Mast cells express connexins on their cytoplasmic membrane.

BACKGROUND: Because of the close association between mast cells and fibroblasts in the microenvironment and the importance of connexins (Cxs) in fibroblast communication with other cells, we hypothesized that mast cells also express Cxs, allowing them to similarly communicate with other cells through gap junctions. OBJECTIVES: We sought to identify the expression of Cxs (particularly Cx43, Cx32, and Cx26) by murine mast cells. METHODS: The expression of Cxs was studied by RT-PCR, Northern blot analysis, Western blot analysis, flow cytometry, and confocal laser scanning microscopy. RESULTS: In this report we demonstrate that murine bone marrow cultured mast cells and the growth factor-independent murine mast cell line C57, express Cx43 and Cx32 as assessed by RT-PCR, Northern blot analysis, Western blot analysis, and flow cytometry, but do not express Cx26. We also show, by confocal laser scanning microscopy, that Cx43 localizes to the cytoplasmic membrane of mast cells in a pattern similar to that seen in fibroblasts. CONCLUSIONS: Mast cells express Cx43 and Cx32, and Cx43 is associated with the cytoplasmic membrane, suggesting that mast cells have the potential to communicate with other cells in their microenvironment in part through gap junctions.

Identification and categorization of inducible mast cell genes in a subtraction library.

Mast cells play an important role in allergic inflammation by releasing inducible proinflammatory cytokines. While many inducible genes have been identified, we hypothesized that a significant number remain to be identified. We thus constructed an activation-specific mast cell subtraction library to establish a profile of induced genes in mast cells following allergic stimulation. To date, we have sequenced 150 cDNA clones. Among them, we have isolated 22 known genes whose expression has not been reported in mast cells, and an additional 26 cDNA clones which do not have significant homology to known genes in the Genbank database. We next selected 10 cDNA clones with strong signals by differential plaque hybridization. Of these cDNA clones, five genes were induced in mast cells upon Fc epsilon RI-mediated stimulation. They are cofilin, annexinVI, interferon (IFN)-beta, serglycin, and a novel inducible mast cell (IMC) gene, IMC-415. Characterization and relevant studies of this novel gene and other inducible known genes in mast cells will provide insight into the functions of mast cells in mammalian biology.

Human mast cells produce the CD4+ T lymphocyte chemoattractant factor, IL-16.

CD4+ T cell infiltration is known to occur in tissues at sites of mast cell activation. The molecules produced and released by mast cells that account for this lymphocyte accumulation are poorly characterized. Here we report that a CD4+ T cell chemoattractant cytokine, IL-16, is stored preformed in bone marrow-cultured human mast cells and a human mast cell line, HMC-1, as demonstrated by intracytoplasmic cytokine staining and flow cytometry, and in human lung mast cells, as detected by immunohistochemistry. In response to the anaphylatoxin, C5a, or to PMA treatment, IL-16 mRNA transcripts detected by Northern blot analysis in HMC-1 cells increased 6- to 10-fold. HMC-1 cell lysates and activated supernatants contained IL-16 protein, as demonstrated by both ELISA and in vitro lymphocyte chemotaxis assays, the latter of which was blocked 59 to 88% by the addition of neutralizing Ab to recombinant human IL-16. IL-16 bioactivity was detected in the supernatants 2 to 4 h after PMA or C5a activation, and this activity remained elevated through 24 h. The capacity of human mast cells to synthesize and release biologically active IL-16 provides a possible link between mast cell activation and the accumulation of T cells in mast cell-dependent inflammation, thus amplifying the immune response and perpetuating the pathologic process.

Lymphotactin gene expression in mast cells following Fc(epsilon) receptor I aggregation: modulation by TGF-beta, IL-4, dexamethasone, and cyclosporin A.

Recruitment of lymphocytes is a prominent feature of allergic inflammation. However, the mechanisms by which lymphocytes are attracted to such sites are not understood. Recently, cDNAs encoding a lymphocyte-specific chemokine, lymphotactin (Ltn), were isolated from mouse pro-T cell and human CD8+ T cell libraries, leading us to hypothesize that mast cells might also produce Ltn. Using the reverse transcriptase-PCR and Northern blot analysis, we found that the Ltn gene is inducible in C1.MC/C57.1 and murine bone marrow-cultured mast cells (BMCMC) by Fc(epsilon)RI aggregation. Activation of a human mast cell (HMC-1) or basophil cell line (KU812) similarly led to transcription of Ltn. Fc(epsilon)RI aggregation-dependent Ltn mRNA expression was detected by 1 to 2 h, maximal at 6 h, independent of de novo protein synthesis, and was inhibited by cyclosporin A and dexamethasone. Compared with macrophage inflammatory protein alpha (MIP-1alpha), Fc(epsilon)RI-dependent Ltn and MIP-1alpha mRNA levels were up-regulated by IL-4, but not IFN-gamma, although higher levels of IL-4 (100 and 1000 U/ml) inhibited Ltn expression only; and TGF-beta preferentially enhanced Fc(epsilon)RI-dependent Ltn mRNA levels, suggesting that Ltn and MIP-1alpha have shared and unique regulatory mechanisms. A rabbit polyclonal Ab against a synthetic peptide was developed for use in immunoblot analysis and detected a 15-kDa Ltn protein within mast cell pellets and in the supernatants of mast cells following Fc(epsilon)RI aggregation. Ltn is thus expressed in mast cells and may contribute to the recruitment of lymphocytes to areas of allergic inflammation.

Food allergy.

Adverse reactions to foods are classified into immediate and delayed reactions. Immediate reactions are caused by interactions between food antigen and antigen-specific IgE that lead to a pathological process mediated by mast cells and basophils. Delayed reactions are more diverse, both in the manifestations and in the biological mechanisms involved. Because the majority of food antigens are proteins or glycoproteins, the increased diversity of food sources and the application of modern molecular biology techniques that allows changes in the protein composition of traditional foods may intensify the public interest in reactions to foods.