Antigen-specific Treg impair CD8(+) T-cell priming by blocking early T-cell expansion.

Foxp3(+) Treg are crucial for the maintenance of self-tolerance and have been shown to control CD8(+) T-cell effector functions. In addition, Treg are thought to control the priming of CD8(+) T cells, which recognize the same antigens as Treg. Taking advantage of our model of peripheral tolerance induction to influenza hemagglutinin (HA) after HA gene transfer, we found that HA-specific Treg suppress antigen-linked CTL responses through early blockade of CD8(+) T-cell expansion. Confronted with their cognate antigen, Treg expand more rapidly than CD8(+) T cells and are highly suppressive only during the initial stages of immune priming. They nullify HA-specific CD8(+) T-cell responses, local inflammatory responses and rejection of HA transduced cells. When HA gene transfer is performed with extensive tissue inflammation, HA-specific Treg are less effective but still reduce the frequency of newly primed HA-specific CD8(+) T cells and the ensuing frequency of memory CD8(+) T cells. Our results demonstrate that Treg control CTL priming in an antigen-specific manner at the level of T-cell expansion, highlighting how self-reactive Treg could prevent the induction of autoimmune responses through selective blockade of autoreactive T-cell proliferation.

Foxp3+ Regulatory and Conventional CD4+ T Cells Display Similarly High Frequencies of Alloantigen-Reactive Cells.

Foxp3+ regulatory T cells (Tregs) play a major role in acquired immune tolerance to allogenic transplants. Their suppressive activity is thought to require T cell receptor (TCR)-driven antigen recognition; little, however, is known about the fraction of Tregs able to recognize alloantigens within this T cell subset primarily educated against self-antigens. Performing transfer experiments of Tregs or conventional T cells (Tconv) into both lymphoreplete and lymphopenic mice, we observed a similarly high proportion of cells signaling through their TCR and proliferating in allogenic hosts. Furthermore, using an in vivo proliferation assay with limited T cell numbers infused into lymphopenic mice, we found that the overall frequency of alloreactive Tregs was similar if not higher to that of alloreactive Tconv. Overall our study highlights a noticeably high level of alloreactive Foxp3+ regulatory T cells accounting for their predominant role in transplantation tolerance.

Antigen-driven interactions with dendritic cells and expansion of Foxp3+ regulatory T cells occur in the absence of inflammatory signals.

Foxp3+ regulatory T cells (Tregs) play a pivotal role in the maintenance of peripheral T cell tolerance and are thought to interact with dendritic cells (DC) in secondary lymphoid organs. We analyzed here the in vivo requirements for selective expansion of Ag-specific Treg vs CD4+CD25- effector T cells and engagement of Ag-specific Treg-DC interactions in secondary lymphoid organs. Using i.v. Ag delivery in the absence of inflammation, we found that CD4+CD25+Foxp3+ Tregs undergo vigorous expansion and accumulate whereas naive CD4+CD25-Foxp3- T cells undergo abortive activation. Quantifying directly the interactions between Tregs and CD11c+ DC, we found that Tregs establish cognate contacts with endogenous CD11c+ DC in spleen and lymph nodes at an early time point preceding their expansion. Importantly, we observed that as few as 10(3) Tregs selectively expanded by i.v. Ag injection are able to suppress B and T cell immune responses in mouse recipients challenged with the Ag. Our results demonstrate that Tregs are selectively mobilized by Ag recognition in the absence of inflammatory signals, and can induce thereafter potent tolerance to defined Ag targets.