Infectious, inflammatory and ‘autoimmune’ male factor infertility: how do rodent models inform clinical practice?

Humans expressing a defective form of the transcription factor AIRE (autoimmune regulator) develop multiorgan autoimmune disease. We used aire- deficient mice to test the hypothesis that this transcription factor regulates autoimmunity by promoting the ectopic expression of peripheral tissue- restricted antigens in medullary epithelial cells of the thymus. This hypothesis proved correct. The mutant animals exhibited a defined profile of autoimmune diseases that depended on the absence of aire in stromal cells of the thymus. Aire-deficient thymic medullary epithelial cells showed a specific reduction in ectopic transcription of genes encoding peripheral antigens. These findings highlight the importance of thymically imposed "central" tolerance in controlling autoimmunity.

Mice are the experimental tool of choice for the majority of immunologists and the study of their immune responses has yielded tremendous insight into the workings of the human immune system. However, as 65 million years of evolution might suggest, there are significant differences. Here we outline known discrepancies in both innate and adaptive immunity, including: balance of leukocyte subsets, defensins, Toll receptors, inducible NO synthase, the NK inhibitory receptor families Ly49 and KIR, FcR, Ig subsets, the B cell (BLNK, Btk, and lambda5) and T cell (ZAP70 and common gamma-chain) signaling pathway components, Thy-1, gammadelta T cells, cytokines and cytokine receptors, Th1/Th2 differentiation, costimulatory molecule expression and function, Ag-presenting function of endothelial cells, and chemokine and chemokine receptor expression. We also provide examples, such as multiple sclerosis and delayed-type hypersensitivity, where complex multicomponent processes differ. Such differences should be taken into account when using mice as preclinical models of human disease.

Freund's adjuvants are irreplaceable components of induction protocols of many experimental animal models of autoimmune disease. Apart from the early studies done in the 1950s and 1960s, no further direct investigation on the mode of action of these adjuvants has been undertaken. It is generally assumed that incomplete (IFA) and complete Freund's adjuvant (CFA) act by prolonging the lifetime of injected autoantigen, by stimulating its effective delivery to the immune system and by providing a complex set of signals to the innate compartment of the immune system, resulting in altered leukocyte proliferation and differentiation. Here, we review evidence collected from various types of studies that provide more insight in the specific alterations of the immune response caused by IFA and CFA. Early events include rapid uptake of adjuvant components by dendritic cells, enhanced phagocytosis, secretion of cytokines by mononuclear phagocytes, and transient activation and proliferation of CD4+ lymphocytes. The mycobacterial components within CFA signal T lymphocytes to assume a Th1 profile so that strong delayed-type hypersensitivity against autoantigens develops. In the absence of mycobacteria, T-lymphocyte differentiation tends to assume a Th2 profile with strong antibody production only. The mycobacterial component also accounts for a morphologic and functional remodeling of the haemopoietic system that develops over a period of several weeks and that is characterized by a drastic expansion of Mac-1+ immature myeloid cells. These cells have been found to be associated with enhanced disease in some models but with reduced disease in others. Thus, in experimental autoimmune diseases, CFA-mediated activation of the innate immune compartment is important not only by regulating the early induction phase but also by providing a surplus of effector and regulator cells in the late phase.