Project description:Biological systems are noisy by nature. This aspect is reflected in our experimental measurements and should be reflected in the models we build to better understand these systems. Noise can be especially consequential when trying to interpret specific regulatory interactions, i.e. regulatory network edges. In this paper, we propose a method to explicitly encode edge-noise in Boolean dynamical systems by probabilistic edge-weight (PEW) operators. PEW operators have two important features: first, they introduce a form of edge-weight into Boolean models through the noise, second, the noise is dependent on the dynamical state of the system, which enables more biologically meaningful modeling choices. Moreover, we offer a simple-to-use implementation in the already well-established BooleanNet framework. In two application cases, we show how the introduction of just a few PEW operators in Boolean models can fine-tune the emergent dynamics and increase the accuracy of qualitative predictions. This includes fine-tuning interactions which cause non-biological behaviors when switching between asynchronous and synchronous update schemes in dynamical simulations. Moreover, PEW operators also open the way to encode more exotic cellular dynamics, such as cellular learning, and to implementing edge-weights for regulatory networks inferred from omics data.

Project description:Foxp3+ regulatory T (TR) cells are phenotypically and functionally diverse and broadly distributed in lymphoid and nonlymphoid tissues. However, the pathways guiding the differentiation of tissue-resident TR cell populations have not been well defined. By regulating E-protein function, Id3 controls the differentiation of CD8+ effector T cells and is essential for TR cell maintenance and function. We show that dynamic expression of Id3 helps define three distinct mouse TR cell populations: Id3+CD62LhiCD44lo central TR cells, Id3+CD62LloCD44hi effector TR (eTR) cells, and Id3- eTR cells. Adoptive transfer experiments and transcriptome analyses support a stepwise model of differentiation from Id3+ central TR to Id3+ eTR to Id3- eTR cells. Furthermore, Id3- eTR cells have high expression of functional inhibitory markers and a transcriptional signature of tissue-resident TR cells. Accordingly, Id3- eTR cells are highly enriched in nonlymphoid organs but virtually absent from blood and lymph. Thus, we propose that tissue-resident TR cells develop in a multistep process associated with Id3 downregulation.

Project description:Pregnancy stimulates induced Foxp3 expression among maternal CD4(+) T cells with fetal specificity. Although sustained maternal regulatory CD4(+) T cell (Treg) expansion is essential for maintaining fetal tolerance during pregnancy, the necessity for Foxp3(+) cells with fetal specificity remains undefined. In this study, we demonstrate that mitigating Treg differentiation among maternal CD4(+) T cells with a single surrogate fetal specificity elicits Ag-specific fetal loss. Using recombinant Listeria monocytogenes to prime stably differentiated Th1 CD4(+) T cells with fetal I-A(b):2W1S55-68 specificity refractory to pregnancy-induced Foxp3 expression, we show that Ag delivery by cytoplasmic L. monocytogenes causes selective loss of 2W1S(+) offspring through CD4 cell- and IFN-γ-dependent pathways. In contrast, CD4(+) T cells primed by L. monocytogenes restricted from the cell cytoplasm are markedly more plastic for induced Foxp3 expression, with normal pregnancy outcomes. Thus, committed Th1 polarization blocks pregnancy induced Treg differentiation among maternal CD4(+) T cells with fetal specificity and triggers Ag-specific fetal loss.

Project description:A precise understanding of the role of miR-223 in human hematopoiesis and in the pathogenesis of acute myeloid leukemia (AML) is still lacking. By measuring miR-223 expression in blasts from 115 AML patients, we found significantly higher miR-223 levels in patients with favorable prognosis, whereas patients with low miR-223 expression levels were associated with worse outcome. Furthermore, miR-223 was hierarchically expressed in AML subpopulations, with lower expression in leukemic stem cell-containing fractions. Genetic depletion of miR-223 decreased the leukemia initiating cell (LIC) frequency in a myelomonocytic AML mouse model, but it was not mandatory for rapid-onset AML. To relate these observations to physiologic myeloid differentiation, we knocked down or ectopically expressed miR-223 in cord-blood CD34⁺ cells using lentiviral vectors. Although miR-223 knockdown delayed myeloerythroid precursor differentiation in vitro, it increased myeloid progenitors in vivo following serial xenotransplantation. Ectopic miR-223 expression increased erythropoiesis, T lymphopoiesis, and early B lymphopoiesis in vivo. These findings broaden the role of miR-223 as a regulator of the expansion/differentiation equilibrium in hematopoietic stem and progenitor cells where its impact is dose- and differentiation-stage-dependent. This also explains the complex yet minor role of miR-223 in AML, a heterogeneous disease with variable degree of myeloid differentiation.

Project description:Th cells that produce IL-17 (Th17 cells) are a distinct subset of Th cells implicated in several autoimmune diseases. Although CD28-B7 interaction has been shown to be involved in Th17 differentiation in vitro, the role of CTLA-4 in controlling Th17 development is completely unknown. We report in this paper that blocking the CTLA-4-B7 interaction potentiates Th17 cell differentiation in vitro and in vivo. Furthermore, blocking CTLA-4-B7 interaction in vivo confers the susceptibility of experimental autoimmune myocarditis to CD28(-/-) mice or increases the severity of experimental autoimmune myocarditis in wild-type mice. The enhanced disease susceptibility is mediated by heightened Th17 responses. With these results, we are the first to demonstrate that CTLA-4-B7 interaction inhibits Th17 differentiation in vitro and in vivo and suppresses Th17-mediated autoimmunity.

Project description:Group living promotes opportunities for both cooperation and competition. Selection on the ability to cope with such opposing social opportunities has been proposed as a driving force in the evolution of large brains in primates and other social species. However, we still know little about the degree of complexity involved in such social strategies. Here, we report advanced social strategies in wild vervet monkeys. Building on recent experimental evidence that subordinate females trade grooming for tolerance from higher-ranking individuals during foraging activities, we show that the audience composition strongly affects this trade. First, tolerance was lower if the audience contained individuals that outranked the subordinate partner, independently of audience size and kinship relationships. Second, we found a significant interaction between previous grooming and relative rank of bystanders: dominant subjects valued recent grooming by subordinates while intermediate ranked subjects valued the option to aggress subordinate partners in the presence of a dominant audience. Aggressors were also more likely to emit coalition recruitment calls if the audience contained individuals that outranked the subordinate partner. In conclusion, vervet monkeys include both recent grooming and knowledge about third-party relationships to make complex decisions when trading grooming for tolerance, leading to a finely balanced trade-off between reciprocation and opportunities to reinforce rank relationships.

Project description:Naive CD4 T cells can differentiate into a number of functional subsets in response to Ag, including Foxp3(+) induced regulatory T cells (iTregs). The in vivo development and function of iTregs has been primarily demonstrated in systems involving Ag encountered systemically or delivered via the intestinal mucosa. In this study, we demonstrate that de novo Foxp3 expression in naive CD4 T cells is a critical mechanism for establishing tolerance for a tissue-restricted neo-self Ag. Naive CD4 T cells lacking a functional Foxp3 gene cannot achieve tolerance, but can be suppressed in vivo in the presence of wild type naive CD4 T cells. Exposure to nonspecific inflammation during priming undermines tolerance through impaired Foxp3 induction, suggesting that the microenvironment also has a role. These data show that de novo Foxp3 expression is an integral component of establishing and maintaining tolerance among naive peripheral CD4 T cells.

Project description:Follicular helper T (T(FH)) cells are critical for germinal center (GC) formation. The processes that drive their generation and effector potential remain unclear. In this study, we define requirements for MHC class II APCs in murine T(FH) cell formation by either transiently ablating or restricting Ag presentation to dendritic cells (DCs). We find that cognate interactions with DCs are necessary and sufficient to prime CD4(+) T cells toward a CXCR5(+)ICOS(+)Bcl6(+) T(FH) cell intermediate. However, in the absence of additional APCs, these T(FH) cells fail to produce IL-21. Furthermore, in vitro priming of naive T cells by B cells engenders optimal production of IL-21, which induces a GC B cell transcriptional profile. These results support a multistep model for effector T(FH) cell priming and GC initiation, in which DCs are necessary and sufficient to induce a T(FH) cell intermediate that requires additional interactions with distinct APCs for full effector function.

Project description:The importance of ubiquitination in MHC class I-restricted Ag processing remains unclear. To address this issue, we overexpressed wild-type and dominant-negative lysineless forms of ubiquitin (Ub) in mammalian cells using an inducible vaccinia virus system. Overexpression of the lysineless Ub nearly abrogated polyubiquitination and potently inhibited epitope presentation from a cytosolic N-end rule substrate as well as endoplasmic reticulum (ER)-targeted model Ags. In contrast, there was little impact on Ag presentation from cytosolic proteins. These trends were location dependent; redirecting cytosolic Ag to the ER rendered presentation lysineless Ub-sensitive, whereas retargeting exocytic Ag to the cytosol had the inverse effect. This dichotomy was further underscored by small interfering RNA knockdown of the ER-associated Ub ligase Hrd1. Thus, Ub-dependent degradation appears to play a major role in the MHC class I-restricted processing of ER-targeted proteins and a more restricted role in the processing of cytosolic proteins.

Project description:Phagocyte NADPH oxidase plays a key role in pathogen clearance via reactive oxygen species (ROS) production. Defects in oxidase function result in chronic granulomatous disease with hallmark recurrent microbial infections and inflammation. The oxidase's role in the adaptive immune response is not well understood. Class II presentation of cytoplasmic and exogenous Ag to CD4(+) T cells was impaired in human B cells with reduced oxidase p40(phox) subunit expression. Naturally arising mutations, which compromise p40(phox) function in a chronic granulomatous disease patient, also perturbed class II Ag presentation and intracellular ROS production. Reconstitution of patient B cells with a wild-type, but not a mutant, p40(phox) allele restored exogenous Ag presentation and intracellular ROS generation. Remarkably, class II presentation of epitopes from membrane Ag was robust in p40(phox)-deficient B cells. These studies reveal a role for NADPH oxidase and p40(phox) in skewing epitope selection and T cell recognition of self Ag.