Upon encountering external challenges,immune cell recognition of response to pathogens constitutes a pivotal physiological process.Here,we designed and engineering an artificial immune signal transduction system utili...Upon encountering external challenges,immune cell recognition of response to pathogens constitutes a pivotal physiological process.Here,we designed and engineering an artificial immune signal transduction system utilizing DNA strands and liposomes to simulate antigen signals presentation,i.e.,the uptake and processing of antigens by antigen-presenting cells(APCs).Through controlled DNA strand displacement reactions,we engineered artificial antigen-presenting cells(mAPCs)that display antigen signals on their surface and mimic phagocytosis.To further simulate antigen presentation,we constructed mimic naïve T cells(mTCs).Then,deoxyribonucleic acid(DNA)ion channels across mTCs membranes,simulating Tcell receptors,were opened by DNA strands on mAPCs mimicking the major histocompatibility complex(MHC),i.e.,MHC molecules that present peptides to the T-cell receptor(TCR)on mTCs(recognition).This allowed Ca^(2+)ions to enter mTCs,increasing calcein fluorescence as activated mTC response indicator.The DNA strands on the surface of A-mAPCs and the Ca^(2+)ions in the solution together act like costimulatory molecules on APCs to trigger responses of mTCs.This simulation of immune signal transduction provides a significant reference value for the construction of bioinspired signal transduction systems and the design of more realistic artificial biological systems.展开更多
Inspired by the light-dependent signal transduction in nature, we herein report a fully synthetic receptor AZO with the capacity of transmembrane signaling, working by photo-induced change of molecular conformation. O...Inspired by the light-dependent signal transduction in nature, we herein report a fully synthetic receptor AZO with the capacity of transmembrane signaling, working by photo-induced change of molecular conformation. Our receptor has an anchoring group, a rigid and photoresponsive transmembrane unit and a precatalyst tailgroup. After doping in lipid membranes, AZO is membrane anchored and the extended trans-isomer enables the tailgroup to bind with intravesicular Zn^(2+), thereby achieving enzyme activation and triggering downstream events(ester hydrolysis). However, the shortened cis-isomer pulls the tailgroup into lipids, thereby preventing the complexation and all transduction processes. Upon alternative irradiation of ultraviolet(UV) and visible light, the transduction process can be reversible switch between“ON” and “OFF”, achieving light signal transduction. This study provides a new strategy for future design of artificial signal transduction receptors.展开更多
Infertility has become one of the most serious diseases worldwide,and 50% of this disease can be attributed to male-related factors.Spermatogenesis,by definition,is a complex process by which spermatogonial stem cells...Infertility has become one of the most serious diseases worldwide,and 50% of this disease can be attributed to male-related factors.Spermatogenesis,by definition,is a complex process by which spermatogonial stem cells(SSCs)self-renew to maintain stem cell population within the testes and differentiate into mature spermatids.It is of great significance to uncover gene regulation and signaling pathways that are involved in the fate determinations of SSCs with aims to better understand molecular mechanisms underlying human spermatogenesis and identify novel targets for gene therapy of male infertility.Significant achievement has recently been made in demonstrating the signaling molecules and pathways mediating the fate decisions of mammalian SSCs.In this review,we address key gene regulation and crucial signaling transduction pathways in controlling the self-renewal,differentiation,and apoptosis of SSCs,and we illustrate the networks of genes and signaling pathways in SSC fate determinations.We also highlight perspectives and future directions in SSC regulation by genes and their signaling pathways.This review could provide novel insights into the genetic regulation of normal and abnormal spermatogenesis and offer molecular targets to develop new approaches for gene therapy of male infertility.展开更多
To cope with unpredictably environmental perturbations and sometimes stresses, plants have evolved with some mechanisms so that these developing stresses can be sensitively perceived and the physiology can be rapidl...To cope with unpredictably environmental perturbations and sometimes stresses, plants have evolved with some mechanisms so that these developing stresses can be sensitively perceived and the physiology can be rapidly regulated. Such perception and regulation can be a kind of feed_forward mechanism and may involve many biochemical and physiological processes and/or the expression of many genes. Although many dehydration_responsive genes have been identified, much fewer of their functions have been known. Such stress_ induced responses should include the initial perception of the dehydration signal, then the complicated signal transduction and cellular transmission until to the final gene activation or expression. As an important plant stress hormone abscisic acid (ABA) mediates many such responses. We believe that starting from the initial perception of dehydration to the gene expression leading to the stress_induced ABA biosynthesis is the most important stress signal transduction pathway among all the plant responses to stresses. Identification of the genes involved and understanding their roles during stress perception and physiological regulation shall be the most important and interesting research field in the coming years.展开更多
Abscisic acid (ABA) plays an important role in plant growth and developmental processes. Although some ABA signal molecules, such as cADPR, Ca2+, etc., have been reported, there. was no evidence proving the involvemen...Abscisic acid (ABA) plays an important role in plant growth and developmental processes. Although some ABA signal molecules, such as cADPR, Ca2+, etc., have been reported, there. was no evidence proving the involvement of cAMP in A-B-A, signal transduction. In this present study, the constructed gene ( rd29A-GUS) was transformed into Nicotiana tabacum, and calli was induced from the transgenic plant. The suspension cells obtained from the callus grew well and uniformly. Treatment of the suspension cells with ABA led to an increase in GUS activity, indicating that these transgenic suspension cells are useful for the study of ABA signaling. Addition of nicotinamide (cADPR inhibitor) or U-73122 (phospholiphase C inhibitor) could only partially inhibit the increase of GUS activity elicited by ABA. The inhibitory effect of nicotinamide was enhanced by application of K252a (inhibitor of protein kinase). Treatment of the suspension cells with 8-Br-cAMP, a membrane-permeable analogue of cAMP, could partially replace the effect of ABA. Furthermore, intracellular addition of IBMX (phosphodiesterase inhibitor) mimicked die effect of exogenous cAMP on the deduction of expression of rd29A promoter. These results suggested that cAMP was an important messenger in ABA signal transduction in tobacco suspension cell.展开更多
The immune responses of plants to foreign pathogens have developed relevant defense mechanisms, which formed complicated disease resistant signal transduction pathways. Salicylic acid(SA), jasmonic acid(JA)/Ethyl...The immune responses of plants to foreign pathogens have developed relevant defense mechanisms, which formed complicated disease resistant signal transduction pathways. Salicylic acid(SA), jasmonic acid(JA)/Ethylene(ET) and brassi- nosteroid (BR) could trigger the immune response to different pathogens in plants, making the plants show some resistance to the pathogens. The study on the trans- duction pathways of these three disease-resistant signals were introduced to provide some useful suggestions for the study on the transduction of disease-resistant sig- nals in plants.展开更多
The growth factor receptor-bound protein 2 (Grb2) -associated binder (Gab) proteins are intracellular scaffolding/ docking molecules,and participate in multiple signaling pathways,usually acting as the downstream ...The growth factor receptor-bound protein 2 (Grb2) -associated binder (Gab) proteins are intracellular scaffolding/ docking molecules,and participate in multiple signaling pathways,usually acting as the downstream effector of protein-tyrosine kinases (PTKs) -triggered signal transduction pathway.When phosphorylated by PTKs,Gab proteins can recruit several signaling molecules (p85,SHP2,and Crk) ,and subsequently activate multiple transmitting signals that are critical for cell growth,survival,differentiation and apoptosis.Recently,it has been reported that Gab2 polymorphism is associated with the increase in the risk of Alzheimer’s disease (AD) and is involved in the pathogenesis of AD.This review mainly focuses on the structure and function of Gab2 protein and its role in the pathogenesis of AD.展开更多
Advances of studies on the acupuncture and pain signal transduction mechanisms in complete Freud's adjuvant arthritis are reviewed from the three aspects, the first messenger of modulating pain signals and the relate...Advances of studies on the acupuncture and pain signal transduction mechanisms in complete Freud's adjuvant arthritis are reviewed from the three aspects, the first messenger of modulating pain signals and the related receptors, the second messenger of modulating pain signals and other factors possibly involved in modulation of pain signal transduction, etc. It is held that modulation of acupuncture for pain signals is a comprehensive course involved in multi-channels, multi-levels, multi-links, and in future, acupuncture analgesic mechanisms for Freud's adjuvant arthritis will be more deeply studied by use of more new techniques and new methods.展开更多
椎间盘由髓核、纤维环和软骨终板组成,对维持脊柱正常生理功能至关重要。椎间盘退变(intervertebral disc degeneration,IDD)是导致腰背痛等脊柱退行性疾病的主要病理基础,给人们的健康状况造成极大的困扰。然而目前对IDD的分子机制仍...椎间盘由髓核、纤维环和软骨终板组成,对维持脊柱正常生理功能至关重要。椎间盘退变(intervertebral disc degeneration,IDD)是导致腰背痛等脊柱退行性疾病的主要病理基础,给人们的健康状况造成极大的困扰。然而目前对IDD的分子机制仍然缺乏清晰的了解,导致缺乏有效的靶向干预措施。RAS同源家族成员A(RAS homolog family member A,RhoA)/Rho相关蛋白激酶(Rho-associated protein kinase,ROCK)信号通路是调节细胞收缩、迁移和生长的经典通路。其被激活后可参与调控细胞骨架重塑、细胞外基质代谢、生物钟节律、细胞表型改变、细胞衰老及死亡等环节,进而影响IDD的病理进程。深入探究RhoA/ROCK信号通路在IDD中的作用,不仅能揭示疾病发生的分子生物学机制,也有望为研发靶向该通路的治疗策略提供理论依据。展开更多
Tunneling nanotubes are crucial structures for cellular communication and are observed in a variety of cell types.Glial cells,the most abundant cells in the nervous system,play a vital role in intercellular signaling ...Tunneling nanotubes are crucial structures for cellular communication and are observed in a variety of cell types.Glial cells,the most abundant cells in the nervous system,play a vital role in intercellular signaling and can show abnormal activation under pathological conditions.Our bibliometric analysis indicated a substantial increase in research on tunneling nanotubes over the past two decades,highlighting their important role in cellular communication.This review focuses on the formation of tunneling nanotubes in various types of glial cells,including astrocytes,microglia,glioma cells,and Schwann cells,as well as their roles in cellular communication and cargo transport.We found that glial cells influence the stability of the neural system and play a role in nerve regeneration through tunneling nanotubes.Tunneling nanotubes facilitate the transmission and progression of diseases by transporting pathogens and harmful substances.However,they are also involved in alleviating cellular stress by removing toxins and delivering essential nutrients.Understanding the interactions between glial cells through tunneling nanotubes could provide valuable insights into the complex neural networks that govern brain function and responses to injury.展开更多
After billions of years of evolution,biological intelligence has converged on unrivalled energy efficiency and environmental adaptability.The human brain,for instance,is highly efficient in information transmission,co...After billions of years of evolution,biological intelligence has converged on unrivalled energy efficiency and environmental adaptability.The human brain,for instance,is highly efficient in information transmission,consuming only about 20 W onaverage in a resting state[1,2].A key to this efficiency is that biological signal transduction and processing rely significantly on multi-ions as the signal carriers.Inspired by this paradigm.展开更多
As sessile organisms,plants must adapt various stresses.Accordingly,they have evolved several plant-specific growth and developmental processes.WRKY53 is a member of the WRKY transcription factor family,which plays a ...As sessile organisms,plants must adapt various stresses.Accordingly,they have evolved several plant-specific growth and developmental processes.WRKY53 is a member of the WRKY transcription factor family,which plays a crucial role in rice growth and development,stress response,and hormone signal transduction.This review discusses the role of WRKY53 in stress response,focusing on its functions in cold tolerance,salt tolerance,disease resistance,and pest defense,and explores its role in regulating rice leaf senescence and seed germination.This article also proposes future research directions,including functional genomics studies,protein interaction network analyses,hormone signal transduction pathways,genetic improvement strategies,applications of gene editing technologies,molecular basis of stress responses,cross-species functional conservation,and bioinformatics and comparative genomics research.This review highlights the importance of WRKY53 in rice biology and provides new perspectives and strategies for future research and genetic improvement of rice.展开更多
Alzheimer’s disease-associated transcriptomic landscapes have been defined in brain tissue.However,changes in blood RNA and their clinical relevance remain poorly understood.In this study,we developed an RNA profile ...Alzheimer’s disease-associated transcriptomic landscapes have been defined in brain tissue.However,changes in blood RNA and their clinical relevance remain poorly understood.In this study,we developed an RNA profile based on 1468 blood samples from both human and mouse studies,which include bulk RNA sequencing(RNA-seq),microRNA-seq,and single-cell RNA-seq data.We developed a comprehensive analysis pipeline that conducted over 11 million comparisons and correlations to identify more than 20,000 blood features.With these findings,we established a blood RNA database related to Alzheimer’s disease,RNAs in Blood of AD(RBAD,http://www.bioinform.cn/RBAD/).Using RBAD,we initially validated well-established Alzheimer’s disease-related pathways,including olfactory transduction.We then observed a decrease in both the proportion and functionality of erythroid cells,likely attributed to their elevated CD45 levels and interactions with GZMK^(+)CD8^(+)T cells.Furthermore,we identified 449 blood RNAs linked to patients’overall survival,along with two mRNAs(H4C3 and CTU1)associated with cognitive decline.In summary,RBAD is the first web-based analysis platform dedicated to investigating blood RNA changes in Alzheimer’s disease,and provides valuable insights into potential peripheral biomarkers and pathogenic mechanisms related to Alzheimer’s disease.展开更多
Objective:Osteoarthritis(OA)is a degenerative joint disease characterized by extracellular matrix(ECM)degradation,chondrocyte apoptosis,and chronic inflammation.Cartilage destruction and ECM degeneration contribute to...Objective:Osteoarthritis(OA)is a degenerative joint disease characterized by extracellular matrix(ECM)degradation,chondrocyte apoptosis,and chronic inflammation.Cartilage destruction and ECM degeneration contribute to joint function loss and disability.Signal transducer and activator of transcription 3(STAT3)up-regulates the expression of MMP-13,which degrades collagen Ⅱ.Our previous study found that 5,7,3',4'-tetramethoxyflavone(TMF)exhibited protective effects on OA chondrocytes.This study aims to investigate the protective role of TMF in inhibiting ECM degradation by mediating the Sirt1/STAT3 signaling pathway.Methods:Rat OA models were established by the injection of monosodium iodoacetate(MIA).Hematoxylin&eosin(HE)staining and immunohistochemistry(IHC)analysis were performed.IL-1β stimulated C28/I2 cells were used as OA-like chondrocyte cell model.Western blotting assays were used to determine the protein expression.Results:The expression of MMP-13 was upregulated while type Ⅱ collagen expression is downregulated,and the phosphorylation level of STAT3 is increased in rat OA models.TMF reverses the STAT3-mediated expression of MMP-13 and type v collagen.Activation of STAT3 or inhibition of Sirt1 function attenuates the inhibitory effect of TMF on ECM degradation.Conclusion:TMF can inhibit ECM degradation mediated by the STAT3 signal pathway by activating Sirt1 expression in OA cell and animal models.展开更多
There are two degradation systems in mammalian cells, autophagy/lysosomal pathway and ubiquitin-proteasome pathway. Proteasome is consist of multiple protein subunits and plays important roles in degradation of short-...There are two degradation systems in mammalian cells, autophagy/lysosomal pathway and ubiquitin-proteasome pathway. Proteasome is consist of multiple protein subunits and plays important roles in degradation of short-lived cellular proteins. Recent studies reveal that proteasomal degradation system is also involved in signal transduction and regulation of various cellular functions. Dysfunction or dysregulation of proteasomal function may thus be an important pathogenic mechanism in certain neurological disorders. This paper reviews the biological functions of proteasome in signal transduction and its potential roles in neurodegenerative diseases.展开更多
基金supported by the National Natural Science Foundation of China(No.82002241)National Key Research and Development Program of China(No.2020YFA0909000)“Clinic Plus”Outstanding Project(No.2024ZY012)from Shanghai Key Laboratory for Nucleic Acid Chemistry and Nanomedicine。
文摘Upon encountering external challenges,immune cell recognition of response to pathogens constitutes a pivotal physiological process.Here,we designed and engineering an artificial immune signal transduction system utilizing DNA strands and liposomes to simulate antigen signals presentation,i.e.,the uptake and processing of antigens by antigen-presenting cells(APCs).Through controlled DNA strand displacement reactions,we engineered artificial antigen-presenting cells(mAPCs)that display antigen signals on their surface and mimic phagocytosis.To further simulate antigen presentation,we constructed mimic naïve T cells(mTCs).Then,deoxyribonucleic acid(DNA)ion channels across mTCs membranes,simulating Tcell receptors,were opened by DNA strands on mAPCs mimicking the major histocompatibility complex(MHC),i.e.,MHC molecules that present peptides to the T-cell receptor(TCR)on mTCs(recognition).This allowed Ca^(2+)ions to enter mTCs,increasing calcein fluorescence as activated mTC response indicator.The DNA strands on the surface of A-mAPCs and the Ca^(2+)ions in the solution together act like costimulatory molecules on APCs to trigger responses of mTCs.This simulation of immune signal transduction provides a significant reference value for the construction of bioinspired signal transduction systems and the design of more realistic artificial biological systems.
基金supported by the National Natural Science Foundation of China (No. 22171085)Shanghai Frontier Science Research Base of Optogenetic Techniques for Cell Metabolism (Shanghai Municipal Education Commission, No. 2021 Sci & Tech 03–28)。
文摘Inspired by the light-dependent signal transduction in nature, we herein report a fully synthetic receptor AZO with the capacity of transmembrane signaling, working by photo-induced change of molecular conformation. Our receptor has an anchoring group, a rigid and photoresponsive transmembrane unit and a precatalyst tailgroup. After doping in lipid membranes, AZO is membrane anchored and the extended trans-isomer enables the tailgroup to bind with intravesicular Zn^(2+), thereby achieving enzyme activation and triggering downstream events(ester hydrolysis). However, the shortened cis-isomer pulls the tailgroup into lipids, thereby preventing the complexation and all transduction processes. Upon alternative irradiation of ultraviolet(UV) and visible light, the transduction process can be reversible switch between“ON” and “OFF”, achieving light signal transduction. This study provides a new strategy for future design of artificial signal transduction receptors.
基金supported by the grants from the National Nature Science Foundation of China(No.32170862)Major Scientific and Technological Projects for Collaborative Prevention and Control of Birth Defect in Hunan Province(No.2019SK1012)+1 种基金the Research Team for Reproduction Health and Translational Medicine of Hunan Normal University(No.2023JC101)Graduate Scientific Research Innovation Project of Hunan Province,China(No.CX2022520).
文摘Infertility has become one of the most serious diseases worldwide,and 50% of this disease can be attributed to male-related factors.Spermatogenesis,by definition,is a complex process by which spermatogonial stem cells(SSCs)self-renew to maintain stem cell population within the testes and differentiate into mature spermatids.It is of great significance to uncover gene regulation and signaling pathways that are involved in the fate determinations of SSCs with aims to better understand molecular mechanisms underlying human spermatogenesis and identify novel targets for gene therapy of male infertility.Significant achievement has recently been made in demonstrating the signaling molecules and pathways mediating the fate decisions of mammalian SSCs.In this review,we address key gene regulation and crucial signaling transduction pathways in controlling the self-renewal,differentiation,and apoptosis of SSCs,and we illustrate the networks of genes and signaling pathways in SSC fate determinations.We also highlight perspectives and future directions in SSC regulation by genes and their signaling pathways.This review could provide novel insights into the genetic regulation of normal and abnormal spermatogenesis and offer molecular targets to develop new approaches for gene therapy of male infertility.
文摘To cope with unpredictably environmental perturbations and sometimes stresses, plants have evolved with some mechanisms so that these developing stresses can be sensitively perceived and the physiology can be rapidly regulated. Such perception and regulation can be a kind of feed_forward mechanism and may involve many biochemical and physiological processes and/or the expression of many genes. Although many dehydration_responsive genes have been identified, much fewer of their functions have been known. Such stress_ induced responses should include the initial perception of the dehydration signal, then the complicated signal transduction and cellular transmission until to the final gene activation or expression. As an important plant stress hormone abscisic acid (ABA) mediates many such responses. We believe that starting from the initial perception of dehydration to the gene expression leading to the stress_induced ABA biosynthesis is the most important stress signal transduction pathway among all the plant responses to stresses. Identification of the genes involved and understanding their roles during stress perception and physiological regulation shall be the most important and interesting research field in the coming years.
文摘Abscisic acid (ABA) plays an important role in plant growth and developmental processes. Although some ABA signal molecules, such as cADPR, Ca2+, etc., have been reported, there. was no evidence proving the involvement of cAMP in A-B-A, signal transduction. In this present study, the constructed gene ( rd29A-GUS) was transformed into Nicotiana tabacum, and calli was induced from the transgenic plant. The suspension cells obtained from the callus grew well and uniformly. Treatment of the suspension cells with ABA led to an increase in GUS activity, indicating that these transgenic suspension cells are useful for the study of ABA signaling. Addition of nicotinamide (cADPR inhibitor) or U-73122 (phospholiphase C inhibitor) could only partially inhibit the increase of GUS activity elicited by ABA. The inhibitory effect of nicotinamide was enhanced by application of K252a (inhibitor of protein kinase). Treatment of the suspension cells with 8-Br-cAMP, a membrane-permeable analogue of cAMP, could partially replace the effect of ABA. Furthermore, intracellular addition of IBMX (phosphodiesterase inhibitor) mimicked die effect of exogenous cAMP on the deduction of expression of rd29A promoter. These results suggested that cAMP was an important messenger in ABA signal transduction in tobacco suspension cell.
基金Supported by the National Natural Science Foundation of China(31360262)Zhuke Contract(2012HK209-38)the Innovation Capacity Platform Construction Project of Guizhou Science and Technology Department(2011018)~~
文摘The immune responses of plants to foreign pathogens have developed relevant defense mechanisms, which formed complicated disease resistant signal transduction pathways. Salicylic acid(SA), jasmonic acid(JA)/Ethylene(ET) and brassi- nosteroid (BR) could trigger the immune response to different pathogens in plants, making the plants show some resistance to the pathogens. The study on the trans- duction pathways of these three disease-resistant signals were introduced to provide some useful suggestions for the study on the transduction of disease-resistant sig- nals in plants.
基金supported by the National Basic Research Development Program of China(No.2006CB500706)the National Natural Science Foundation of China(No.30700251,30872729,30971031)+1 种基金Shanghai Key Discipline Program(No.S30202)the Program for Out-standing Medical Academic Leader(No.LJ 06003)
文摘The growth factor receptor-bound protein 2 (Grb2) -associated binder (Gab) proteins are intracellular scaffolding/ docking molecules,and participate in multiple signaling pathways,usually acting as the downstream effector of protein-tyrosine kinases (PTKs) -triggered signal transduction pathway.When phosphorylated by PTKs,Gab proteins can recruit several signaling molecules (p85,SHP2,and Crk) ,and subsequently activate multiple transmitting signals that are critical for cell growth,survival,differentiation and apoptosis.Recently,it has been reported that Gab2 polymorphism is associated with the increase in the risk of Alzheimer’s disease (AD) and is involved in the pathogenesis of AD.This review mainly focuses on the structure and function of Gab2 protein and its role in the pathogenesis of AD.
基金Supported by Scientific Research Project Foundation of Shanghai City Science and Technology Committee:07dz19722-5
文摘Advances of studies on the acupuncture and pain signal transduction mechanisms in complete Freud's adjuvant arthritis are reviewed from the three aspects, the first messenger of modulating pain signals and the related receptors, the second messenger of modulating pain signals and other factors possibly involved in modulation of pain signal transduction, etc. It is held that modulation of acupuncture for pain signals is a comprehensive course involved in multi-channels, multi-levels, multi-links, and in future, acupuncture analgesic mechanisms for Freud's adjuvant arthritis will be more deeply studied by use of more new techniques and new methods.
文摘椎间盘由髓核、纤维环和软骨终板组成,对维持脊柱正常生理功能至关重要。椎间盘退变(intervertebral disc degeneration,IDD)是导致腰背痛等脊柱退行性疾病的主要病理基础,给人们的健康状况造成极大的困扰。然而目前对IDD的分子机制仍然缺乏清晰的了解,导致缺乏有效的靶向干预措施。RAS同源家族成员A(RAS homolog family member A,RhoA)/Rho相关蛋白激酶(Rho-associated protein kinase,ROCK)信号通路是调节细胞收缩、迁移和生长的经典通路。其被激活后可参与调控细胞骨架重塑、细胞外基质代谢、生物钟节律、细胞表型改变、细胞衰老及死亡等环节,进而影响IDD的病理进程。深入探究RhoA/ROCK信号通路在IDD中的作用,不仅能揭示疾病发生的分子生物学机制,也有望为研发靶向该通路的治疗策略提供理论依据。
基金supported by the National Natural Science Foundation of China,No.82101115(to JY)the Wuhan University Independent Innovation Fund Youth Project,No.2042021kf0094(to JY).
文摘Tunneling nanotubes are crucial structures for cellular communication and are observed in a variety of cell types.Glial cells,the most abundant cells in the nervous system,play a vital role in intercellular signaling and can show abnormal activation under pathological conditions.Our bibliometric analysis indicated a substantial increase in research on tunneling nanotubes over the past two decades,highlighting their important role in cellular communication.This review focuses on the formation of tunneling nanotubes in various types of glial cells,including astrocytes,microglia,glioma cells,and Schwann cells,as well as their roles in cellular communication and cargo transport.We found that glial cells influence the stability of the neural system and play a role in nerve regeneration through tunneling nanotubes.Tunneling nanotubes facilitate the transmission and progression of diseases by transporting pathogens and harmful substances.However,they are also involved in alleviating cellular stress by removing toxins and delivering essential nutrients.Understanding the interactions between glial cells through tunneling nanotubes could provide valuable insights into the complex neural networks that govern brain function and responses to injury.
文摘After billions of years of evolution,biological intelligence has converged on unrivalled energy efficiency and environmental adaptability.The human brain,for instance,is highly efficient in information transmission,consuming only about 20 W onaverage in a resting state[1,2].A key to this efficiency is that biological signal transduction and processing rely significantly on multi-ions as the signal carriers.Inspired by this paradigm.
基金supported by the Hubei Provincial Natural Science Foundation,China(Grant No.2024AFB917).
文摘As sessile organisms,plants must adapt various stresses.Accordingly,they have evolved several plant-specific growth and developmental processes.WRKY53 is a member of the WRKY transcription factor family,which plays a crucial role in rice growth and development,stress response,and hormone signal transduction.This review discusses the role of WRKY53 in stress response,focusing on its functions in cold tolerance,salt tolerance,disease resistance,and pest defense,and explores its role in regulating rice leaf senescence and seed germination.This article also proposes future research directions,including functional genomics studies,protein interaction network analyses,hormone signal transduction pathways,genetic improvement strategies,applications of gene editing technologies,molecular basis of stress responses,cross-species functional conservation,and bioinformatics and comparative genomics research.This review highlights the importance of WRKY53 in rice biology and provides new perspectives and strategies for future research and genetic improvement of rice.
基金supported by Research and Innovation Foundation of Wuhan Asia General Hospital,No.2022KYCX1-B10(to FH)the Natural ScienceFoundation of Hubei Province,No.2023AFB550(to FH)+2 种基金the National Natural Science Foundation of China,Nos.32400554(to FH),82371444(to YZ)theGuiding Project of the Scientific Research Program of the Department of Education of Hubei Province,No.B2021016(to FH)the Natural Science Foundationof Hubei Province,No.2024AFB853(to QW).
文摘Alzheimer’s disease-associated transcriptomic landscapes have been defined in brain tissue.However,changes in blood RNA and their clinical relevance remain poorly understood.In this study,we developed an RNA profile based on 1468 blood samples from both human and mouse studies,which include bulk RNA sequencing(RNA-seq),microRNA-seq,and single-cell RNA-seq data.We developed a comprehensive analysis pipeline that conducted over 11 million comparisons and correlations to identify more than 20,000 blood features.With these findings,we established a blood RNA database related to Alzheimer’s disease,RNAs in Blood of AD(RBAD,http://www.bioinform.cn/RBAD/).Using RBAD,we initially validated well-established Alzheimer’s disease-related pathways,including olfactory transduction.We then observed a decrease in both the proportion and functionality of erythroid cells,likely attributed to their elevated CD45 levels and interactions with GZMK^(+)CD8^(+)T cells.Furthermore,we identified 449 blood RNAs linked to patients’overall survival,along with two mRNAs(H4C3 and CTU1)associated with cognitive decline.In summary,RBAD is the first web-based analysis platform dedicated to investigating blood RNA changes in Alzheimer’s disease,and provides valuable insights into potential peripheral biomarkers and pathogenic mechanisms related to Alzheimer’s disease.
基金Project Supported by Jiangxi Provincial Natural Science Foundation(20212ACB206002)。
文摘Objective:Osteoarthritis(OA)is a degenerative joint disease characterized by extracellular matrix(ECM)degradation,chondrocyte apoptosis,and chronic inflammation.Cartilage destruction and ECM degeneration contribute to joint function loss and disability.Signal transducer and activator of transcription 3(STAT3)up-regulates the expression of MMP-13,which degrades collagen Ⅱ.Our previous study found that 5,7,3',4'-tetramethoxyflavone(TMF)exhibited protective effects on OA chondrocytes.This study aims to investigate the protective role of TMF in inhibiting ECM degradation by mediating the Sirt1/STAT3 signaling pathway.Methods:Rat OA models were established by the injection of monosodium iodoacetate(MIA).Hematoxylin&eosin(HE)staining and immunohistochemistry(IHC)analysis were performed.IL-1β stimulated C28/I2 cells were used as OA-like chondrocyte cell model.Western blotting assays were used to determine the protein expression.Results:The expression of MMP-13 was upregulated while type Ⅱ collagen expression is downregulated,and the phosphorylation level of STAT3 is increased in rat OA models.TMF reverses the STAT3-mediated expression of MMP-13 and type v collagen.Activation of STAT3 or inhibition of Sirt1 function attenuates the inhibitory effect of TMF on ECM degradation.Conclusion:TMF can inhibit ECM degradation mediated by the STAT3 signal pathway by activating Sirt1 expression in OA cell and animal models.
基金This work was supported by the National Natural Science Foundation of China (No. 30470587, No. 30600197).
文摘There are two degradation systems in mammalian cells, autophagy/lysosomal pathway and ubiquitin-proteasome pathway. Proteasome is consist of multiple protein subunits and plays important roles in degradation of short-lived cellular proteins. Recent studies reveal that proteasomal degradation system is also involved in signal transduction and regulation of various cellular functions. Dysfunction or dysregulation of proteasomal function may thus be an important pathogenic mechanism in certain neurological disorders. This paper reviews the biological functions of proteasome in signal transduction and its potential roles in neurodegenerative diseases.
