Cocultivation of primary hepatocytes with a plethora of nonparenchymal cells (from within and outside the liver) has been shown to support hepatic functions in vitro. Despite significant investigation into this phenomenon, the molecular mechanism underlying epithelial-nonparenchymal interactions in hepatocyte cocultures remains poorly understood. In this study, we present a functional genomic approach utilizing gene expression profiling to isolate molecular mediators potentially involved in induction of liver-specific functions by nonparenchymal cells. Specifically, primary rat hepatocytes were cocultivated with closely related murine fibroblast cell types (3T3-J2, NIH-3T3, mouse embryonic fibroblasts) to allow their classification as "high," "medium," or "low" inducers of hepatic functions. These functional responses were correlated with fibroblast gene expression profiles obtained using Affymetrix GeneChips. Microarray data analysis provided us with 17 functionally characterized candidate genes in the cell communication category (cell surface, extracellular matrix, secreted factors) that may be involved in induction of hepatic functions. Further analysis using various databases (i.e., PubMed, GenBank) facilitated prioritization of the candidates for functional characterization. We experimentally validated the potential role of two candidates in our coculture model. The cell surface protein, neural cadherin (N-cadherin), was localized to hepatocyte-fibroblast junctions, while adsorbed decorin up-regulated hepatic functions in pure cultures as well as cocultures with low-inducing fibroblasts. In the future, identifying mediators of hepatocyte differentiation may have implications for both fundamental hepatology and cell-based therapies (e.g., bioartificial liver devices). In conclusion, the functional genomic approach presented in this study may be utilized to investigate mechanisms of cell-cell interaction in a variety of tissues and disease states.
Keloids and hypertrophic scars are significant symptomatic clinical problems characterized by excess collagen. Although extensive research has focused on fibroblasts and collagen turnover in these aberrant scars, little work has been done on the expression of integrins (cell membrane structures that link cells to extracellular matrix) within these lesions. Integrin-mediated regulation of collagen synthesis has previously been observed in explanted fibroblasts from normal and fibrotic dermis, and integrin alpha1 knockout mice maintain increased collagen synthesis consistent with a role for alpha1beta1 in providing negative feedback on collagen synthesis. These findings suggested the need to evaluate integrin roles in keloids and hypertrophic scars. In this study we examined integrin expression in keloids (n = 11), hypertrophic scars (n = 5), radiation ulcers (n = 2), and normal skin specimens (n = 8). We used a novel approach to analysis by isolating dermal fibroblasts directly from tissue (without explant culture) and determining surface integrin expression by flow cytometry. We found that keloids and hypertrophic scars have marked alterations in fibroblast integrin expression and contain several distinct populations of fibroblasts. One of these populations expresses high levels of alpha1 integrin, and the proportion of these cells is higher in keloids (63% +/- 3.6% SEM) and hypertrophic scars (45% +/- 2.7% SEM) than in normal skin tissues (28% +/- 4.7% SEM). The different populations of fibroblasts defined by integrin expression merge, however, when the cells are serially cultured, suggesting that there may be aspects of the dermal microenvironment that maintain the integrin phenotypic heterogeneity in dermal fibroblasts.
A biomimetic delivery strategy for transforming growth factor beta (TGF-β) is described, in which TGF-β is presented in a latent form (the small latent complex, SLC), which is inactive until modified by the actions of the cells. In this work, SLC is tethered to a hyaluronic acid hydrogel scaffold to enhance in vitro chondrogenesis.
The dermis of the holothurian Cucumaria frondosa is a mutable collagenous tissue (MCT). In this study, the inner and outer regions of the dermis were separated and used to make two different tissue extracts. These extracts were applied to intact pieces of dermis, one invoking a stiff mechanical state and the other invoking a compliant state. The extracts were effective on tissues incubated in artificial sea water (ASW) and in those incubated in Ca(2+)-chelated ASW. Furthermore, the extracts were effective on both fresh tissues and tissues in which the cells had been lysed by freeze-thawing, indicating that the sites of action are in the extracellular matrix. Dynamic oscillatory shear tests and analyses were used to measure both the dynamic shear stiffness (G*) and the relative damping (tan delta) of the tissue. These two parameters proved to be inversely related to each other (i.e. when G* increased, tan delta decreased). A theoretical viscoelastic model is constructed to interpret the results of these tests. It is concluded that changes in the mechanical state of the tissue involve interactions between elastic elements within the tissue rather than an alteration of its viscous components.
Collagen fibrils are some of the most-abundant and important extracellular structures in our bodies, yet we are unsure of their shape and size. This is largely due to an inherent difficulty in isolating them from their surrounding tissues. Echinoderms have collagenous tissues that are similar to ours in many ways, yet they can be manipulated to easily relinquish their collagen fibrils, providing an excellent opportunity to study native fibrillar structure. In the early 1990s, they were found to defy the commonly accepted fibrillar model of the time in that they were much shorter, they were shaped like double-ended spindles, and their centers exhibited a reversal in molecular polarity. Realization of these features helped to reform the questions that were being asked about vertebrate fibrils, shifting the focus toward shape and size. Since then, researchers working with both groups (echinoderms and vertebrates) have worked together to find the structure of native fibrils. This information will be fundamental in understanding what holds collagenous tissues together at the fibrillar level, and could have important implications for people with Ehlers-Danlos syndrome.
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