Human clinical trials in type 1 diabetes (T1D) patients using mesenchymal stem cells (MSC) are presently underway without prior validation in a mouse model for the disease. In response to this void, we characterized bone marrow-derived murine MSC for their ability to modulate immune responses in the context of T1D, as represented in NOD mice. In comparison to NOD mice, BALB/c-MSC mice were found to express higher levels of the negative costimulatory molecule PD-L1 and to promote a shift toward Th2-like responses in treated NOD mice. In addition, transfer of MSC from resistant strains (i.e., nonobese resistant mice or BALB/c), but not from NOD mice, delayed the onset of diabetes when administered to prediabetic NOD mice. The number of BALB/c-MSC trafficking to the pancreatic lymph nodes of NOD mice was higher than in NOD mice provided autologous NOD-MSC. Administration of BALB/c-MSC temporarily resulted in reversal of hyperglycemia in 90% of NOD mice (p = 0.002). Transfer of autologous NOD-MSC imparted no such therapeutic benefit. We also noted soft tissue and visceral tumors in NOD-MSC-treated mice, which were uniquely observed in this setting (i.e., no tumors were present with BALB/c- or nonobese resistant mice-MSC transfer). The importance of this observation remains to be explored in humans, as inbred mice such as NOD may be more susceptible to tumor formation. These data provide important preclinical data supporting the basis for further development of allogeneic MSC-based therapies for T1D and, potentially, for other autoimmune disorders.
OBJECTIVES-To investigate a B-cell-depleting strategy to reverse diabetes in naïve NOD mice. RESEARCH DESIGN AND METHODS-We targeted the CD22 receptor on B-cells of naïve NOD mice to deplete and reprogram B-cells to effectively reverse autoimmune diabetes.RESULTS-Anti-CD22/cal monoclonal antibody (mAb) therapy resulted in early and prolonged B-cell depletion and delayed disease in pre-diabetic mice. Importantly, when new-onset hyperglycemic mice were treated with the anti-CD22/cal mAb, 100% of B-celldepleted mice became normoglycemic by 2 days, and 70% of them maintained a state of long-term normoglycemia. Early therapy after onset of hyperglycemia and complete B-cell depletion are essential for optimal efficacy. Treated mice showed an increase in percentage of regulatory T-cells in islets and pancreatic lymph nodes and a diminished immune response to islet peptides in vitro. Transcriptome analysis of reemerging B-cells showed significant changes of a set of proinflammatory genes. Functionally, reemerging B-cells failed to present autoantigen and prevented diabetes when cotransferred with autoreactive CD4 ϩ T-cells into NOD.SCID hosts. Most individuals affected by type 1 diabetes exhibit multiple features associated with impaired B-cell function, including autoantibodies against a variety of islet cell antigens (6,7). Data from different groups using NOD mice, the best animal model for the study of type 1 diabetes, have confirmed the importance of B-cells in the onset of diabetes (2-4,8,9). NOD mice that are deficient in B-cells have been shown to be protected from autoimmune diabetes (3,10,11) and are deficient in the development of a T-cell response to major autoantigens (such as 65-kDa glutamate decarboxylase) (3,10,11). In humans, the production of autoantibodies to islet antigens is well documented as an early indicator of disease onset (12). These observations render B-cell targeting a particularly attractive and novel strategy for the treatment of type 1 diabetes (13-15). Unfortunately, this strategy has not been fully described in naïve NOD mice. Only recently did a publication show the positive effects of an anti-CD20 -based B-cell-depleting strategy in transgenic NOD mice expressing the humanized CD20 receptor on B-cells (8). Interestingly, use of B-cell depletion as a therapy for human autoimmune disease (16 -20), including in patients with new-onset type 1 diabetes, is ongoing (21,22). CONCLUSIONS-TargetingWe made use of a newly developed reagent (anti-CD22 calicheamicin-conjugated monoclonal antibody [anti-CD22/cal mAb]) that efficiently depletes mature B-cells in mice (13) to establish a therapeutic approach for type 1 diabetes. Our main hypothesis was that depleting B-cells by targeting CD22 should prevent diabetes onset and restore normoglycemia in newly hyperglycemic NOD mice. Furthermore, we hypothesize that our approach will generate a pool of reemerging B-cells that may function to regulate the autoimmune response in vivo, establishing a state of long-term tolerance toward autoantigens. RESEA...
Acceptance of the fetus expressing allogeneic paternal Ags by the mother is a physiologic model of transplantation tolerance. Various mechanisms contribute to fetal evasion from immune attack by maternal leukocytes. We have recently demonstrated that the inhibitory costimulatory molecule PDL1 plays a critical role in fetomaternal tolerance in that PDL1 blockade or deficiency resulted in decreased allogeneic fetal survival rates. CD4+CD25+ T regulatory cells (Tregs) have also been demonstrated to play an important role in fetomaternal tolerance. Since PDL1 is expressed on Tregs, we explored the interactions between PDL1 and Tregs in vivo in a mouse model of fetomaternal tolerance. Depletion of CD25+ T cells abrogated the effect of anti-PDL1 Ab indicating that the effect of PDL1 is possibly mediated by CD25+ Tregs. Adoptive transfer of Tregs from wild-type but not PDL1-deficient mice into PDL1-deficient recipients significantly improved fetal survival. The frequency, phenotype and placental trafficking of Tregs from PDL1-deficient mice were similar to those of wild-type controls, but were defective in inhibiting alloreactive Th1 cells in vitro. This is the first report providing evidence for a link between PDL1 and T regulatory cells in mediating fetomaternal tolerance.
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