During human skin development, embryonic-and fetal-specific periderm cells and incompletely keratinized cells are replaced by keratinocytes that differentiate while stratifying to form the fully functional epidermis. Proliferating basal cells of fetal skin also develop into epidermal appendages such as hair follicles and glands. We demonstrate that programmed cell death, not emphasized in conventional epidermal biology, has an important function in establishing the final architecture of the human epidermis and its appendages. Immunohistochemical localization of transglutaminases in fetal periderm, intermediate epidermal cells, and within appendages coincides with DNA fragmentation indicating that apoptosis is involved in deletion of these stagespecific cells and remodeling of appendages. The data also suggest that terminal differentiation of epidermal cells might be a specialized form of apoptosis. The pattern of expression of bcl-2, a gene associated with survival of some cells, is exclusive of the distribution patterns of markers of the cell death pathway. Bcl-2 protein is correlated with specific morphogenetic events in hair follicles and eccrine sweat glands, and its presence in single cells of the hair follicle bulge suggests that Bcl-2 may be a stem cell marker.
Our previous studies have shown that a major protein isolated from purified cell walls of Proteus mirabilis (39-kDa protein) is a strong modulator of the specific immune responses to lipopolysaccharide (LPS) from this bacterium. When the protein is mixed with LPS before immunization of mice, the responses of antibody-producing cells specific for LPS are greatly enhanced and converted predominantly to the immunoglobulin G isotype. In the present study, the immunomodulating effects of the 39-kDa protein were tested at the level of interaction of LPS with macrophages. Activation of macrophages was determined by measuring the production of oxygen radicals in a chemiluminescence assay with lucigenin as the amplifier. LPS from P. mirabilis induced strong oxidative metabolism in both peritoneal and bone marrow-derived murine macrophages. These responses were inhibited in a dose-dependent manner by mixing LPS with increasing amounts of the protein. In contrast, bovine serum albumin and methylated bovine serum albumin enhanced the response of macrophages dramatically when complexed with LPS. The inhibiting activity of the 39-kDa protein was also observed with LPS from Escherichia coli K-12.
We previously showed that a major protein isolated from purified cell walls of Proteus mirabilis (39-kDa protein) is a strong modulator of the specific immune responses to LPS from this bacterium in mice. When mixed with LPS before immunization, this protein enhances T cell-dependent, IgG antibody-producing cell responses specific for LPS. Furthermore, complexes of the 39-kDa protein with LPS drastically inhibit the production of oxygen radicals by murine macrophages activated with LPS, as measured in a chemiluminescence assay. In the present report, we have further investigated possible modulating effects of the protein at the level of LPS-macrophage interaction. When mixed with LPS, the 39-kDa protein inhibited IL-1 production by murine macrophages derived from bone marrow in a dose-dependent manner, as determined in an IL-2-dependent IL-1 assay. On the other hand, the protein had little effect on LPS-mediated suppression of MHC class II expression on the surface of macrophages induced with IFN-gamma. Some abrogation of suppression was observed, but the amounts of protein needed for this effect were quite large, in comparison with the amounts rendering inhibition of IL-1 production. In contrast, the 39-kDa protein enhanced the LPS-induced cytotoxicity of macrophages against L929 target cells, primarily as the result of production of TNF. These results show that the 39-kDa protein is a potent modulator of the interaction of LPS with macrophages, exerting its effects in a differential manner with respect to various parameters of LPS-induced activation of macrophages.
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