A dendritic cell line genetically modified to express CTLA4-IG as a means to prolong islet allograft survival.

BACKGROUND: Dendritic cells are potent antigen-presenting cells that bind allogeneic T cells. They are thus candidates for targeting immunoregulatory molecules to the alloreactive T cell compartment and suppressing the alloimmune response. METHOD: A dendritic cell line derived from the BALB/c mouse (H2d) was genetically modified to express the immunoregulatory molecule CTLA4-Ig. The ability of these dendritic cell transfectants to downregulate the alloimmune response was tested in an islet transplant model. Allogeneic C57Bl/6 (H2b) mice were rendered diabetic with streptozocin, and they received BALB/c islet (H2d) transplants. Mice were administered 25 million untransfected or CTLA4-Ig-transfected D2SC/1 cells i.v. on the day of islet transplantation and 6 days later[fnc]. RESULT: Mice treated with CTLA4-Ig-transfected D2SC/1 cells demonstrated prolonged allograft survival (mean = 20 days, median = 17 days, SD = 9.39) compared with mice treated with untransfected D2SC/1 cells (mean = 12 days, median = 11 days, SD=2.74) or untreated control mice (mean = 11 days, median = 11 days SD = 1.41). Third party allograft survival was not prolonged in mice receiving similar treatment. CONCLUSIONS: These results demonstrate that a genetically modified dendritic cell line can suppress the alloimmune response and prolong islet allograft survival in an allospecific manner. The findings also suggest that genetically modified dendritic cells may be useful in targeting alloreactive T cells and prolonging allograft survival.

In vivo functions mediated by the p41 isoform of the MHC class II-associated invariant chain.

We used a "hit and run" gene targeting strategy to generate mice expressing only the p41 isoform of the conserved invariant (Ii) chain associated with MHC class II molecules. In contrast to mutants expressing only p31 Ii chain, a small proportion of A(alpha)b A(beta)b molecules produced by these animals have reduced mobilities in SDS-PAGE and appear incompletely processed. Nonetheless, class II surface expression, peptide occupancy, CD4+ T cell maturation, and proliferative responses toward intact protein Ags are efficiently reconstituted. Moreover, spleen cells exclusively expressing p41 or p31 alone display equivalent dose-response curves in Ag presentation assays. Similar conclusions were reached analyzing mutants expressing two independent MHC haplotypes. Overall, these results demonstrate that Ii chain functional activities as a class II-specific chaperone are largely shared by p31 and p41 isoforms in the intact animal. Mutant mouse strains producing only p31 or p41 under control of endogenous regulatory elements responsible for constitutive and inducible Ii chain expression should prove useful for dissecting the contributions of these isoforms to diverse CD4+ T cell responses in vivo, such as those responsible for Ab production, inflammatory responses, autoimmune diseases, and protection against infectious agents.

Major histocompatibility class II peptide occupancy, antigen presentation, and CD4+ T cell function in mice lacking the p41 isoform of invariant chain.

We used a "hit and run" gene targeting strategy to generate mice expressing only the p31 isoform of the conserved invariant (Ii) chain associated with major histocompatibility complex (MHC) class II molecules. Spleen cells from these mice appear indistinguishable from wild type with respect to class II subunit assembly, transport, peptide acquisition, surface expression, and the ability to present intact protein antigens. Moreover, these mutant mice have normal numbers of thymic and peripheral CD4+ T cells, and intact CD4+ T-dependent proliferative responses towards a soluble antigen. In short, MHC class II expression and function are surprisingly unaffected in mice lacking p41 invariant chain, implying that the p31 and p41 isoforms may be functionally redundant in the intact animal.