Project description:Acetylcholine (ACh) and its receptors (AChRs) are widely produced by various kinds of immune cells and fine-tune both innate and adaptive immune responses. However, whether cholinergic signaling regulates immune cell development is unclear. Here, we show that mouse CD4+CD8+ double-positive (DP) thymocytes express high levels of a9 nicotinic (n) AChR, and that this receptor controls the negative selection of thymocytes. Knock-out mice lacking a9 nAChR show an altered TCR repertoire and reduced CD4+ and CD8+ T cells in a mixed bone marrow chimera setting. Although thymic tuft cells, B cells, and a portion of T cells were all found to express choline acetyltransferase (ChAT) and so are sources of ACh in mouse thymus, T cell-derived ACh plays a more important regulatory role. Our results thus reveal a new mechanism of immune cell development control that involves lymphocyte-mediated cholinergic signaling.

Project description:Group 2 innate lymphoid cells (ILC2s) reside in multiple tissues including lymphoid organs and barrier surfaces, and secrete type 2 cytokines including interleukin (IL)-5, IL-9 and IL-13. These cells participate in multiple physiological processes including allergic inflammation, tissue repair, metabolic homeostasis and host defense against helminth infections. Recent studies indicate that neuropeptides can play an important role in regulating ILC2 responses, however, the mechanisms that underlie these processes in vivo remain incompletely defined. Here, we identify that activated ILC2s upregulate choline acetyltransferase (ChAT)—the enzyme responsible for the biosynthesis of acetylcholine (ACh)—following infection with the helminth parasite Nippostrongylus brasiliensis or treatment with alarmins or cytokines including IL-25, IL-33 and thymic stromal lymphopoietin (TSLP). ILC2s also express acetylcholine receptors (AChRs), and ACh administration promotes ILC2 cytokine production and elicits expulsion of helminth infection. In accordance with this, ChAT deficiency in ILC2s leads to defective ILC2 responses and impaired immunity against helminth infection. Together, these results reveal a previously unrecognized role of the ChAT-ACh pathway in promoting type 2 innate immunity to helminth infection.

Project description:ACh was originally isolated from spleen back in 1929, however, its contribution to immune regulation has only recently been appreciated. Subsets of both T and B lymphocytes have been found to express choline acetyltransferase (Chat) and produce ACh. To date, Chat-expressing T cells have been described as relaying neural signals in the spleen to modulate immune responses; regulating blood pressure; and promoting anti-viral immune responses. In a murine multi-hit model of hepatocellular carcinoma, we observed activation of the adaptive immune response and induction of Chat-expressing CD4+ T cells. These cholinergic T cells curtail the development of liver cancer by supporting anti-tumor immune responses. We used single-cell RNA sequencing to investigate the transcriptome and TCR repertoire of the Chat-expressing CD4+ T cells in healthy and HCC-bearing livers.

Project description:Germinal centers (GCs) are sites of B cell clonal expansion, diversification, and antibody affinity selection. This process is limited and directed by T follicular helper cells that provide helper signals to B cells that endocytose, process, and present cognate antigens in proportion to their B cell receptor (BCR) affinity. Under this model, the BCR functions as an endocytic receptor for antigen capture. How signaling through the BCR contributes to selection is not well understood. To investigate the role of BCR signaling in GC selection, we developed a tracker for antigen binding and presentation and a Bruton’s tyrosine kinase drug-resistant-mutant mouse model. We showed that BCR signaling per se is necessary for the survival and priming of light zone B cells to receive T cell help. Our findings provide insight into how high-affinity antibodies are selected within GCs and are fundamental to our understanding of adaptive immunity and vaccine development.

Project description:Germinal centers (GCs) are sites of B cell clonal expansion, diversification, and antibody affinity selection. This process is limited and directed by T follicular helper cells that provide helper signals to B cells that endocytose, process, and present cognate antigens in proportion to their B cell receptor (BCR) affinity. Under this model, the BCR functions as an endocytic receptor for antigen capture. How signaling through the BCR contributes to selection is not well understood. To investigate the role of BCR signaling in GC selection, we developed a tracker for antigen binding and presentation and a Bruton’s tyrosine kinase drug-resistant-mutant mouse model. We showed that BCR signaling per se is necessary for the survival and priming of light zone B cells to receive T cell help. Our findings provide insight into how high-affinity antibodies are selected within GCs and are fundamental to our understanding of adaptive immunity and vaccine development.

Project description:During a germinal center (GC) response, B cells diversify their immunoglobulin (Ig) genes by somatic hyper-mutation (SHM) and undergo clonal expansion and positive selection thereby enabling the generation of higher affinity antibodies. We have analyzed the genomic states underlying GC B cell dynamics by single cell RNA-Seq. Profiling of antigen specific GC B cells during the peak of the response, revealed four distinctive genomic states characterized by antigen presentation, apoptotic, mitochondrial and mitotic gene expression modules. Intersection of genomic states and Ig heavy-chain (Igh) class-switch trajectory suggested that mitochondrial machinery is utilized to support class-switch recombination (CSR). Furthermore, by analyzing the transcriptomes of B cells with varying affinity BCR sequences that assembled from single-cell RNA-seq data through a novel algorithm, we show that high affinity GC B cells manifest enhanced mitotic and BCR signaling transduction, but compromised antigen processing and presentation gene expression modules. Thus, we are developing a comprehensive framework of the genomic states and molecular pathways underlying GC B cell dynamics.

Project description:Background: Stress exacerbates symptoms of schizophrenia and attention deficit hyperactivity disorder, which are characterized by impairments in sustained attention. Yet how stress regulates attention remains largely unexplored. Here we investigated whether a 6-day variable stressor (VS) altered sustained attention and the cholinergic attention system in male and female rats. Methods: Sustained attention was tested with the sustained attention task (SAT). Successful performance on SAT relies on the release of acetylcholine (ACh) into the cortex from cholinergic neurons in the nucleus basalis of Meynert (NBM). Thus, we evaluated whether VS altered the morphology of these neurons with a novel approach using Cre-dependent virus in genetically modified ChAT::Cre rats, a species used for this manipulation only. Next, electrochemical recordings measured cortical ACh following VS. Finally, we used RNAseq to identify VS-induced transcriptional changes in the NBM. Results: VS impaired attentional performance in SAT and increased the dendritic complexity of NBM cholinergic neurons in both sexes. NBM cholinergic neurons are mainly under inhibitory control, so this morphological change could increase inhibition on these neurons, reducing downstream ACh release to impair attention. Indeed, VS decreased ACh release in the prefrontal cortex of males. Quantification of global transcriptional changes revealed that, although VS induced many sex-specific changes in gene expression, it increased several signaling molecules in both sexes.

Project description:The germinal center response or reaction (GCR) is a hallmark event of adaptive humoral immunity. Unfolding in the B cell follicles of the secondary lymph organs, a GC culminates in the production of high-affinity antibody-secreting plasma cells along with memory B cells. By interacting with follicular dendritic cells (FDC) and T follicular helper (Tfh) cells, GC B cells exhibit complex spatiotemporal dynamics. Driving the B cell dynamics are the intracellular signal transduction and gene regulatory network that responds to cell surface signaling molecules, cytokines, and chemokines. As our knowledge of the GC continues to expand in depth and in scope, mathematical modeling has become an important tool to help disentangle the intricacy of the GCR and inform novel mechanistic and clinical insights. While the GC has been modeled at different granularities, a multiscale spatial simulation framework – integrating molecular, cellular, and tissue-level responses – is still rare. Here, we report our recent progress toward this end with a hybrid stochastic GC framework developed on the Cellular Potts Model-based CompuCell3D platform. Tellurium is used to simulate the B cell intracellular molecular network comprising NF-κB, FOXO1, MYC, AP4, CXCR4, and BLIMP1 that responds to B cell receptor (BCR) and CD40-mediated signaling. The molecular outputs of the network drive the spatiotemporal behaviors of B cells, including cyclic migration between the dark zone (DZ) and light zone (LZ) via chemotaxis; clonal proliferative bursts, somatic hypermutation, and DNA damage-induced apoptosis in the DZ; and positive selection, apoptosis via a death timer, and emergence of plasma cells in the LZ. Our simulations are able to recapitulate key molecular, cellular, and morphological GC events including B cell population growth, affinity maturation, and clonal dominance. This novel modeling framework provides an open-source, customizable, and multiscale virtual GC simulation platform that enables qualitative and quantitative in silico investigations of a range of mechanic and applied research questions on the adaptive humoral immune response in future.

Project description:Protective immune responses to many pathogens depend on the development of high affinity antibody-producing plasma cells in germinal centers. Transgenic models suggest that there is a stringent affinity-based barrier to plasma cell development. Whether a similar high affinity barrier regulates plasma cell development under physiologic circumstances, and the nature of the plasma cell fate decision has not been defined precisely. Here we use a fate mapping approach to examine the relationship between germinal center (GC) B cells selected to undergo additional rounds of affinity maturation, germinal center pre-plasma cells and plasma cells. The data show that initial plasma cell selection overlaps with germinal center B cell selection, but that the plasma cell compartment accumulates a less diverse and higher affinity collection of antibodies over time. Thus, whereas the GC continues to diversify over time, affinity-based pre-plasma cell selection sieves the germinal center to enable accumulation of a more restricted group of high affinity antibody secreting plasma cells.

Project description:Compared with naïve B cells, the B cell receptor (BCR) signal in germinal center (GC) B cells is attenuated; however, the significance of this signaling attenuation has not been well defined. Here, to investigate the role of attenuation of BCR signaling, we employed a Csk mutant mouse model in which Csk-deficiency in GC B cells resulted in augmentation of net BCR signaling with no apparent effect on antigen presentation. We found that Csk is required for GC maintenance and efficient antibody affinity maturation. Mechanistically, ROS-induced apoptosis was exacerbated concomitantly with mitochondrial dysfunction in Csk-deficient GC B cells. Hence, our data suggest that attenuation of the BCR signal restrains hyper-ROS production, thereby protecting GC B cells from apoptosis and contributing to efficient affinity maturation.