Project description:The superior cervical ganglion (SCG) innervates multiple effector organs within cranial tissues and elicits responses including pupil dilation, piloerection, vasoconstriction and inhibition of salivation. Coordinated activation of these targets is associated with the display of different emotions; however, the underlying circuit organization and cellular heterogeneity of SCG neurons remain unclear. Here, we combined neuronal tracing with single-cell and spatial transcriptomics to characterize the SCG circuitry and heterogeneity. We found that each SCG neuron innervates a single effector organ. SCG subtypes defined by their projection (P) targets form two major compartments within the ganglia, but individual P-types were intermingled. Mature SCG transcriptomic types (T) emerge postnatally and exhibit rostra-caudal biases. While some T-types were enriched in SCG populations with specific axon projections, they did not show a strict one-to-one correspondence with P-types. These results suggest that individual sympathetic cranial effectors mediating facial emotions are controlled combinatorially by multiple transcriptomic SCG types.

Project description:Pancreatic beta cell generation from induced pluripotent stem cells (iPSCs) offers an alternative donor tissue source; however, the efficiency of induction of INSULIN (INS)+ cells from human iPSCs (hiPSCs) is low. We aimed to establish an efficient differentiation protocol for generating INS+ cells from hiPSCs by identifying novel inducers. We screened small molecules that increased the induction rate of INS+ cells from hiPSC-derived PDX1+ pancreatic progenitor cells by using high-throughput screening (HTS) system. We identified one compound, sodium cromoglicate (SCG) out of about 1,250 small molecules that we screened. When SCG was combined with the previously described protocol, the induction rate of INS+ cells increased up to 15–20%, and the cells developed the ability to secrete C-peptide in vitro. We found that SCG facilitates the differentiation of multiple endocrine cell types, including INS+ cells, in both hiPSC differentiation cultures and mouse embryonic pancreas explants by inducing NEUROG3+ endocrine precursor cells. We also confirmed that the mechanisms of action by which SCG induces the pancreatic endocrine differentiation include the inhibition of BMP4 signaling.

Project description:We have undertaken a genome-wide study of transcriptional activity in embryonic superior cervical ganglia (SCG) and dorsal root ganglia (DRG) during a time course of neurite outgrowth in vitro. Gene expression observed in these models likely includes both developmental gene expression patterns and regenerative responses to axotomy, which occurs as the result of tissue dissection. Comparison across both models revealed many genes with similar gene expression patterns during neurite outgrowth. These patterns were minimally affected by exposure to the potent inhibitory cue Semaphorin3A, indicating that this extrinsic cue does not exert major effects at the level of nuclear transcription. We also compared our data to several published studies of DRG and SCG gene expression in animal models of regeneration, and found the expression of a large number of genes in common between neurite outgrowth in vitro and regeneration in vivo. Experiment Overall Design: We wished to determine the transcriptional profiles of neurons undergoing neurite outgrowth in vitro. We were particularly interested in finding genes whose expression is generally associated with the process of neurite outgrowth, rather than with cell type-specific effects. Thus, in order to avoid focusing on transcripts unique to one tissue type versus another, we used a comparative strategy to look for effects that were common to two tissue types and therefore more likely to be involved in the general process of neurite outgrowth. While these explants contain multiple cell types, we felt this was preferable to the more disruptive conditions required to dissociate neurons or obtain a pure neuron population. To this end, we monitored gene expression in cultured explants from SCG and DRG using DNA microarrays. We initiated our studies by culturing embryonic day 13 (E13) mouse SCG in vitro and harvesting tissue for RNA isolation at time points from 2 to 65 hours. Time points were selected to detect both fast, short-term responses (2, 5 and 12 hours), as well as sustained, long-term changes (24, 40, and 65 hours). Samples were hybridized to Affymetrix MG-U74v2 A and B microarrays, with RNA from acutely dissected explants serving as a baseline reference. We followed these experiments with a parallel analysis of a more heterogeneous tissue type, the DRG, which is more frequently used than SCG for in vivo studies of neurite regeneration. Cervical and upper thoracic DRG from E12 embryos were cultured with NGF (the same trophic support as in SCG cultures), harvested at time points from 2 to 40 hours, and hybridized to Affymetrix MOE 430A microarrays.

Project description:We have undertaken a genome-wide study of transcriptional activity in embryonic superior cervical ganglia (SCG) and dorsal root ganglia (DRG) during a time course of neurite outgrowth in vitro. Gene expression observed in these models likely includes both developmental gene expression patterns and regenerative responses to axotomy, which occurs as the result of tissue dissection. Comparison across both models revealed many genes with similar gene expression patterns during neurite outgrowth. These patterns were minimally affected by exposure to the potent inhibitory cue Semaphorin3A, indicating that this extrinsic cue does not exert major effects at the level of nuclear transcription. We also compared our data to several published studies of DRG and SCG gene expression in animal models of regeneration, and found the expression of a large number of genes in common between neurite outgrowth in vitro and regeneration in vivo. Experiment Overall Design: We wished to determine the transcriptional profiles of neurons undergoing neurite outgrowth in vitro. We were particularly interested in finding genes whose expression is generally associated with the process of neurite outgrowth, rather than with cell type-specific effects. Thus, in order to avoid focusing on transcripts unique to one tissue type versus another, we used a comparative strategy to look for effects that were common to two tissue types and therefore more likely to be involved in the general process of neurite outgrowth. While these explants contain multiple cell types, we felt this was preferable to the more disruptive conditions required to dissociate neurons or obtain a pure neuron population. To this end, we monitored gene expression in cultured explants from SCG and DRG using DNA microarrays. We initiated our studies by culturing embryonic day 13 (E13) mouse SCG in vitro and harvesting tissue for RNA isolation at time points from 2 to 65 hours. Time points were selected to detect both fast, short-term responses (2, 5 and 12 hours), as well as sustained, long-term changes (24, 40, and 65 hours). Samples were hybridized to Affymetrix MG-U74v2 A and B microarrays, with RNA from acutely dissected explants serving as a baseline reference. We followed these experiments with a parallel analysis of a more heterogeneous tissue type, the DRG, which is more frequently used than SCG for in vivo studies of neurite regeneration. Cervical and upper thoracic DRG from E12 embryos were cultured with NGF (the same trophic support as in SCG cultures), harvested at time points from 2 to 40 hours, and hybridized to Affymetrix MOE 430A microarrays.

Project description:We have undertaken a genome-wide study of transcriptional activity in embryonic superior cervical ganglia (SCG) and dorsal root ganglia (DRG) during a time course of neurite outgrowth in vitro. Gene expression observed in these models likely includes both developmental gene expression patterns and regenerative responses to axotomy, which occurs as the result of tissue dissection. Comparison across both models revealed many genes with similar gene expression patterns during neurite outgrowth. These patterns were minimally affected by exposure to the potent inhibitory cue Semaphorin3A, indicating that this extrinsic cue does not exert major effects at the level of nuclear transcription. We also compared our data to several published studies of DRG and SCG gene expression in animal models of regeneration, and found the expression of a large number of genes in common between neurite outgrowth in vitro and regeneration in vivo. Experiment Overall Design: We wished to determine the transcriptional profiles of neurons undergoing neurite outgrowth in vitro. We were particularly interested in finding genes whose expression is generally associated with the process of neurite outgrowth, rather than with cell type-specific effects. Thus, in order to avoid focusing on transcripts unique to one tissue type versus another, we used a comparative strategy to look for effects that were common to two tissue types and therefore more likely to be involved in the general process of neurite outgrowth. While these explants contain multiple cell types, we felt this was preferable to the more disruptive conditions required to dissociate neurons or obtain a pure neuron population. To this end, we monitored gene expression in cultured explants from SCG and DRG using DNA microarrays. We initiated our studies by culturing embryonic day 13 (E13) mouse SCG in vitro and harvesting tissue for RNA isolation at time points from 2 to 65 hours. Time points were selected to detect both fast, short-term responses (2, 5 and 12 hours), as well as sustained, long-term changes (24, 40, and 65 hours). Samples were hybridized to Affymetrix MG-U74v2 A and B microarrays, with RNA from acutely dissected explants serving as a baseline reference. We followed these experiments with a parallel analysis of a more heterogeneous tissue type, the DRG, which is more frequently used than SCG for in vivo studies of neurite regeneration. Cervical and upper thoracic DRG from E12 embryos were cultured with NGF (the same trophic support as in SCG cultures), harvested at time points from 2 to 40 hours, and hybridized to Affymetrix MOE 430A microarrays.

Project description:Background More than 70% of cancer patients who underwent cranial radiotherapy have cognitive problems, suggesting that they might undergo accelerated brain aging due to the cancer treatment. Radiotherapy is known to induce cellular senescence in tumors and in various cell types in vitro. Therefore, we hypothesized that cranial radiotherapy induces cellular senescence in the brain. Methods We treated male C57BL/6 mice with various dosages of (fractionated) CT-guided cranial radiotherapy. The brains were analyzed for various senescence and glial markers using immunohistochemistry, histochemistry, Cosmx SMI and RT-qPCR. To contextualize the findings regarding cranial radiotherapy in young animals and assess whether these changes parallel natural aging, we studied the brains from 77-week-old female mice, which is considered middle-aged to old representing early aging. Results Surprisingly, we found no increase in markers for cellular senescence in the brain after cranial radiotherapy. However, we did detect profound changes in different types of glia. In early-aged mice we again did not detect an increase in senescence markers, but we observed the same directionality in the effects on glia. These effects on glia were milder compared to those upon cranial radiotherapy. Conclusion Overall, cellular senescence in the healthy brain seems a rather uncommon phenomenon and not induced upon cranial radiotherapy, but profound changes in different types of glia were detected upon cranial radiotherapy.

Project description:We optimized a workflow combining imaging-based spatial transcriptomics (MERFISH) and immunostaining on ganglion cell layer retinal flatmounts of C57/Bl6J mice.The MERFISH data shows molecularly-defined retinal ganglion cell types types exhibited non-uniform distributions. We also analyzed local neighborhoods for each cell and registered several RGC types as enriched in the perivascular niche.

Project description:Cytotoxic T lymphocytes (CTL) kill malignant and infected cells via cytotoxic proteins such as granzyme B (GzmB) that are released into the immunological synapse in the form of ~110 nm supramolecular attack particles (SMAPs). However, it is not known where SMAPs are stored in the cell and how they are released. To address this, we utilized knock-in mice to label fusogenic cytotoxic granules with synaptobrevin2-mRFP. We identified two classes of fusion-competent granules, single core granules (SCG) and multi core granules (MCG), with different diameter, morphology, and protein composition. Functional analyses demonstrate that both classes of granules fuse with the plasma membrane at the IS. SCG fusion resulted in rapid dispersal of GzmB. MCG labelled with the SMAP marker thrombospondin-1 and their fusion events resulted in deposition of SMAPs. The CTL attack strategy thus includes SCG fusion to disperse immediately active cytotoxic proteins and parallel MCG fusion to deposit concentrated latent SMAPs onto the target.

Project description:Hypertension-induced left ventricular hypertrophy (LVH) is a cardiac structural remodeling and dysfunction resulting from chronic hypertension and is an independent risk factor for cardiovascular morbidity and mortality. Studies have implicated the involvement of the adrenal gland (AG) and superior cervical ganglion (SCG) in hypertension regulation. However, the molecular mechanisms of AG and SCG during hypertension-induced LVH remain unclear. In this study, we investigated the transcriptome characteristics of the left ventricle, AG, and SCG in 24-week-old spontaneously hypertensive rats (SHR) and Wistar-Kyoto (WKY) rats using transcriptome sequencing (RNA-seq) technology. We identified 671 differentially expressed genes (DEGs) in the left ventricle, 1596 DEGs in the AG, and 343 DEGs in the SCG between SHR and WKY rats. Functional analysis revealed that these DEGs were involved in pathways related to immune inflammation, metabolic responses, and synaptic transmission. Further analysis demonstrated the presence of crosstalk among DEGs across these three organs, including 63 overlapping DEGs among these three organs, of which 59 DEGs exhibited consistent changes. In summary, we elucidates the transcriptome features of AG and SCG during hypertension-induced LVH in SHR, highlighting the complex molecular interactions across multiple organs.

Project description:PoolPy combinatorially pooled DAP-seq