The autoimmune process that results in Type 1 (insulin-dependent) diabetes mellitus may be viewed as a failure to develop or maintain tolerance to self-antigens expressed in the islets of Langerhans. During T-cell development in the thymus, cells that are reactive with self antigens encountered there may undergo clonal deletion or, as more recently described, clonal anergy which effectively removes these cells from the pool of mature antigen reactive T cells. For antigens not found in the thymus, tolerance to self antigens is more complex and may depend on site of antigen expression, ambient concentrations of lymphokines, and availability of antigen-presenting cells that can deliver co-stimulatory signals. Transgenic mice in which the majority of T cells express T-cell receptors against "self" antigens or in which expression of antigens is targeted to peripheral tissues have proven useful for studies of tolerance in both T- and B-cell compartments. In general, T-cell reactivity against foreign antigen expressed on Beta cells does not occur because of the failure to activate T cells reactive with the antigen, termed clonal ignorance. This may be broken with, for example, viral infection or cytokines. In one transgenic model, dendritic cells that surround the islets of Langerhans have been shown to be responsible for presentation of islet antigens to the immune system. B-cell tolerance can also involve mechanisms of clonal deletion or clonal anergy similar to that occurring with T cells. In addition, a mechanism for changing the affinity of the B-cell antigen receptor termed "receptor editing" has been described, which may play an important role in diversifying the B-cell repertoire while removing self-reactive cells. Tolerance to antigens may also be inducible. For example, monoclonal antibodies against T-cell epitopes may induce antigen-specific tolerance that is transferable to other animals, and MHC blocking peptides which can inhibit T-cell responses that are restricted by disease associated MHC molecules. In conclusion, although several possible triggers and mechanisms of autoimmune diabetes can be envisioned, none can be excluded by existing data. However, advances in understanding mechanisms of tolerance to islet and other self antigens suggest potentially useful therapeutic approaches to arresting the autoimmune response.