Project description:The formation of vascular niche is pivotal during the early stage of peripheral nerve regeneration. This antecedent angiogenesis meets the nutrient requirements for subsequent rapid axon regeneration and remyelination. Nevertheless, the mechanisms of vascular niche in the regulation of peripheral nerve remain unclear. The axon guidance molecule Netrin-1 (NTN1) is widely expressed in peripheral nerves and particularly was found up-regulated in sciatic nerve stump after peripheral nerve injury (PNI). Herein, we demonstrated that NTN1-high endothelial cells (NTN1+ECs) were the critical component of vascular niche, fostering angiogenesis, axon regeneration and repair-related phenotypes. And we also found that NTN1+ECs derived exosomes (NTN1 EC-EXO) were involved in the formation of vascular niche as a critical role. Multi-omics analysis further verified that NTN1 EC-EXO carried a low-level expression of let7a-5p and activated key pathways associated with niche formation including focal adhesion, axon guidance, PI3K-AKT signaling pathway and mTOR signaling pathway. Taken together, our findings suggested the potential construction of a pre-regenerative niche induced by NTN1 EC-EXO, thereby establishing a conductive microenvironment for nerve repair and facilitating the functional recovery after PNI in the early injury phase.

Project description:The formation of vascular niche is pivotal during the early stage of peripheral nerve regeneration. This antecedent angiogenesis meets the nutrient requirements for subsequent rapid axon regeneration and remyelination. Nevertheless, the mechanisms of vascular niche in the regulation of peripheral nerve remain unclear. The axon guidance molecule Netrin-1 (NTN1) is widely expressed in peripheral nerves and particularly was found up-regulated in sciatic nerve stump after peripheral nerve injury (PNI). Herein, we demonstrated that NTN1-high endothelial cells (NTN1+ECs) were the critical component of vascular niche, fostering angiogenesis, axon regeneration and repair-related phenotypes. And we also found that NTN1+ECs derived exosomes (NTN1 EC-EXO) were involved in the formation of vascular niche as a critical role. Multi-omics analysis further verified that NTN1 EC-EXO carried a low-level expression of let7a-5p and activated key pathways associated with niche formation including focal adhesion, axon guidance, PI3K-AKT signaling pathway and mTOR signaling pathway. Taken together, our findings suggested the potential construction of a pre-regenerative niche induced by NTN1 EC-EXO, thereby establishing a conductive microenvironment for nerve repair and facilitating the functional recovery after PNI in the early injury phase.

Project description:The formation of vascular niche is pivotal during the early stage of peripheral nerve regeneration. This antecedent angiogenesis meets the nutrient requirements for subsequent rapid axon regeneration and remyelination. Nevertheless, the mechanisms of vascular niche in the regulation of peripheral nerve remain unclear. The axon guidance molecule Netrin-1 (NTN1) is widely expressed in peripheral nerves and particularly was found up-regulated in sciatic nerve stump after peripheral nerve injury (PNI). Herein, we demonstrated that NTN1-high endothelial cells (NTN1+ECs) were the critical component of vascular niche, fostering angiogenesis, axon regeneration and repair-related phenotypes. And we also found that NTN1+ECs derived exosomes (NTN1 EC-EXO) were involved in the formation of vascular niche as a critical role. Multi-omics analysis further verified that NTN1 EC-EXO carried a low-level expression of let7a-5p and activated key pathways associated with niche formation including focal adhesion, axon guidance, PI3K-AKT signaling pathway and mTOR signaling pathway. Taken together, our findings suggested the potential construction of a pre-regenerative niche induced by NTN1 EC-EXO, thereby establishing a conductive microenvironment for nerve repair and facilitating the functional recovery after PNI in the early injury phase.

Project description:The formation of vascular niche is pivotal during the early stage of peripheral nerve regeneration. This antecedent angiogenesis meets the nutrient requirements for subsequent rapid axon regeneration and remyelination. Nevertheless, the mechanisms of vascular niche in the regulation of peripheral nerve remain unclear. The axon guidance molecule Netrin-1 (NTN1) is widely expressed in peripheral nerves and particularly was found up-regulated in sciatic nerve stump after peripheral nerve injury (PNI). Herein, we demonstrated that NTN1-high endothelial cells (NTN1+ECs) were the critical component of vascular niche, fostering angiogenesis, axon regeneration and repair-related phenotypes. And we also found that NTN1+ECs derived exosomes (NTN1 EC-EXO) were involved in the formation of vascular niche as a critical role. Multi-omics analysis further verified that NTN1 EC-EXO carried a low-level expression of let7a-5p and activated key pathways associated with niche formation including focal adhesion, axon guidance, PI3K-AKT signaling pathway and mTOR signaling pathway. Taken together, our findings suggested the potential construction of a pre-regenerative niche induced by NTN1 EC-EXO, thereby establishing a conductive microenvironment for nerve repair and facilitating the functional recovery after PNI in the early injury phase.

Project description:Peripheral nerve repair and functional recovery depend on the rate of nerve regeneration and the quality of target reinnervation. It is important to fully understand the cellular and molecular basis underlying the specificity of peripheral nerve regeneration, which means the achieving of respective correct pathfinding and accurate target reinnervation for regrowing motor and sensory axons. In this study, a quantitative proteomic technique, based on isobaric tags for relative and absolute quantitation (iTRAQ) was used to profile the protein expression pattern between single motor and sensory nerves at 14 days after peripheral nerve transection. Among a total of 1259 proteins identified, 176 proteins showed the differential expressions between injured motor and sensory nerves. Quantitative real-time RT-PCR and Western blot analysis were applied to validate the proteomic data on representative differentially expressed proteins. Functional categorization indicated that differentially expressed proteins were linked to a diverse array of molecular functions, including axonogenesis, response to axon injury, tissue remodeling, axon ensheathment, cell proliferation and adhesion, vesicle-mediated transport, response to oxidative stress, internal signal cascade, and macromolecular complex assembly, which might play an essential role in peripheral motor and sensory nerve regeneration. Overall, we hope that the proteomic database obtained in this study could serve as a solid foundation for the comprehensive investigation of differentially expressed proteins between injured motor and sensory nerves and for the mechanism elucidation of the specificity of peripheral nerve regeneration.

Project description:In this study, a quantitative proteomic technique based on isobaric tags for relative and absolute quantitation (iTRAQ) was used to compare the proteome of cultured sensory and motor nerve fibroblasts (Fbs). Among a total of 2597 overlapping proteins identified, we obtained 148 differentially expressed proteins, of which 116 proteins were significantly higher expressed in sensory Fbs, and 32 proteins were significantly higher expressed in motor Fbs. Western blot and qPCR analysis were applied to validate differentially expressed proteins. Functional categorization indicated that differentially expressed proteins were linked to a diverse array of biological processes , including regeneration, axon guidance, cytoskeleton organization, cell proliferation, cell migration, cell adhesion, and tissue remodeling, which might play a critical role in the specificity of peripheral nerve regeneration. Furthermore, following co-culture of motor neurons with motor or sensory Fbs , motor Fbs significantly enhanced neurite growth than sensory Fbs. These findings indicated that nerve Fbs expressed the distinct motor and sensory phenotypes involved in different patterns of protein expression, biological processes, and effects on neurons.

Project description:Vascular endothelial cells (ECs) establish via paracrine signaling tissue-specific niches that promote organ revascularization and regeneration. Given these executive functions, transplantation of ECs into the vasculature has been used to stimulate organ repair. However, challenges in faithfully deriving tissue-specific endothelium within in vitro culture conditions limit large-scale expansion potential, long-term functional stability, and the cell homing and engraftment potential towards the target organ. Identification of the transcriptional regulators that modulate the specification of generic or unspecified endothelial cell populations into tissue-specific vascular ECs may provide novel factors to be incorporated into standard stem-cell differentiation protocols. Such controlled expression of the appropriate angiocrine factors—in combination with the niche microenvironment—could support the necessary crosstalk and cell-to-cell membrane interactions necessary for positioning and anastomosis when transplanted. Previously, investigation of the transcriptome profiles of ECs originating from diverse vascular beds has helped identify potential transcriptional regulators and gene markers of EC tissue specification. We aim to expand on these studies by elaborating on the progression of EC tissue specification as it occurs from embryonic development to adulthood. A better understanding of how ECs acquire their tissue specificity and deconvolution of the transient expression patterns of key molecular regulators could provide crucial information on the establishment of EC tissue-specific function which can then be recapitulated in vitro. Our long-term goal is to generate transcriptionally stable and functional tissue-specific ECs from stem-cell derived EC banks suitable for transplantation for the purpose of promoting non-fibrotic tissue regeneration after organ injury.

Project description:Primary sensory neurons with cell soma in dorsal root ganglia (DRG) project axons in both the peripheral nervous system and the spinal cord. Whereas the peripheral axon can regenerate after injury, the central axon cannot, providing an opportunity to identify the mechanisms that promote axon regeneration. Using this system, multiple intrinsic mechanisms operating in sensory neurons have been shown to promote axon regeneration. Peripheral sensory neurons also benefit from a supportive environment. In particular, macrophages play important roles in nerve regeneration by clearing debris and regulating Schwann cell function at the site of injury in the nerve. Nerve macrophages have been characterized at the molecular level and derive for the most part from infiltrating monocytes. However, the role and origin of macrophages in the DRG remains poorly understood. Following a 14-days treatment with a CSF1R inhibitor, less than 10% of macrophages remained in the DRG. Recovery from this treatment resulted in a dramatic macrophage repopulation, with the number of DRG macrophages reaching level similar to untreated mice three days post injury. These repopulated DRG macrophages contribute to promote axon regeneration. Our scRNA-seq analysis allow in-depth characterization of the repopulated DRG macrophages in response to nerve injury. These data will provide a better understanding of DRG macrophages and the molecular mechanisms by which they contribute to peripheral nerve repair. These studies may lead to new potential targets to promote axon regeneration.

Project description:In cancer progression to metastasis, disseminated cancer cells frequently lodge near vasculature in secondary organs. However, our understanding of the cellular crosstalk evoked at perivascular sites is still rudimentary. In this study, we identified an inter-cellular machinery governing formation of a pro-metastatic vascular niche during breast cancer colonization in lungs. Transcriptomic analysis of endothelial cells (ECs) isolated from mouse lungs with metastases revealed a marked upregulation of genes linked to proliferation, inflammation and numerous secreted proteins. We showed that four secreted factors, INHBB, SCGB3A1, OPG and LAMA1, induced in ECs form a supportive niche that promotes metastasis in mice, by enhancing stem cell properties and survival ability of cancer cells. Interestingly, the blocking vascular endothelial cell growth factor (VEGF), a major cytokine regulating EC behaviors, dramatically suppressed EC proliferation whereas no impact was observed on the expression of the four vascular niche factors in lung ECs. We found that the formation of a vascular niche is correlated with inflammation, and revealed that metastasis-associated macrophages are essential for production of all of four niche factors in lung ECs. Macrophages are activated via TNC-TLR4 at perivasculature and sequentially stimulate ECs to produce the four niche factors. Thus, our findings provide mechanistic insights into the formation of a perivascular niche and offer the possibility that targeting macrophages may synergize with existing anti-angiogenic drugs to effectively suppress vascular function in metastatic colonization. We used microarrays to analyze the global changes of gene expression in mouse lung endothelial cells associated with metastasis of Tenascin C-depleted breast cancer cells

Project description:In cancer progression to metastasis, disseminated cancer cells frequently lodge near vasculature in secondary organs. However, our understanding of the cellular crosstalk evoked at perivascular sites is still rudimentary. In this study, we identified an inter-cellular machinery governing formation of a pro-metastatic vascular niche during breast cancer colonization in lungs. Transcriptomic analysis of endothelial cells (ECs) isolated from mouse lungs with metastases revealed a marked upregulation of genes linked to proliferation, inflammation and numerous secreted proteins. We showed that four secreted factors, INHBB, SCGB3A1, OPG and LAMA1, induced in ECs form a supportive niche that promotes metastasis in mice, by enhancing stem cell properties and survival ability of cancer cells. Interestingly, the blocking vascular endothelial cell growth factor (VEGF), a major cytokine regulating EC behaviors, dramatically suppressed EC proliferation whereas no impact was observed on the expression of the four vascular niche factors in lung ECs. We found that the formation of a vascular niche is correlated with inflammation, and revealed that metastasis-associated macrophages are essential for production of all of four niche factors in lung ECs. Macrophages are activated via TNC-TLR4 at perivasculature and sequentially stimulate ECs to produce the four niche factors. Thus, our findings provide mechanistic insights into the formation of a perivascular niche and offer the possibility that targeting macrophages may synergize with existing anti-angiogenic drugs to effectively suppress vascular function in metastatic colonization. We used microarrays to analyze the global changes of gene expression in SUM159 human breast cancer cells with ectopic expression of SCGB3A1.