Induction of tolerance to male bone marrow and spleen cell engraftment by HY peptide. (A) Intranasal administration of HY^AbDby peptide facilitates engraftment of syngeneic male bone marrow grafts. Appearance of B6.Thy1.1 male T cells in PBL of female B6 (Thy1.2) recipients pretreated intranasally with 3 × 100 μg HY^AbDby peptide 10 days before irradiation (200 R) and with intravenous injection of 5 × 106 B6 Thy1.1 male bone marrow cells. FACS profiles of PBLs stained for each Thy1 allele, 2 weeks after bone marrow transplantation, of single representative PBS-treated mice (i), peptide-treated mice (ii), and percentage of donor-derived Thy1.1⁺ T cells in PBLs from recipient mice, PBS-treated, n = 6 (iii), and peptide-treated, n = 6 (iv) at 2, 4, and 6 weeks after bone marrow injection. Each symbol represents data from an individual mouse. Significant differences of peptide-treated from PBS control: P = .0021 at 4 weeks, P = .0028 at 6 weeks. (B) The in vivo cytotoxicity assay: FACS analysis of CFSE-label and tetramer. A mixture of male and female spleen cells labeled with different concentrations of CFSE (male, low; female, high) were injected intravenously into recipient mice: a PBS-treated naive female (i-ii) and an HY^AbDby peptide–pretreated female (iii-iv). PBLs taken 14 days later were stained with CD8 and tetramer and examined by FACS. Panels i and iii show the remaining CFSE-labeled donor cells; panels ii and iv show tetramer-positive cells of recipient origin. (C) Intranasal HY^AbDby peptide prolongs survival of syngeneic male spleen cells. B6 females were given intranasal PBS (n = 8) or 3 × 100 μgHY^AbDby peptide (n = 8). Ten days later they received intravenously a mixture of differentially CFSE-labeled male and female splenocytes, and sequential PBL samples were analyzed as described. Panels i and ii show ratio of male to female cells, panels iii and iv show frequency of HY^DbUty tetramer-positive cells within CD8⁺ T-cell population. Each symbol represents an individual mouse.