Project description:Analysis of the differential transcriptome of DC derived from tissue vs. LN origin. The overall hypothesis is these data would reveal how migratory DC may be differently programmed from classical DC and might also suggest difference within migratory DC subsets relating to function. RNA obtained from migratory DC subsets and classical CD8a DC isolated by flow cytometry sorting from skin draining LNs of Flt3L treated mice or LPS treated mice

Project description:Immune responses within barrier tissues are regulated, in part, by nociceptors, specialized peripheral sensory neurons that detect noxious stimuli. Previous work has shown that nociceptor ablation not only alters local responses at peripheral sites of immune challenge, but also within draining lymph nodes (LNs). The mechanism and significance of nociceptor-dependent modulation of LN homeostasis are unknown. Indeed, although sympathetic innervation of LNs is well documented, it has been unclear whether the LN parenchyma itself is innervated by sensory neurons. Here, using a combination of high-resolution imaging, retrograde viral tracing, optogenetics, and single-cell transcriptomics (scRNA-seq), we describe a sensory neuro-immune circuit that is preferentially located in the outermost cortex of skin-draining LNs. Transcriptomic profiling revealed that sensory neurons that innervate LNs are composed of at least four discrete subsets with a predominance of peptidergic nociceptors, an innervation pattern that is distinct from that in the surrounding skin. To identify potential LN-resident communication partners for LN-innervating sensory neurons, we employed scRNA-seq to generate an atlas of all murine LN cells and, based on receptor-ligand expression patterns, nominated candidate target populations among stromal and immune cells. We experimentally validated these inferred connections by comparing scRNA-seq signatures before and after selective optogenetic stimulation of LN-innervating axons. Acute neuronal activation triggered rapid transcriptional changes preferentially in endothelium and other nodal stroma cells, as well as in several innate leukocyte populations. Thus, LNs are monitored by a unique population of sensory neurons that possess profound immunomodulatory potential.

Project description:Immune responses within barrier tissues are regulated, in part, by nociceptors, specialized peripheral sensory neurons that detect noxious stimuli. Previous work has shown that nociceptor ablation not only alters local responses at peripheral sites of immune challenge, but also within draining lymph nodes (LNs). The mechanism and significance of nociceptor-dependent modulation of LN homeostasis are unknown. Indeed, although sympathetic innervation of LNs is well documented, it has been unclear whether the LN parenchyma itself is innervated by sensory neurons. Here, using a combination of high-resolution imaging, retrograde viral tracing, optogenetics, and single-cell transcriptomics (scRNA-seq), we describe a sensory neuro-immune circuit that is preferentially located in the outermost cortex of skin-draining LNs. Transcriptomic profiling revealed that sensory neurons that innervate LNs are composed of at least four discrete subsets with a predominance of peptidergic nociceptors, an innervation pattern that is distinct from that in the surrounding skin. To identify potential LN-resident communication partners for LN-innervating sensory neurons, we employed scRNA-seq to generate an atlas of all murine LN cells and, based on receptor-ligand expression patterns, nominated candidate target populations among stromal and immune cells. We experimentally validated these inferred connections by comparing scRNA-seq signatures before and after selective optogenetic stimulation of LN-innervating axons. Acute neuronal activation triggered rapid transcriptional changes preferentially in endothelium and other nodal stroma cells, as well as in several innate leukocyte populations. Thus, LNs are monitored by a unique population of sensory neurons that possess profound immunomodulatory potential.

Project description:Lymph node (LN) stromal cells, particularly fibroblastic reticular cells (FRCs), provide critical structural support and regulate immunity, tolerance and transport properties of LNs. In many tumors, LN metastasis is predictive of poor prognosis, however, stromal contribution to the evolving microenvironment of tumor draining LNs (TDLN) remains poorly understood. Here we present comparative transcriptional data of resting and TDLN FRCs after different time points of tumor drainage. FRCs were isolated from lymph nodes and FACS sorted based on the expression of CD45-, CD31- and PDPN+

Project description:CD8+ T cell responses to pulmonary challenges are primed by lung-migratory dendritic cells (mDCs), which capture antigens in the lung and migrate to the lung-draining mediastinal lymph node (med-LNs) to activate T cells. Notably, the lung and the spleen are not connected by the lymphatic vasculature. Thus, the current paradigm suggests that the med-LN is the only site for T cell priming to viruses that are restricted to the respiratory tract. Our results challenge this “LN-centric” paradigm. Using an influenza virus infection, we show here that lung-mDCs egress the med-LN and traffic to the spleen, where they prime influenza-specific CD8+ T cells. Importantly, CD8+ T cells primed in the spleen are transcriptionally different and have enhanced ability to differentiate into long-lived memory cells compared to med-LN-primed counterparts. Thus, our data reveal a previously ignored lung-mDC trafficking pathway that connects the lung with the spleen and has profound immunological implications.

Project description:Sphingosine 1-phosphate (S1P), a lipid chemoattractant, guides immune cells from the low-S1P environment of tissues into the high-S1P environment of circulatory fluids. Most notably, S1P directs T cell exit from lymph nodes (LN), where T cells are initially activated to fight pathogens, into lymph, from which T cells flow into blood and ultimately reach inflamed tissues. T cells follow these gradients primarily using S1P receptor 1 (S1PR1). The drugs Gilenya and Siponimod, both FDA-approved for the autoimmune disease multiple sclerosis, target S1PR1. They blind self-reactive T cells to S1P gradients, block them from exiting LN, and thus prevent them from infiltrating the central nervous system. While recent work has revealed key aspects of how S1P gradients are established at steady-state, very little is known about S1P distribution in disease, and in turn how changing S1P gradients may affect the immune response. Here, we find that LN S1P increases during an immune response, which prolongs the time T cells spend in the LN before exiting into lymph. Inflammatory monocytes, which had not previously been implicated in shaping S1P gradients, are an important source of this S1P. Inflammatory monocytes must express the early activation marker CD69 to supply S1P to T cells; CD69 represses transcription of S1P receptor 5 (S1pr5), enabling monocytes to infiltrate the LN T zone and efficiently release S1P. Here we compared RNA sequencing of inflammatory monocytes WT or CD69-KO infiltrating the draining lymph node.$

Project description:Subset-specific and progenitor gene expression analysis of Klf4+/+ and Klf4-/- DCs. The two major lineages of classical dendritic cells (cDCs) express and require either IRF8 or IRF4 transcription factors for their development and function. IRF8-dependent cDCs promote anti-viral and T-helper 1 (Th1) cell responses, whereas IRF4-expressing cDCs have been implicated in controlling both Th2 and Th17 cell responses. Here, we have provided evidence that Kruppel-like factor 4 (Klf4) is required in IRF4-expressing cDCs to promote Th2 but not Th17 cell responses in vivo. Conditional Klf4 deletion within cDCs impaired Th2 cell responses during Schistosoma mansoni infection, Schistosoma egg antigen (SEA) immunization, and house dust mite challenge (HDM), without affecting cytotoxic T lymphocyte (CTL), Th1 and Th17 cell responses to herpes simplex virus, Toxoplasma gondii and Citrobacter rodentium infections. Further, Klf4 deletion reduced IRF4 expression in pre-cDCs and resulted in selective loss of IRF4-expressing cDCs subsets in several tissues. These results indicate that Klf4 guides a transcriptional program promoting IRF4-expressing cDCs heterogeneity. Bone marrow progenitors and skin draining LN subsets were harvested from 4 Klf4fl/fl cre negative or Vav1-icre mice and were sorted to >95% purity on the FACS Aria 3.

Project description:C-C chemokine receptor 5 (CCR5) is a co-receptor of HIV. Its ligand, CCL5 significantly augmented the number of wild-type osteoclasts but not Ccr5-deficient cells, indicating that CCL5 enhanced RANKL-induced osteoclastogenesis through CCR5. To investigate the changes in the transcriptional signatures induced by CCL5 in osteoclastogenesis, cultured osteoclasts at pOC stages were incubated with or without rmCCL5 for 2 days, and then subjected for RNA sequencing.

Project description:Regulatory T cells (Treg) are present in lymphoid and non-lymphoid tissues where they restrict immune activation, prevent autoimmunity and regulate inflammation. Treg in non-lymphoid tissues are typically resident, while those in lymph nodes (LNs) are considered to recirculate. However, Treg in LNs are not a homogenous population and circulation kinetics of different Treg subsets are poorly characterized. Furthermore, whether Treg can acquire memory T cell properties and persist for extended periods after their activation in LNs is unclear. Here, we used in situ labeling with a stabilized photoconvertible protein to uncover turnover rates of Treg in LNs in vivo. We found that while the majority of Treg in LNs recirculate, 10-20% are memory-like resident cells that remain in their respective LNs for weeks to months. Single cell RNA sequencing revealed that LN-resident cells are a functionally and ontogenetically heterogeneous population and share the same core residency gene signature with conventional CD4+ and CD8+ T cells. Resident cells in LNs did not actively proliferate and did not require continuous TCR signaling for their residency. Yet, resident and circulating Treg had distinct TCR repertoires, and each LN contained exclusive clonal subpopulations of resident Treg. Our results demonstrate that, similar to conventional T cells, Treg can form resident memory-like populations in LNs after adaptive immune responses. Specific and local suppression of immune responses by resident Treg in draining LNs might provide new therapeutic opportunities for the treatment of local chronic inflammatory conditions.

Project description:Analysis of classical and migratory DC from the skin draining LNs of Flt3L treated mice and comparison to LPS treated DC from skin draining LN and peritoneal macrophages