Immortalization of Cells from Brains Derived from a Strain (MSM/MSfB6C3F1) of Wild Mouse

Escape from cellular aging is the rate-limiting step of multistep carcinogenesis. While normal human cells invariably undergo cellular aging and almost never spontaneously immortalize, cells derived from rodents such as mice are relatively easily immortalized. In this experiment, we studied the immortalization patterns of cells obtained from brain tissues of an inbred strain (MSM/MSfB6C3F1) derived from wild mice. We established 12 cell strains derived from 12 mouse brains in order to investigate whether these cells show cellular aging in the same fashion as human cells or whether these cells are immortalized as easily as rodent cells reported previously. As a result, all cell strains were immortalized up to about 200 days in culture. One strain immortalized very early, in the first 50 days, four strains immortalized in the last 200 days, and the other seven strains became immortal between 150 and 200 days in culture. All immortalized cell strains showed varying amounts of chromosome abnormalities, numerically and structurally, but no specific changes related to immortalization were detected. Before immortalization, three types of cells, glial-like, polygonal flat-thin, and fibroblast-like cells, were observed in culture, but after immortalization most of the cultures became fibroblastic. From these results, we concluded that fibroblast-like cells derived from brains of these mice immortalized in like fashion to fibroblasts of other inbred mice.</p

Regulation of murine hypersensitive responses by Fc receptors

Humoral and cellular immune responses communicate with each other via Fc receptors (FcR) expressed on various hematopoietic cells. Recent studies on several FcR knockout mice demonstrated pivotal roles of an IgG/FcγR system in the regulation of immune responses and the onset of hypersensitivity. The γ subunit of FcR is an essential component of the complex and is required for both receptor assembly and signal transduction. FcR γ chain-deficient mice have lost the functional expression of FcεRI, FcγRI, and FcγRIII and are unable to mount several types of hypersensitive reactions, including the skin Arthus reaction. In contrast, FcγRII-deficient mice exhibit augmented humoral immune responses and IgG-mediated anaphylaxis reactions. Thus, the regulatory system of murine hypersensitive responses involves both positive and negative signaling through FcR. In B cells, FcγRIIb modulates membrane Ig-induced Ca2+ mobilization by inhibiting Ca2+ influx through phosphorylation of its immunoreceptor tyrosine-based inhibition motif and recruitment of cytoplasmic phosphatases. Elucidation of the detailed mechanisms of negative regulatory signaling in the inflammatory effector cells by FcγRIIb as well as several groups of potent inhibitory molecules expressed on such cells should be valuable in the development of novel therapeutic procedures for allergic disorders