目的:探讨加味桃红四物汤(MTSD)对视网膜Müller细胞rMC-1缺氧损伤的保护作用。方法:用加味桃红四物汤含药血清干预缺氧条件下rMC-1细胞,随机分为正常对照组(21%O_(2))、缺氧模型组(1%O_(2))、含药血清低(1%O_(2)+5%含药血清)、中(1...目的:探讨加味桃红四物汤(MTSD)对视网膜Müller细胞rMC-1缺氧损伤的保护作用。方法:用加味桃红四物汤含药血清干预缺氧条件下rMC-1细胞,随机分为正常对照组(21%O_(2))、缺氧模型组(1%O_(2))、含药血清低(1%O_(2)+5%含药血清)、中(1%O_(2)+10%含药血清)、高剂量组(1%O_(2)+15%含药血清),CCK-8法检测细胞的活力,ELISA法检测血管内皮生长因子(VEGF)和色素上皮衍生因子(PEDF)分泌,Western blot检测磷酸化转录激活因子3(p-STAT3)、转录激活因子3(STAT3)和缺氧诱导因子-1α(HIF-1α)的蛋白表达,Real time PCR检测VEGF、PEDF、STAT3和HIF-1α的基因表达。结果:在1%O_(2)条件下培养48h,rMC-1细胞活力较正常对照组明显受到抑制(P<0.05),加味桃红四物汤含药血清低、中剂量组均可以改善rMC-1细胞缺氧48h的细胞存活率(P<0.05),而高剂量组无改善作用(P>0.05)。加味桃红四物汤含药血清低、中剂量组均可减少缺氧条件下rMC-1细胞上清液VEGF的蛋白表达量(P<0.05),但不能增加PEDF的蛋白含量(P>0.05),对p-STAT3和HIF-1α在蛋白水平均有下调作用(P<0.05),且低剂量组抑制作用优于中剂量(P<0.05)。加味桃红四物汤含药血清中剂量组对缺氧后rMC-1细胞STAT3的蛋白表达有上调作用(P<0.05)。加味桃红四物汤含药血清低、中剂量组对缺氧后rMC-1细胞VEGF基因表达均有下调作用(P<0.05),对PEDF基因表达均有上调作用(P<0.05),且低剂量组优于中剂量(P<0.05);并且加味桃红四物汤含药血清低剂量可下调缺氧后STAT3和HIF-1α的基因表达(P<0.05)。结论:加味桃红四物汤含药血清可能通过抑制STAT3/HIF-1α通路,下调缺氧诱导的视网膜Müller细胞rMC-1的VEGF蛋白和基因表达,上调PEDF基因表达,减轻该细胞的缺氧损伤。展开更多
The transcription factor Sox11 plays important roles in retinal neurogenesis during vertebrate eye development.However,its function in retina regeneration remains elusive.Here we report that Sox11 b,a zebrafish Sox11 ...The transcription factor Sox11 plays important roles in retinal neurogenesis during vertebrate eye development.However,its function in retina regeneration remains elusive.Here we report that Sox11 b,a zebrafish Sox11 homolog,regulates the migration and fate determination of Müller glia-derived progenitors(MGPCs)in an adult zebrafish model of mechanical retinal injury.Following a stab injury,the expression of Sox11 b was induced in proliferating MGPCs in the retina.Sox11 b knockdown did not affect MGPC formation at 4 days post-injury,although the nuclear morphology and subsequent radial migration of MGPCs were alte red.At 7 days post-injury,Sox11 b knockdown res ulted in an increased proportion of MGPCs in the inner retina and a decreased propo rtion of MGPCs in the outer nuclear layer,compared with controls.Furthermore,Sox11 b knockdown led to reduced photoreceptor regeneration,while it increased the numbe rs of newborn amacrines and retinal ganglion cells.Finally,quantitative polymerase chain reaction analysis revealed that Sox11 b regulated the expression of Notch signaling components in the retina,and Notch inhibition partially recapitulated the Sox11 b knockdown phenotype,indicating that Notch signaling functions downstream of Sox11 b.Our findings imply that Sox11 b plays key roles in MGPC migration and fate determination during retina regeneration in zebrafish,which may have critical im plications for future explorations of retinal repair in mammals.展开更多
The majority of inherited retinal degenerative diseases and dry age-related macular degeneration are characterized by decay of the outer retina and photoreceptors,which leads to progressive loss of vision.The inner re...The majority of inherited retinal degenerative diseases and dry age-related macular degeneration are characterized by decay of the outer retina and photoreceptors,which leads to progressive loss of vision.The inner retina,including second-and third-order retinal neurons,also shows aberrant structural changes at all stages of degeneration.Müller glia,the major glial cells maintain retinal homeostasis,activating and rearranging immediately in response to photoreceptor stress.These phenomena are collectively known as retinal remodeling and are anatomically well described,but their impact on visual function is less well characterized.Retinal remodeling has traditionally been considered a detrimental chain of events that decreases visual function.However,emerging evidence from functional assays suggests that remodeling could also be a part of a survival mechanism wherein the inner retina responds plastically to outer retinal degeneration.The visual system’s first synapses between the photoreceptors and bipolar cells undergo rewiring and functionally compensate to maintain normal signal output to the brain.Distinct classes of retinal ganglion cells remain even after the massive loss of photoreceptors.Müller glia possess the regenerative potential for retinal recovery and possibly exert adaptive transcriptional changes in response to neuronal loss.These types of homeostatic changes could potentially explain the well-maintained visual function observed in patients with inherited retinal degenerative diseases who display prominent anatomic retinal pathology.This review will focus on our current understanding of retinal neuronal and Müller glial adaptation for the potential preservation of retinal activity during photoreceptor degeneration.Targeting retinal self-compensatory responses could help generate universal strategies to delay sensory disease progression.展开更多
The onset of retinal degenerative disease is often associated with neuronal loss. Therefore, how to regenerate new neurons to restore vision is an important issue. NeuroD1 is a neural transcription factor with the abi...The onset of retinal degenerative disease is often associated with neuronal loss. Therefore, how to regenerate new neurons to restore vision is an important issue. NeuroD1 is a neural transcription factor with the ability to reprogram brain astrocytes into neurons in vivo. Here, we demonstrate that in adult mice, NeuroD1 can reprogram Müller cells, the principal glial cell type in the retina, to become retinal neurons. Most strikingly, ectopic expression of NeuroD1 using two different viral vectors converted Müller cells into different cell types. Specifically, AAV7 m8 GFAP681::GFP-ND1 converted Müller cells into inner retinal neurons, including amacrine cells and ganglion cells. In contrast, AAV9 GFAP104::ND1-GFP converted Müller cells into outer retinal neurons such as photoreceptors and horizontal cells, with higher conversion efficiency. Furthermore, we demonstrate that Müller cell conversion induced by AAV9 GFAP104::ND1-GFP displayed clear dose-and time-dependence. These results indicate that Müller cells in adult mice are highly plastic and can be reprogrammed into various subtypes of retinal neurons.展开更多
文摘目的:探讨加味桃红四物汤(MTSD)对视网膜Müller细胞rMC-1缺氧损伤的保护作用。方法:用加味桃红四物汤含药血清干预缺氧条件下rMC-1细胞,随机分为正常对照组(21%O_(2))、缺氧模型组(1%O_(2))、含药血清低(1%O_(2)+5%含药血清)、中(1%O_(2)+10%含药血清)、高剂量组(1%O_(2)+15%含药血清),CCK-8法检测细胞的活力,ELISA法检测血管内皮生长因子(VEGF)和色素上皮衍生因子(PEDF)分泌,Western blot检测磷酸化转录激活因子3(p-STAT3)、转录激活因子3(STAT3)和缺氧诱导因子-1α(HIF-1α)的蛋白表达,Real time PCR检测VEGF、PEDF、STAT3和HIF-1α的基因表达。结果:在1%O_(2)条件下培养48h,rMC-1细胞活力较正常对照组明显受到抑制(P<0.05),加味桃红四物汤含药血清低、中剂量组均可以改善rMC-1细胞缺氧48h的细胞存活率(P<0.05),而高剂量组无改善作用(P>0.05)。加味桃红四物汤含药血清低、中剂量组均可减少缺氧条件下rMC-1细胞上清液VEGF的蛋白表达量(P<0.05),但不能增加PEDF的蛋白含量(P>0.05),对p-STAT3和HIF-1α在蛋白水平均有下调作用(P<0.05),且低剂量组抑制作用优于中剂量(P<0.05)。加味桃红四物汤含药血清中剂量组对缺氧后rMC-1细胞STAT3的蛋白表达有上调作用(P<0.05)。加味桃红四物汤含药血清低、中剂量组对缺氧后rMC-1细胞VEGF基因表达均有下调作用(P<0.05),对PEDF基因表达均有上调作用(P<0.05),且低剂量组优于中剂量(P<0.05);并且加味桃红四物汤含药血清低剂量可下调缺氧后STAT3和HIF-1α的基因表达(P<0.05)。结论:加味桃红四物汤含药血清可能通过抑制STAT3/HIF-1α通路,下调缺氧诱导的视网膜Müller细胞rMC-1的VEGF蛋白和基因表达,上调PEDF基因表达,减轻该细胞的缺氧损伤。
基金supported by the National Key Research and Development Project of China,Nos.2017YFA0104100(to JL),2017YFA0701304(to HX)National Natural Science Foundation of China Nos.81970820(to HX),31930068(to JL)。
文摘The transcription factor Sox11 plays important roles in retinal neurogenesis during vertebrate eye development.However,its function in retina regeneration remains elusive.Here we report that Sox11 b,a zebrafish Sox11 homolog,regulates the migration and fate determination of Müller glia-derived progenitors(MGPCs)in an adult zebrafish model of mechanical retinal injury.Following a stab injury,the expression of Sox11 b was induced in proliferating MGPCs in the retina.Sox11 b knockdown did not affect MGPC formation at 4 days post-injury,although the nuclear morphology and subsequent radial migration of MGPCs were alte red.At 7 days post-injury,Sox11 b knockdown res ulted in an increased proportion of MGPCs in the inner retina and a decreased propo rtion of MGPCs in the outer nuclear layer,compared with controls.Furthermore,Sox11 b knockdown led to reduced photoreceptor regeneration,while it increased the numbe rs of newborn amacrines and retinal ganglion cells.Finally,quantitative polymerase chain reaction analysis revealed that Sox11 b regulated the expression of Notch signaling components in the retina,and Notch inhibition partially recapitulated the Sox11 b knockdown phenotype,indicating that Notch signaling functions downstream of Sox11 b.Our findings imply that Sox11 b plays key roles in MGPC migration and fate determination during retina regeneration in zebrafish,which may have critical im plications for future explorations of retinal repair in mammals.
基金supported by NIH R01EY032492Boston Children’s Hospital(OFD/BTREC/CTREC Faculty Career Development Grant 97906,Pilot Grant 92214,and Ophthalmology Foundation 85010)+5 种基金Mass Lions Eye Foundation 87820Blind Children’s Center 89282(to ZF)Academy of Finland grant 346295Finnish Eye and Tissue Bank FoundationRetina Registered Association(Finland)Sokeain Yst?v?t/De Blindas V?nner Registered Association(to HOL)。
文摘The majority of inherited retinal degenerative diseases and dry age-related macular degeneration are characterized by decay of the outer retina and photoreceptors,which leads to progressive loss of vision.The inner retina,including second-and third-order retinal neurons,also shows aberrant structural changes at all stages of degeneration.Müller glia,the major glial cells maintain retinal homeostasis,activating and rearranging immediately in response to photoreceptor stress.These phenomena are collectively known as retinal remodeling and are anatomically well described,but their impact on visual function is less well characterized.Retinal remodeling has traditionally been considered a detrimental chain of events that decreases visual function.However,emerging evidence from functional assays suggests that remodeling could also be a part of a survival mechanism wherein the inner retina responds plastically to outer retinal degeneration.The visual system’s first synapses between the photoreceptors and bipolar cells undergo rewiring and functionally compensate to maintain normal signal output to the brain.Distinct classes of retinal ganglion cells remain even after the massive loss of photoreceptors.Müller glia possess the regenerative potential for retinal recovery and possibly exert adaptive transcriptional changes in response to neuronal loss.These types of homeostatic changes could potentially explain the well-maintained visual function observed in patients with inherited retinal degenerative diseases who display prominent anatomic retinal pathology.This review will focus on our current understanding of retinal neuronal and Müller glial adaptation for the potential preservation of retinal activity during photoreceptor degeneration.Targeting retinal self-compensatory responses could help generate universal strategies to delay sensory disease progression.
基金supported by the Guangdong Grant Key Technologies for Treatment of Brain Disorders,China,No. 2018B030332001 (to GC)the Guangzhou Key Projects of Brain Science and Brain-Like Intelligence Technology,No. 20200730009 (to YX)the Guangdong Basic and Applied Basic Research Foundation,No. 2020A1515110898 (to WYC)。
文摘The onset of retinal degenerative disease is often associated with neuronal loss. Therefore, how to regenerate new neurons to restore vision is an important issue. NeuroD1 is a neural transcription factor with the ability to reprogram brain astrocytes into neurons in vivo. Here, we demonstrate that in adult mice, NeuroD1 can reprogram Müller cells, the principal glial cell type in the retina, to become retinal neurons. Most strikingly, ectopic expression of NeuroD1 using two different viral vectors converted Müller cells into different cell types. Specifically, AAV7 m8 GFAP681::GFP-ND1 converted Müller cells into inner retinal neurons, including amacrine cells and ganglion cells. In contrast, AAV9 GFAP104::ND1-GFP converted Müller cells into outer retinal neurons such as photoreceptors and horizontal cells, with higher conversion efficiency. Furthermore, we demonstrate that Müller cell conversion induced by AAV9 GFAP104::ND1-GFP displayed clear dose-and time-dependence. These results indicate that Müller cells in adult mice are highly plastic and can be reprogrammed into various subtypes of retinal neurons.