We have recently demonstrated that EBV binds to human neutrophils and stimulates a wide range of activities, including homeotypic aggregation, total RNA synthesis, and expression of the chemokines IL-8 and macrophage inflammatory protein-1alpha (MIP-1alpha). Neutrophil function is also known to be modulated by priming with granulocyte-macrophage colony-stimulating factor (GM-CSF). We have therefore investigated the modulation of EBV-induced activation of human neutrophils by GM-CSF. Treatment of neutrophils with GM-CSF before EBV activation enhanced the production of both MIP-1alpha and IL-8. The IL-8 produced under these conditions was biologically active as determined in the calcium mobilization assay. GM-CSF was also found to increase the ability of EBV to prime neutrophils for increased leukotriene B4 (LTB4) synthesis. Prior treatment of GM-CSF with neutralizing Abs inhibited these effects. GM-CSF also increased the specific binding of FITC-EBV to the neutrophil surface, as evaluated by fluorocytometry. Local production of GM-CSF in tissues invaded by EBV could therefore serve to potentiate a host defense mechanism directed toward the destruction of the infectious virus via increased production of chemotactic factors. Since both IL-8 and MIP-1alpha are reported to be chemoattractants in vitro for T cells and T and B cells, respectively, the ability of EBV to induce their production by neutrophils may enhance its ability to infect B and T lymphocytes via increased recruitment to sites of infection.
The survival of thick tissues/organs produced by tissue engineering requires rapid revascularization after grafting. Although capillary-like structures have been reconstituted in some engineered tissues, little is known about the interaction between normal epithelial cells and endothelial cells involved in the in vitro angiogenic process. In the present study, we used the self-assembly approach of tissue engineering to examine this relationship. An endothelialized tissue-engineered dermal substitute was produced by adding endothelial cells to the tissue-engineered dermal substitute produced by the self-assembly approach. The latter consists in culturing fibroblasts in the medium supplemented with serum and ascorbic acid. A network of tissue-engineered capillaries (TECs) formed within the human extracellular matrix produced by dermal fibroblasts. To determine whether epithelial cells modify TECs, the size and form of TECs were studied in the endothelialized tissue-engineered dermal substitute cultured in the presence or absence of epithelial cells. In the presence of normal keratinocytes from skin, cornea or uterine cervix, endothelial cells formed small TECs (cross-sectional area estimated at less than 50 μm2) reminiscent of capillaries found in the skin's microcirculation. In contrast, TECs grown in the absence of epithelial cells presented variable sizes (larger than 50 μm2), but the addition of keratinocyte-conditioned media or exogenous vascular endothelial growth factor induced their normalization toward a smaller size. Vascular endothelial growth factor neutralization inhibited the effect of keratinocyte-conditioned media. These results provide new direct evidence that normal human epithelial cells play a role in the regulation of the underlying TEC network, and advance our knowledge in tissue engineering for the production of TEC networks in vitro.
After human epidermis wounding, transepithelial potential (TEP) present in nonlesional epidermis decreases and induces an endogenous direct current epithelial electric field (EEF) that could be implicated in the wound re-epithelialization. Some studies suggest that exogenous electric stimulation of wounds can stimulate healing, although the mechanisms remain to be determined.Little is known concerning the exact action of the EEF during healing. The mechanism responsible for TEP and EEF is unknown due to the lack of an in vitro model to study this phenomenon.We carried out studies by using a wound created in a human tissue-engineered skin and determined that TEP undergoes ascending and decreasing phases during the epithelium formation. The in vitro TEP measurements over time in the wound were corroborated with histological changes and with in vivo TEP variations during porcine skin wound healing. The expression of a crucial element implicated in Na+ transport, Na+/K+ ATPase pumps, was also evaluated at the same time points during the re-epithelialization process. The ascending and decreasing TEP values were correlated with changes in the expression of these pumps. The distribution of Na+/K+ ATPase pumps also varied according to epidermal differentiation. Further, inhibition of the pump activity induced a significant decrease of the TEP and of the re-epithelization rate.A better comprehension of the role of EEF could have important future medical applications regarding the treatment of chronic wound healing.This study brings a new perspective to understand the formation and restoration of TEP during the cutaneous wound healing process.
Wehave developed a tissue-engineering approach for the production of a completely biological blood vessel from cultured human cells. In the present study, we took advantage of this tissue-engineering method to demonstrate that it can be used to reproduce the subtle differences in the expression of receptors present on the media of native human blood vessels. Indeed, a small percentage (3 of 18) of native human umbilical cord veins (HUCVs) responded to endothelin, the most powerful vasopressor agent known to date, via both endothelin A (ETA) and endothelin B (ETB) receptor activation. In contrast, most HUCVs tested responded toETviaETA receptor activation only. Tissue-engineered vascular media (TEVM) were next reconstructed by using vascular smooth muscle cells (VSMCs) isolated and cultured from HUCVs expressing both ETA and ETB receptors to determine the functional integrity of our TEVM model. The reconstructed TEVM presents an endothelin response similar to that of respective HUCVs from which VSMCs were isolated. Reverse transcriptase polymerase chain reaction on TEVM reconstructed in vitro correlated these vasocontractile profiles by showing the presence of messenger RNA for both ETA and ETB receptors. Taken together with recently published results on TEVM expressing only ETA receptor, these results show that our reconstructed TEVM present a similar ET response profile as the blood vessel from which the VSMCs were isolated and cultured. These findings indicate that subtle differences, such as receptor expression, are preserved in the reconstructed tissue. Therefore, our TEVM offers a valuable human in vitro model with which to study the functionality of human blood vessels, such as their vasoactive response, or to perform pharmacologic studies.
