Inhibition of thrombin receptor signaling on α-smooth muscle actin(+) CD34(+) progenitors leads to repair after murine immune vascular injury.

OBJECTIVE: The goal of this study was to use mice expressing human tissue factor pathway inhibitor (TFPI) on α-smooth muscle actin (α-SMA)(+) cells as recipients of allogeneic aortas to gain insights into the cellular mechanisms of intimal hyperplasia (IH). METHODS AND RESULTS: BALB/c aortas (H-2(d)) transplanted into α-TFPI-transgenic (Tg) mice (H-2(b)) regenerated a quiescent endothelium in contrast to progressive IH seen in C57BL/6 wild-type (WT) mice even though both developed aggressive anti-H-2(d) alloresponses, indicating similar vascular injuries. Adoptively transferred Tg CD34(+) (but not CD34(-)) cells inhibited IH in WT recipients, indicating the phenotype of α-TFPI-Tg mice was due to these cells. Compared with syngeneic controls, endogenous CD34(+) cells were mobilized in significant numbers after allogeneic transplantation, the majority showing sustained expression of tissue factor and protease-activated receptor-1 (PAR-1). In WT, most were CD45(+) myeloid progenitors coexpressing CD31, vascular endothelial growth factor receptor-2 and E-selectin; 10% of these cells coexpressed α-SMA and were recruited to the neointima. In contrast, the α-SMA(+) human TFPI(+) CD34(+) cells recruited in Tg recipients were from a CD45(-) lineage. WT CD34(+) cells incubated with a PAR-1 antagonist or taken from PAR-1-deficient mice inhibited IH as Tg cells did. CONCLUSIONS: Specific inhibition of thrombin generation or PAR-1 signaling on α-SMA(+) CD34(+) cells inhibits IH and promotes regenerative repair despite ongoing immune-mediated damage.

Bone marrow-derived CX3CR1 progenitors contribute to neointimal smooth muscle cells via fractalkine CX3CR1 interaction.

Smooth muscle cells play a major role in numerous vascular diseases that contribute to remodeling, repair after injury, and arteriogenesis, and the source of these cells is thought to lie within the vessel wall and the circulating blood. Currently, the precise origin and mechanism of differentiation of extravascular smooth muscle progenitor cells (SPCs) is unclear. We show here that the CX(3)CR1 mononuclear cell population of murine bone marrow provides a source of SPCs that contributes to smooth muscle cells within the neointimal plaque after vascular injury. Moreover, CX(3)CR1-fractalkine (FKN) interaction in vivo is essential for smooth muscle cell differentiation of bone marrow-derived progenitor cells at the vessel wall level. Functional competence of bone marrow-derived CX(3)CR1 positive cells to interact with FKN is also crucial in part for neointima formation following vascular injury. Finally, in a pure preparation of bone marrow-derived CX(3)CR1 positive cells, we show that in vitro smooth muscle cell differentiation increases markedly in the presence of FKN. Our data highlight a novel functional relationship between the myeloid and vascular systems and in the context of vascular injury and repair underscores a key chemokine-receptor pathway that may regulate cell fate when smooth muscle cell differentiation is required.

Lines of cell differentiation in solitary fibrous tumor: an ultrastructural and immunohistochemical study of 10 cases.

BACKGROUND: Solitary fibrous tumor (SFT) is a rare ubiquitous mesenchymal neoplasm of probable fibroblastic type with a prominent hemangiopericytoma-like vascular pattern. Since their initial description as arising from the pleura, SFTs have been reported in many extraserosal sites. It is now accepted that this neoplasm is derived from mesenchymal cells but its histogenesis is still not known. METHODS: The authors gathered clinical data on 10 patients with SFT. Tissue microarrays were constructed to perform inmunohistochemical tests and we reviewed hematoxilin-eosin-stained slides. Electron-microscopically collected samples were fixed with formalin or Karnovsky reactive and embedded in epoxy resin. RESULTS: The histopathological review showed varying degrees of cell density and mitotic activity, which correlated with clinical behavior. Immunohistochemically most tumors stained positively for vimentin, CD99, and CD34. Ultrastructural study showed some degree of myofibroblastic differentiation in all cases and focal smooth muscle features. In addition, 9 cases showed perivascular undifferentiated cells. CONCLUSION: SFT is an uncommon neoplasm with different histological patterns and clinical behavior. The authors hypothesize that the perivascular undifferentiated cells that most cases showed might correspond to a quiescent stage of adult stem mesenchymal cell and could be the target of the molecular aberrations implied in its pathogenesis.

Subepithelial myofibroblasts are novel nonprofessional APCs in the human colonic mucosa.

The human gastrointestinal mucosa is exposed to a diverse normal microflora and dietary Ags and is a common site of entry for pathogens. The mucosal immune system must respond to these diverse signals with either the initiation of immunity or tolerance. APCs are important accessory cells that modulate T cell responses which initiate and maintain adaptive immunity. The ability of APCs to communicate with CD4+ T cells is largely dependent on the expression of class II MHC molecules by the APCs. Using immunohistochemistry, confocal microscopy, and flow cytometry, we demonstrate that alpha-smooth muscle actin(+), CD90+ subepithelial myofibroblasts (stromal cells) constitutively express class II MHC molecules in normal colonic mucosa and that they are distinct from professional APCs such as macrophages and dendritic cells. Primary isolates of human colonic myofibroblasts (CMFs) cultured in vitro were able to stimulate allogeneic CD4+ T cell proliferation. This process was dependent on class II MHC and CD80/86 costimulatory molecule expression by the myofibroblasts. We also demonstrate that CMFs, engineered to express a specific DR4 allele, can process and present human serum albumin to a human serum albumin-specific and DR4 allele-restricted T cell hybridoma. These studies characterize a novel cell phenotype which, due to its strategic location and class II MHC expression, may be involved in capture of Ags that cross the epithelial barrier and present them to lamina propria CD4+ T cells. Thus, human CMFs may be important in regulating local immunity in the colon.