Paul deRoos

Metabolites produced by commensal bacteria promote peripheral regulatory T-cell generation

Intestinal microbes provide multicellular hosts with nutrients and confer resistance to infection. The delicate balance between pro- and anti-inflammatory mechanisms, essential for gut immune homeostasis, is affected by the composition of the commensal microbial community. Regulatory T cells (Treg cells) expressing transcription factor Foxp3 have a key role in limiting inflammatory responses in the intestine. Although specific members of the commensal microbial community have been found to potentiate the generation of anti-inflammatory Treg or pro-inflammatory T helper 17 (TH17) cells, the molecular cues driving this process remain elusive. Considering the vital metabolic function afforded by commensal microorganisms, we reasoned that their metabolic by-products are sensed by cells of the immune system and affect the balance between pro- and anti-inflammatory cells. We tested this hypothesis by exploring the effect of microbial metabolites on the generation of anti-inflammatory Treg cells. We found that in mice a short-chain fatty acid (SCFA), butyrate, produced by commensal microorganisms during starch fermentation, facilitated extrathymic generation of Treg cells. A boost in Treg-cell numbers after provision of butyrate was due to potentiation of extrathymic differentiation of Treg cells, as the observed phenomenon was dependent on intronic enhancer CNS1 (conserved non-coding sequence 1), essential for extrathymic but dispensable for thymic Treg-cell differentiation. In addition to butyrate, de novo Treg-cell generation in the periphery was potentiated by propionate, another SCFA of microbial origin capable of histone deacetylase (HDAC) inhibition, but not acetate, which lacks this HDAC-inhibitory activity. Our results suggest that bacterial metabolites mediate communication between the commensal microbiota and the immune system, affecting the balance between pro- and anti-inflammatory mechanisms.

Regulatory T-cell suppressor program co-opts transcription factor IRF4 to control TH2 responses

In the course of infection or autoimmunity, particular transcription factors orchestrate the differentiation of TH1, TH2 or TH17 effector cells, the responses of which are limited by a distinct lineage of suppressive regulatory T cells (Treg). Treg cell differentiation and function are guided by the transcription factor Foxp3, and their deficiency due to mutations in Foxp3 results in aggressive fatal autoimmune disease associated with sharply augmented TH1 and TH2 cytokine production. Recent studies suggested that Foxp3 regulates the bulk of the Foxp3-dependent transcriptional program indirectly through a set of transcriptional regulators serving as direct Foxp3 targets. Here we show that in mouse Treg cells, high amounts of interferon regulatory factor-4 (IRF4), a transcription factor essential for TH2 effector cell differentiation, is dependent on Foxp3 expression. We proposed that IRF4 expression endows Treg cells with the ability to suppress TH2 responses. Indeed, ablation of a conditional Irf4 allele in Treg cells resulted in selective dysregulation of TH2 responses, IL4-dependent immunoglobulin isotype production, and tissue lesions with pronounced plasma cell infiltration, in contrast to the mononuclear-cell-dominated pathology typical of mice lacking Treg cells. Our results indicate that Treg cells use components of the transcriptional machinery, promoting a particular type of effector CD4+ T cell differentiation, to efficiently restrain the corresponding type of the immune response.

Deficient Positive Selection of CD4 T Cells in Mice Displaying Altered Repertoires of MHC Class II–Bound Self-Peptides

The role of self-peptides in positive selection of CD4+ T cells has been controversial. We show that some self-peptides are presented by the MHC class II molecule I-A(b) in mice lacking Ii or H-2M but not in mice expressing a transgene-encoded peptide fused to I-A(b). In experiments using specific antibodies to block selection, these low-abundance self-peptides were implicated in the positive selection of some CD4+ T cells in H-2M-/- mice. However, all three mutant backgrounds failed to positively select two class II-restricted transgenic T cell receptors. Our findings suggest that minor components of the self-peptide repertoire can contribute to positive selection of a significant number of CD4+ T cells. In addition, the data suggest that T cell receptor repertoires selected in wild-type mice and in mice displaying limited spectra of self-peptides are distinct.

A Role for Cathepsin L and Cathepsin S in Peptide Generation for MHC Class II Presentation

The enzymes that degrade proteins to peptides for presentation on MHC class II molecules are poorly understood. The cysteinal lysosomal proteases, cathepsin L (CL) and cathepsin S (CS), have been shown to process invariant chain, thereby facilitating MHC class II maturation. However, their role in Ag processing is not established. To examine this issue, we generated embryonic fibroblast lines that express CL, CS, or neither. Expression of CL or CS mediates efficient degradation of invariant chain as expected. Ag presentation was evaluated using T cell hybridoma assays as well as mass spectroscopic analysis of peptides eluted from MHC class II molecules. Interestingly, we found that the majority of peptides are presented regardless of CL or CS expression, although these proteases often alter the relative levels of the peptides. However, for a subset of Ags, epitope generation is critically regulated by CL or CS. This result suggests that these cysteinal proteases participate in Ag processing and generate qualitative and quantitative differences in the peptide repertoires displayed by MHC class II molecules.

In vivo MHC class II presentation of cytosolic proteins revealed by rapid automated tandem mass spectrometry and functional analyses.

We report a strategy for high through‐put sequence analyses of large MHC class II‐bound peptide repertoires which combines automated electrospray ionization tandem mass‐spectrometry with computer‐assisted interpretation of the tandem mass spectra using the algorithm SEQUEST. This powerful approach discerned 128 peptide sequences displayed by the murine MHC class II molecule I‐Abin activated B cells and macrophages, including a surprisingly large number of peptides derived from self cytosolic proteins. Mice lacking the chaperone molecule H‐2M were used to generate T cells specific for selected self peptides. Functional T cell analyses of ex vivo antigen‐presenting cells indicated that peptides originating from cytosolic proteins are efficiently presented by splenic and thymic dendritic cells, but less so by resting B cells or thymic cortical epithelial cells. These results suggest that central tolerance to at least some MHC class II‐bound self peptidesderived from cytosolic proteins exists in vivo.

Cutting Edge: Depletion of Foxp3+ Cells Leads to Induction of Autoimmunity by Specific Ablation of Regulatory T Cells in Genetically Targeted Mice

We have recently described two independent mouse models in which the administration of diphtheria toxin (DT) leads to specific depletion of regulatory T cells (Tregs) due to expression of DT receptor-enhanced GFP under the control of the Foxp3 promoter. Both mouse models develop severe autoimmune disorders when Foxp3+ Tregs are depleted. Those findings were challenged in a recent study published in this journal suggesting the expression of Foxp3 in epithelial cells as the cause for disease development. By using genetic, cellular, and immunohistochemical approaches, we do not find evidence for Foxp3-expression in nonhematopoietic cells. DT injection does not lead to a loss of epithelial integrity in our Foxp3-DTR models. Instead, Foxp3 expression is Treg-specific and ablation of Foxp3+ Tregs leads to the induction of fatal autoimmune disorders. Autoimmunity can be reversed by the adoptive transfer of Tregs into depleted hosts, and the transfer of Foxp3-deficient bone marrow into T cell-deficient irradiated recipients leads to full-blown disease development.

Intracellular assembly and transport of endogenous peptide-MHC class II complexes

To define the intracellular site of assembly of endogenous peptide-MHC class II complexes, an immunochemical approach was undertaken employing a monoclonal antibody specific for an endogenous peptide-class II complex in combination with subcellular fractionation. Here, we show that newly synthesized MHC class II molecules, upon exit from the Golgi, are delivered into a dense endocytic compartment (MIIC) distinct from late endosomes and lysosomes. Endogenous peptide-class II complexes are initially formed in this compartment and subsequently traffic through late endosomal vesicles prior to cell surface expression. Exogenous antigen delivered via immunoglobulin receptors is targeted to MIIC en route to lysosomes after passing through early and late endosomes. Processing of an endocytosed antigen was observed in this compartment. Our results suggest a specific role for MIIC in the processing of endogenous and exogenous proteins as well as the assembly of peptide-MHC class II complexes.

Positive selection of self-MHC-reactive T cells by individual peptide–MHC class II complexes

If T cells require specific interactions with MHC-bound peptides during positive selection, then the specificities of T cells selected by one peptide should be distinct from those selected by another. We have examined positive selection of CD4 T cells in four strains of mice, each overexpressing a different peptide–1-Ab(Ab) complex. We show that a subset of CD4 T cells is selected by the overexpressed peptide and that the specificities of the CD4 T cells, as measured by reactivity to wild-type antigen-presenting cells, vary greatly depending on which peptide is overexpressed. These differences in specificity are mediated through positive selection not negative selection. Each of the four peptide–Ab complexes appears to adopt a different conformation, and these differences correlate with the differences in reactivity. Our results suggest that individual peptide–MHC complexes positively select different subsets of self-MHC-reactive T cells and that the conformation of the peptide–MHC complex may contribute to this process.