Zanthoxylum bungeanum is an economically important crop worldwide due to its high content of aroma-producing monoterpenoids,and development of varieties with enhanced flavor and overall quality is a crucial research a...Zanthoxylum bungeanum is an economically important crop worldwide due to its high content of aroma-producing monoterpenoids,and development of varieties with enhanced flavor and overall quality is a crucial research area.However,the transcriptional regulatory mechanisms underlying monoterpenoid synthesis in Z.bungeanum remain unclear,hindering these breeding efforts.In this study,RNA sequencing,gas chromatography–mass spectrometry,and other molecular biology techniques were used to identify the underlying transcriptional regulation mechanisms.Two transcription factors,ZbbHLH2 and ZbERF6,were identified as key regulators of monoterpenoid synthesis in Z.bungeanum that upregulate various monoterpenoid synthesis-associated genes and are novel transcriptional activators of ZbIDI,which encodes the rate-limiting enzyme in plant monoterpenoid synthesis.Functional analysis revealed that the expression of three genes[1]modulates monoterpenoid accumulation in Z.bungeanum peel.These findings provide novel insights into the metabolic regulatory network of monoterpenoid synthesis in Z.bungeanum peel,offer potential strategies for the biofortification of specific monoterpenoids,and will promote the development of Z.bungeanum germplasm for targeted breeding and quality improvement.展开更多
Background:The regulatory mechanisms governing vasculogenic mimicry(VM)in oral squamous cell carcinoma(OSCC)remain largely undefined.This study aimed to identify critical factors and elucidate the epigenetic mechanism...Background:The regulatory mechanisms governing vasculogenic mimicry(VM)in oral squamous cell carcinoma(OSCC)remain largely undefined.This study aimed to identify critical factors and elucidate the epigenetic mechanisms underlying VM in OSCC.Methods:Bioinformatics analysis was performed utilizing single-cell RNA-seq,bulk RNA-seq,and histone H3 lysine 27 acetylation(H3K27ac)Chromatin Immunoprecipitation(ChIP)-seq data obtained from The Cancer Genome Atlas(TCGA)and Gene Expression Omnibus(GEO)databases.ChIP-qPCR was used to validate the binding of ETS transcription factor ELK4(ELK4)to the dihydrofolate reductase(DHFR)enhancer.In vitro VM formation and invasion of OSCC cells were assessed using Matrigel-based tube formation and Transwell assays,respectively.Results:Elevated expression of VM-related genes predicts unfavorable prognosis in OSCC patients.High-dimensional weighted gene co-expression network analysis(hdWGCNA)identified epithelial subcluster C4 as most strongly associated with VM and metastasis.Three co-expression modules within this subcluster exhibited significant positive correlations with both phenotypic traits.Among the 30 eigengenes from the three modules,DHFR emerged as a key regulator of VM and metastasis.Knockdown or inhibition of DHFR significantly suppressed VM formation and invasion in OSCC cells.Mechanistically,ELK4 activated DHFR transcription through direct binding to its enhancer.DHFR overexpression rescued VM and invasion impairment induced by ELK4 knockdown.Conclusion:DHFR was a pivotal enhancer-regulated gene driving VM and metastasis in OSCC.ELK4 directly binds to DHFR enhancer regions to activate its transcription,thereby promoting these malignant phenotypes.These findings identified the ELK4/DHFR axis as a promising therapeutic target for anti-angiogenic intervention in OSCC.展开更多
AIM:To investigate whether vaccinia-related kinase 1(VRK1)mediates transforming growth factor-beta2(TGF-β2)-caused epithelial-mesenchymal transition(EMT)and inflammatory responses in retinal pigment epithelial(RPE)ce...AIM:To investigate whether vaccinia-related kinase 1(VRK1)mediates transforming growth factor-beta2(TGF-β2)-caused epithelial-mesenchymal transition(EMT)and inflammatory responses in retinal pigment epithelial(RPE)cells through regulating snail family transcriptional repressor 1(SNAI1),and to validate its role in a proliferative vitreoretinopathy(PVR)mouse model.METHODS:Human RPE cell line ARPE-19 cells were treated with TGF-β2 to construct an EMT model.Western blot detected VRK1 level.The effects of VRK1 on SNAI1 expression and biological behavior of ARPE-19 cells were detected by immunofluorescence,ELISA,Transwell,and scratch assay,and the interaction between VRK1 and SNAI1 was confirmed through immunoprecipitation.A PVR mouse model was constructed,and the effects of VRK1 or/and SNAI1 on retinal damage were assessed by pathologic staining.Inflammatory factors and EMT-related proteins were assessed with ELISA and Western blot.RESULTS:VRK1 was upregulated in ARPE-19 cells after TGF-β2 treatment.Overexpression of VRK1 increased cell viability,promoted cell migration and EMT,and the levels of inflammatory factors.Silencing of VRK1 reversed the above indexes.There was a direct interaction between VRK1 and SNAI1,and overexpresssion SNAI1 weakened the impacts of silencing of VRK1.In PVR mice,silencing of VRK1 ameliorated retinal structural damage,decreased proinflammatory factor levels,and suppressed SNAI1 and mesenchymal marker expression.SNAI1 overexpression antagonized the protective effects of silencing VRK1 and exacerbated EMT and inflammatory responses.CONCLUSION:VRK1 plays a key role in retinal structural and inflammatory damage in PVR mice by regulating SNAI1 and mediating TGF-β2-caused EMT and inflammatory responses in RPE cells.展开更多
Objective The basic helix-loop-helix(bHLH)transcription factors(TFs)are pivotal in regulating fungal growth,development,and secondary metabolism.However,the knowledge about the Ganoderma lucidum bHLHs(GlbHLHs)in ganod...Objective The basic helix-loop-helix(bHLH)transcription factors(TFs)are pivotal in regulating fungal growth,development,and secondary metabolism.However,the knowledge about the Ganoderma lucidum bHLHs(GlbHLHs)in ganoderic acid(GA)biosynthesis of G.lucidum was limited.This study aimed to explore the functions of bHLH genes in ganoderic acid biosynthesis during G.lucidum growth development.Methods First,the genome-wide identification of GlbHLHs was performed through Hidden Markov model searches and Two-way blast.Furthermore,through physicochemical properties,gene structure,and phylogenetic analysis,as well as combining the transcriptome and metabolome data from different developmental stages of G.lucidum,candidate GlbHLHs were screened.Subsequently,their regulatory roles in ganoderic acid biosynthesis were explored using yeast one-hybrid and dual-luciferase reporter assays.Results A total of 11 GlbHLH members were characterized in G.lucidum.The upstream promoter regions of these genes enriched hormones and abiotic stress responsive elements.Although individual ganoderic acid monomers demonstrated marked differences in accumulation patterns across specific growth phases and tissue types,overall,the total GA content was consistently higher in caps than in stipes throughout development.In addition,all GlbHLHs exhibited high expression in whole G.lucidum from the primordium to maturation stages.Among them,GlbHLH5 and GlbHLH7 showed the highest expression in any stage and highly correlated with key genes associated with GA pathway.Functional validation through dual-luciferase assays and yeast one-hybrid experiments had demonstrated that GlbHLH5 activated the P2 region of the lanosterol synthase promoter,while GlbHLH7 activated the promoters of squalene epoxidase and squalene synthase.Conclusion Compared to plants,G.lucidum harbored a small number of bHLH members but all high expression in any stages.Additionally,GlbHLH5 and GlbHLH7 with the highest expression among GlbHLHs showed activation in regulating the biosynthesis of GA.These results provide a theoretical reference for further research on ganoderic acid regulation in G.lucidum,and thereby providing a molecular foundation for enhancing ganoderic acid yield to optimize the medicinal value of G.lucidum.展开更多
Objective:Leucine-rich alpha-2 glycoprotein 1(Lrg1)could regulate diverse cells in cerebral ischemiareperfusion.Our study seeks to uncover Lrg1’s impact on endothelial cell heterogeneity via differentiation pathways ...Objective:Leucine-rich alpha-2 glycoprotein 1(Lrg1)could regulate diverse cells in cerebral ischemiareperfusion.Our study seeks to uncover Lrg1’s impact on endothelial cell heterogeneity via differentiation pathways and transcription factors.Method:The CSOmap model measured cell-to-brain-center distances using single-cell RNA sequencing(scRNA-seq)data in middle cerebral artery occlusion reperfusion(MCAO/R).Monocle2 mapped endothelial differentiation paths.Gene set enrichment analysis(GSEA)analyzed endothelial subcluster variations.Database searches revealed a zinc finger MIZ-type containing 1 protein-frizzled 3(Zmiz1-Fzd3)promoter interaction.Endothelial cells were transfected with a Fzd3 promoter-luciferase plasmid.Polymerase chain reaction(PCR)and western blotting assessed MCAO/R or Zmiz1 overexpression effects on Fzd3-related mRNA and proteins.A retroviral vector carrying Zmiz1 was injected into the brains of mice to study its effect on Fzd3.Result:Lrg1−/−mice exhibited elevated cell adhesion proteins and decreased microvascular leakage after MCAO/R.CSOmap showed widened astrocyte spacing in thesemice.RSS revealed Zmiz1 overexpression inMCAO/R+Lrg1−/−mice.MCAO/R and pcDNA3-Zmiz1 transfection both enhanced luciferase activity with Fzd3,indicating Zmiz1 binding to Fzd3.Retroviral Zmiz1 injection or knockdown disrupted ischemic brain tight junctions,highlighting Zmiz1’s key role in blood-brain barrier protection,likely through Fzd3 pathway modulation.Conclusion:The findings indicate Lrg1 knockout induces endothelial differentiation by activating Zmiz1,which is crucial for maintaining blood-brain barrier function,possibly via modulating the Fzd3 pathway.展开更多
Objectives:The current treatment options and therapeutic targets for triple-negative breast cancer(TNBC),an aggressive subtype of breast cancer(BrCA),are limited.This study aimed to identify novel biomarkers and trans...Objectives:The current treatment options and therapeutic targets for triple-negative breast cancer(TNBC),an aggressive subtype of breast cancer(BrCA),are limited.This study aimed to identify novel biomarkers and transcriptional regulatory networks(TRN)inherent in TNBC samples.Methods:We analyzed pan-cancer BrCA datasets from The Cancer Genome Atlas(TCGA)to compare triple-positive breast cancer(TPBC)with TNBC.TRN algorithms and virtual inference of protein-enriched regulon(VIPER)were used to identify master regulators and their target genes.Utilizing TNBC cells(MDA-MB-231 and MDA-MB-468),we validated the relationship of nuclear factor erythroid 2-like 3(NFE2L3)and basic helix-loop-helix family member E 40(BHLHE40)by performing a luciferase assay.The expression levels of these targets were measured after transfections with plasmid and siRNA via qRT-PCR and western blots.The effect of these genes on cell proliferation and migration was studied using phenotypic assays.Results:Using computational approaches,we identified NFE2L3 as a master regulator with BHLHE40 as its target gene.NFE2L3 protein binds to the promoter region of BHLHE40 and regulates its transcriptional activity.Additionally,silencing and overexpressing NFE2L3 and BHLHE40 in TNBC cell lines MDA-MB-231 and MDA-MB-468 showed that NFE2L3 directly regulates BHLHE40 at both transcriptional and translational levels.We found that BHLHE40 requires NFE2L3 for cell proliferation and migration in TNBC.Conclusion:These findings underscore the significance of NFE2L3 and BHLHE40 in TNBC,highlighting NFE2L3’s role in regulating the oncogenic activity of BHLHE40 in TNBC cells.展开更多
Tomato is an important economic crop all over the world.Volatile flavors in tomato fruit are key factors influencing consumer liking and commercial quality.However,the regulatory mechanism controlling the volatile fla...Tomato is an important economic crop all over the world.Volatile flavors in tomato fruit are key factors influencing consumer liking and commercial quality.However,the regulatory mechanism controlling the volatile flavors of tomatoes is still not clear.Here,we integrated the metabolome and transcriptome of the volatile flavors in tomato fruit to explore the regulatory mechanism of volatile flavor formation,using wild and cultivated tomatoes with significant differences in flavors.A total of 35 volatile flavor compounds were identified,based on the solid phase microextraction-gas chromatography-mass spectrometry(SPME-GC-MS).The content of the volatiles,affecting fruit flavor,significantly increased in the transition from breaker to red ripe fruit stage.Moreover,the total content of the volatiles in wild tomatoes was much higher than that in the cultivated tomatoes.The content variations of all volatile flavors were clustered into 10 groups by hierarchical cluster and Pearson coefficient correlation(PCC)analysis.The fruit transcriptome was also patterned into 10 groups,with significant variations both from the mature green to breaker fruit stage and from the breaker to red ripe fruit stage.Combining the metabolome and the transcriptome of the same developmental stage of fruits by co-expression analysis,we found that the expression level of 1182 genes was highly correlated with the content of volatile flavor compounds,thereby constructing two regulatory pathways of important volatile flavors.One pathway is tetrahydrothiazolidine N-hydroxylase(SlTNH1)-dependent,which is regulated by two transcription factors(TFs)from the bHLH and AP2/ERF families,controlling the synthesis of 2-isobutylthiazole in amino acid metabolism.The other is lipoxygenase(Sl LOX)-dependent,which is regulated by one TF from the HD-Zip family,controlling the synthesis of hexanal and(Z)-2-heptenal in fatty acid metabolism.Dual-luciferase assay confirmed the binding of b HLH and AP2/ERF to their structural genes.The findings of this study provide new insights into volatile flavor formation in tomato fruit,which can be useful for tomato flavor improvement.展开更多
Tomato(Solanum lycopersicum)is an important fruit and vegetable crop in worldwide.The fertility of tomato reproductive organs can be dramatically decreased when ambient temperatures rise above 35°C,reducing tomat...Tomato(Solanum lycopersicum)is an important fruit and vegetable crop in worldwide.The fertility of tomato reproductive organs can be dramatically decreased when ambient temperatures rise above 35°C,reducing tomato fruit yield.It is necessary to identify transcription factors(TFs)and target genes involved in heat stress response(HSR)signaling cascades in tomato flower buds to improve tomato plant thermotolerance.In this study,we profiled genes expressed in three developmental stages of tomato flower buds.Red and turquoise modules for heat stress(HS)were identified through gene co-expression network analysis,and the genes within these modules were enriched in HS-related pathways.By focusing on the TFs in the two modules,we identified several novel HSR-related TFs,including SlWRKY75,SlMYB117,and SlNAM.Furthermore,homology analysis illustrated a conserved signaling cascade in tomato.Lastly,we identified and experimentally validated four HSF-regulated genes,namely SlGrpE,SlERDJ3A,SlTIL,and SlPOM1,that likely modulate thermotolerance in plants.These results provide a high-resolution atlas of gene expression during tomato flower bud development under HS conditions,which is a valuable resource for uncovering potential regulatory networks associated with the HSR in tomato.展开更多
bHLH transcription factors,widely exist in various plants,and are vital for the growth and development of these plants.Among them,many have been implicated in anthocyanin biosynthesis across various plants.In the pres...bHLH transcription factors,widely exist in various plants,and are vital for the growth and development of these plants.Among them,many have been implicated in anthocyanin biosynthesis across various plants.In the present study,a PdbHLH57 gene,belonging to the bHLH IIIf group,was characterized,which was isolated and cloned from the colored-leaf poplar‘Zhongshancaiyun’(ZSCY).The cDNA sequence of PdbHLH57 was 1887 base pairs,and the protein encoded by PdbHLH57 had 628 amino acids,the isoelectric point and molecular weight of which were 6.26 and 69.75 kDa,respectively.Through bioinformatics analysis,PdbHLH57 has been classified into the IIIf bHLH subgroup,with many members of this subgroup known to participate in anthocyanin biosynthesis.The subcellular localization analysis conducted in the leaf protoplasts of‘ZSCY’revealed that the PdbHLH57 protein is specifically localized in the nucleus.The transcription activation analysis was also conducted,and the results showed that the PdbHLH57 protein had self-transcription activation.To better explore the functions of the PdbHLH57 protein,two parts of this protein(PdbHLH57-1,PdbHLH57-2)were split to detect their transcriptional activation activity.The results indicated that PdbHLH57-1(1-433aa)had self-transcription activation,and PdbHLH57-2(433-628aa)had no transcription activation.The expression of PdbHLH57 peaked in June during different developmental stages in‘ZSCY’,and it was most highly expressed in the phloem among various tissues.These findings offer a basis for understanding the role of PdbHLH57 in colored-leaf poplar.展开更多
Myeloblastosis(MYB)transcription factors(TFs)are evolutionarily conserved regulatory proteins that are crucial for plantgrowth,development,secondarymetabolism,andstress adaptation.Recent studieshavehighlighted their c...Myeloblastosis(MYB)transcription factors(TFs)are evolutionarily conserved regulatory proteins that are crucial for plantgrowth,development,secondarymetabolism,andstress adaptation.Recent studieshavehighlighted their crucial role in coordinating growth–defense trade-offs through transcriptional regulation of key biosynthetic and stress-response genes.Despite extensive functional characterization in model plants such as Arabidopsis thaliana,systematically evaluating the broader functional landscape of MYB TFs across diverse species and contexts remains necessary.This systematic review integrates results from 24 peer-reviewed studies sourced from Scopus and Web of Science,focusing on the functional diversity of MYB TFs,particularly in relation to abiotic stress tolerance,metabolic regulation,and plant developmental processes.Advances in genomic technologies,such as transcriptomics,genome editing,and comparative phylogenetics,have considerably enhanced our understanding of MYB-mediated regulatory mechanisms.These tools have facilitated the identification and functional characterization of MYB genes across model and non-model plant species.Key findings underscore the multifaceted roles of MYB TFs in enhancing stress resilience,modulating anthocyanin and flavonoid biosynthesis,and contributing to yield-related traits,thereby highlighting their potential applications in crop improvement and sustainable agriculture.However,critical gaps exist in understanding MYB interactions within complex regulatory networks,particularly in underrepresented plant species and ecological contexts.This review consolidates current knowledge as well as identifies research gaps and proposes future directions to advance the understanding and application of MYB TFs.The insights derived from this study underscore their transformative potential in addressing global challenges including food security and climate resilience through innovative agricultural practices.展开更多
Commercial cultivars of garlic,a popular condiment,are sterile,making genetic variation and germplasm innovation of this plant challenging.Understanding mechanism of gamete sterility in garlic and their key regulatory...Commercial cultivars of garlic,a popular condiment,are sterile,making genetic variation and germplasm innovation of this plant challenging.Understanding mechanism of gamete sterility in garlic and their key regulatory networks is therefore important for fertility restoration.In this work,we conducted a detailed phenotypic analysis of fertile and sterile garlic genotypes and found that enlargement of topset in the inflorescence of sterile genotypes led to abnormal flowers.Additional cytological observations showed that aberrant meiotic cytokinesis in sterile garlic ultimately resulted in pollen degeneration.Transcriptomics analysis of sterile and fertile genotypes identified possible molecular mechanisms underlying gamete abortion.A total of 100710 differentially expressed genes(DEGs)between the fertile and sterile garlic flowers at three stages of gamete development were identified,many of which were involved in homologous chromosome synapsis during meiosis,MYB transcription factor regulation,ribosome biogenesis and plant hormone signal transduction.Taken together,these results provide insight into the molecular mechanisms and regulatory networks underlying gamete development in garlic and point to a set of candidate genes for further functional characterization.展开更多
Retinal aging has been recognized as a significant risk factor for various retinal disorders,including diabetic retinopathy,age-related macular degeneration,and glaucoma,following a growing understanding of the molecu...Retinal aging has been recognized as a significant risk factor for various retinal disorders,including diabetic retinopathy,age-related macular degeneration,and glaucoma,following a growing understanding of the molecular underpinnings of their development.This comprehensive review explores the mechanisms of retinal aging and investigates potential neuroprotective approaches,focusing on the activation of transcription factor EB.Recent meta-analyses have demonstrated promising outcomes of transcription factor EB-targeted strategies,such as exercise,calorie restriction,rapamycin,and metformin,in patients and animal models of these common retinal diseases.The review critically assesses the role of transcription factor EB in retinal biology during aging,its neuroprotective effects,and its therapeutic potential for retinal disorders.The impact of transcription factor EB on retinal aging is cell-specific,influencing metabolic reprogramming and energy homeostasis in retinal neurons through the regulation of mitochondrial quality control and nutrient-sensing pathways.In vascular endothelial cells,transcription factor EB controls important processes,including endothelial cell proliferation,endothelial tube formation,and nitric oxide levels,thereby influencing the inner blood-retinal barrier,angiogenesis,and retinal microvasculature.Additionally,transcription factor EB affects vascular smooth muscle cells,inhibiting vascular calcification and atherogenesis.In retinal pigment epithelial cells,transcription factor EB modulates functions such as autophagy,lysosomal dynamics,and clearance of the aging pigment lipofuscin,thereby promoting photoreceptor survival and regulating vascular endothelial growth factor A expression involved in neovascularization.These cell-specific functions of transcription factor EB significantly impact retinal aging mechanisms encompassing proteostasis,neuronal synapse plasticity,energy metabolism,microvasculature,and inflammation,ultimately offering protection against retinal aging and diseases.The review emphasizes transcription factor EB as a potential therapeutic target for retinal diseases.Therefore,it is imperative to obtain well-controlled direct experimental evidence to confirm the efficacy of transcription factor EB modulation in retinal diseases while minimizing its risk of adverse effects.展开更多
The NAC(NAM,ATAF1/2,and CUC2)is a defense-associated transcription factor(TF)family that positively regulates defense responses to pathogen infection.TaNAC069 positively regulates resistance in wheat to Puccinia triti...The NAC(NAM,ATAF1/2,and CUC2)is a defense-associated transcription factor(TF)family that positively regulates defense responses to pathogen infection.TaNAC069 positively regulates resistance in wheat to Puccinia triticina(Pt).However,the molecular mechanism of its interaction with a Pt effector is not clear.We found that Pt effector Pt-1234 interacts with TaNAC069 to subvert host immunity during Pt infection.Quantitative real-time PCR analysis showed that expression of Pt-1234 was significantly upregulated during the early stage of Pt infection.Protein-mediated cell death assays in wheat showed that the Pt-1234 protein was unable to induce cell death in wheat near-isogenic lines carrying different leaf rust resistance genes,whereas it suppressed BAX-induced cell death in leaves of Nicotiana benthamiana.Silencing of Pt-1234 by host-induced gene silencing(HIGS)significantly reduced the virulence of Pt in the susceptible wheat variety Thatcher.The C subdomain of TaNAC069 was responsible for its interaction with Pt-1234,and the E subdomain was required for TaNAC069-mediated defense responses to Pt in planta.These findings indicate that Pt utilizes Pt-1234 to interact with wheat transcription factor TaNAC069 through its C subdomain,thereby modulating wheat immunity.展开更多
The emergence of novel phytopathogens and the accelerated spread of plant diseases to new regions,driven by global climate change,constitute significant threats to agricultural resources.Rice,a major tropical staple c...The emergence of novel phytopathogens and the accelerated spread of plant diseases to new regions,driven by global climate change,constitute significant threats to agricultural resources.Rice,a major tropical staple crucial for global food security,possesses six transcription factor superfamilies-AP2/ERF,bHLH,bZIP,MYB,NAC,and WRKY-that function in innate immunity against pathogens.We review their biological functions and regulatory mechanisms in rice immunity.展开更多
Magnolol,a compound extracted from Magnolia officinalis,demonstrates potential efficacy in addressing metabolic dysfunction and cardiovascular diseases.Its biological activities encompass anti-inflammatory,antioxidant...Magnolol,a compound extracted from Magnolia officinalis,demonstrates potential efficacy in addressing metabolic dysfunction and cardiovascular diseases.Its biological activities encompass anti-inflammatory,antioxidant,anticoagulant,and anti-diabetic effects.Growth/differentiation factor-15(GDF-15),a member of the transforming growth factorβsuperfamily,is considered a potential therapeutic target for metabolic disorders.This study investigated the impact of magnolol on GDF-15 production and its underlying mechanism.The research examined the pharmacological effect of magnolol on GDF-15 expression in vitro and in vivo,and determined the involvement of endoplasmic reticulum(ER)stress signaling in this process.Luciferase reporter assays,chromatin immunoprecipitation,and in vitro DNA binding assays were employed to examine the regulation of GDF-15 by activating transcription factor 4(ATF4),CCAAT enhancer binding proteinγ(CEBPG),and CCCTC-binding factor(CTCF).The study also investigated the effect of magnolol and ATF4 on the activity of a putative enhancer located in the intron of the GDF-15 gene,as well as the influence of single nucleotide polymorphisms(SNPs)on magnolol and ATF4-induced transcription activity.Results demonstrated that magnolol triggers GDF-15 production in endothelial cells(ECs),hepatoma cell line G2(HepG2)and hepatoma cell line 3B(Hep3B)cell lines,and primary mouse hepatocytes.The cooperative binding of ATF4 and CEBPG upstream of the GDF-15 gene or the E1944285 enhancer located in the intron led to full-power transcription of the GDF-15 gene.SNP alleles were found to impact the magnolol and ATF4-induced transcription activity of GDF-15.In high-fat diet ApoE^(-/-)mice,administration of magnolol induced GDF-15 production and partially suppressed appetite through GDF-15.These findings suggest that magnolol regulates GDF-15 expression through priming of promoter and enhancer activity,indicating its potential as a drug for the treatment of metabolic disorders.展开更多
BACKGROUND Diabetic retinopathy(DR)is a major microvascular complication of diabetes mellitus,leading to significant visual impairment and blindness among adults.Current treatment options are limited,making it essenti...BACKGROUND Diabetic retinopathy(DR)is a major microvascular complication of diabetes mellitus,leading to significant visual impairment and blindness among adults.Current treatment options are limited,making it essential to explore novel therapeutic strategies.Curcumol,a sesquiterpenoid derived from traditional Chinese medicine,has shown anti-inflammatory and anti-cancer properties,but its potential role in DR remains unclear.AIM To investigate the therapeutic effects of curcumol on the progression of DR and to elucidate the underlying molecular mechanisms,particularly its impact on the fat mass and obesity-associated(FTO)protein and the long non-coding RNA(lncRNA)MAF transcription factor G antisense RNA 1(MAFG-AS1).METHODS A streptozotocin-induced mouse model of DR was established,followed by treatment with curcumol.Retinal damage and inflammation were evaluated through histological analysis and molecular assays.Human retinal vascular endothelial cells were exposed to high glucose conditions to simulate diabetic environments in vitro.Cell proliferation,migration,and inflammation markers were assessed in curcumoltreated cells.LncRNA microarray analysis identified key molecules regulated by curcumol,and further experiments were conducted to confirm the involvement of FTO and MAFG-AS1 in the progression of DR.RESULTS Curcumol treatment significantly reduced blood glucose levels and alleviated retinal damage in streptozotocininduced DR mouse models.In high-glucose-treated human retinal vascular endothelial cells,curcumol inhibited cell proliferation,migration,and inflammatory responses.LncRNA microarray analysis identified MAFG-AS1 as the most upregulated lncRNA following curcumol treatment.Mechanistically,FTO demethylated MAFG-AS1,stabilizing its expression.Rescue experiments demonstrated that the protective effects of curcumol against DR were mediated through the FTO/MAFG-AS1 signaling pathway.CONCLUSION Curcumol ameliorates the progression of DR by modulating the FTO/MAFG-AS1 axis,providing a novel therapeutic pathway for the treatment of DR.These findings suggest that curcumol-based therapies could offer a promising alternative for managing this debilitating complication of diabetes.展开更多
Loss-of-function variants of low-density lipoprotein receptor-related protein 5(LRP5)can lead to reduced bone formation,culminating in diminished bone mass.Our previous study reported transcription factor osterix(SP7)...Loss-of-function variants of low-density lipoprotein receptor-related protein 5(LRP5)can lead to reduced bone formation,culminating in diminished bone mass.Our previous study reported transcription factor osterix(SP7)-binding sites on the LRP5 promoter and its pivotal role in upregulating LRP5 expression during implant osseointegration.However,the potential role of SP7 in ameliorating LRP5-dependent osteoporosis remained unknown.In this study,we used mice with a conditional knockout(c KO)of LRP5 in mature osteoblasts,which presented decreased osteogenesis.The in vitro experimental results showed that SP7 could promote LRP5 expression,thereby upregulating the osteogenic markers such as alkaline phosphatase(ALP),Runt-related transcription factor 2(Runx2),andβ-catenin(P<0.05).For the in vivo experiment,the SP7 overexpression virus was injected into a bone defect model of LRP5 c KO mice,resulting in increased bone mineral density(BMD)(P<0.001)and volumetric density(bone volume(BV)/total volume(TV))(P<0.001),and decreased trabecular separation(Tb.Sp)(P<0.05).These data suggested that SP7 could ameliorate bone defect healing in LRP5 c KO mice.Our study provides new insights into potential therapeutic opportunities for ameliorating LRP5-dependent osteoporosis.展开更多
Objective:Polycystic ovary syndrome(PCOS)is a common endocrine disorder that affects women’s health.This study aims to investigate gene and transcription factor(TF)expression differences between PCOS patients and hea...Objective:Polycystic ovary syndrome(PCOS)is a common endocrine disorder that affects women’s health.This study aims to investigate gene and transcription factor(TF)expression differences between PCOS patients and healthy individuals using bioinformatics approaches,and to verify the function of key transcription factors,with the goal of providing new insights into the pathogenesis of PCOS.Methods:Differentially expressed genes(DEGs)and differentially expressed transcription factors(DETFs)between PCOS patients and controls were identified from the RNA sequencing dataset GSE168404 using bioinformatics methods.Functional enrichment analysis was performed using Gene Ontology(GO)and Kyoto Encyclopedia of Genes and Genomes(KEGG)databases.The expression and function of core transcription factors were further validated in ovarian tissues of PCOS model mice and control mice using Western blotting and reverse transcription quantitative polymerase chain reaction(RTqPCR).Results:A total of 332 DEGs were identified between PCOS patients and controls,including 259 upregulated and 73 downregulated genes in the PCOS group.19 DETFs were further screened,of which 16 were upregulated and 3 were downregulated in PCOS.The upregulated DETFs(including TFCP2L1,DACH1,ESR2,AFF3,SMAD9,ZNF331,HOPX,ATOH8,HIF3α,DPF3,HOXC4,HES1,ID1,JDP2,SOX4,and ID3)were primarily associated with lipid metabolism,development,and cell adhesion.Protein and mRNA expression analysis in PCOS model mice revealed significantly decreased levels of hypoxia-inducible factor(HIF)1αand HIF2α,and significantly increased expression of HIF3αcompared to control mice(all P<0.001).Conclusion:Significant differences in gene and TF expression exist between PCOS patients and healthy individuals.HIF-3αmay play a crucial role in PCOS and could serve as a novel biomarker for diagnosis and a potential therapeutic target.展开更多
Fruit ripening is a complex developmental process tightly regulated by hormonal crosstalk,transcriptional networks,and epigenetic modifications,with striking divergence between climacteric and non-climacteric species....Fruit ripening is a complex developmental process tightly regulated by hormonal crosstalk,transcriptional networks,and epigenetic modifications,with striking divergence between climacteric and non-climacteric species.In climacteric fruits,such as tomatoes,apples,and bananas,ethylene acts as the master regulator,driving autocatalytic biosynthesis through ACS/ACO genes and activating hierarchical transcriptional cascades mediated by MADS-box(RIN),NAC(NOR),and ERF-family transcription factors.These pathways are amplified by epigenetic reprogramming,including DNA demethylation at ripening-related promoters and histone acetylation,which enhance chromatin accessibility to facilitate gene expression.Conversely,non-climacteric fruits like strawberries and grapes predominantly rely on abscisic acid(ABA)to coordinate ripening.Hormonal interplay,such as ethylene-ABA synergy in climacteric fruit systems,further fine-tunes ripening dynamics.Advances in CRISPR-based gene editing and epigenome engineering now enable precise manipulation of these pathways,offering transformative solutions to reduce postharvest losses,enhance nutritional quality,and improve climate resilience.This review integrates mechanistic insights across species,emphasizing opportunities to translate fundamental discoveries into sustainable agricultural innovations,from breeding nutrient-rich cultivars to optimizing postharvest technologies for global food security.展开更多
Background:E26 transformation-specific(ETS)family transcription factors have confirmed roles in several types of cancers.This study aimed to clarify the role of ETS family transcription factor alterations in gastric c...Background:E26 transformation-specific(ETS)family transcription factors have confirmed roles in several types of cancers.This study aimed to clarify the role of ETS family transcription factor alterations in gastric cancers.Methods:This study examines molecular alterations of ETS transcription factors in gastric adenocarcinomas based on an analysis of publicly available cohorts from the Protein Atlas and the Cancer Genome Atlas.The expression and relationships of members of the ETS transcription factor family with other important factors in the process of gastric carcinogenesis were evaluated using the same resources.Results:mRNA expression levels of ETS family members in gastric carcinoma tissues were variable,with ELF3,ETS2,EHF,ERF,and ELF1 being the family members with the highest expression.Mutations in individual transcription factors of the ETS family were rare in gastric cancers.The family member ELF3 was well expressed in the mRNA level in a subset of gastric cancers(n=91),and its expression correlated with the expression of other transcription factors involved in gastric cancer pathogenesis,including HNF4A,HNF1A,CDX2,GATA4,GATA6,and EHF.Cancers with high co-expression of ELF3 and HNF4A were frequently chromosomally instability(CIN),intestinal-type adenocarcinomas,and harbored TP53 mutations and WWOX deletions.Conclusion:Expression of E74 like ETS transcription factor 3(ELF3),an ETS transcription family member,correlates with expression of other key factors in gastric cancer and confers specific characteristics that may become exploited in targeted therapeutic interventions.展开更多
基金supported by the National Natural Science Foundation of China(31872706)the National Key Research and Development Program of China(2019 YFD1000603).
文摘Zanthoxylum bungeanum is an economically important crop worldwide due to its high content of aroma-producing monoterpenoids,and development of varieties with enhanced flavor and overall quality is a crucial research area.However,the transcriptional regulatory mechanisms underlying monoterpenoid synthesis in Z.bungeanum remain unclear,hindering these breeding efforts.In this study,RNA sequencing,gas chromatography–mass spectrometry,and other molecular biology techniques were used to identify the underlying transcriptional regulation mechanisms.Two transcription factors,ZbbHLH2 and ZbERF6,were identified as key regulators of monoterpenoid synthesis in Z.bungeanum that upregulate various monoterpenoid synthesis-associated genes and are novel transcriptional activators of ZbIDI,which encodes the rate-limiting enzyme in plant monoterpenoid synthesis.Functional analysis revealed that the expression of three genes[1]modulates monoterpenoid accumulation in Z.bungeanum peel.These findings provide novel insights into the metabolic regulatory network of monoterpenoid synthesis in Z.bungeanum peel,offer potential strategies for the biofortification of specific monoterpenoids,and will promote the development of Z.bungeanum germplasm for targeted breeding and quality improvement.
基金supported by Hebei Natural Science Foundation(H2024206476)Medical Science Research Project of Hebei(20240101).
文摘Background:The regulatory mechanisms governing vasculogenic mimicry(VM)in oral squamous cell carcinoma(OSCC)remain largely undefined.This study aimed to identify critical factors and elucidate the epigenetic mechanisms underlying VM in OSCC.Methods:Bioinformatics analysis was performed utilizing single-cell RNA-seq,bulk RNA-seq,and histone H3 lysine 27 acetylation(H3K27ac)Chromatin Immunoprecipitation(ChIP)-seq data obtained from The Cancer Genome Atlas(TCGA)and Gene Expression Omnibus(GEO)databases.ChIP-qPCR was used to validate the binding of ETS transcription factor ELK4(ELK4)to the dihydrofolate reductase(DHFR)enhancer.In vitro VM formation and invasion of OSCC cells were assessed using Matrigel-based tube formation and Transwell assays,respectively.Results:Elevated expression of VM-related genes predicts unfavorable prognosis in OSCC patients.High-dimensional weighted gene co-expression network analysis(hdWGCNA)identified epithelial subcluster C4 as most strongly associated with VM and metastasis.Three co-expression modules within this subcluster exhibited significant positive correlations with both phenotypic traits.Among the 30 eigengenes from the three modules,DHFR emerged as a key regulator of VM and metastasis.Knockdown or inhibition of DHFR significantly suppressed VM formation and invasion in OSCC cells.Mechanistically,ELK4 activated DHFR transcription through direct binding to its enhancer.DHFR overexpression rescued VM and invasion impairment induced by ELK4 knockdown.Conclusion:DHFR was a pivotal enhancer-regulated gene driving VM and metastasis in OSCC.ELK4 directly binds to DHFR enhancer regions to activate its transcription,thereby promoting these malignant phenotypes.These findings identified the ELK4/DHFR axis as a promising therapeutic target for anti-angiogenic intervention in OSCC.
文摘AIM:To investigate whether vaccinia-related kinase 1(VRK1)mediates transforming growth factor-beta2(TGF-β2)-caused epithelial-mesenchymal transition(EMT)and inflammatory responses in retinal pigment epithelial(RPE)cells through regulating snail family transcriptional repressor 1(SNAI1),and to validate its role in a proliferative vitreoretinopathy(PVR)mouse model.METHODS:Human RPE cell line ARPE-19 cells were treated with TGF-β2 to construct an EMT model.Western blot detected VRK1 level.The effects of VRK1 on SNAI1 expression and biological behavior of ARPE-19 cells were detected by immunofluorescence,ELISA,Transwell,and scratch assay,and the interaction between VRK1 and SNAI1 was confirmed through immunoprecipitation.A PVR mouse model was constructed,and the effects of VRK1 or/and SNAI1 on retinal damage were assessed by pathologic staining.Inflammatory factors and EMT-related proteins were assessed with ELISA and Western blot.RESULTS:VRK1 was upregulated in ARPE-19 cells after TGF-β2 treatment.Overexpression of VRK1 increased cell viability,promoted cell migration and EMT,and the levels of inflammatory factors.Silencing of VRK1 reversed the above indexes.There was a direct interaction between VRK1 and SNAI1,and overexpresssion SNAI1 weakened the impacts of silencing of VRK1.In PVR mice,silencing of VRK1 ameliorated retinal structural damage,decreased proinflammatory factor levels,and suppressed SNAI1 and mesenchymal marker expression.SNAI1 overexpression antagonized the protective effects of silencing VRK1 and exacerbated EMT and inflammatory responses.CONCLUSION:VRK1 plays a key role in retinal structural and inflammatory damage in PVR mice by regulating SNAI1 and mediating TGF-β2-caused EMT and inflammatory responses in RPE cells.
基金funding from the Scientific and Technological Innovation Project of China Academy of Chinese Medical Sciences(No.CI2021A04008)National Key Research and Development Project(No.2023YFC3504104)+2 种基金Hangzhou Joint Fund of the Zhejiang Provincial Natural Science Foundation of China(No.LHZSZ24H280003)Technology Major Program on Agricultural New Variety Breeding(No.2021C02073)Central Guiding Local Science and Technology Development Fund Project(No.2024ZY01009).
文摘Objective The basic helix-loop-helix(bHLH)transcription factors(TFs)are pivotal in regulating fungal growth,development,and secondary metabolism.However,the knowledge about the Ganoderma lucidum bHLHs(GlbHLHs)in ganoderic acid(GA)biosynthesis of G.lucidum was limited.This study aimed to explore the functions of bHLH genes in ganoderic acid biosynthesis during G.lucidum growth development.Methods First,the genome-wide identification of GlbHLHs was performed through Hidden Markov model searches and Two-way blast.Furthermore,through physicochemical properties,gene structure,and phylogenetic analysis,as well as combining the transcriptome and metabolome data from different developmental stages of G.lucidum,candidate GlbHLHs were screened.Subsequently,their regulatory roles in ganoderic acid biosynthesis were explored using yeast one-hybrid and dual-luciferase reporter assays.Results A total of 11 GlbHLH members were characterized in G.lucidum.The upstream promoter regions of these genes enriched hormones and abiotic stress responsive elements.Although individual ganoderic acid monomers demonstrated marked differences in accumulation patterns across specific growth phases and tissue types,overall,the total GA content was consistently higher in caps than in stipes throughout development.In addition,all GlbHLHs exhibited high expression in whole G.lucidum from the primordium to maturation stages.Among them,GlbHLH5 and GlbHLH7 showed the highest expression in any stage and highly correlated with key genes associated with GA pathway.Functional validation through dual-luciferase assays and yeast one-hybrid experiments had demonstrated that GlbHLH5 activated the P2 region of the lanosterol synthase promoter,while GlbHLH7 activated the promoters of squalene epoxidase and squalene synthase.Conclusion Compared to plants,G.lucidum harbored a small number of bHLH members but all high expression in any stages.Additionally,GlbHLH5 and GlbHLH7 with the highest expression among GlbHLHs showed activation in regulating the biosynthesis of GA.These results provide a theoretical reference for further research on ganoderic acid regulation in G.lucidum,and thereby providing a molecular foundation for enhancing ganoderic acid yield to optimize the medicinal value of G.lucidum.
基金supported by the Foundation Project:National Natural Science.Foundation of China(Nos.:82460249,82100417,81760094)The Foundation of Jiangxi Provincial Department of Science and Technology Outstanding Youth Fund Project(20212BAB206022,20242BAB23080).
文摘Objective:Leucine-rich alpha-2 glycoprotein 1(Lrg1)could regulate diverse cells in cerebral ischemiareperfusion.Our study seeks to uncover Lrg1’s impact on endothelial cell heterogeneity via differentiation pathways and transcription factors.Method:The CSOmap model measured cell-to-brain-center distances using single-cell RNA sequencing(scRNA-seq)data in middle cerebral artery occlusion reperfusion(MCAO/R).Monocle2 mapped endothelial differentiation paths.Gene set enrichment analysis(GSEA)analyzed endothelial subcluster variations.Database searches revealed a zinc finger MIZ-type containing 1 protein-frizzled 3(Zmiz1-Fzd3)promoter interaction.Endothelial cells were transfected with a Fzd3 promoter-luciferase plasmid.Polymerase chain reaction(PCR)and western blotting assessed MCAO/R or Zmiz1 overexpression effects on Fzd3-related mRNA and proteins.A retroviral vector carrying Zmiz1 was injected into the brains of mice to study its effect on Fzd3.Result:Lrg1−/−mice exhibited elevated cell adhesion proteins and decreased microvascular leakage after MCAO/R.CSOmap showed widened astrocyte spacing in thesemice.RSS revealed Zmiz1 overexpression inMCAO/R+Lrg1−/−mice.MCAO/R and pcDNA3-Zmiz1 transfection both enhanced luciferase activity with Fzd3,indicating Zmiz1 binding to Fzd3.Retroviral Zmiz1 injection or knockdown disrupted ischemic brain tight junctions,highlighting Zmiz1’s key role in blood-brain barrier protection,likely through Fzd3 pathway modulation.Conclusion:The findings indicate Lrg1 knockout induces endothelial differentiation by activating Zmiz1,which is crucial for maintaining blood-brain barrier function,possibly via modulating the Fzd3 pathway.
文摘Objectives:The current treatment options and therapeutic targets for triple-negative breast cancer(TNBC),an aggressive subtype of breast cancer(BrCA),are limited.This study aimed to identify novel biomarkers and transcriptional regulatory networks(TRN)inherent in TNBC samples.Methods:We analyzed pan-cancer BrCA datasets from The Cancer Genome Atlas(TCGA)to compare triple-positive breast cancer(TPBC)with TNBC.TRN algorithms and virtual inference of protein-enriched regulon(VIPER)were used to identify master regulators and their target genes.Utilizing TNBC cells(MDA-MB-231 and MDA-MB-468),we validated the relationship of nuclear factor erythroid 2-like 3(NFE2L3)and basic helix-loop-helix family member E 40(BHLHE40)by performing a luciferase assay.The expression levels of these targets were measured after transfections with plasmid and siRNA via qRT-PCR and western blots.The effect of these genes on cell proliferation and migration was studied using phenotypic assays.Results:Using computational approaches,we identified NFE2L3 as a master regulator with BHLHE40 as its target gene.NFE2L3 protein binds to the promoter region of BHLHE40 and regulates its transcriptional activity.Additionally,silencing and overexpressing NFE2L3 and BHLHE40 in TNBC cell lines MDA-MB-231 and MDA-MB-468 showed that NFE2L3 directly regulates BHLHE40 at both transcriptional and translational levels.We found that BHLHE40 requires NFE2L3 for cell proliferation and migration in TNBC.Conclusion:These findings underscore the significance of NFE2L3 and BHLHE40 in TNBC,highlighting NFE2L3’s role in regulating the oncogenic activity of BHLHE40 in TNBC cells.
基金supported by the National Natural Science Foundation of China(Grant Nos.32120103010,32002050)Beijing Joint Research Program for Germplasm Innovation and New Variety Breeding(Grant No.G20220628003-03)the Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences。
文摘Tomato is an important economic crop all over the world.Volatile flavors in tomato fruit are key factors influencing consumer liking and commercial quality.However,the regulatory mechanism controlling the volatile flavors of tomatoes is still not clear.Here,we integrated the metabolome and transcriptome of the volatile flavors in tomato fruit to explore the regulatory mechanism of volatile flavor formation,using wild and cultivated tomatoes with significant differences in flavors.A total of 35 volatile flavor compounds were identified,based on the solid phase microextraction-gas chromatography-mass spectrometry(SPME-GC-MS).The content of the volatiles,affecting fruit flavor,significantly increased in the transition from breaker to red ripe fruit stage.Moreover,the total content of the volatiles in wild tomatoes was much higher than that in the cultivated tomatoes.The content variations of all volatile flavors were clustered into 10 groups by hierarchical cluster and Pearson coefficient correlation(PCC)analysis.The fruit transcriptome was also patterned into 10 groups,with significant variations both from the mature green to breaker fruit stage and from the breaker to red ripe fruit stage.Combining the metabolome and the transcriptome of the same developmental stage of fruits by co-expression analysis,we found that the expression level of 1182 genes was highly correlated with the content of volatile flavor compounds,thereby constructing two regulatory pathways of important volatile flavors.One pathway is tetrahydrothiazolidine N-hydroxylase(SlTNH1)-dependent,which is regulated by two transcription factors(TFs)from the bHLH and AP2/ERF families,controlling the synthesis of 2-isobutylthiazole in amino acid metabolism.The other is lipoxygenase(Sl LOX)-dependent,which is regulated by one TF from the HD-Zip family,controlling the synthesis of hexanal and(Z)-2-heptenal in fatty acid metabolism.Dual-luciferase assay confirmed the binding of b HLH and AP2/ERF to their structural genes.The findings of this study provide new insights into volatile flavor formation in tomato fruit,which can be useful for tomato flavor improvement.
基金supported by grants from the National Natural Science Foundation of China(Grant No.32072571)the 111 Project(Grant No.B17043)the Construction of Beijing Science,and Technology Innovation and Service Capacity in Top Subjects(Grant No.CEFF-PXM2019_014207_000032)。
文摘Tomato(Solanum lycopersicum)is an important fruit and vegetable crop in worldwide.The fertility of tomato reproductive organs can be dramatically decreased when ambient temperatures rise above 35°C,reducing tomato fruit yield.It is necessary to identify transcription factors(TFs)and target genes involved in heat stress response(HSR)signaling cascades in tomato flower buds to improve tomato plant thermotolerance.In this study,we profiled genes expressed in three developmental stages of tomato flower buds.Red and turquoise modules for heat stress(HS)were identified through gene co-expression network analysis,and the genes within these modules were enriched in HS-related pathways.By focusing on the TFs in the two modules,we identified several novel HSR-related TFs,including SlWRKY75,SlMYB117,and SlNAM.Furthermore,homology analysis illustrated a conserved signaling cascade in tomato.Lastly,we identified and experimentally validated four HSF-regulated genes,namely SlGrpE,SlERDJ3A,SlTIL,and SlPOM1,that likely modulate thermotolerance in plants.These results provide a high-resolution atlas of gene expression during tomato flower bud development under HS conditions,which is a valuable resource for uncovering potential regulatory networks associated with the HSR in tomato.
基金supported by the Natural Science Foundation of Jiangsu Province,China(BK20242007)the Natural Science Foundation of China(32271916)the Jiangsu Agricultural Science and Technology Innovation Fund[CX(24)3048].
文摘bHLH transcription factors,widely exist in various plants,and are vital for the growth and development of these plants.Among them,many have been implicated in anthocyanin biosynthesis across various plants.In the present study,a PdbHLH57 gene,belonging to the bHLH IIIf group,was characterized,which was isolated and cloned from the colored-leaf poplar‘Zhongshancaiyun’(ZSCY).The cDNA sequence of PdbHLH57 was 1887 base pairs,and the protein encoded by PdbHLH57 had 628 amino acids,the isoelectric point and molecular weight of which were 6.26 and 69.75 kDa,respectively.Through bioinformatics analysis,PdbHLH57 has been classified into the IIIf bHLH subgroup,with many members of this subgroup known to participate in anthocyanin biosynthesis.The subcellular localization analysis conducted in the leaf protoplasts of‘ZSCY’revealed that the PdbHLH57 protein is specifically localized in the nucleus.The transcription activation analysis was also conducted,and the results showed that the PdbHLH57 protein had self-transcription activation.To better explore the functions of the PdbHLH57 protein,two parts of this protein(PdbHLH57-1,PdbHLH57-2)were split to detect their transcriptional activation activity.The results indicated that PdbHLH57-1(1-433aa)had self-transcription activation,and PdbHLH57-2(433-628aa)had no transcription activation.The expression of PdbHLH57 peaked in June during different developmental stages in‘ZSCY’,and it was most highly expressed in the phloem among various tissues.These findings offer a basis for understanding the role of PdbHLH57 in colored-leaf poplar.
基金funded by the Fundamental Research Grant Scheme(Grant No.FRGS/1/2023/STG03/UM/02/2)Universiti Malaya RU Grant(RU002-2025B).
文摘Myeloblastosis(MYB)transcription factors(TFs)are evolutionarily conserved regulatory proteins that are crucial for plantgrowth,development,secondarymetabolism,andstress adaptation.Recent studieshavehighlighted their crucial role in coordinating growth–defense trade-offs through transcriptional regulation of key biosynthetic and stress-response genes.Despite extensive functional characterization in model plants such as Arabidopsis thaliana,systematically evaluating the broader functional landscape of MYB TFs across diverse species and contexts remains necessary.This systematic review integrates results from 24 peer-reviewed studies sourced from Scopus and Web of Science,focusing on the functional diversity of MYB TFs,particularly in relation to abiotic stress tolerance,metabolic regulation,and plant developmental processes.Advances in genomic technologies,such as transcriptomics,genome editing,and comparative phylogenetics,have considerably enhanced our understanding of MYB-mediated regulatory mechanisms.These tools have facilitated the identification and functional characterization of MYB genes across model and non-model plant species.Key findings underscore the multifaceted roles of MYB TFs in enhancing stress resilience,modulating anthocyanin and flavonoid biosynthesis,and contributing to yield-related traits,thereby highlighting their potential applications in crop improvement and sustainable agriculture.However,critical gaps exist in understanding MYB interactions within complex regulatory networks,particularly in underrepresented plant species and ecological contexts.This review consolidates current knowledge as well as identifies research gaps and proposes future directions to advance the understanding and application of MYB TFs.The insights derived from this study underscore their transformative potential in addressing global challenges including food security and climate resilience through innovative agricultural practices.
基金supported by the National Characteristic Vegetable Industry Technology System of China(Grant No.CARS24-A-07)the Jiangsu Modern Agricultural Industry Technology System Construction Special Fund(Grant No.JATS[2023]050)Xuzhou Academy of Agricultural Sciences Research Fund Project(Grant No.XM2021003)。
文摘Commercial cultivars of garlic,a popular condiment,are sterile,making genetic variation and germplasm innovation of this plant challenging.Understanding mechanism of gamete sterility in garlic and their key regulatory networks is therefore important for fertility restoration.In this work,we conducted a detailed phenotypic analysis of fertile and sterile garlic genotypes and found that enlargement of topset in the inflorescence of sterile genotypes led to abnormal flowers.Additional cytological observations showed that aberrant meiotic cytokinesis in sterile garlic ultimately resulted in pollen degeneration.Transcriptomics analysis of sterile and fertile genotypes identified possible molecular mechanisms underlying gamete abortion.A total of 100710 differentially expressed genes(DEGs)between the fertile and sterile garlic flowers at three stages of gamete development were identified,many of which were involved in homologous chromosome synapsis during meiosis,MYB transcription factor regulation,ribosome biogenesis and plant hormone signal transduction.Taken together,these results provide insight into the molecular mechanisms and regulatory networks underlying gamete development in garlic and point to a set of candidate genes for further functional characterization.
基金supported by the Start-up Fund for new faculty from the Hong Kong Polytechnic University(PolyU)(A0043215)(to SA)the General Research Fund and Research Impact Fund from the Hong Kong Research Grants Council(15106018,R5032-18)(to DYT)+1 种基金the Research Center for SHARP Vision in PolyU(P0045843)(to SA)the InnoHK scheme from the Hong Kong Special Administrative Region Government(to DYT).
文摘Retinal aging has been recognized as a significant risk factor for various retinal disorders,including diabetic retinopathy,age-related macular degeneration,and glaucoma,following a growing understanding of the molecular underpinnings of their development.This comprehensive review explores the mechanisms of retinal aging and investigates potential neuroprotective approaches,focusing on the activation of transcription factor EB.Recent meta-analyses have demonstrated promising outcomes of transcription factor EB-targeted strategies,such as exercise,calorie restriction,rapamycin,and metformin,in patients and animal models of these common retinal diseases.The review critically assesses the role of transcription factor EB in retinal biology during aging,its neuroprotective effects,and its therapeutic potential for retinal disorders.The impact of transcription factor EB on retinal aging is cell-specific,influencing metabolic reprogramming and energy homeostasis in retinal neurons through the regulation of mitochondrial quality control and nutrient-sensing pathways.In vascular endothelial cells,transcription factor EB controls important processes,including endothelial cell proliferation,endothelial tube formation,and nitric oxide levels,thereby influencing the inner blood-retinal barrier,angiogenesis,and retinal microvasculature.Additionally,transcription factor EB affects vascular smooth muscle cells,inhibiting vascular calcification and atherogenesis.In retinal pigment epithelial cells,transcription factor EB modulates functions such as autophagy,lysosomal dynamics,and clearance of the aging pigment lipofuscin,thereby promoting photoreceptor survival and regulating vascular endothelial growth factor A expression involved in neovascularization.These cell-specific functions of transcription factor EB significantly impact retinal aging mechanisms encompassing proteostasis,neuronal synapse plasticity,energy metabolism,microvasculature,and inflammation,ultimately offering protection against retinal aging and diseases.The review emphasizes transcription factor EB as a potential therapeutic target for retinal diseases.Therefore,it is imperative to obtain well-controlled direct experimental evidence to confirm the efficacy of transcription factor EB modulation in retinal diseases while minimizing its risk of adverse effects.
基金funded by State Key Laboratory of North China Crop Improvement and Regulation(NCCIR2023ZZ-10)the National Natural Science Foundation of China(32172384 and 31501623)+1 种基金the Natural Science Foundation of Hebei(C2020204028)the Science and Technology Research Project of Higher Education of Hebei(ZC2023178).
文摘The NAC(NAM,ATAF1/2,and CUC2)is a defense-associated transcription factor(TF)family that positively regulates defense responses to pathogen infection.TaNAC069 positively regulates resistance in wheat to Puccinia triticina(Pt).However,the molecular mechanism of its interaction with a Pt effector is not clear.We found that Pt effector Pt-1234 interacts with TaNAC069 to subvert host immunity during Pt infection.Quantitative real-time PCR analysis showed that expression of Pt-1234 was significantly upregulated during the early stage of Pt infection.Protein-mediated cell death assays in wheat showed that the Pt-1234 protein was unable to induce cell death in wheat near-isogenic lines carrying different leaf rust resistance genes,whereas it suppressed BAX-induced cell death in leaves of Nicotiana benthamiana.Silencing of Pt-1234 by host-induced gene silencing(HIGS)significantly reduced the virulence of Pt in the susceptible wheat variety Thatcher.The C subdomain of TaNAC069 was responsible for its interaction with Pt-1234,and the E subdomain was required for TaNAC069-mediated defense responses to Pt in planta.These findings indicate that Pt utilizes Pt-1234 to interact with wheat transcription factor TaNAC069 through its C subdomain,thereby modulating wheat immunity.
基金supported by Research Program for Agricultural Science and Technology Development,Republic of Korea(PJ01570601)the Fellowship Program(PJ01661001)of the National Institute of Agricultural Sciences,Republic of KoreaRural Development Administration,Republic of Korea.
文摘The emergence of novel phytopathogens and the accelerated spread of plant diseases to new regions,driven by global climate change,constitute significant threats to agricultural resources.Rice,a major tropical staple crucial for global food security,possesses six transcription factor superfamilies-AP2/ERF,bHLH,bZIP,MYB,NAC,and WRKY-that function in innate immunity against pathogens.We review their biological functions and regulatory mechanisms in rice immunity.
基金supported by the National Natural Science Foundation of China(Nos.82171552 and 82170479)the Natural Science Foundation of Shanghai Ctiy(No.21ZR1457500)the Science and Technology Bureau of Shanghai Putuo District(No.ptkwws202102).
文摘Magnolol,a compound extracted from Magnolia officinalis,demonstrates potential efficacy in addressing metabolic dysfunction and cardiovascular diseases.Its biological activities encompass anti-inflammatory,antioxidant,anticoagulant,and anti-diabetic effects.Growth/differentiation factor-15(GDF-15),a member of the transforming growth factorβsuperfamily,is considered a potential therapeutic target for metabolic disorders.This study investigated the impact of magnolol on GDF-15 production and its underlying mechanism.The research examined the pharmacological effect of magnolol on GDF-15 expression in vitro and in vivo,and determined the involvement of endoplasmic reticulum(ER)stress signaling in this process.Luciferase reporter assays,chromatin immunoprecipitation,and in vitro DNA binding assays were employed to examine the regulation of GDF-15 by activating transcription factor 4(ATF4),CCAAT enhancer binding proteinγ(CEBPG),and CCCTC-binding factor(CTCF).The study also investigated the effect of magnolol and ATF4 on the activity of a putative enhancer located in the intron of the GDF-15 gene,as well as the influence of single nucleotide polymorphisms(SNPs)on magnolol and ATF4-induced transcription activity.Results demonstrated that magnolol triggers GDF-15 production in endothelial cells(ECs),hepatoma cell line G2(HepG2)and hepatoma cell line 3B(Hep3B)cell lines,and primary mouse hepatocytes.The cooperative binding of ATF4 and CEBPG upstream of the GDF-15 gene or the E1944285 enhancer located in the intron led to full-power transcription of the GDF-15 gene.SNP alleles were found to impact the magnolol and ATF4-induced transcription activity of GDF-15.In high-fat diet ApoE^(-/-)mice,administration of magnolol induced GDF-15 production and partially suppressed appetite through GDF-15.These findings suggest that magnolol regulates GDF-15 expression through priming of promoter and enhancer activity,indicating its potential as a drug for the treatment of metabolic disorders.
文摘BACKGROUND Diabetic retinopathy(DR)is a major microvascular complication of diabetes mellitus,leading to significant visual impairment and blindness among adults.Current treatment options are limited,making it essential to explore novel therapeutic strategies.Curcumol,a sesquiterpenoid derived from traditional Chinese medicine,has shown anti-inflammatory and anti-cancer properties,but its potential role in DR remains unclear.AIM To investigate the therapeutic effects of curcumol on the progression of DR and to elucidate the underlying molecular mechanisms,particularly its impact on the fat mass and obesity-associated(FTO)protein and the long non-coding RNA(lncRNA)MAF transcription factor G antisense RNA 1(MAFG-AS1).METHODS A streptozotocin-induced mouse model of DR was established,followed by treatment with curcumol.Retinal damage and inflammation were evaluated through histological analysis and molecular assays.Human retinal vascular endothelial cells were exposed to high glucose conditions to simulate diabetic environments in vitro.Cell proliferation,migration,and inflammation markers were assessed in curcumoltreated cells.LncRNA microarray analysis identified key molecules regulated by curcumol,and further experiments were conducted to confirm the involvement of FTO and MAFG-AS1 in the progression of DR.RESULTS Curcumol treatment significantly reduced blood glucose levels and alleviated retinal damage in streptozotocininduced DR mouse models.In high-glucose-treated human retinal vascular endothelial cells,curcumol inhibited cell proliferation,migration,and inflammatory responses.LncRNA microarray analysis identified MAFG-AS1 as the most upregulated lncRNA following curcumol treatment.Mechanistically,FTO demethylated MAFG-AS1,stabilizing its expression.Rescue experiments demonstrated that the protective effects of curcumol against DR were mediated through the FTO/MAFG-AS1 signaling pathway.CONCLUSION Curcumol ameliorates the progression of DR by modulating the FTO/MAFG-AS1 axis,providing a novel therapeutic pathway for the treatment of DR.These findings suggest that curcumol-based therapies could offer a promising alternative for managing this debilitating complication of diabetes.
文摘Loss-of-function variants of low-density lipoprotein receptor-related protein 5(LRP5)can lead to reduced bone formation,culminating in diminished bone mass.Our previous study reported transcription factor osterix(SP7)-binding sites on the LRP5 promoter and its pivotal role in upregulating LRP5 expression during implant osseointegration.However,the potential role of SP7 in ameliorating LRP5-dependent osteoporosis remained unknown.In this study,we used mice with a conditional knockout(c KO)of LRP5 in mature osteoblasts,which presented decreased osteogenesis.The in vitro experimental results showed that SP7 could promote LRP5 expression,thereby upregulating the osteogenic markers such as alkaline phosphatase(ALP),Runt-related transcription factor 2(Runx2),andβ-catenin(P<0.05).For the in vivo experiment,the SP7 overexpression virus was injected into a bone defect model of LRP5 c KO mice,resulting in increased bone mineral density(BMD)(P<0.001)and volumetric density(bone volume(BV)/total volume(TV))(P<0.001),and decreased trabecular separation(Tb.Sp)(P<0.05).These data suggested that SP7 could ameliorate bone defect healing in LRP5 c KO mice.Our study provides new insights into potential therapeutic opportunities for ameliorating LRP5-dependent osteoporosis.
基金supported by the Natural Science Foundation of Hunan Province,China(2022JJ30886).
文摘Objective:Polycystic ovary syndrome(PCOS)is a common endocrine disorder that affects women’s health.This study aims to investigate gene and transcription factor(TF)expression differences between PCOS patients and healthy individuals using bioinformatics approaches,and to verify the function of key transcription factors,with the goal of providing new insights into the pathogenesis of PCOS.Methods:Differentially expressed genes(DEGs)and differentially expressed transcription factors(DETFs)between PCOS patients and controls were identified from the RNA sequencing dataset GSE168404 using bioinformatics methods.Functional enrichment analysis was performed using Gene Ontology(GO)and Kyoto Encyclopedia of Genes and Genomes(KEGG)databases.The expression and function of core transcription factors were further validated in ovarian tissues of PCOS model mice and control mice using Western blotting and reverse transcription quantitative polymerase chain reaction(RTqPCR).Results:A total of 332 DEGs were identified between PCOS patients and controls,including 259 upregulated and 73 downregulated genes in the PCOS group.19 DETFs were further screened,of which 16 were upregulated and 3 were downregulated in PCOS.The upregulated DETFs(including TFCP2L1,DACH1,ESR2,AFF3,SMAD9,ZNF331,HOPX,ATOH8,HIF3α,DPF3,HOXC4,HES1,ID1,JDP2,SOX4,and ID3)were primarily associated with lipid metabolism,development,and cell adhesion.Protein and mRNA expression analysis in PCOS model mice revealed significantly decreased levels of hypoxia-inducible factor(HIF)1αand HIF2α,and significantly increased expression of HIF3αcompared to control mice(all P<0.001).Conclusion:Significant differences in gene and TF expression exist between PCOS patients and healthy individuals.HIF-3αmay play a crucial role in PCOS and could serve as a novel biomarker for diagnosis and a potential therapeutic target.
基金the National Natural Science Foundation of China(32372780 and 32172643)the Institutional Research Funding of Sichuan University(2022SCUNL105)+2 种基金the Natural Science Foundation of Sichuan Province(2024NSFSC1302)the China Postdoctoral Science Foundation(2023M732486)the Guangxi Science and Technology Program(2024AB08197).
文摘Fruit ripening is a complex developmental process tightly regulated by hormonal crosstalk,transcriptional networks,and epigenetic modifications,with striking divergence between climacteric and non-climacteric species.In climacteric fruits,such as tomatoes,apples,and bananas,ethylene acts as the master regulator,driving autocatalytic biosynthesis through ACS/ACO genes and activating hierarchical transcriptional cascades mediated by MADS-box(RIN),NAC(NOR),and ERF-family transcription factors.These pathways are amplified by epigenetic reprogramming,including DNA demethylation at ripening-related promoters and histone acetylation,which enhance chromatin accessibility to facilitate gene expression.Conversely,non-climacteric fruits like strawberries and grapes predominantly rely on abscisic acid(ABA)to coordinate ripening.Hormonal interplay,such as ethylene-ABA synergy in climacteric fruit systems,further fine-tunes ripening dynamics.Advances in CRISPR-based gene editing and epigenome engineering now enable precise manipulation of these pathways,offering transformative solutions to reduce postharvest losses,enhance nutritional quality,and improve climate resilience.This review integrates mechanistic insights across species,emphasizing opportunities to translate fundamental discoveries into sustainable agricultural innovations,from breeding nutrient-rich cultivars to optimizing postharvest technologies for global food security.
文摘Background:E26 transformation-specific(ETS)family transcription factors have confirmed roles in several types of cancers.This study aimed to clarify the role of ETS family transcription factor alterations in gastric cancers.Methods:This study examines molecular alterations of ETS transcription factors in gastric adenocarcinomas based on an analysis of publicly available cohorts from the Protein Atlas and the Cancer Genome Atlas.The expression and relationships of members of the ETS transcription factor family with other important factors in the process of gastric carcinogenesis were evaluated using the same resources.Results:mRNA expression levels of ETS family members in gastric carcinoma tissues were variable,with ELF3,ETS2,EHF,ERF,and ELF1 being the family members with the highest expression.Mutations in individual transcription factors of the ETS family were rare in gastric cancers.The family member ELF3 was well expressed in the mRNA level in a subset of gastric cancers(n=91),and its expression correlated with the expression of other transcription factors involved in gastric cancer pathogenesis,including HNF4A,HNF1A,CDX2,GATA4,GATA6,and EHF.Cancers with high co-expression of ELF3 and HNF4A were frequently chromosomally instability(CIN),intestinal-type adenocarcinomas,and harbored TP53 mutations and WWOX deletions.Conclusion:Expression of E74 like ETS transcription factor 3(ELF3),an ETS transcription family member,correlates with expression of other key factors in gastric cancer and confers specific characteristics that may become exploited in targeted therapeutic interventions.
