Proteomic analysis of human eosinophil activation mediated by mast cells, granulocyte macrophage colony stimulating factor and tumor necrosis factor alpha.

We assessed mast cell influence on eosinophils, the prominent cells in late and chronic allergic reactions, by comparing the proteomic pattern of eosinophils incubated with mast cells, tumor necrosis factor alpha (TNF-alpha) or granulocyte macrophage colony stimulating factor (GM-CSF). Eosinophils were incubated with the human mast cell line HMC-1 cellular sonicate and their survival and GM-CSF production were evaluated. For proteomic studies, eosinophils were cultured with HMC-1 sonicate, TNF-alpha or GM-CSF in the presence of [(35)S]methionine, solubilized and submitted to isolelectric focusing separation and sodium dodecyl sulfate polyacrylamide gel electrophoresis in the ISODALT system, followed by radiofluorography and computer image analysis. HMC-1-incubated eosinophils displayed increased survival partly mediated by mast cell-associated TNF-alpha, and produced GM-CSF. Metabolically labeled eosinophils incubated with either HMC-1, TNF-alpha or GM-CSF released eosinophil peroxidase. Comparison of two-dimensional gel spots from the eosinophils revealed that each of the three activating signals yielded a distinctly different proteomic pattern of labeled polypeptides. GM-CSF provided the strongest signal and the highest rate of protein synthesis (1,018 spots) followed by TNF-alpha (747 spots) and HMC-1 sonicate (611 spots). A portion of spots differed both in terms of quality and quantity. Although each stimulus induced similar functional effects, the resulting biosynthetic programs of the eosinophils greatly differed. The presented proteomic analysis is the first step in the exploration of molecular mechanisms involved in eosinophil activation.

Clonal proteomics: one gene - family of proteins.

The work presented here attempts to consolidate our knowledge on cellular transcriptome and proteome. It takes into account that a typical activated cell (lymphocyte) contains 40 000 mRNA molecules at any time, and it represents about 5000 different molecular species of transcripts. Such a cell has about 1 000 000 000 protein molecules, some of them being present at 10 000 000 copies while others at a very low copy number (say 1 to 10 copies per cell). By studying cell free expression of individual cDNA clones (or pools of known complexity) we address to those rare molecular components that will remain undetected by the current analytical means. For our analysis we use cell free translation systems (wheat germ or rabbit reticulocyte origin) and we study polypeptide products originating from intact, or restriction endonuclease-treated cDNA clones. We conclude that in most instances expressed genes yield transcript(s) that translate into several, and often very numerous families of polypeptide species. In our ISODALT two-dimensional gel system we characterize the proteomic profile of the clonal polypeptide families in terms of their molecular mass, charge, multiple products, and appearance.