Spinal cord injury triggers complex pathological cascades,resulting in destructive tissue damage and incomplete tissue repair.Scar formation is generally considered a barrier for regeneration in the central nervous sy...Spinal cord injury triggers complex pathological cascades,resulting in destructive tissue damage and incomplete tissue repair.Scar formation is generally considered a barrier for regeneration in the central nervous system.However,the intrinsic mechanism of scar formation after spinal cord injury has not been fully elucidated.Here,we report that excess cholesterol accumulates in phagocytes and is inefficiently removed from spinal cord lesions in young adult mice.Interestingly,we observed that excessive cholesterol also accumulates in injured peripheral nerves but is subsequently removed by reverse cholesteroltransport.Meanwhile,preventing reverse cholesterol transport leads to macrophage accumulation and fibrosis in injured peripheral nerves.Furthermore,the neonatal mouse spinal cord lesions are devoid of myelin-derived lipids and can heal without excess cholesterol accumulation.We found that transplantation of myelin into neonatal lesions disrupts healing with excessive cholesterol accumulation,persistent macrophage activation,and fibrosis.Myelin internalization suppresses macrophage apoptosis mediated by CD5L expression,indicating that myelin-derived cholesterol plays a critical role in impaired wound healing.Taken together,our data suggest that the central nervous system lacks an efficient approach for cholesterol clearance,resulting in excessive accumulation of myelin-derived cholesterol,thereby inducing scar formation after injury.展开更多
Gila outnumber neurons and are the most abundant cell type in the nervous system. Whereas neurons are the major carriers, transducers, and processors of information, glial cells, once considered mainly to play a passi...Gila outnumber neurons and are the most abundant cell type in the nervous system. Whereas neurons are the major carriers, transducers, and processors of information, glial cells, once considered mainly to play a passive supporting role, are now recognized for their active contributions to almost every aspect of nervous system development. Recently, insights from the invertebrate organism Drosophila melanogaster have advanced our knowledge of glial cell biology. In particular, findings on neuron-glia interactions via intrinsic and extrinsic mechanisms have shed light on the importance of gtia during different stages of neuronal development. Here, we summarize recent advances in understanding the functions of Drosophila glia, which resemble their mammalian counterparts in morphology and function, neural stem-cell conversion, synapse formation, and developmental axon pruning. These discoveries reinforce the idea that glia are substantial players in the developing nervous system and further advance the understanding of mechanisms leading to neurodegeneration.展开更多
Epsilon-near-zero (ENZ) media are opening up exciting opportunities to observe exotic wave phenomena. In this work, we demonstrate that the ENZ medium comprising multiple dielectric photonic dopants would yield a comb...Epsilon-near-zero (ENZ) media are opening up exciting opportunities to observe exotic wave phenomena. In this work, we demonstrate that the ENZ medium comprising multiple dielectric photonic dopants would yield a comb-like dispersion of the effective permeability, with each magnetic resonance dominated by one specific dopant. Furthermore, at multiple frequencies of interest, the resonant supercouplings appearing or not can be controlled discretely via whether corresponding dopants are assigned or not. Importantly, the multiple dopants in the ENZ host at their magnetic resonances are demonstrated to be independent. Based on this platform, the concept of dispersion coding is proposed, where photonic dopants serve as “bits” to program the spectral response of the whole composite medium. As a proof of concept, a compact multi-doped ENZ cavity is fabricated and experimentally characterized, whose transmission spectrum is manifested as a multi-bit reconfigurable frequency comb. The dispersion coding is demonstrated to fuel a batch of innovative applications including dynamically tunable comb-like dispersion profiled filters, radio-frequency identification tags, etc.展开更多
基金financially supported by the International Cooperation Project of National Natural Science Foundation of China(Grant No.81810001048)the National Natural Science Foundation of China(Grant Nos.81922039,81873994,82225027,and 82202702)+1 种基金Key basic research projects of Shanghai Science and Technology Commission(Grant No.19JC141470)the Fundamental Research Funds for the Central Universities of China.
文摘Spinal cord injury triggers complex pathological cascades,resulting in destructive tissue damage and incomplete tissue repair.Scar formation is generally considered a barrier for regeneration in the central nervous system.However,the intrinsic mechanism of scar formation after spinal cord injury has not been fully elucidated.Here,we report that excess cholesterol accumulates in phagocytes and is inefficiently removed from spinal cord lesions in young adult mice.Interestingly,we observed that excessive cholesterol also accumulates in injured peripheral nerves but is subsequently removed by reverse cholesteroltransport.Meanwhile,preventing reverse cholesterol transport leads to macrophage accumulation and fibrosis in injured peripheral nerves.Furthermore,the neonatal mouse spinal cord lesions are devoid of myelin-derived lipids and can heal without excess cholesterol accumulation.We found that transplantation of myelin into neonatal lesions disrupts healing with excessive cholesterol accumulation,persistent macrophage activation,and fibrosis.Myelin internalization suppresses macrophage apoptosis mediated by CD5L expression,indicating that myelin-derived cholesterol plays a critical role in impaired wound healing.Taken together,our data suggest that the central nervous system lacks an efficient approach for cholesterol clearance,resulting in excessive accumulation of myelin-derived cholesterol,thereby inducing scar formation after injury.
基金supported by grants from the National Basic Research Program of China (973 Program 2010CB944900 and 2013CB945602)the National Natural Science Foundation of China (31270825 and 31171043)Fundamental Research Funds for the Central Universities We thank members of the Ho lab for discussion and comments
文摘Gila outnumber neurons and are the most abundant cell type in the nervous system. Whereas neurons are the major carriers, transducers, and processors of information, glial cells, once considered mainly to play a passive supporting role, are now recognized for their active contributions to almost every aspect of nervous system development. Recently, insights from the invertebrate organism Drosophila melanogaster have advanced our knowledge of glial cell biology. In particular, findings on neuron-glia interactions via intrinsic and extrinsic mechanisms have shed light on the importance of gtia during different stages of neuronal development. Here, we summarize recent advances in understanding the functions of Drosophila glia, which resemble their mammalian counterparts in morphology and function, neural stem-cell conversion, synapse formation, and developmental axon pruning. These discoveries reinforce the idea that glia are substantial players in the developing nervous system and further advance the understanding of mechanisms leading to neurodegeneration.
基金the National Natural Science Foundation of China(NSFC)under grant 62022045in part by the Beijing Nova Program of Science and Technology under Grant Z191100001119082as well as the support from the Beijing National Research Center for Information Science and Technology.I.L.acknowledges support from project RTI2018-093714-J-I00 sponsored by MCIU/AEI/FEDER/UE.
文摘Epsilon-near-zero (ENZ) media are opening up exciting opportunities to observe exotic wave phenomena. In this work, we demonstrate that the ENZ medium comprising multiple dielectric photonic dopants would yield a comb-like dispersion of the effective permeability, with each magnetic resonance dominated by one specific dopant. Furthermore, at multiple frequencies of interest, the resonant supercouplings appearing or not can be controlled discretely via whether corresponding dopants are assigned or not. Importantly, the multiple dopants in the ENZ host at their magnetic resonances are demonstrated to be independent. Based on this platform, the concept of dispersion coding is proposed, where photonic dopants serve as “bits” to program the spectral response of the whole composite medium. As a proof of concept, a compact multi-doped ENZ cavity is fabricated and experimentally characterized, whose transmission spectrum is manifested as a multi-bit reconfigurable frequency comb. The dispersion coding is demonstrated to fuel a batch of innovative applications including dynamically tunable comb-like dispersion profiled filters, radio-frequency identification tags, etc.
