Localization and expression of fibronectin during mouse decidualization in vitro: mechanisms of cell:matrix interactions.

Abstract

During implantation, the embryonic trophoblast aggressively invades the uterine stroma. The resulting uterine reaction, decidualization, involves differentiation of new cell morphologies and remodeling of the extracellular matrix. This creates an environment that first permits invasion, then controls this invasion to allow the establishment of the placenta. The production, organization, and cellular interactions with the matrix are thought to underlie decidual functions. We have begun a reductional analysis of the components of the decidual matrix, focusing on extracellular fibronectin (FN). Using decidual cell cultures prepared from day 7 implantation sites, the synthesis, extracellular organization, and details of decidual cell:FN interaction were studied. Employing immunofluorescence, immunoprecipitation, and dot blot analysis, decidualizing cultures showed a constitutive level of FN synthesis and deposition. The differentiating cells organized extracellular FN in patterns similar to that seen in vivo. The predominant, flattened dendritic decidual cells organized FN in long, thin fibrils. Large, rounded decidual cells, limited to the primary decidual zone in vivo, showed FN limited to punctate membrane patches and short, thick fibrils. Using double labeling techniques, FN expression was co-localized with actin microfilament (MF) bundles during the cytoskeletal changes associated with the differentiation of both decidual cell types. The function of MFs in maintaining morphology was demonstrated by cytochalasin B perturbation. Attachment of decidual cells to FN was calcium dependent and gly-arg-gly-asp-ser-pro (GRGDSP) sensitive, with dendritic decidual cells expressing the alpha 5 and beta 1 integrin subunits. This suggests that an integrin system functions to attach decidual MF bundles to extracellular FN. This work shows that during decidual matrix remodeling, constitutive levels of FN are maintained to provide an extracellular framework to stabilize the decidual cytoskeleton and support morphological differentiation of decidual cells.