The interaction of human papillary and reticular fibroblasts and human keratinocytes in the contraction of three-dimensional floating collagen lattices

Roles of MicroRNA-21 in Skin Wound Healing: A Comprehensive Review

MicroRNA-21 (miR-21), one of the early mammalian miRNAs identified, has been detected to be upregulated in multiple biological processes. Increasing evidence has demonstrated the potential values of miR-21 in cutaneous damage and skin wound healing, but lack of a review article to summarize the current evidence on this issue. Based on this review, relevant studies demonstrated that miR-21 played an essential role in wound healing by constituting a complex network with its targeted genes (i.e., PTEN, RECK. SPRY1/2, NF-κB, and TIMP3) and the cascaded signaling pathways (i.e., MAPK/ERK, PI3K/Akt, Wnt/β-catenin/MMP-7, and TGF-β/Smad7-Smad2/3). The treatment effectiveness developed by miR-21 might be associated with the promotion of the fibroblast differentiation, the improvement of angiogenesis, anti-inflammatory, enhancement of the collagen synthesis, and the re-epithelialization of the wound. Currently, miRNA nanocarrier systems have been developed, supporting the feasibility clinical feasibility of such miR-21-based therapy. After further investigations, miR-21 may serve as a potential therapeutic target for wound healing.

Cutting into wound repair

The skin is home to an assortment of fibroblastic lineages that shape the wound repair response toward scars or regeneration. In this review, we discuss the distinct embryonic origins, anatomic locations, and functions of fibroblastic lineages, and how these distinct lineages of fibroblasts dictate the skin's wound response across injury depths, anatomic locations, and embryonic development to promote either scarring or regeneration. We highlight the supportive role of the fascia in dictating scarring outcomes; we then discuss recent findings that indicate fascia mobilization by its resident fibroblasts supersede the classical de novo deposition program of wound matrix formation. These recent findings reconfigure our traditional view of wound repair and present exciting new therapeutic avenues to treat scarring and fibrosis across a range of medical settings.

The effect of TGFβRI inhibition on fibroblast heterogeneity in hypertrophic scar 2D in vitro models

In burn patients, wound healing is often accompanied by hypertrophic scarring (HTS), resulting in both functional and aesthetic problems. HTSs are characterized by abundant presence of myofibroblasts (MFs) residing in the dermis. HTS development and MF persistence is primarily regulated by TGF-β signalling. A promising method to target the transforming growth factor receptor I (TGFβRI; also known as activin-like kinase 5 (ALK5)) is by making use of exon skipping through antisense oligonucleotides. In HTS the distinguishing border between the papillary dermis and the reticular dermis is completely abrogated, thus exhibiting a one layered dermis containing a heterogenous fibroblast population, consisting of papillary fibroblasts (PFs), reticular fibroblasts (RFs) and MFs. It has been proposed that PFs, as opposed to RFs, exhibit anti-fibrotic properties. Currently, it is still unclear which fibroblast subtype is most affected by exon skipping treatment. Therefore, the aim of this study was to investigate the effect of TGFβRI inhibition by exon skipping in PF, RF and HTS fibroblast monocultures. Morphological analyses revealed the presence of a PF-like population after exon skipping in the different fibroblast cultures. This observation was further confirmed by the expression of genes specific for PFs, demonstrated by qPCR analyses. Further investigations on mRNA and protein level revealed that indeed MFs and to a lesser extent RFs are targeted by exon skipping. Furthermore, collagen gel contraction analysis showed that ALK5 exon skipping reduced TGF-β- induced contraction together with decreased alpha-smooth muscle actin expression levels. In conclusion, we show for the first time that exon skipping primarily targets pro-fibrotic fibroblasts. This could be a promising step towards reduced HTS development of burn tissue.

Human keratinocyte-derived microvesicle miRNA-21 promotes skin wound healing in diabetic rats through facilitating fibroblast function and angiogenesis

Skin wound healing is a complex physiological process that maintains the integrity of the skin tissues, involving a variety of distinct cell types and signaling molecules. The specific signaling pathways or extracellular cues that govern the healing processes remain elusive. Microvesicles (MVs) have recently emerged as critical mediators of cell communication by delivery of genetic materials to target cells. In this study, we found the direct delivery of HEKa-MVs expressing miR-21 mimics significantly promoted the healing of skin wound in diabetic rats. In-depth studies showed that MV miR-21 promoted fibroblast migration, differentiation, and contraction, induced a pro-angiogenic process of endothelial cells and mediated a pro-inflammatory response. Mechanically, MV miR-21 might target specific essential effector mRNA in fibroblasts such as MMP-1, MMP-3, TIMP3, and TIMP4 to increase MMPs expression and enzymatic activities. Moreover, MV miR-21 regulated ɑ-SMA and N-cadherin to induce fibroblast-myofibroblast differentiation. MV miR-21 up-regulated the IL-6 and IL-8 expressions and their secretion to amplify the immune response. Furthermore, MV miR-21 down-regulated PTEN and RECK in protein level, and activate MAPK/ERK signaling cascade, thereby promoting fibroblast functions. Thus, our study has provided for the first time the basis for the potential application of HEKa-MVs, and MV miR-21 in particular for wound healing.

Toward Immunocompetent 3D Skin Models

3D human skin models provide a platform for toxicity testing, biomaterials evaluation, and investigation of fundamental biological processes. However, the majority of current in vitro models lack an inflammatory system, vasculature, and other characteristics of native skin, indicating scope for more physiologically complex models. Looking at the immune system, there are a variety of cells that could be integrated to create novel skin models, but to do this effectively it is also necessary to understand the interface between skin biology and tissue engineering as well as the different roles the immune system plays in specific health and disease states. Here, a progress report on skin immunity and current immunocompetent skin models with a focus on construction methods is presented; scaffold and cell choice as well as the requirements of physiologically relevant models are elaborated. The wide range of technological and fundamental challenges that need to be addressed to successfully generate immunocompetent skin models and the steps currently being made globally by researchers as they develop new models are explored. Induced pluripotent stem cells, microfluidic platforms to control the model environment, and new real-time monitoring techniques capable of probing biochemical processes within the models are discussed.

Biological Principles of Scar and Contracture

Hypertrophic scar and contracture in burn patients is a complex process. Contributing factors include critical injury depth and activation of key cell subpopulations, including deep dermal fibroblasts, myofibroblasts, fibrocytes, and T-helper cells, which cause scarring rather than regeneration. These cells influence each other via cellular profibrotic and antifibrotic signals, which help to determine the outcome. These cells also both modify and interact with extracellular matrix of the wound, ultimately forming hypertrophic scar. Current treatments reduce hypertrophic scar formation or improve remodeling by targeting these pathways and signals.

Human melanocytes mitigate keratinocyte-dependent contraction in an in vitro collagen contraction assay

Scarring is an extensive problem in burn care, and treatment can be especially complicated in cases of hypertrophic scarring. Contraction is an important factor in scarring but the contribution of different cell types remains unclear. We have investigated the contractile behavior of keratinocytes, melanocytes and fibroblasts by using an in vitro collagen gel assay aimed at identifying a modulating role of melanocytes in keratinocyte-mediated contraction. Cells were seeded on a collagen type I gel substrate and the change in gel dimensions were measured over time. Hematoxylin & Eosin-staining and immunohistochemistry against pan-cytokeratin and microphthalmia-associated transcription factor showed that melanocytes integrated between keratinocytes and remained there throughout the experiments. Keratinocyte- and fibroblast-seeded gels contracted significantly over time, whereas melanocyte-seeded gels did not. Co-culture assays showed that melanocytes mitigate the keratinocyte-dependent contraction (significantly slower and 18-32% less). Fibroblasts augmented the contraction in most assays (approximately 6% more). Non-contact co-cultures showed some influence on the keratinocyte-dependent contraction. Results show that mechanisms attributable to melanocytes, but not fibroblasts, can mitigate keratinocyte contractile behavior. Contact-dependent mechanisms are stronger modulators than non-contact dependent mechanisms, but both modes carry significance to the contraction modulation of keratinocytes. Further investigations are required to determine the mechanisms involved and to determine the utility of melanocytes beyond hypopigmentation in improved clinical regimes of burn wounds and wound healing.

Characterization of a human skin equivalent model to study the effects of ultraviolet B radiation on keratinocytes

The incidences of skin cancers resulting from chronic ultraviolet radiation (UVR) exposure are on the incline in both Australia and globally. Hence, the cellular and molecular pathways that are associated with UVR-induced photocarcinogenesis need to be urgently elucidated, in order to develop more robust preventative and treatment strategies against skin cancers. In vitro investigations into the effects of UVR (in particular, the highly mutagenic UVB wavelength) have, to date, mainly involved the use of cell culture and animal models. However, these models possess biological disparities to native skin, which, to some extent, have limited their relevance to the in vivo situation. To address this, we characterized a three-dimensional, tissue-engineered human skin equivalent (HSE) model (consisting of primary human keratinocytes cultured on a dermal-derived scaffold) as a representation of a more physiologically relevant platform to study keratinocyte responses to UVB. Significantly, we demonstrate that this model retains several important epidermal properties of native skin. Moreover, UVB irradiation of the HSE constructs was shown to induce key markers of photodamage in the HSE keratinocytes, including the formation of cyclobutane pyrimidine dimers, the activation of apoptotic pathways, the accumulation of p53, and the secretion of inflammatory cytokines. Importantly, we also demonstrate that the UVB-exposed HSE constructs retain the capacity for epidermal repair and regeneration after photodamage. Together, our results demonstrate the potential of this skin equivalent model as a tool to study various aspects of the acute responses of human keratinocytes to UVB radiation damage.

Development of a novel liquid crystal based cell traction force transducer system

Keratinocyte traction forces play a crucial role in wound healing. The aim of this study was to develop a novel cell traction force (CTF) transducer system based on cholesteryl ester liquid crystals (LC). Keratinocytes cultured on LC induced linear and isolated deformation lines in the LC surface. As suggested by the fluorescence staining, the deformation lines appeared to correlate with the forces generated by the contraction of circumferential actin filaments which were transmitted to the LC surface via the focal adhesions. Due to the linear viscoelastic behavior of the LC, Hooke's equation was used to quantify the CTFs by associating Young's modulus of LC to the cell induced stresses and biaxial strain in forming the LC deformation. Young's modulus of the LC was profiled by using spherical indentation and determined at approximately 87.1±17.2kPa. A new technique involving cytochalasin-B treatment was used to disrupt the intracellular force generating actin fibers, and consequently the biaxial strain in the LC induced by the cells was determined. Due to the improved sensitivity and spatial resolution (∼1μm) of the LC based CTF transducer, a wide range of CTFs was determined (10-120nN). These were found to be linearly proportional to the length of the deformations. The linear relationship of CTF-deformations was then applied in a bespoke CTF mapping software to estimate CTFs and to map CTF fields. The generated CTF map highlighted distinct distributions and different magnitude of CTFs were revealed for polarized and non-polarized keratinocytes.

Cell motility and mechanics in three-dimensional collagen matrices

Fibrous connective tissues provide mechanical support and frameworks for other tissues of the body and play an integral role in normal tissue physiology and pathology. Three-dimensional collagen matrices exhibit mechanical and structural features that resemble fibrous connective tissue and have become an important model system to study cell behavior in a tissue-like environment. This review focuses on motile and mechanical interactions between cells—especially fibroblasts—and collagen matrices. We describe several matrix contraction models, the interactions between fibroblasts and collagen fibrils at global and subcellular levels, unique features of mechanical feedback between cells and the matrix, and the impact of the cell-matrix tension state on cell morphology and mechanical behavior. We develop a conceptual framework to explain the balance between cell migration and collagen translocation including the concept of promigratory and procontractile growth factor environments. Finally, we review the significance of these concepts for the physiology of wound repair.

Scar and contracture: biological principles

Dysregulated wound healing and pathologic fibrosis cause abnormal scarring, leading to poor functional and aesthetic results in hand burns. Understanding the underlying biologic mechanisms involved allows the hand surgeon to better address these issues, and suggests new avenues of research to improve patient outcomes. In this article, the authors review the biology of scar and contracture by focusing on potential causes of abnormal wound healing, including depth of injury, cytokines, cells, the immune system, and extracellular matrix, and explore therapeutic measures designed to target the various biologic causes of poor scar.

Aging alters functionally human dermal papillary fibroblasts but not reticular fibroblasts: a new view of skin morphogenesis and aging

Understanding the contribution of the dermis in skin aging is a key question, since this tissue is particularly important for skin integrity, and because its properties can affect the epidermis. Characteristics of matched pairs of dermal papillary and reticular fibroblasts (Fp and Fr) were investigated throughout aging, comparing morphology, secretion of cytokines, MMPs/TIMPs, growth potential, and interaction with epidermal keratinocytes. We observed that Fp populations were characterized by a higher proportion of small cells with low granularity and a higher growth potential than Fr populations. However, these differences became less marked with increasing age of donors. Aging was also associated with changes in the secretion activity of both Fp and Fr. Using a reconstructed skin model, we evidenced that Fp and Fr cells do not possess equivalent capacities to sustain keratinopoiesis. Comparing Fp and Fr from young donors, we noticed that dermal equivalents containing Fp were more potent to promote epidermal morphogenesis than those containing Fr. These data emphasize the complexity of dermal fibroblast biology and document the specific functional properties of Fp and Fr. Our results suggest a new model of skin aging in which marked alterations of Fp may affect the histological characteristics of skin.

Cigarette smoke inhibits human bronchial epithelial cell repair processes

By interfering with the ability of airway epithelial cells to support repair processes, cigarette smoke could contribute to alterations of airway structures and functions that characterize chronic obstructive pulmonary disease (COPD). The current study assessed the ability of cigarette smoke extract (CSE) to alter human airway epithelial cell chemotaxis, proliferation, and contraction of three-dimensional collagen gels, a model of extracellular matrix remodeling. The volatile components contained in cigarette smoke, acetaldehyde and acrolein, were able to inhibit all three processes. Nonvolatile components contained within lyophilized CSE also inhibited chemotaxis but displayed no activity in the other two bioassays. CSE also inhibited the ability of airway epithelial cells to release transforming growth factor (TGF)-beta and fibronectin. Exogenous fibronectin was unable to restore epithelial cell contraction of collagen gels. Exogenous TGF-beta partially restored the ability of airway epithelial cells to contract collagen gels and to produce fibronectin. This supports a role for inhibition of TGF-beta release in mediating the inhibitory effects of cigarette smoke. Taken together, the results of the current study suggest that epithelial cells present in the airways of smokers may be altered in their ability to support repair responses, which may contribute to architectural disruptions present in the airways in COPD associated with cigarette smoking.

KERATINOCYTE-DRIVEN CONTRACTION OF RECONSTRUCTED HUMAN SKIN

We have previously reported that reconstructed human skin, using deepidermized acellular sterilized dermis and allogeneic keratinocytes and fibroblasts, significantly contracts in vitro. Contracture of split skin grafts in burns injuries remains a serious problem and this in vitro model provides an opportunity to study keratinocyte/mesenchymal cell interactions and cell interactions with extracted normal human dermis. The aim of this study was to investigate the nature of this in vitro contraction and explore several approaches to prevent or reduce contraction. Three different methodologies for sterilization of the dermal matrix were examined: glycerol, ethylene oxide and a combination of glycerol and ethylene oxide. While the nature of the sterilization technique influenced the extent of contraction and thinner dermal matrices contracted proportionately more than thicker matrices, in all cases contraction was driven by the keratinocytes with relatively little influence from the fibroblasts. The contraction of the underlying dermis did not represent any change in tissue mass but rather a reorganization of the dermis which was rapidly reversed (within minutes) when the epidermal layer was removed. Pharmacological approaches to block contraction showed forskolin and mannose-6-phosphate to be ineffective and ascorbic acid-2-phosphate to exacerbate contraction. However, Galardin, a matrix metalloproteinase inhibitor and keratinocyte conditioned media, both inhibited contraction.

Endothelial cell-mediated type I collagen gel contraction is regulated by hemin

The contraction of three-dimensional type I collagen gels is regarded as a model of contraction during wound healing and tissue remodeling. Because such a process could contribute to vessel narrowing, we hypothesized that endothelial cells may be able to mediate gel contraction. To demonstrate this, type I collagen was extracted from rat tail tendon and used to prepare collagen gels. Bovine arterial endothelial cells (BAECs) or human pulmonary artery endothelial cells (HPAECs) were then plated on the top of the gels in serum-free Ham's F-12 medium or 2% fetal calf serum-endothelium growth medium-2 (FCS-EGM2), respectively. After 48 hours of attachment, gels were released and floated in 0.2% FCS-Ham's F-12 medium (BAECs) or 2% FCS-EGM2 (HPAECs). Gel size was measured with an image analyzer daily for 5 consecutive days. Gels were then digested with collagenase to quantify DNA and hydroxyproline. BAECs contracted the gels in a time-dependent manner over the 5 days. Contraction was dependent on cell density (gel size was 100% of initial size after 5 days with no cells vs. 66.4%+/-0.5% with 0.9x10(4) cells/cm2 and 22.1%+/-0.3% with 7.5x10(4) cells/cm2) and was inversely related to collagen concentration (gel size was 22.3%+/-0.05%, 46.4%+/-0.9%, 72.3%+/-0.4%, and 87.4% +/-0.3% of initial size for gels prepared with 0.5 mg/mL, 0.75 mg/mL, 1 mg/mL, and 2 mg/mL of collagen, respectively). Hemin (a precursor for CO) and cytochalasin D inhibited collagen gel contraction mediated by both bovine and human endothelial cells without changing cell number or hydroxyproline content. In contrast, prostaglandin E2, an inhibitor, and transforming growth factor-beta1, a stimulator of fibroblast-mediated gel contraction, had no effect on endothelial cell-mediated contraction. These findings demonstrate that endothelial cells are able to contract native type I collagen gels and that this process can be modulated by exogenous mediators. Such a capability may cause remodeling of subjacent matrix of endothelial cells and may contribute to vessel narrowing.

Modification of type I collagenous gels by alveolar epithelial cells

Contraction of type I collagen gels is an in vitro model of tissue remodeling. In addition to fibroblasts, some epithelial cells can mediate this process. We therefore hypothesized that alveolar epithelial cells might contract extracellular matrices and have the potential to directly participate in the remodeling of the lung after alveolar injury. A549 cells were plated on top of collagen gels, and the gels were floated in culture medium. A549 cells contracted the gels in a time- and cell density-dependent manner. A549 cells, as well as human bronchial epithelial cells (HBEC) and rat alveolar epithelial cells (RalvEC) contracted collagen gels more when they were plated on top of the gel than when they were embedded inside, in contrast to human fetal lung fibroblast (HFL1), which contracted more when cast inside. The amount of hydroxyproline in the collagen gels remained unchanged throughout the contraction. Anti-beta(1) integrin antibody inhibited A549 cell-mediated contraction. Transforming growth factor beta augmented the contraction by A549 cells as well as that by HBEC and HFL1. Prostaglandin E(2) inhibited the contraction by HFL1 but did not affect the contraction by A549 cells, HBEC, or RalvEC. Cytomix (a mixture of tumor necrosis factor-alpha, interleukin-1beta, and interferon-gamma) inhibited the contraction by HFL1 but strongly enhanced the contraction by A549 cells. Cytomix also caused a morphologic change of A549 cells from a polygonal to a spindle shape. Immunocytochemistry showed that cytomix induced alpha-tubulin expression in A549 cells, whereas cytokeratin, vimentin, smooth muscle actin, beta(1) integrin, and paxillin expressions were not changed. This study thus demonstrates that alveolar epithelial cells can cause contraction of extracellular matrices and that this process is modulated by exogenous mediators, which also modify the microtubular system. Such an activity might contribute to alveolar remodeling after injury.

Cell surface receptors transmit sufficient force to bend collagen fibrils

To better understand the dynamic interaction of cells with their surrounding extracellular matrix, chondrocytes and rat embryo fibroblasts were overlaid with individual collagen fibrils and observed with high-resolution video-enhanced differential interference contrast microscopy. Although the cells had a polygonal shape characteristic of nonmotile cells, they used processes usually associated with cell locomotion to acquire the collagen fibrils. Instead of being transported in a retrograde direction, fibrils on the dorsal cell surface were bent, and regions of the bent fibrils were shifted in diverse directions. A blocking antibody to the beta1 integrin subunit significantly inhibited collagen fibril acquisition and bending. Enhanced actin assembly was only occasionally associated with fibrils undergoing rearrangement. Considering that the relatively stiff collagen fibrils require the application of force to be bent, this study shows that cells with a polygonal morphology (as opposed to a polarized, motile shape) are capable of exerting force through the beta1 integrins on the dorsal surface of the cell. Analysis of the bending patterns indicates that fibril buckling was induced by retrograde force combined with regions held stationary and/or the fibrils were bent by forces acting in opposing directions.

Human bronchial epithelial cells can contract type I collagen gels

Fibroblasts can contract collagen gels, a process thought to be related to tissue remodeling. Because epithelial cells are also involved in repair responses, we postulated that human bronchial epithelial cells (HBECs) could cause contraction of collagen gels. To evaluate this, HBECs were plated on the top of native type I collagen gels and were incubated for 48 h. After this, the gels were released and floated in LHC-9-RPMI 1640 for varying times, and gel size was measured with an image analyzer. HBECs caused a marked contraction of the gels within 24 h; the area was reduced by 88 +/- 4% (P < 0.01). The degree of gel contraction was dependent on cell density; 12,500 cells/cm2 resulted in maximal contraction, and half-maximal contraction occurred at 7,500 cells/cm2. Contraction varied inversely with the collagen concentration (91 +/- 1% with 0.5 mg/ml collagen vs. 43 +/- 5% with 1.5 mg/ml collagen). In contrast to fibroblasts that contract gels most efficiently when cast into the gel, HBEC-mediated contraction was significantly (P < 0.01) more efficient when cells were on top of the gels rather than when cast into the gels. Anti-beta 1-integrin antibody blocked HBEC-mediated contraction by > 50%, whereas anti-alpha 2-, anti-alpha 3-, anti-alpha v-, anti-alpha v beta 5-, anti-beta 2-, or anti-beta 4-integrin antibody was without effect. The combination of anti-beta 1-integrin antibody and an anti-alpha-subfamily antibody completely blocked gel contraction induced by HBECs. In contrast, anti-cellular fibronectin antibody did not block HBEC-induced gel contraction, whereas it did block fibroblast-mediated gel contraction. In summary, human airway epithelial cells can contract type I collagen gels, a process that appears to require integrins but may not require fibronectin. This process may contribute to airway remodeling.

A comparison of the ability of intra-oral and extra-oral fibroblasts to stimulate extracellular matrix reorganization in a model of wound contraction

Intra-oral wounds, like wounds in children, demonstrate privileged healing when compared with adult wounds at extra-oral sites. This study investigated whether this preferential healing is related to an increased ability of oral mucosal fibroblasts to reorganize extracellular matrix (ECM) when compared with their dermal counterparts. ECM reorganization was investigated by means of a fibroblast-populated collagen lattice (FPCL) system. The effect of donor age was also investigated in this system. Differences in ECM reorganization and FPCL contraction were evident: FPCL contraction was more rapid by oral mucosal fibroblasts than dermal fibroblasts (p < 0.01). FPCL contraction was also greater in child (donor < 10 years) than adult (donor > 18 years) oral mucosal fibroblasts (p < 0.01). These differences were not related to phenotypic differences in cell viability (p > 0.5), DNA synthesis (p > 0.05), and cell number (p > 0.5) within the FPCLs, or cellular attachment to collagen (p > 0.07). FPCL contraction was not stimulated by the addition of conditioned medium from oral mucosal or dermal fibroblasts (p > 0.05). These data show that the significantly increased ability of oral mucosal fibroblasts to reorganize ECM in vitro, when compared with dermal fibroblasts, represents a distinct phenotypic contractile difference, rather than differences in their production of soluble mediators or cell attachment to ECM.

Non-vascular vitreoretinopathy: the cells and the cellular basis of contraction

BACKGROUND

We consider epiretinal membrane in terms of the two repair processes of gliosis and fibrosis and look at the cellular basis of contraction.

METHODS

Pathological material removed at surgery was examined by a range of morphological procedures. Cultures of fibroblasts, retinal pigment epithelium cells and retinal glia were subjected to bioassays which relate to behavioural activities in scar formation.

RESULTS AND CONCLUSIONS

Our findings highlight the importance of activities such as migration and adhesion in the formation of epiretinal membranes, and also show that these activities are central to our understanding of contraction.

The generation of a human dermal equivalent to assess the potential contribution of human dermal fibroblasts to the sulphur mustard-induced vesication response

1. A human dermal equivalent (HDE) gel was constructed from rat tail tendon collagen (type 1) and human dermal fibroblasts (HFs). Histological studies revealed that the HFs within the HDE gel matrix assumed the shape of differentiated dermal fibroblasts and were metabolically viable as determined by the MTT assay. 2. The HDE system was developed to determine if viable, differentiated HFs have the potential to contribute to tissue damage by releasing the proteolytic enzyme elastase following exposure to sulphur mustard (HD). Elastase was measured, using the substrate suc-ala-ala-val-p-nitroanilide (SAAVNA), because of its association with various human pathological bullous skin diseases. An additional elastase substrate (suc-ala-ala-ala-p-nitroanilide; SAAANA) was also used. A miniaturised assay was employed to measure lactate dehydrogenase (LDH), a cytosolic enzyme released following damage to the cell membrane. 3. Elastase levels (measured with SAAVNA) increased to over 740% of those in control culture medium at 24 h after exposure of the HDE to HD (2 mM) and may therefore be part of the mechanism associated with dermo-epidermal separation and blistering in humans following exposure of skin to HD. LDH was released from the HDE after exposure to HD in a time dependent fashion, suggesting a steady leakage of cytosolic constituents after the initial exposure. 4. The results suggest that differentiated human dermal fibroblasts have the potential to contribute to the development of the vesication response by releasing proteases such as elastase extracellularly after HD exposure.(ABSTRACT TRUNCATED AT 250 WORDS)

Cytokines modulate contraction of periosteal explants from rabbit calvariae

Periosteal explants obtained from rabbit calvariae are introduced as a model system to study contraction of soft connective tissue. Culturing of these explants resulted in a substantial time-dependent decrease of the surface area which coincided with a similar decrease in volume. A 75% reduction of the initial explant surface area was observed after a culture period of 72h in the presence of 10% serum. Also in the absence of serum contraction of explants was found, indicating that serum components were not essential. Following devitalization of the explants no contraction did occur. A strong inhibition of contraction was found following interference with the formation of microfilaments, microtubules or intracellular cyclic-AMP levels by using cytochalasin B, colchicine or dibutyryl-cAMP, respectively. These data indicated that viable cells and an intact cytoskeleton were a prerequisite for contraction to occur. A number of cytokines (EGF, aFGF, bFGF, IGF-1, PDGF, TGF-beta and IL-1alpha) was tested for their ability to influence contraction. IL-1alpha was shown to inhibit contraction from the 48h culture period on. Anti-IL-1alpha-serum completely abolished this effect. The IL-1alpha-inducible inhibition of contraction was also partially blocked by indomethacin. TGF-beta enhanced contraction dose-dependently during the 24-48h culture period, whereas TGF-1 and IL-1alpha, added to the cultures in combination, proved to antagonize each other. The other growth factors did neither influence contraction not the IL-1alpha-induced inhibition of contraction.

Sheep vibrissa dermal papillae induce hair follicle formation in heterotypic skin equivalents

Cultured skin equivalents were constructed by combining keratinocytes, outer root sheath cells or isolated epidermis, in vitro, with a matrix composed of collagen and cultured fibroblasts. When equivalents were grafted on to host animals, the epidermis thickened considerably, and tongues of cells penetrated the dermis, giving the dermal/epidermal junction a deeply sculptured profile. No cutaneous appendages were found in these grafts. We explored the possibility of inducing hair follicles by incorporating ovine hair follicle dermal papillae into constructs composed of an isolated epidermal sheet and a contracted dermal equivalent. In vitro, no morphogenetic changes associated with follicle formation were observed in the recombinants, but when grafted on to nude mice, follicle-like structures were identified. The follicles were large, and had developed adjacent to the epidermis, indicating that the matrix environment of the induced follicles may not have been compatible with the downgrowth of the epidermal plugs normally observed during follicle formation in living skin. Nevertheless, in histological sections, the induced structures displayed many of the morphological characteristics of follicles in vivo, including the production of keratinized hairs. These results indicate that skin equivalents provide a useful model for the study of the chemical and structural features of matrices that facilitate hair follicle development.

Inter- and intra-site heterogeneity in the expression of fetal-like phenotypic characteristics by gingival fibroblasts: potential significance for wound healing

We have previously reported that fetal and adult skin fibroblasts display distinctive migratory phenotypes on 3-D collagen substrata and that these behavioural characteristics may be quantified by a function defined as the cell density migration index (CDMI). Subsequent work indicated that this difference in migratory phenotype was due to the production by fetal fibroblasts of a migration stimulating factor (MSF) that is not produced by normal adult skin fibroblasts. We now present data indicating that: (a) unselected fibroblasts obtained from 14/14 (100%) of adult gingival explants expressed fetal-like CDMI values compared to only 1/10 (10%) of similarly explanted paired skin cells; (b) 12/12 (100%) of these gingival fibroblast lines also produced detectable quantities of MSF compared to 0/9 (0%) of the tested skin cells; (c) by microdissection studies, gingival fibroblasts obtained from different anatomical microdomains consisted of behaviourally distinct subpopulations, with cells derived from the papillary tips (PAP fibroblasts) displaying fetal-like CDMI values and persistent MSF production, whilst cells obtained from the deeper reticular tissue (RET fibroblasts) were adult-like with respect to these two criteria; (d) PAP fibroblasts were also smaller and achieved higher saturation cell densities compared to paired RET cells; (e) PAP fibroblasts passaged in vitro underwent a fetal-to-adult phenotypic transition characterized by the adoption of various RET cell characteristics, including the acquisition of CDMI values falling within the adult range and cessation in MSF production; and (f) early passage PAP fibroblasts incubated in the presence of an affinity-purified anti-MSF rabbit polyclonal antibody were induced to alter their migratory phenotype and exhibited CDMI values falling within the adult range. Statistical analysis indicated a highly significant correlation between the expression of a fetal-like CDMI and production of MSF (P &lt; 0.00001, using the Fisher exact contingency test). Taken together, these observations suggest that the production of MSF by PAP fibroblasts is responsible for their characteristically fetal-like migratory behaviour. The existence of such inter- and intra-site phenotypic heterogeneity in populations of skin and gingival fibroblasts is discussed in the context of fibroblast lineage relationships and the possible contribution of persistently fetal-like fibroblast subpopulations to connective tissue function in wound healing.

Growth and differentiation properties of normal and transformed human keratinocytes in organotypic culture

The growth and differentiation of human normal keratinocytes and their transformed counterparts were examined in organotypic cultures in which the keratinocytes were grown at the air-liquid interface on top of contracted collagen gel containing fibroblasts. We developed a modified culture procedure including the use of a mixed medium for keratinocytes and fibroblasts. Normal keratinocytes formed a three-dimensional structure of epithelium that closely resembled the epidermis in vivo, consisting of basal, spinous, granular and cornified layers. Cells synthesizing DNA were located in the lowest basal layer facing the collagen gel. Expressions of proteins involved in epidermal differentiation were examined by immunohistochemical staining and compared with those in skin in vivo. In the organotypic culture, transglutaminase, involucrin and filaggrin were expressed, as in the epidermis in vitro, most prominently in the granular layer. Type IV collagen, a component of basement membrane, was expressed at the interface between the keratinocyte sheet and the contracted collagen gel. Keratinocytes transformed by simian virus 40 or human papilloma virus (HPV) exhibited a highly disorganized pattern of squamous differentiation. In particular, HPV-transformed cells invaded the collagen gel. Organotypic culture is unique in that regulatory mechanisms of growth and differentiation of keratinocytes can be investigated under conditions mimicking those in vivo.

Differential responses of human papillary and reticular fibroblasts to growth factors

Differences in the responses to growth factors of normal fibroblasts and scleroderma fibroblasts have been demonstrated previously. Because human dermal fibroblasts are heterogeneous populations, whether known differences between papillary and reticular dermal fibroblasts could account for the noted differences between normal and scleroderma fibroblasts was investigated. Papillary dermal fibroblasts were grown from a dermatome section of normal skin from an adult donor. Reticular dermal fibroblasts were cultured from punch biopsy specimens taken from the same location. In vitro, papillary dermal fibroblasts proliferated more rapidly, had a higher mitotic index and reached greater density at confluence, confirming previous observations. The reticular dermal fibroblasts were more dendritic. Reticular dermal fibroblasts had higher rates of tritiated thymidine uptake and larger increases in mitotic index in response to isoforms of platelet-derived growth factor (PDGF). The characteristic response of scleroderma fibroblasts, potentiation of the mitogenicity of PDGF AA by transforming growth factor-beta (TGF-beta), was not observed in either cell type. Therefore, the phenotypic characteristics of scleroderma fibroblasts cannot be explained by an unusual admixture of papillary and reticular fibroblasts.

Expression of basement membrane components in skin equivalents--influence of dermal fibroblasts

We have made a skin equivalent constructed of fibroblasts embedded in a type I collagen, with an overlying stratified keratinocyte epithelium to examine formation of the basement membrane. We assessed the influence of the existence and species of fibroblasts in the collagen gel. Cultured human keratinocytes were well attached to the dermal equivalent. Plating efficiency was not clearly different among several types of gel. On the control and mouse fibroblast gel, sheet formation was delayed and epithelial stratification on the human fibroblast gel was more remarkable than on the control gel. On the human fibroblast gel, we observed the expression of basement membrane components (bulbous phemphigoid antigen, laminin, type IV collagen and fibronectin) between the sheet of cultured keratinocytes and the human fibroblast gel earlier than those on the control gel and mouse fibroblast gel. Type VIII collagen was not observed in any of the models at 4 weeks.

Contraction of collagen gels by intestinal epithelial cells depends on microfilament function

We have developed a model system to quantify the tractional forces generated by intestinal epithelial cells during organization into a confluent epithelial cell sheet. In this model system, IEC-6 cells, a rat intestinal crypt cell line, rapidly contracted collagen gels reducing the gel surface area by 97% at 24 hr. The tractional forces measured by gel contraction were directly related to the number of cells added and were inversely related to the collagen concentration of the gel. Actin microfilament function was required for gel contraction, but microtubular function was not. Fetal bovine serum and protein synthesis were required for maximal gel contraction. IEC-6 (5 x 10(5)) cells per gel and fibroblasts (5 x 10(4)) cells added to collagen gels resulted in contraction of the gels by 50% at 24 hr. Therefore, intestinal epithelial cells and fibroblasts generate tractional forces of similar strength capable of organizing the surrounding extracellular matrix, which should be considered in models of intestinal morphogenesis and repair.

Deficiency in integrin-mediated transmembrane signaling and microfilament stress fiber formation by aging dermal fibroblasts from normal and Down's syndrome patients

Previous evidence has shown a deficiency in microfilament stress fiber formation upon short-term cycloheximide treatment of cultured human dermal fibroblasts while cytoplasmic spreading appeared completely normal and other cytoskeletal networks organized normally. This deficiency applied to collagen substrata (not fibronectin substrata) and was specific for in vitro-aged normal fibroblasts and for fibroblasts from three different Down's syndrome patients at any passage level. To identify the mechanism(s) for matrix receptor deficiency in aging cells, cells were evaluated for amounts and distributions of several integrin subunits using specific monoclonal antibodies and two complementary experimental approaches. Flow cytometric analyses have shown that all these cells at all passage levels have large amounts of alpha 3 and beta 1 integrin subunits and smaller amounts of the alpha 5 subunit, directed to fibronectin, which are minimally affected in their cell surface availability by cycloheximide treatment. In contrast, cycloheximide treatment leads to the loss from surface availability of most of the alpha 2 subunit, directed to collagen, in late-passage papillary and reticular normal fibroblasts and in all three Down's patient cells at all passages. Prior growth of cells in ascorbate-supplemented medium, which overcomes the deficiency in stress fiber formation, conserves the large amounts of cell surface-available alpha 2 subunit detectable by flow cytometry. When amounts of integrin subunits were evaluated by immunoprecipitation of [35S]methionine-radiolabeled cells, there was no diminution of the alpha 2 subunit or any other subunit for any cells upon cycloheximide treatment; however, there was much less alpha 2 subunit complexed with beta 1 in aging normal and Down's cells. Therefore, cycloheximide treatment does not lead to loss in the amounts of the alpha 2 subunit but rather to its masking at the cell surface and inability to transmit signals across the plasma membrane to effect stress fiber formation. This aging-related deficiency in integrin-mediated signaling can now be studied mechanistically with a variety of approaches to determine the nature of cell-surface molecules interacting with integrins (cis- and/or trans-acting molecules) that discriminate functional from nonfunctional receptors.

Human ovarian surface epithelial cells are capable of physically restructuring extracellular matrix

OBJECTIVE

After ovulation the human ovarian surface epithelium proliferates at the wound edges, migrates over the ovulatory defect, and contributes to its repair primarily by the action of proteolytic enzymes and by the deposition of new matrix material. We examined the potential for human ovarian surface epithelial cells to physically remodel extracellular matrix in culture, similar to collagen gel lattice contraction by fibroblasts, a well-known culture model for wound repair, as an additional role of human ovarian surface epithelium in wound repair.

STUDY DESIGN

Human ovarian surface epithelium cells from ovarian biopsies of 11 patients were grown in culture and plated onto a combination of collagen gel and rat ovarian surface epithelial-derived extracellular matrix. The degree of matrix contraction was measured as the percentage of the original culture diameter.

RESULTS

Human ovarian surface epithelial cells surrounded and contracted the combination of matrices into a dense matrix organoid. The degree of organoid contraction was related to the number of human ovarian surface epithelial cells plated per organoid and to the inclusion of fibroblasts within the collagen gel but was not affected either by adding epidermal growth factor and hydrocortisone to the culture medium or by reducing the serum component of the medium.

CONCLUSION

Human ovarian surface epithelial organoids may be useful for the study of normal and abnormal ovarian events such as ovulatory wound repair and cyst formation.

Peripheral anchorage of dermal equivalents

Human fibroblasts can induce collagen gel contraction with different kinetics depending on the number of cells and on the collagen concentration within this lattice, which has been considered as a dermal equivalent. Skin equivalent is a combined culture of dermo-epidermal layers which may be of therapeutic value in the treatment of burn patients. However, the current production of the dermal equivalent component gives results that present many drawbacks for their eventual clinical use as a first step in obtaining a skin equivalent. These include: (i) final surfaces which are very small; less than 20% of the initial size (ii) excessive thickness which may hamper successful graft take (iii) fibroblasts that do not have an arrangement comparable with normal dermal tissue. We propose, as a solution to these problems, the utilization of a 5-mm-wide fibre-glass filter ring peripherally attached to the surface of the Petri dishes to prevent inordinate contraction while the fibroblasts reorganize the collagen gel. Using this technique the initial surface was preserved and the dermal equivalent contracted only in thickness. Histological analysis of these anchored equivalents confirmed an alignment of fibroblasts and collagen fibres resembling normal dermal tissue. We consider this method useful in the development of dermo-epidermal sheets for clinical purposes.

Extracellular matrix contraction by fibroblasts: peptide promoters and second messengers

Cells contracting connective tissue matrices generate tractional forces in tissues. Studies of fibroblast contraction, using collagen gels in an in vitro model, demonstrate that it involves the actin cytoskeleton, specific extracellular matrix receptors and requires stimulation by exogenous promoters. Fibroblast contraction is stimulated by factors released by platelets and potentially secreted within the contracting tissue. Endothelial cells secrete a potent promoter of fibroblast contraction which has been identified as endothelin 1. The pathway through which fibroblast contraction is stimulated appears to require activation of protein kinase C. Tumor cells can also secrete endothelin. These mechanisms may be relevant to tumor progression.

Variability in the retraction of collagen lattices by scleroderma fibroblasts--relationship to protein synthesis and clinical data

Skin fibroblasts from 18 scleroderma patients were seeded into collagen lattices and their ability to retract their substratum was compared with that of control fibroblasts from healthy donors. When considered as a whole, scleroderma fibroblasts retracted lattices earlier and more intensely than controls. Analysis of individual results demonstrated that morphea and diffuse systemic sclerosis (dSSc) fibroblasts had different kinetics of lattice retraction. Fibroblasts which contracted lattices more intensely than controls were found to produce increased levels of fibronectin. A comparison of the retraction of collagen lattices by fibroblasts from involved (IS) and uninvolved skin (US) of the same patients (n = 4) showed that those from IS retracted the lattices more than fibroblasts from normal donors, whereas a high variability was found with fibroblasts from US. The increased retraction of collagen lattices seems to be a feature of the more severe forms of scleroderma.

Collagen gel contraction by fibroblasts requires cellular fibronectin but not plasma fibronectin

Fibroblasts embedded in three-dimensional lattices of collagen fibrils have been known to require serum constituents to induce a cell-mediated contraction of collagen gels. The gel contraction was studied with human skin fibroblasts cultured in the presence of fetal bovine serum (FBS). Removal of bovine serum fibronectin (sFN) from FBS did not affect the extent of gel contraction. Gel contraction occurred in serum-free defined media. Therefore, it is concluded that sFN is not required for gel contraction. That cellular FN (cFN) synthesized and secreted by fibroblasts plays a crucial role in gel contraction was suggested by the following experiments: (1) We obtained monoclonal antibodies (mAb A3A5) against fibroblast surface antigens, which suppressed the fibroblast-mediated gel contraction. Immunoblot analyses showed that mAb A3A5 recognizes cFN secreted by human fibroblasts and human plasma FN (pFN), but not bovine sFN in FBS used for culture. (2) Addition of rabbit antisera, which recognize human cFN, to a serum-free gel culture inhibited contraction. Uninvolvement of human pFN in gel contraction was further confirmed by the fact that neither pretreatment of fibroblasts with excess amounts of human pFN nor the presence of excess amounts of human pFN in gels affected the extent of gel contraction. This study seems to be the first demonstration of functional difference between cFN and pFN (or sFN) and proposes a novel mode of binding of fibroblasts with collagen fibrils via cFN during cell-mediated collagen morphogenesis.

Transforming growth factor-beta and platelet-derived growth factor synergistically stimulate contraction by testicular peritubular cells in culture in serum-free medium

We report investigations on factors influencing contractility by testicular peritubular cells (PC) maintained in culture in a three-dimensional collagen gel system, and the behavior of PC in culture on a two-dimensional system. At low and moderate cell densities, PC embedded in collagen gels in serum-free Eagle's minimal essential medium (MEM) have a lesser degree of contractility than PC in culture in MEM containing calf serum. The contractility by PC, measured by determining changes in diameter of the collagen gel, was increased by addition of transforming growth factor-beta (TGF-beta) to serum-free MEM, and this was further enhanced by supplementing the medium with platelet-derived growth factor (PDGF). In the absence of TGF-beta, however, PDGF had no detectable effects on PC contractility. Other growth factors examined (epidermal growth factor, insulin, and fibroblast growth factor) did not influence the degree of contractility of PC in serum-free MEM in the presence or absence of TGF-beta. PC maintained in MEM supplemented with platelet-poor serum (PPS) have a lesser degree of contractility than their counterparts in MEM containing 2.5% calf serum. The addition of TGF-beta and PDGF to PPS-supplemented MEM restored contractility by PC to a level comparable to that observed by PC in MEM containing complete serum. The addition of nonpurified bovine serum albumin (BSA) to MEM greatly increased PC contractility. By contrast, highly purified BSA had no such effect, suggesting that one or more components adsorbed to the impure BSA was implicated. Polyclonal antibody against fibronectin did not influence the contractility of PC in collagen gels in the presence or absence of serum. Antiserum against TGF-beta partially blocked the enhancement of contractility of PC in MEM containing non-purified BSA. In PC plated on top of a collagen gel lattice, the attachment, spreading, and cell shape were greatly influenced by the presence of TGF-beta and PDGF, both singly and together. Data presented are interpreted to indicate that effects elicited by serum on the properties of PC in culture, and on the contractility of PC, can be attributed in part to the combined influences of TGF-beta and PDGF in serum.

Grafting of venous leg ulcers. An intraindividual comparison between cultured skin equivalents and full-thickness skin punch grafts

Skin equivalents that consisted of a noncontracted collagen gel populated with allogeneic fibroblasts and covered with autologous cultured keratinocytes were used for grafting venous leg ulcers. The results were compared in the same patient with those obtained with a routinely used standard method of grafting with autologous full-thickness punch grafts. The skin equivalents and the punch grafts were grafted successfully in four of five patients. The median healing time of ulcers grafted with skin equivalents was 18 days whereas that of ulcers covered with punch grafts was 15 days. The cosmetic appearance of the skin equivalent-grafted ulcers was better than that of the punch-grafted ulcers.

Influence of initial collagen and cellular concentrations on the final surface area of dermal and skin equivalents: a Box-Behnken analysis

Our laboratory has been involved in finding optimal conditions for producing dermal and skin equivalents. As an original approach, a Box-Behnken experimental design was used to study the effects of the initial collagen and fibroblast concentrations and the initial gel thickness on the contraction of dermal and skin equivalents. The final surface area of dermal equivalent varied significantly with the initial concentration of collagen and fibroblast, whereas the initial thickness of gel had no appreciable effect on the contraction of the dermal equivalent. When keratinocytes were grown on these dermal equivalents they produced a very severe contraction, to an extent that all skin equivalents had a similar final surface area. This severe contraction was independent of collagen and fibroblast concentrations. Models for the prediction of the final percentage contraction of dermal and skin equivalents as a function of the initial concentration of collagen, the logarithm of fibroblast concentration, and the initial gel thickness were obtained and analyzed. Keratinocytes grown at the lowest seeding density did not contract the equivalents. However, histologic analysis has shown an incomplete coverage by these cells of the equivalents. The extensive contraction of the skin equivalent presenting adequate morphology is a major drawback toward its clinical utilization for burn wound coverage.

Human keratinocytes contain carbohydrates that are recognized by keratan sulfate-specific monoclonal antibodies

Monoclonal antibodies that recognize carbohydrate epitopes found in keratan sulfate glycosaminoglycan chains identified both intracytoplasmic and cell-surface carbohydrates of human keratinocytes. These carbohydrates were detected, using indirect immunoperoxidase methods, both in sections of paraffin-embedded tissues and in intact cultured keratinocytes. Of the seven anti-keratan sulfate monoclonal antibodies used in this study, five detected significant amounts of epitopes associated with keratinocytes. This indicates that only certain, specific types of keratan sulfate-like carbohydrates were expressed by these cells. The extent and localization of keratan sulfate-like carbohydrates appeared to be closely related to the differentiation status of cultured keratinocytes. These epitopes were very weakly expressed on surfaces of all monolayer keratinocytes, but flattened, suprabasal cells in high Ca++ cultures strongly expressed keratan sulfate-like carbohydrates on their surfaces. A much larger population of cultured keratinocytes expressed intracellular keratan sulfate-like carbohydrates identified by the same five antibodies that detected surface epitopes. In monolayer cells, keratan sulfate-like carbohydrates were predominantly found in a broad perinuclear zone. In addition, three of the five immunoreactive antibodies detected epitopes that appeared at cell boundaries, specifically at sites of close cell-to-cell contact. Thus, molecules bearing carbohydrates recognized by anti-keratan sulfate antibodies appear at developmentally important stages of keratinocyte differentiation, indicating that these carbohydrates may serve as markers for molecules important in the differentiation of human keratinocytes.

Cell-type-specific expression of alternatively spliced human fibronectin IIICS mRNAs

Fibronectin polypeptide diversity is generated to a large extent by alternative splicing of the fibronectin primary transcript at three sites: two extra domain exons encoding extra structural repeats and a region of nonhomologous sequence termed the type-III connecting segment (IIICS). A novel double primer extension assay was developed to identify and quantify simultaneously each of the five human IIICS mRNA splicing variants. Expression of the five IIICS variants was analyzed in a variety of human normal and tumor cell types as well as in human liver. Differences in IIICS expression patterns were observed among different cell types, among fibroblasts of different tissue origins, and between comparable normal and transformed cells. The most predominant cell-type-specific differences were in the abundance of the one IIICS- mRNA variant relative to the four IIICS+ variants. The percentage of O variant (IIICS-) mRNAs within the total fibronectin mRNA pool varied between 3 and 17% among tumor cells and between 7 and 46% among normal cells. The O variant composed 57% of the fibronectin mRNA in liver tissue, correlating with the previously described increased abundance of IIICS- polypeptide subunits in plasma fibronectin, compared with those in cellular fibronectins. Additional cell-type-specific changes among the expression levels of the four IIICS+ mRNA variants are consistent with a proposed model in which regulation of an alternative selection of a 3'splice site predominates over regulation of the selection of a 5' splice site in generating specific patterns of IIICS mRNA expression.

Cell-type-specific expression of alternatively spliced human fibronectin IIICS mRNAs

Fibronectin polypeptide diversity is generated to a large extent by alternative splicing of the fibronectin primary transcript at three sites: two extra domain exons encoding extra structural repeats and a region of nonhomologous sequence termed the type-III connecting segment (IIICS). A novel double primer extension assay was developed to identify and quantify simultaneously each of the five human IIICS mRNA splicing variants. Expression of the five IIICS variants was analyzed in a variety of human normal and tumor cell types as well as in human liver. Differences in IIICS expression patterns were observed among different cell types, among fibroblasts of different tissue origins, and between comparable normal and transformed cells. The most predominant cell-type-specific differences were in the abundance of the one IIICS- mRNA variant relative to the four IIICS+ variants. The percentage of O variant (IIICS-) mRNAs within the total fibronectin mRNA pool varied between 3 and 17% among tumor cells and between 7 and 46% among normal cells. The O variant composed 57% of the fibronectin mRNA in liver tissue, correlating with the previously described increased abundance of IIICS- polypeptide subunits in plasma fibronectin, compared with those in cellular fibronectins. Additional cell-type-specific changes among the expression levels of the four IIICS+ mRNA variants are consistent with a proposed model in which regulation of an alternative selection of a 3'splice site predominates over regulation of the selection of a 5' splice site in generating specific patterns of IIICS mRNA expression.

Aging-related changes and topology of adhesion responses sensitive to cycloheximide on collagen substrata by human dermal fibroblasts

Human dermal fibroblasts (both papillary and reticular) were tested during in vivo or in vitro aging for their responses on collagen and/or fibronectin (FN) substrata, as well as on topologically mixed substrata. Cycloheximide treatments were used to evaluate whether receptors to these matrix molecules, mediating F-actin reorganization into stress fibers, are altered during aging processes. Late-passage (but not mid-passage) papillary and reticular cells from both an elderly male and a newborn infant spread effectively on collagen +/- FN but failed to generate stress fibers after lengthy pretreatment of cells with cycloheximide. In contrast, treatment with cycloheximide only when cells were reattaching was not inhibitory. None of the treatments had any effect on stress fiber formation of cells on FN-only substrata, demonstrating that drug sensitivity was specific for collagen responses. The inhibition could be reversed by rinsing cycloheximide out of cultures and could be prevented by prior growth of cells in ascorbate-supplemented medium to stimulate production/maturation of collagen and possibly collagen-specific receptors. Adjacent regions of coverslips were adsorbed with collagen and a proteolytic fragment of plasma FN lacking the collagen-binding domain but retaining other binding domains; cells bridging the interface were of special interest. When fragment F155 containing both the RGDS cell-binding and the heparin II-binding domains was tested in this paradigm, cells generated stress fibers continuous from the collagen-facing side into the F155-facing side of the same cell, consistent with the compatability of both collagen and FN receptors in generating the same stress fiber. However, F110 lacking the heparin II domain was incapable of facilitating stress fiber formation; fibers formed effectively on the collagen side and terminated abruptly at the collagen:F110 interface. These experiments demonstrate stringent regulation of where stress fibers begin, span, and terminate in the cytoplasm by matrix receptors at the cell's undersurface and establish that there are alterations of collagen-specific receptors as a consequence of in vitro aging, but not of in vivo aging, in both papillary and reticular human dermal fibroblasts.