Transgenic B lymphocytes expressing a human cold agglutinin escape tolerance following experimental infection of mice by Mycoplasma pulmonis.

Several microbial infections, including Mycoplasma pneumoniae respiratory infection, are capable, in man, of transiently inducing the expression of anti-red blood cell autoantibody called cold agglutinins (CA). To analyze the mechanisms by which immune tolerance is broken following a mycoplasma infection, we used transgenic mice expressing a pathogenic human CA, designated CA-GAS, specific for sialylated carbohydrates. In these mice peripheral deletion of autoreactive B lymphocytes and receptor editing, prevent the development of autoimmune hemolytic anemia. Experimental infections of transgenic mice with Mycoplasma pulmonis resulted in a high anti-mycoplasma antibody response (despite a severe B cell depletion at the onset of infection), and an important induction of serum CA concentrations, reaching in some mice pathological titers. Whereas in naïve mice, only a small percentage of CA-expressing cells could be detected, in infected mice, a majority of circulating B lymphocytes were large B220(-) cells, which expressed the transgenic immunoglobulin. Immunization of the transgenic mice with keyhole limpet hemocyanin and Freund's adjuvant, to nonspecifically stimulate the expression of the passenger transgenes, only moderately increased the CA titers. These results indicate that M. pulmonis infection is capable of breaking immune tolerance in the CA-transgenic mice, in part through specific activation of CA-expressing B lymphocytes. This experimental infection mimics the induction of CA in humans and provide an animal model for studying the genesis of the autoimmune hemolytic anemia.

Diversity of regulatory CD4+T cells controlling distinct organ-specific autoimmune diseases.

Depletion of selected regulatory CD4+ T cell subsets induces the spontaneous onset of various immune or autoimmune disorders. It is not clear, however, whether a given subset, notably CD4+CD25+ regulatory T cells, protects from a wide spectrum of immune disorders, or whether specialized subsets of regulatory T cells control each given disease or group of diseases. We report here, using diabetes prone nonobese diabetic (NOD) mice, that depending on the regulatory T cells that are depleted, i.e., CD25+, CD62L+, or CD45RB(low), distinct immune diseases appear after transfer into NOD severe combined immunodeficiency (SCID) recipients. Thus, reconstitution of NOD SCID mice with CD25- T cells induces major gastritis and late-onset diabetes, but no or mild colitis. Reconstitution with CD62L- T cells induces fulminant diabetes with no colitis or gastritis. Reconstitution with CD45RB(high) T cells induces major colitis with wasting disease and no or very moderate gastritis and diabetes. Major differences among the three regulatory T cell subsets are also seen in vitro. The bulk of suppressor cells inhibiting the proliferation of CD4+CD25- T cells in coculture is concentrated within the CD25+ but not the CD62L+ or CD45RB(low) T cell subsets. Similarly, cytokine production patterns are significantly different for each regulatory T cell subset. Collectively, these data point to the diversity and organ selectivity of regulatory T cells controlling distinct autoimmune diseases whatever the underlying mechanisms.