Resistance to tolerance induction in B cells of autoimmune mice—Abnormal expansion of low affinity IgG-producing B-cell population

Abstract

Several strains of mice are known to develop spontaneous autoimmune diseases like lupus erythematosus and they show various immunological abnormalities as well. Despite different genetic backgrounds, they manifest various immunological abnormalities in common, e.g., polyclonal B-cell activation (PBA) and resistance to tolerance induction. To elucidate mechanisms of the development of autoimmunity, tolerance inducibility was examined in autoimmune and normal mice using trinitrophenylated carboxymethyl cellulose (TNP-CMC) as tolerogen which is known to induce TNP-specific B-cell tolerance without the participation of T cells. NZB and MRL/Mp- lpr/lpr mice were used as autoimmune mice and C57BL/6, BALB/c, and MRL/Mp-+/+ mice as nonautoimmune mice. When TNP-CMC-injected mice were challenged with T-independent antigens, all of the mice tested were shown to be tolerant. In contrast, when TNP-CMC-injected mice were challenged with T-dependent antigen and secondary IgG responses were assessed, autoimmune mice showed rather hyperreactivity, while nonautoimmune mice showed hyporesponsiveness. Cyclophosphamide improved this defective tolerance inducibility. By the solid-phase radioimmunoassay it was revealed that average affinity of serum anti-TNP antibodies produced in TNP-CMC-injected mice was low. Such low affinity antibodies were produced in large amount in autoimmune mice. Hence, it was suggested that B-cell clones destined to produce low affinity IgG antibodies were responsible for the resistance to tolerance induction and such clones were expanding in autoimmune mice.