Skin graft rejection and delayed-type hypersensitivity responses to H-Y in an I-Ab mutant

Peripheral expression of self-MHC-II influences the reactivity and self-tolerance of mature CD4(+) T cells: evidence from a lymphopenic T cell model

While intrathymic MHC expression influences the specificity of developing thymocytes, we considered that peripheral MHC expression might influence the reactivity of postthymic T cells. We now report for CD4(+) T cells that peripheral MHC-II expression does influence their reactivity and self-tolerance. Upon transfer into MHC-II-deficient lymphopenic hosts, mature CD4(+) T cells were found to acquire an activated memory phenotype and to become: (1) autoreactive against syngeneic MHC-II(+) skin grafts, (2) hyperreactive against third-party MHC-II(+) skin grafts, and (3) functionally dysregulated, resulting in a lymphoproliferative disorder characterized by intraepithelial infiltrations. Peripheral MHC-II expression appeared to influence CD4(+) T cell reactivity by two complementary mechanisms: maintenance of CD4(+)CD25(+) regulatory T cells ("suppression") and direct dampening of CD4(+) T cell reactivity ("tuning").

Active cell migration in retransplanted rat cardiac allografts during the course of chronic rejection

BACKGROUND

Chronic allograft vasculopathy (CAV) is caused by the infiltration of host immune cells to a graft, but it has been technically difficult to monitor the movements of the cells in graft rejection.

METHODS

We used a male-specific gene, SRY, as a marker to investigate the dynamics of host cells in a model of CAV in which immunosuppression was unnecessary and anti-male responses were practically negligible. Fluorescent-based real-time quantitative polymerase chain reaction (PCR) was adapted to estimate the fraction of host cells in a graft by the ratio of SRY to IL-2 gene. Using this technique, we studied the turnover and migration of host cells during the course of CAV progression by retransplanting female allografts from male to female or from female to male rats.

RESULTS

We detected histologic CAV 60 days after retransplantation in allografts retransplanted to the F(1) progeny of donor x recipient on the 5th day, but not in those retransplanted on the 3rd day, regardless of the mismatches in the genders. Most of the initial infiltrating cells disappeared rapidly in both cases. The fraction of migrating cells from the second recipient, however, continuously increased in allografts developing CAV, and 60 days after retransplantation exceeded 50%, whereas it stayed at 5% to 15% in those not developing CAV. ED-1-positive macrophages/monocytes were likely candidates for the migrated cells.

CONCLUSION

We have developed a simple method to measure the migration of host cells into a graft. This technique was useful, at least in certain rat strains, to investigate the cellular mechanisms of chronic cardiac allograft rejection.

The role of interleukin-4 in the induction phase of allogeneic neonatal tolerance

We previously reported that prolonged graft survival in neonatally tolerant mice was associated with enhanced Th2/Th1 cytokines. To determine whether Th2 CD4 cells function in tolerance, we examined whether we could prevent tolerance by blocking Th2 CD4 maturation, using anti-interleukin (IL)-4 monoclonal antibody treatment during neonatal antigen exposure. Anti-IL-4 treatment restored the ability BALB/c of mice to reject A/J skin grafts and blocked the induction of tolerance through multiple mechanisms. Anti-IL-4 treatment blocked the development of donor microchimerism and recovered the ability of mice to proliferate and to generate appropriate delayed-type hypersensitivity (DTH) and cytotoxic T lymphocyte (CTL) responses against A/J in a dose-dependent manner. Low-dose anti-IL-4 recovered DTH responses and interferon (IFN)-gamma production, but failed to completely prevent IL-4 production or to recover the CTL activity. No A/J-reactive IFN-gamma-producing CD8 cells were detected in these mice. In contrast, mice treated with higher doses of anti-IL-4 generated normal CTL responses against A/J, and contained A/J-reactive IFN-gamma-producing CD8 cells. The recovery of CTL responses and IFN-gamma-producing CD8 cells was associated with a more complete blocking of Th2 cytokine production. Therefore, the presence of IL-4 may play an important role in the induction of neonatal tolerance by shifting maturation of CD4 cells toward Th2 cells and away from Th1 cells, and also by preventing maturation of alloreactive CD8 CTL cells.

Presentation of the H-Y antigen on Langerhans' cell-negative corneal grafts downregulates the cytotoxic T cell response and converts responder strain mice into phenotypic nonresponders

We have used the murine cornea is an allograft model to investigate the relative roles of graft-derived IA+ APC (Langerhans' cells) and host-derived APC during the induction of CTL responses to H-Y. The natural exclusion of LC from the immunizing corneal graft led to a specific state of unresponsiveness to H-Y in responder strain mice, while inclusion of LC resulted in responsiveness. Failure to respond to H-Y could not be attributed to the absence of H-Y or IA antigen expression on the surface of LC-deficient grafts but instead, appeared to be due to active suppression of the T helper cell response during in vivo priming. Reprocessing of the H-Y antigen by host APC did not occur after immunization with H-Y presented on H-2-incompatible grafts unless presented initially by graft-derived LC. H-2 as well as some non-H-2 alloantigens were presented to the host without a requirement for donor-derived LC. Thus there appear to be differential requirements for the processing and presentation of alloantigens.

Ir gene-controlled response to haptenated hen ovomucoid: isotypic specificity and dominant nonresponsiveness

We have examined the isotypic pattern of the response of mice to the Ir gene-controlled antigen, dinitrophenyl-ovomucoid (DNP-OM). H-2 kappa mice are high responders (HR); (H-2b,d mice are low responders (LR). The isotype patterns of HR and LR strains differ both quantitatively and qualitatively. In the primary response to doses of 20-100 micrograms DNP-OM, HR strains produce IgM and IgG antibodies, whereas LR strains produce only IgM. Background genes modify the kinetics of the IgGl primary response in HR strains, but no background was found which allowed an IgG response in a LR strain. In secondary responses, priming with 0.2 microgram DNP-OM increases secondary responses in HR strains, and decreases them in LR strains. Control of this response maps to I-A, and is not altered by the bm 12 I-Ab mutation. The LR phenotype is dominant in (HR X LR)F1 mice.

Abolition of specific immune response defect by immunization with dendritic cells

Murine cytotoxic T (Tc)-cell responses to various antigens are controlled by immune response (Ir) genes mapping in the major histocompatibility complex (H-2). The genes responsible are those encoding the class I and class II H-2 antigens. The H-2 I-Ab mutant mouse strain bm12 differs from its strain of origin, C57BL/6 (H-2b), only in three amino acids in the I-A beta bm12 class II H-2 molecule. As a consequence, female bm12 mice are Tc-cell nonresponders to the male antigen H-Y and do not reject H-Y disparate skin grafts. We now report that bm12 mice generate strong H-Y-specific Tc cells following priming in vivo and restimulation in vitro with male bm12 dendritic cells (DC). Female bm12 mice primed with male DC also reject male skin grafts. Furthermore, we demonstrate that only responder cell populations containing a mixture of L3T4+ (T-helper (Th) phenotype) and Lyt 2+ (Tc phenotype) T lymphocytes generate H-Y-specific Tc cells. These data imply an essential role for Th cells, activated by DC as antigen-presenting cells (APC), in changing H-Y-nonresponder bm12 mice into H-Y responders. Priming and restimulation with DC allows the triggering of a T-cell repertoire not demonstrable by the usual modes of immunization. This principle might be used to overcome other specific immune response defects.

Female popliteal lymph node responses to H-Y antigen on male thymocytes in mice. I. Regulation of primary and secondary responses by H-2-associated Ir genes

H-2-linked genes which control popliteal lymph node (PLN) immune responses to the H-Y antigen were analysed. It was found that at least two genes or two groups of genes are involved in the genetic control and are responsible for the four variants of relations observed between the primary and the secondary response: +/-, +/+, -/+ and -/- ('+' and '-' stand for a high and a low response, respectively). The results obtained with H-2 recombinant haplotypes indicated that the genes controlling the primary and secondary responses map to the left and to the right of the E alpha locus, respectively. A high primary response was observed in the presence of b alleles at K, A beta, A alpha, and E beta loci, whereas a high secondary response occurred only in the presence of d alleles in the chromosomal segment between E alpha and D loci. From the experiments with F1 hybrids it is clear that low secondary responses are, for the most part, dominant and that the two seemingly separate control mechanisms for the primary and secondary responses may interact.