Rhodamine-phalloidin. DF in collagen matrix exhibit diffuse cytoplasmic staining while, in monolayer, they display prominent staining stress fibers. SMC in monolayer and in matrices show stained clumps at the periphery of the cell. The addition of 200 U/ml heparin to SMC eliminates those actin aggregates and causes the formation of stress fibers. It also causes stress fibers to form in dermal fibroblasts in a collagen lattice. However, the elongation and spreading--and the formation of stress fibers brought about by heparin--lead to an inhibition of lattice contraction. Heparin effectively inhibits cell-mediated lattice contraction in SMC and DF, and it also causes the formation of cytoplasmic stress fibers.     

Regulation of connective tissue growth factor gene expression in human skin fibroblasts and during wound repair.

Connective tissue growth factor (CTGF) is a cysteine-rich peptide that exhibits platelet-derived growth factor (PDGF)-like biological and immunological activities. CTGF is a member of a family of peptides that include serum-induced immediate early gene products, a v-src-induced peptide, and a putative avian transforming gene, nov. In the present study, we demonstrate that human foreskin fibroblasts produce high levels of CTGF mRNA and protein after activation with transforming growth factor beta (TGF-beta) but not other growth factors including PDGF, epidermal growth factor, and basic fibroblast growth factor. Because of the high level selective induction of CTGF by TGF-beta, it appears that CTGF is a major autocrine growth factor produced by TGF-beta-treated human skin fibroblasts. Cycloheximide did not block the large TGF-beta stimulation of CTGF gene expression, indicating that it is directly regulated by TGF-beta. Similar regulatory mechanisms appear to function in vivo during wound repair where there is a coordinate expression of TGF-beta 1 before CTGF in regenerating tissue, suggesting a cascade process for control of tissue regeneration and repair.     

SPARC regulates processing of procollagen I and collagen fibrillogenesis in dermal fibroblasts

A characterization of the factors that control collagen fibril formation is critical for an understanding of tissue organization and the mechanisms that lead to fibrosis. SPARC (secreted protein acidic and rich in cysteine) is a counter-adhesive protein that binds collagens. Herein we show that collagen fibrils in SPARC-null skin from mice 1 month of age were inefficient in fibril aggregation and accumulated in the diameter range of 60-70 nm, a proposed intermediate in collagen fibril growth. In vitro, procollagen I produced by SPARC-null dermal fibroblasts demonstrated an initial preferential association with cell layers, in comparison to that produced by wild-type fibroblasts. However, the collagen I produced by SPARC-null cells was not efficiently incorporated into detergent-insoluble fractions. Coincident with an initial increase in cell association, greater amounts of total collagen I were present as processed forms in SPARC-null versus wild-type cells. Addition of recombinant SPARC reversed collagen I association with cell layers and decreased the processing of procollagen I in SPARC-null cells. Although collagen fibers formed on the surface of SPARC-null fibroblasts earlier than those on wild-type cells, fibers on SPARC-null fibroblasts did not persist. We conclude that SPARC mediates the association of procollagen I with cells, as well as its processing and incorporation into the extracellular matrix.     

Melanocyte stem cells: a melanocyte reservoir in hair follicles for hair and skin pigmentation

Most mammals are coated with pigmented hair. Melanocytes in each hair follicle produce melanin pigments for the hair during each hair cycle. The key to understanding the mechanism of cyclic melanin production is the melanocyte stem cell (MelSC) population, previously known as 'amelanotic melanocytes'. The MelSCs directly adhere to hair follicle stem cells, the niche cells for MelSCs and reside in the hair follicle bulge-subbulge area, the lower permanent portion of the hair follicle, to serve as a melanocyte reservoir for skin and hair pigmentation. MelSCs form a stem cell system within individual hair follicles and provide a 'hair pigmentary unit' for each cycle of hair pigmentation. This review focuses on the identification of MelSCs and their characteristics and explains the importance of the MelSC population in the mechanisms of hair pigmentation, hair greying, and skin repigmentation.     

Microgravity and hypergravity effects on collagen biosynthesis of human dermal fibroblasts

Astronauts experiencing long periods of space flight suffer from severe loss of bone tissue, particularly in those bones that carry the body weight under normal gravity. It is assumed that the lack of mechanical load decreases connective tissue biosynthesis in bone-forming cells. To test this assumption, quantitative and qualitative aspects of collagen synthesis under microgravity, normal gravity, and hypergravity conditions were investigated by incubating human fibroblast cultures with [³H]-proline for 4, 7, 10, and 20 h during the Spacelab D2-mission in 1993. Quantitative analysis revealed an increase of collagen synthesis under microgravity conditions, being up to 143% higher than in 1 g controls. In contrast, hypergravity samples showed a decrease in collagen synthesis with increasing g, being at the 13% level at 10 g. The relative proportion of collagen in total synthesized protein showed a slight decrease with increasing g. The secretion of collagen by the cells, proline hydroxylation of individual collagen -chains, and the relative proportions of synthesized collagens I, III, and V were not affected under any of the applied conditions.Our research was supported financially by Dara GmbH Bonn (grant. no. 01QV 8866), the Deutsche Forschungsgemeinschaft (SFB A1/367) and BMFT grant. no. 01 KM 9303/8.     

Tumor necrosis factor inhibits collagen and fibronectin synthesis in human dermal fibroblasts

Tumor necrosis factor (TNF) caused inhibition of collagen production by confluent cultures of human dermal fibroblasts in a dose-dependent manner. Concomitant increase of prostaglandin E2 release was observed as a result of TNF-induced cell activation. However, a blockade of the cyclooxygenase pathway of arachidonate metabolism by indomethacin did not abrogate the inhibitory effect of TNF on collagen synthesis, suggesting that this effect could be independent of prostaglandin metabolism. Gel electrophoresis of the newly synthesized macromolecules from the culture media showed that both type I and type III collagens as well as fibronectin were affected by the inhibition. Electrophoresis of cell layer-associated proteins demonstrated that the reduction in amounts of collagen and fibronectin in the medium did not result from an intracellular accumulation of these macromolecules. Production of procollagens was reduced in parallel to that of collagens, suggesting that the effect of TNF is exerted before the processing steps of procollagens. These results clearly show that TNF could play a role in modulation of matrix deposition by fibroblasts during inflammatory processes.     

Mesenchymal stem cells and skin wound repair and regeneration: possibilities and questions

Adult mesenchymal stem cells (MSCs) have the capacity for self-renewal and for differentiating into a variety of cells and tissues. They may leave their niche to migrate to remote tissues and play a critical role in wound repair and tissue regeneration. Because of their multipotency, easy isolation and culture, highly expansive potential, and immunosuppression properties, these cells may be an attractive therapeutic tool for regenerative medicine and tissue engineering. Several studies have indicated a contribution of MSCs to reconstituting skin in cutaneous wounds, but problems still need resolution before MSCs can be widely used clinically. This review focuses mainly on the benefits of MSCs in skin wound healing and tissue regeneration and on the questions that remain to be answered before MSCs can be used in clinical practice. This study was supported in part by the National Natural Science Foundation of China (30730090, 30672176, 30500194) and by State Key Development Program of Basic Research of China (973 Program, 2005CB522603).     

Role of collagen XII in skin homeostasis and repair

Skin integrity and function depends to a large extent on the composition of the extracellular matrix, which regulates tissue organization. Collagen XII is a homotrimer with short collagenous domains that confer binding to the surface of collagen I-containing fibrils and extended flexible arms, which bind to non-collagenous matrix components. Thereby, collagen XII helps to maintain collagen suprastructure and to absorb stress. Mutant or absent collagen XII leads to reduced muscle and bone strength and lax skin, whereas increased collagen XII amounts are observed in tumor stroma, scarring and fibrosis.This study aimed at uncovering in vivo mechanisms by which collagen XII may achieve these contrasting outcomes. We analyzed skin as a model tissue that contains abundant fibrils, composed of collagen I, III and V with collagen XII decorating their surface, and which is subject to mechanical stress. The impact of different collagen XII levels was investigated in collagen XII-deficient (Col12-KO) mice and in mice with collagen XII overexpression in the dermis (Col12-OE). Unchallenged skin of these mice was histologically inconspicuous, but at the ultrastructural level revealed distinct aberrations in collagen network suprastructure. Repair of excisional wounds deviated from controls in both models by delayed healing kinetics, which was, however, caused by completely different mechanisms in the two mouse lines. The disorganized matrix in Col12-KO wounds failed to properly sequester TGFβ, resulting in elevated numbers of myofibroblasts. These are, however, unable to contract and remodel the collagen XII-deficient matrix. Excess of collagen XII, in contrast, promotes persistence of M1-like macrophages in the wound bed, thereby stalling the wounds in an early inflammatory stage of the repair process and delaying healing.Taken together, we demonstrate that collagen XII is a key component that assists in orchestrating proper skin matrix structure, controls growth factor availability and regulates cellular composition and function. Together, these functions are pivotal for re-establishing homeostasis after injury.     

Collagenolytic cleavage products of collagen type I as chemoattractants for human dermal fibroblasts

The chemoattractive properties of collagen in native (triple-helical) and denatured (random coil) conformation were compared in a Boyden chamber type assay to those of collagen fragments derived from cleavage with mammalian or bacterial collagenase using human embryonic dermal fibroblasts as target cells. Chemotaxis to native collagen required low collagen concentrations because fibril formation at high concentrations and at physiological pH and ionic strength prevented chemoattractiveness. Chemotaxis of denatured collagen was comparable to that of native collagen in solution. Cleavage of native collagen with mammalian collagenase increased, digestion with bacterial collagenase abolished its chemotactic activity. It is thought that these data may reflect the in vivo situation during inflammation and wound repair.     

Effects of cardiotonic steroids on dermal collagen synthesis and wound healing.

We previously reported that cardiotonic steroids stimulate collagen synthesis by cardiac fibroblasts in a process that involves signaling through the Na-K-ATPase pathway (Elkareh et al. Hypertension 49: 215-224, 2007). In this study, we examined the effect of cardiotonic steroids on dermal fibroblasts collagen synthesis and on wound healing. Increased collagen expression by human dermal fibroblasts was noted in response to the cardiotonic steroid marinobufagenin in a dose- and time-dependent fashion. An eightfold increase in collagen synthesis was noted when cells were exposed to 10 nM marinobufagenin for 24 h (P < 0.01). Similar increases in proline incorporation were seen following treatment with digoxin, ouabain, and marinobufagenin (10 nM x 24 h, all results P < 0.01 vs. control). The coadministration of the Src inhibitor PP2 or N-acetylcysteine completely prevented collagen stimulation by marinobufagenin. Next, we examined the effect of digoxin, ouabain, and marinobufagenin on the rate of wound closure in an in vitro model where human dermal fibroblasts cultures were wounded with a pipette tip and monitored by digital microscopy. Finally, we administered digoxin in an in vivo wound healing model. Olive oil was chosen as the digoxin carrier because of a favorable partition coefficient observed for labeled digoxin with saline. This application significantly accelerated in vivo wound healing in rats wounded with an 8-mm biopsy cut. Increased collagen accumulation was noted 9 days after wounding (both P < 0.01). The data suggest that cardiotonic steroids induce increases in collagen synthesis by dermal fibroblasts, as could potentially be exploited to accelerate wound healing.