The Syrian hamster is unique among laboratory animals because products of class I MHC genes are monomorphic. Thus, this species may be a model in which to test the relationship between MHC polymorphism and the T cell antigen receptor repertoire. Recently, cytotoxic and helper T cell subpopulations have been distinguished on the basis of cell surface phenotype detected with monoclonal antibodies (mAb). We used these reagents (mAb 110 detects all peripheral T cells and mAb 38 detects cytotoxic T cells) to dissect and categorize thymic populations according to relative maturational status. The two mAb divide thymocytes into four subpopulations in the young adult. Two (110+ 38+, 110+ 38-) were peripheral-like and were housed in the medulla, exclusively; another subset (110- 38+) consisted almost entirely of TdT+ cortical thymocytes. The fourth subset (110- 38-), bearing neither marker, was heterogeneous and consisted mostly of medium-large-size thymocytes, including cells with an early phenotype (nuclear TdT+). Cells with the cortical phenotype proved to be the most sensitive to cortisone treatment, whereas those which expressed the medullary marker, 110, were most resistant. To ascertain the relationship between 110- and 110+ T lineage cells, we followed the appearance of the four thymic subpopulations during ontogeny of the hamster thymus. Adult-like thymic architecture (delineation of cortex and medulla) as well as the two 110- subsets were established before expression of 110 antigen was apparent in the thymus. However, lymphocytes bearing the 110 antigen were found in lymph nodes prior to thymus during ontogeny, concomitant with developing T cell function in peripheral tissue. This finding implies that cells lacking 110 antigen were exported from the thymus and subsequently acquired expression of the molecule in the periphery, and we suggest that acquisition of 110 antigen may be a stage of postthymic maturation. Although 110+ cells appeared to be the most mature subset by several criteria, all functional thymocytes of adults or neonates were not 110+. Thus, we conclude that the 110 marker is acquired after T cells reach functional maturity. Moreover, the response profile of isolated 38+ thymocytes was analogous to peripheral 38+ T cells, suggesting that the dichotomy of function detected with our mAb also occurs before acquisition of 110 antigen. We have modeled what is known about hamster T cell development into a hypothetical scheme.