To understand the functional identification of large-scale genomic sequences in Forsythia,tobacco rattle virus(TRV)-mediated virus-induced gene silencing(VIGS),suitable for the plant,was explored in this study.The res...To understand the functional identification of large-scale genomic sequences in Forsythia,tobacco rattle virus(TRV)-mediated virus-induced gene silencing(VIGS),suitable for the plant,was explored in this study.The results showed that the TRV-mediated VIGS system could be successfully used in Forsythia for silencing the reporter gene FsPDS(Forsythia phytoene desaturase)using stem infiltration and leaf infiltrationmethods.All the treated plants were pruned below the injection site after 7–15 d infection;the FsPDS was silenced and typical photobleaching symptoms were observed in newly sprouted leaves at the whole-plant level.Meanwhile,this system has been successfully tested and verified through virus detection and qRT-PCR analysis.After the optimization,Forsythia magnesium chelatase subunit H(FsChlH)was silenced successfully in Forsythia using this system,resulting in yellow leaveswith decreased chlorophyll content.The system was stable,highly efficient and had greater rapidity and convenience,which made it suitable to study the function of genes related to physiological pathways such as growth and development,and metabolic regulation in Forsythia.展开更多
AIM To establish a permanent piwi like RNA-mediated genesilencing 1(PIWIL1) gene knockout in AGP01 gastric cancer cell line using CRISPR-Cas9 system and analyze phenotypic modifications as well as gene expression alte...AIM To establish a permanent piwi like RNA-mediated genesilencing 1(PIWIL1) gene knockout in AGP01 gastric cancer cell line using CRISPR-Cas9 system and analyze phenotypic modifications as well as gene expression alterations.METHODS CRISPR-Cas9 system used was purchased from Dharmacon GE Life Sciences(Lafayette, CO, United States) and permanent knockout was performed according to manufacturer's recommendations. Woundhealing assay was performed to investigate the effect of PIWIL1 knockout on migration capability of cells and Boyden chamber invasion assay was performed to investigate the effect on invasion capability. For the gene expression analysis, a one-color microarray-based gene expression analysis kit(Agilent Technologies, Santa Clara, CA, United States) was used according to the protocol provided by the manufacturer. RESULTS PIWIL1 gene knockout caused a significant decrease in AGP01 migration capacity as well as a significant decrease in cell invasiveness. Moreover, functional analysis based on grouping of all differentially expressed m RNAs identified a total of 35 genes(5 up-regulated and 30 down-regulated) encoding proteins involved in cellular invasion and migration. According to current literature, 9 of these 35 genes(DOCK2, ZNF503, PDE4 D, ABL1, ABL2, LPAR1, SMAD2, WASF3 and DACH1) are possibly related to the mechanisms used by PIWIL1 to promote carcinogenic effects related to migration and invasion, since their functions are consistent with the changes observed(being up-or down-regulated after knockout). CONCLUSION Taken together, these data reinforce the idea that PIWIL1 plays a crucial role in the signaling pathway of gastric cancer, regulating several genes involved in migration and invasion processes; therefore, its use as a therapeutic target may generate promising results in the treatment of gastric cancer.展开更多
Alfalfa(Medicago sativa L.) is a legume forage that is widely cultivated owing to its high biomass yield and favorable nutrient values. However, alfalfa contains relatively high lignin, which limits its utilization.Do...Alfalfa(Medicago sativa L.) is a legume forage that is widely cultivated owing to its high biomass yield and favorable nutrient values. However, alfalfa contains relatively high lignin, which limits its utilization.Downregulation of two transcriptional factors, Transparent Testa8(TT8) and Homeobox12(HB12), has been proposed to reduce lignin content in alfalfa. Therefore, silencing of TT8(TT8i) and HB12(HB12i) in alfalfa was achieved by RNAi technology. The objective of this project was to determine effect of gene modification through silencing of TT8 and HB12 genes in alfalfa plants on lignin and phenolic content,bioenergic value, nutrient supply from rumen degradable and undegradable fractions, and in vitro ammonia production in response to the silencing of TT8 and HB12 genes in alfalfa. All gene silenced alfalfa plants(5 TT8i and 11 HB12i) were grown under greenhouse conditions with wild type as a control.Samples were analyzed for bioactive compounds, degradation fractions, truly digestible nutrients, energetic values and in vitro ammonia productions in ruminant systems. Furthermore, relationships between physiochemical, metabolic and fermentation characteristics and molecular spectral parameters were determined using vibrational molecular spectroscopy. Results showed that the HB12i had higher lignin, while TT8i had higher phenolics. Both silenced genotypes had higher rumen slowly degraded carbohydrate fractions and truly digestible neutral detergent fiber, but lower rumen degradable protein fractions. Moreover, the HB12i had lower truly digestible crude protein, energetic values and ammonia production compared with other silenced genotypes. In addition, in relation to the nutritive values of alfalfa, structural carbohydrate parameters were negatively correlated, whereas alpha/beta ratio in protein structure was positively correlated. Furthermore, good predictions were obtained for degradation of protein and carbohydrate fractions and energy values from molecular spectral parameters. In conclusion, silencing of the TT8 and HB12 genes decreased protein availability and increased fiber availability. Silencing of the HB12 gene also increased lignin and decreased energy and rumen ammonia production. Moreover, nutritional alterations were closely correlated with molecular spectral parameters. Therefore, gene modification through silencing the TT8 and HB12 genes in alfalfa influenced physiochemical, metabolic and fermentation characteristics.展开更多
Tomato yellow leaf curl virus(TYLCV)is known to encode 6 canonical viral proteins.Our recent study revealed that TYLCV also encodes some additional small proteins with potential virulence functions.The fifth ORF of TY...Tomato yellow leaf curl virus(TYLCV)is known to encode 6 canonical viral proteins.Our recent study revealed that TYLCV also encodes some additional small proteins with potential virulence functions.The fifth ORF of TYLCV in the complementary sense,which we name C5,is evolutionarily conserved,but little is known about its expression and function during viral infection.Here,we confirmed the expression of the TYLCV C5 by analyzing the promoter activity of its upstream sequences and by detecting the C5 protein in infected cells by using a specific custom-made antibody.Ectopic expression of C5 using a potato virus X(PVX)vector resulted in severe mosaic symptoms and higher virus accumulation levels followed by a burst of reactive oxygen species(ROS)in Nicotiana benthamiana plants.C5 was able to effectively suppress local and systemic post-transcriptional gene silencing(PTGS)induced by single-stranded GFP but not double-stranded GFP,and reversed the transcriptional gene silencing(TGS)of GFP.Furthermore,the mutation of C5 in TYLCV inhibited viral replication and the development of disease symptoms in infected plants.Transgenic overexpression of C5 could complement the virulence of a TYLCV infectious clone encoding a dysfunctional C5.Collectively,this study reveals that TYLCV C5 is a pathogenicity determinant and RNA silencing suppressor,hence expanding our knowledge of the functional repertoire of the TYLCV proteome.展开更多
Global prophylactic vaccination programmes have helped to curb new hepatitis B virus(HBV)infections.However,it is estimated that nearly 300 million people are chronically infected and have a high risk of developing he...Global prophylactic vaccination programmes have helped to curb new hepatitis B virus(HBV)infections.However,it is estimated that nearly 300 million people are chronically infected and have a high risk of developing hepatocellular carcinoma.As such,HBV remains a serious health priority and the development of novel curative therapeutics is urgently needed.Chronic HBV infection has been attributed to the persistence of the covalently closed circular DNA(cccDNA)which establishes itself as a minichromosome in the nucleus of hepatocytes.As the viral transcription intermediate,the cccDNA is responsible for producing new virions and perpetuating infection.HBV is dependent on various host factors for cccDNA formation and the minichromosome is amenable to epigenetic modifications.Two HBV proteins,X(HBx)and core(HBc)promote viral replication by modulating the cccDNA epigenome and regulating host cell responses.This includes viral and host gene expression,chromatin remodeling,DNA methylation,the antiviral immune response,apoptosis,and ubiquitination.Elimination of the cccDNA minichromosome would result in a sterilizing cure;however,this may be difficult to achieve.Epigenetic therapies could permanently silence the cccDNA minichromosome and promote a functional cure.This review explores the cccDNA epigenome,how host and viral factors influence transcription,and the recent epigenetic therapies and epigenome engineering approaches that have been described.展开更多
Plant Dicer-like(DCL)and Argonaute(AGO)are the key enzymes involved in anti-virus post-transcriptional gene silencing(AV-PTGS).Here we show that AV-PTGS exhibited nucleotide preference by calculating a relative AV-PTG...Plant Dicer-like(DCL)and Argonaute(AGO)are the key enzymes involved in anti-virus post-transcriptional gene silencing(AV-PTGS).Here we show that AV-PTGS exhibited nucleotide preference by calculating a relative AV-PTGS efficiency on processing viral RNA substrates.In comparison with genome sequences of dicot-infecting Turnip mosaic virus(TuMV)and monocot-infecting Cocksfoot streak virus(CSV),viral-derived small interfering RNAs(vsiRNAs)displayed positive correlations between AV-PTGS efficiency and G+C content(GC%).Further investigations on nucleotide contents revealed that the vsiRNA populations had G-biases.This finding was further supported by our analyses of previously reported vsiRNA populations in diverse plant-virus associations,and AGO associated Arabidopsis endogenous siRNA populations,indicating that plant AGOs operated with G-preference.We further propose a hypothesis that AV-PTGS imposes selection pressure(s)on the evolution of plant viruses.This hypothesis was supported when potyvirus genomes were analysed for evidence of GC elimination,suggesting that plant virus evolution to have low GC%genomes would have a unique function,which is to reduce the host AV-PTGS attack during infections.展开更多
BCL-2 gene as well as its products is recognized as a promising target for the molecular targeted therapy of tumors.However,due to certain defense measures of tumor cells,the therapeutic effect based on the gene silen...BCL-2 gene as well as its products is recognized as a promising target for the molecular targeted therapy of tumors.However,due to certain defense measures of tumor cells,the therapeutic effect based on the gene silencing of BCL-2 is greatly reduced.Here we fabricate a smart response nucleic acid therapeutic that could silence the gene effectively through a dual-targeted and cascade-enhanced strategy.In brief,nano-graphene oxide(GO),working as a nano-carrier,is loaded with a well-designed DNAzyme,which can target and silence the BCL-2 mRNA.Furthermore,upon binding with the BCL-2 mRNA,the enzymatic activity of the DNAzyme can be initiated,cutting a substrate oligonucleotide to produce an anti-nucleolin aptamer AS1411.Nucleolin,a nucleolar phosphoprotein,is known as a stabilizer of BCL-2 mRNA.Via binding and inactivating the nucleolin,AS1411 can destabilize BCL-2 mRNA.By this means of simultaneously targeting mRNA and its stabilizer in an integrated system,effective silencing of the BCL-2 gene of tumor cells is achieved at both the cellular and in vivo levels.After being dosed with this nucleic acid therapeutic and without any chemotherapeutics,apoptosis of tumor cells at the cellular level and apparent shrinkage of tumors in vivo are observed.By labeling a molecular beacon on the substrate of DNAzyme,visualization of the enzymatic activity as well as the tumor in vivo can be also achieved.Our work presents a pure bio-therapeutic strategy that has positive implications for enhancing tumor treatment and avoiding side effects of chemotherapeutics.展开更多
Oligonucleotide drugs have been used widely as therapeutic agents for gene therapy,while their instability in biological media and inefficiency for intracellular delivery remain major hurdles for practical in vivo app...Oligonucleotide drugs have been used widely as therapeutic agents for gene therapy,while their instability in biological media and inefficiency for intracellular delivery remain major hurdles for practical in vivo applications.Herein,we report a circular Y-shaped aptamer–DNAzyme conjugate(cYAD)for highly efficient in vivo gene silencing via RNA cleavage,which can been employed in various disease treatments,including cancer,inflammation,as well as viral infections.Systematic studies revealed that cyclization of the DNA structure could improve the stability of oligonucleotide drugs in vivo.Besides,the bivalent aptamer motifs provided a specific and enhanced tumor cell targeting ability for accumulation and retention of the oligonucleotide drugs at the tumor site.As a proof of concept,a widely applicable Na+-dependent fluorescent sensor,NaA43 DNAzyme,was used to inhibit MET gene expression in mice tumor model tissues,which exhibited highly efficient gene silencing performance in vivo,which confirmed our findings with cYAD.This strategy provides a novel approach for the construction of oligonucleotide drugs for practical therapeutic applications.展开更多
With the development of bioinformatics,it is easy to obtain information and data about thousands of genes,but the determi nation of the functions of these genes depends on methods for rapid and effective functi on al ...With the development of bioinformatics,it is easy to obtain information and data about thousands of genes,but the determi nation of the functions of these genes depends on methods for rapid and effective functi on al identification.Virus-induced gene sile ncing(VIGS)is a mature method of gene functional identification developed over the last 20 years,which has been widely used in many research fields involving many species.Fruit quality formation is a complex biological process,which is closely related to ripening.Here,we review the progress and contribution of VIGS to our understanding of fruit biology and its advantages and disadvantages in determining gene function.展开更多
Toxic aggregated amyloid-βaccumulation is a key pathogenic event in Alzheimer’s disease.Treatment approaches have focused on the suppression,deferral,or dispersion of amyloid-βfibers and plaques.Gene therapy has ev...Toxic aggregated amyloid-βaccumulation is a key pathogenic event in Alzheimer’s disease.Treatment approaches have focused on the suppression,deferral,or dispersion of amyloid-βfibers and plaques.Gene therapy has evolved as a potential therapeutic option for treating Alzheimer’s disease,owing to its rapid advancement over the recent decade.Small interfering ribonucleic acid has recently garnered considerable attention in gene therapy owing to its ability to down-regulate genes with high sequence specificity and an almost limitless number of therapeutic targets,including those that were once considered undruggable.However,lackluster cellular uptake and the destabilization of small interfering ribonucleic acid in its biological environment restrict its therapeutic application,necessitating the development of a vector that can safeguard the genetic material from early destruction within the bloodstream while effectively delivering therapeutic genes across the bloodbrain barrier.Nanotechnology has emerged as a possible solution,and several delivery systems utilizing nanoparticles have been shown to bypass key challenges regarding small interfering ribonucleic acid delivery.By reducing the enzymatic breakdown of genetic components,nanomaterials as gene carriers have considerably enhanced the efficiency of gene therapy.Liposomes,polymeric nanoparticles,magnetic nanoparticles,dendrimers,and micelles are examples of nanocarriers that have been designed,and each has its own set of features.Furthermore,recent advances in the specific delivery of neurotrophic compounds via gene therapy have provided promising results in relation to augmenting cognitive abilities.In this paper,we highlight the use of different nanocarriers in targeted gene delivery and small interfering ribonucleic acid-mediated gene silencing as a potential platform for treating Alzheimer’s disease.展开更多
The phytoene desaturase(PDS)encodes a crucial enzyme in the carotenoid biosynthesis pathway.Silencing or inhibiting PDS expression leads to the appearance of mottled,chlorosis,or albino leaves.In this study,the CDS se...The phytoene desaturase(PDS)encodes a crucial enzyme in the carotenoid biosynthesis pathway.Silencing or inhibiting PDS expression leads to the appearance of mottled,chlorosis,or albino leaves.In this study,the CDS sequence of EuPDS(Eucommia ulmoides Phytoene Desaturase)was first cloned and then PDS was silenced in Nicotiana benthamiana.Result showed the expression level of EuPDS in leaves was higher than that in the roots and stems.In N.benthamiana leaves,which were treated by Agrobacterium for 24 h,photo-bleaching was shown on the fresh leaves one week after injection and the transcript level of PDS was down-regulated during the period of emersion.This suggested that EuPDS could silence PDS of N.benthamiana,so as to cause the phenotype of leaf whitening.PDS is the main reporter gene involved in virus-induced gene silencing(VIGS).This study offered molecular evidence for identifying PDS gene involved in Carotenoid’s biosynthesis pathway and the regulation networks in E.ulmides.It also laid a useful foundation for study on leaf discoloration mechanism of other woody plants.展开更多
The introduction of Bacillus thuringiensis(Bt)cotton has reduced the burden of pests without harming the environment and human health.However,the efficacy of Bt cotton has decreased due to field-evolved resistance in ...The introduction of Bacillus thuringiensis(Bt)cotton has reduced the burden of pests without harming the environment and human health.However,the efficacy of Bt cotton has decreased due to field-evolved resistance in insect pests over time.In this review,we have discussed various factors that facilitate the evolution of resistance in cotton pests.Currently,different strategies like pyramided cotton expressing two or more distinct Bt toxin genes,refuge strategy,releasing of sterile insects,and gene silencing by RNAi are being used to control insect pests.Pyramided cotton has shown resistance against different cotton pests.The multiple genes pyramiding and silencing(MGPS)approach has been proposed for the management of cotton pests.The genome information of cotton pests is necessary for the development of MGPS-based cotton.The expression cassettes against various essential genes involved in defense,detoxification,digestion,and development of cotton pests will successfully obtain favorable agronomic characters for crop protection and production.The MGPS involves the construction of transformable artificial chromosomes,that can express multiple distinct Bt toxins and RNAi to knockdown various essential target genes to control pests.The evolution of resistance in cotton pests will be delayed or blocked by the synergistic action of high dose of Bt toxins and RNAi as well as compliance of refuge requirement.展开更多
Soybean mosaic virus(SMV)is a member of the genus Potyvirus that extensively impairs global soybean production.The full-length coding sequence of the MADS-box transcription factor Gm CAL was cloned from the SMV-resist...Soybean mosaic virus(SMV)is a member of the genus Potyvirus that extensively impairs global soybean production.The full-length coding sequence of the MADS-box transcription factor Gm CAL was cloned from the SMV-resistant soybean cultivar Kefeng 1.SMV-induced expression analysis indicated that Gm CAL responded quickly to SMV-SC8 infection in Kefeng 1 but not in NN1138-2.Gm CAL was expressed at high levels in flowers and pods but at lower levels in leaves.The gene was localized to the nucleus by subcellular localization assay.Virus-induced gene silencing did not increase the accumulation of SMV in Gm CAL-silenced Kefeng 1 plants(with silencing efficiency~80%)after SC8 inoculation.Gm CAL-silencing plants still conferred resistance to SC8 that might be owing to incomplete silencing of genes with lower expression.SMV content decreased significantly in Gm CAL-overexpressing NN1138-2 plants after SMVSC3,SMV-SC7,and SMV-SC8 inoculation in comparison with a vector control,showing that overexpression of Gm CAL conferred broad-spectrum resistance to multiple SMV strains.These results confirm that Gm CAL,a key regulator but not a specific SC8 resistance gene(Rsc8),is a positive regulatory transcription factor involved in soybean resistance to SMV.展开更多
Pre-harvest sprouting (PHS) reduces yields and grain quality, resulting in seriously economic losses in wheat. It has been showed that PHS is significantly correlated to seed dormancy levels. <em>FUSCA3</em&g...Pre-harvest sprouting (PHS) reduces yields and grain quality, resulting in seriously economic losses in wheat. It has been showed that PHS is significantly correlated to seed dormancy levels. <em>FUSCA3</em> (<em>FUS3</em>) gene is considered to be the key regulator of seed dormancy. However, little information is available about the function of <em>FUS3</em> gene (<em>TaFUS3</em>) in wheat. In this study, three homologous genes were identified in wheat grain, and their functions were investigated by gene silencing. Three full-length DNA (3477, 3534 and 3501 bp) and cDNA (1015, 1012 and 1015 bp) sequences encoding a B3 transcription factor, designated <em>TaFUS3-3A</em>, <em>TaFUS3-3B</em> and <em>TaFUS3-3D</em>, were first isolated from common wheat. The transcription of three <em>TaFUS3</em> genes in seed development and germination process was detected.<em> TaFUS3-3B</em> and<em> TaFUS3-3D</em> had similar expression profiles, and high levels of gene transcripts were detected in seeds at 25 DAP (days after pollination) and after 24 h of imbibition. However, the transcription of <em>TaFUS3-3A </em>was not detected. Silencing of <em>TaFUS3</em> in common wheat spikes resulted in increased seed germination and PHS. Compared with wild-type, the <em>TaFUS3</em>-silenced plants showed increased expression of genes related to GA biosynthesis and ABA metabolism, and decreased expression of genes associated with ABA biosynthesis. Moreover, silencing of <em>TaFUS3</em> in wheat plants led to a decrease in embryo sensitivity to ABA and changed the expression of genes involved in ABA signal transduction. The results of gene silencing indicated that<em> TaFUS3</em> plays a positive role in wheat seed dormancy and PHS-resistance, which might be associated with ABA, GA level and signal transduction.展开更多
Although Blufensins(Bln)have important functions in the response of plants to biotic stress the precise functioning of Bln in wheat remains largely unknown.Here we isolated a Bln gene(TaBln4)from Suwon 11 infected by ...Although Blufensins(Bln)have important functions in the response of plants to biotic stress the precise functioning of Bln in wheat remains largely unknown.Here we isolated a Bln gene(TaBln4)from Suwon 11 infected by Puccinia striiformis f.sp.tritici(Pst).Expression of TaBln4 increased in host plants at the early stage of infection with a virulent Pst race(CYR31)but was unchanged in response to infection by an avirulent race(CYR23).Transcription levels of TaBln4 were also regulated by hormone and abiotic stresses.Expression of TaBln4 in tobacco leaves suppressed Bax-induced programmed cell death.Knockdown of TaBln4 by virus-induced gene silencing inhibited colonization of race CYR31 by increasing the accumulation of H2O2 and formation of hypersensitive responses(HR).Transient overexpression of TaBln4 by a transient overexpression system(BSMV-VOX)increased the susceptibility of wheat to CYR31.Results from bimolecular fluorescence complementation and pull-down assays demonstrated that TaBLN4 interacted with calmodulin.Taken together,our results suggest that TaBln4 negatively regulates resistance in wheat to Pst in a reactive oxygen species(ROS)-and HR-dependent manner.展开更多
Hepatitis B virus(HBV)infection,although preventable by vaccination,remains a global health problem and a major cause of chronic liver disease.Although current treatment strategies suppress viral replication very effi...Hepatitis B virus(HBV)infection,although preventable by vaccination,remains a global health problem and a major cause of chronic liver disease.Although current treatment strategies suppress viral replication very efficiently,the optimal endpoint of hepatitis B surface antigen(HBsAg)clearance is rarely achieved.Moreover,the thorny problems of persistent chromatin-like covalently closed circular DNA and the presence of integrated HBV DNA in the host genome are ignored.Therefore,the scientific community has focused on developing innovative therapeutic approaches to achieve a functional cure of HBV,defined as undetectable HBV DNA and HBsAg loss over a limited treatment period.A deeper understanding of the HBV life cycle has led to the introduction of novel direct-acting antivirals that exert their function through multiple mechanisms,including inhibition of viral entry,transcriptional silencing,epigenetic manipulation,interference with capsid assembly,and disruption of HBsAg release.In parallel,another category of new drugs aims to restore dysregulated immune function in chronic hepatitis B accompanied by lethargic cellular and humoral responses.Stimulation of innate immunity by pattern-recognition receptor agonists leads to upregulation of antiviral cytokine expression and appears to contribute to HBV containment.Immune checkpoint inhibitors and adoptive transfer of genetically engineered T cells are breakthrough technologies currently being explored that may elicit potent HBV-specific T-cell responses.In addition,several clinical trials are attempting to clarify the role of therapeutic vaccination in this setting.Ultimately,it is increasingly recognized that elimination of HBV requires a treatment regimen based on a combination of multiple drugs.This review describes the rationale for progressive therapeutic interventions and discusses the latest findings in the field of HBV therapeutics.展开更多
Transcription factors(TFs)orchestrate the regulation of cellular gene expression and thereby determine cell functionality.In this study,we analyzed the distribution of TFs containing domains,which named as ZnFTFs,both...Transcription factors(TFs)orchestrate the regulation of cellular gene expression and thereby determine cell functionality.In this study,we analyzed the distribution of TFs containing domains,which named as ZnFTFs,both in ascomycete and basidiomycete fungi.We found that ZnFTFs were widely distributed in these fungal species,but there was more expansion of the ZnFTF class in Ascomycota than Basidiomycota.We identified 40 ZnFTFs in Ustilaginoidea virens,and demonstrated the involvement of UvZnFTF1 in vegetative growth,conidiation,pigment biosynthesis and pathogenicity.RNA-Seq analysis suggested that UvZnFTF1 may regulate different nutrient metabolism pathways,the production of secondary metabolites,and the expression of pathogen-host interaction genes and secreted protein-encodi ng genes.Analysis of the distributi on of differe nt fungal TFs in U.virens further dem on strated that UvZnFTFs make up a large TF family and may play essential biological roles in U.virens.展开更多
Cotton (Gossypium spp.) is the most important natural textile fiber crop in the world.The ideal plant architecture of cotton is suitable for mechanical harvesting and productivity in modern agricultural production.How...Cotton (Gossypium spp.) is the most important natural textile fiber crop in the world.The ideal plant architecture of cotton is suitable for mechanical harvesting and productivity in modern agricultural production.However,cotton genes regulating plant development and architecture have not been fully identified.We identified a basic helix-loop-helix (b HLH) transcription factor,GhPAS1 (PAGODA1 SUPPRESSOR1) in G.hirsutum (Upland cotton).GhPAS1 was located in the nucleus and showed a strong transcription activation effect.Tissue-specific expression patterns showed that GhPAS1 was highly expressed in floral organs,followed by high expression in early stages of ovule development and rapid fiber elongation.GhPAS1 overexpression in Arabidopsis and BRZ (brassinazole,BR biosynthesis inhibitor) treatment indicated that GhPAS1 positively regulates and responds to the BR (brassinosteroid) signaling pathway and promotes cell elongation.GhPAS1 overexpression in Arabidopsis mediated plant development in addition to increasing plant biomass.Virus-induced gene silencing of GhPAS1 indicated that down-regulation of GhPAS1 inhibited cotton growth and development,as plant height,fruit branch length,and boll size of silenced plants were lower than in control plants.Fiber length and seed yield were also lower in silenced plants.We conclude that GhPAS1,a b HLH transcription factor,regulates plant development and architecture in cotton.These findings may help breeders and researchers develop cotton cultivars with desirable agronomic characteristics.展开更多
Graphene oxide(GO) has emerged as a potential drug delivery vector. For siRNA delivery, GO should be modified to endow it with gene delivery ability and targeting effect. However, the cationic materials used previousl...Graphene oxide(GO) has emerged as a potential drug delivery vector. For siRNA delivery, GO should be modified to endow it with gene delivery ability and targeting effect. However, the cationic materials used previously usually had greater toxicity. In this study, GO was modified with a non-toxicity cationic material(chitosan) and a tumor specific monoclonal antibody(anti-EpCAM) for the delivery of survivin-siRNA(GCE/siRNA). And the vector(GCE) prepared was proved with excellent biosafety and tumor targeting effect. The GCE exhibited superior performance in loading si RNA, maintained stability in different solutions and showed excellent protection effect for survivin-siRNA in vitro. The gene silencing results in vitro showed that the m RNA level and protein level were down-regulated by 48.24% ± 2.50% and 44.12% ± 3.03%, respectively, which was equal with positive control( P > 0.05). It was also demonstrated that GCE/siRNA had a strong antitumor effect in vitro, which was attributed to the efficient antiproliferation, and migration and invasion inhibition effect of GCE/siRNA. The results in vivo indicated that GCE could accumulate siRNA in tumor tissues. The tumor inhibition rate of GCE/siRNA 54.74% ± 5.51% was significantly higher than control 4.87% ±8.49%. Moreover, GCE/siRNA showed no toxicity for blood and main organs, suggesting that it is a biosafety carrier for gene delivery. Taken together, this study provides a novel design strategy for gene delivery system and siRNA formulation.展开更多
基金Thanks for the technical support of Dr.Daqi Fu and Dr.Lanhuan Meng of China Agricultural University.This work was supported by Beijing Municipal Science and Technology Project(Grant No.Z181100002418006)the Fundamental Research Fund for the Central University(Grant No.2015ZCQ-YL-03)the World-Class Discipline Construction and Characteristic Development Guidance Funds for Beijing Forestry University(Grant No.2019XKJS0323).
文摘To understand the functional identification of large-scale genomic sequences in Forsythia,tobacco rattle virus(TRV)-mediated virus-induced gene silencing(VIGS),suitable for the plant,was explored in this study.The results showed that the TRV-mediated VIGS system could be successfully used in Forsythia for silencing the reporter gene FsPDS(Forsythia phytoene desaturase)using stem infiltration and leaf infiltrationmethods.All the treated plants were pruned below the injection site after 7–15 d infection;the FsPDS was silenced and typical photobleaching symptoms were observed in newly sprouted leaves at the whole-plant level.Meanwhile,this system has been successfully tested and verified through virus detection and qRT-PCR analysis.After the optimization,Forsythia magnesium chelatase subunit H(FsChlH)was silenced successfully in Forsythia using this system,resulting in yellow leaveswith decreased chlorophyll content.The system was stable,highly efficient and had greater rapidity and convenience,which made it suitable to study the function of genes related to physiological pathways such as growth and development,and metabolic regulation in Forsythia.
基金Supported by Fundacao Amazonia de Amparo a Estudos e Pesquisa(FAPESPA),No.174/2014
文摘AIM To establish a permanent piwi like RNA-mediated genesilencing 1(PIWIL1) gene knockout in AGP01 gastric cancer cell line using CRISPR-Cas9 system and analyze phenotypic modifications as well as gene expression alterations.METHODS CRISPR-Cas9 system used was purchased from Dharmacon GE Life Sciences(Lafayette, CO, United States) and permanent knockout was performed according to manufacturer's recommendations. Woundhealing assay was performed to investigate the effect of PIWIL1 knockout on migration capability of cells and Boyden chamber invasion assay was performed to investigate the effect on invasion capability. For the gene expression analysis, a one-color microarray-based gene expression analysis kit(Agilent Technologies, Santa Clara, CA, United States) was used according to the protocol provided by the manufacturer. RESULTS PIWIL1 gene knockout caused a significant decrease in AGP01 migration capacity as well as a significant decrease in cell invasiveness. Moreover, functional analysis based on grouping of all differentially expressed m RNAs identified a total of 35 genes(5 up-regulated and 30 down-regulated) encoding proteins involved in cellular invasion and migration. According to current literature, 9 of these 35 genes(DOCK2, ZNF503, PDE4 D, ABL1, ABL2, LPAR1, SMAD2, WASF3 and DACH1) are possibly related to the mechanisms used by PIWIL1 to promote carcinogenic effects related to migration and invasion, since their functions are consistent with the changes observed(being up-or down-regulated after knockout). CONCLUSION Taken together, these data reinforce the idea that PIWIL1 plays a crucial role in the signaling pathway of gastric cancer, regulating several genes involved in migration and invasion processes; therefore, its use as a therapeutic target may generate promising results in the treatment of gastric cancer.
文摘Alfalfa(Medicago sativa L.) is a legume forage that is widely cultivated owing to its high biomass yield and favorable nutrient values. However, alfalfa contains relatively high lignin, which limits its utilization.Downregulation of two transcriptional factors, Transparent Testa8(TT8) and Homeobox12(HB12), has been proposed to reduce lignin content in alfalfa. Therefore, silencing of TT8(TT8i) and HB12(HB12i) in alfalfa was achieved by RNAi technology. The objective of this project was to determine effect of gene modification through silencing of TT8 and HB12 genes in alfalfa plants on lignin and phenolic content,bioenergic value, nutrient supply from rumen degradable and undegradable fractions, and in vitro ammonia production in response to the silencing of TT8 and HB12 genes in alfalfa. All gene silenced alfalfa plants(5 TT8i and 11 HB12i) were grown under greenhouse conditions with wild type as a control.Samples were analyzed for bioactive compounds, degradation fractions, truly digestible nutrients, energetic values and in vitro ammonia productions in ruminant systems. Furthermore, relationships between physiochemical, metabolic and fermentation characteristics and molecular spectral parameters were determined using vibrational molecular spectroscopy. Results showed that the HB12i had higher lignin, while TT8i had higher phenolics. Both silenced genotypes had higher rumen slowly degraded carbohydrate fractions and truly digestible neutral detergent fiber, but lower rumen degradable protein fractions. Moreover, the HB12i had lower truly digestible crude protein, energetic values and ammonia production compared with other silenced genotypes. In addition, in relation to the nutritive values of alfalfa, structural carbohydrate parameters were negatively correlated, whereas alpha/beta ratio in protein structure was positively correlated. Furthermore, good predictions were obtained for degradation of protein and carbohydrate fractions and energy values from molecular spectral parameters. In conclusion, silencing of the TT8 and HB12 genes decreased protein availability and increased fiber availability. Silencing of the HB12 gene also increased lignin and decreased energy and rumen ammonia production. Moreover, nutritional alterations were closely correlated with molecular spectral parameters. Therefore, gene modification through silencing the TT8 and HB12 genes in alfalfa influenced physiochemical, metabolic and fermentation characteristics.
基金funded by the National Key Research and Development Program of China(2021YFD1400400)the National Natural Science Foundation of China(32172385 and 3193089).
文摘Tomato yellow leaf curl virus(TYLCV)is known to encode 6 canonical viral proteins.Our recent study revealed that TYLCV also encodes some additional small proteins with potential virulence functions.The fifth ORF of TYLCV in the complementary sense,which we name C5,is evolutionarily conserved,but little is known about its expression and function during viral infection.Here,we confirmed the expression of the TYLCV C5 by analyzing the promoter activity of its upstream sequences and by detecting the C5 protein in infected cells by using a specific custom-made antibody.Ectopic expression of C5 using a potato virus X(PVX)vector resulted in severe mosaic symptoms and higher virus accumulation levels followed by a burst of reactive oxygen species(ROS)in Nicotiana benthamiana plants.C5 was able to effectively suppress local and systemic post-transcriptional gene silencing(PTGS)induced by single-stranded GFP but not double-stranded GFP,and reversed the transcriptional gene silencing(TGS)of GFP.Furthermore,the mutation of C5 in TYLCV inhibited viral replication and the development of disease symptoms in infected plants.Transgenic overexpression of C5 could complement the virulence of a TYLCV infectious clone encoding a dysfunctional C5.Collectively,this study reveals that TYLCV C5 is a pathogenicity determinant and RNA silencing suppressor,hence expanding our knowledge of the functional repertoire of the TYLCV proteome.
文摘Global prophylactic vaccination programmes have helped to curb new hepatitis B virus(HBV)infections.However,it is estimated that nearly 300 million people are chronically infected and have a high risk of developing hepatocellular carcinoma.As such,HBV remains a serious health priority and the development of novel curative therapeutics is urgently needed.Chronic HBV infection has been attributed to the persistence of the covalently closed circular DNA(cccDNA)which establishes itself as a minichromosome in the nucleus of hepatocytes.As the viral transcription intermediate,the cccDNA is responsible for producing new virions and perpetuating infection.HBV is dependent on various host factors for cccDNA formation and the minichromosome is amenable to epigenetic modifications.Two HBV proteins,X(HBx)and core(HBc)promote viral replication by modulating the cccDNA epigenome and regulating host cell responses.This includes viral and host gene expression,chromatin remodeling,DNA methylation,the antiviral immune response,apoptosis,and ubiquitination.Elimination of the cccDNA minichromosome would result in a sterilizing cure;however,this may be difficult to achieve.Epigenetic therapies could permanently silence the cccDNA minichromosome and promote a functional cure.This review explores the cccDNA epigenome,how host and viral factors influence transcription,and the recent epigenetic therapies and epigenome engineering approaches that have been described.
基金supported by the Vietnamese Studentship to TH(Ministry of Education and Training,Decision No 322/QD-TTg)NERC(UK)grants to TD(NER/A/S/2003/00547)+1 种基金HW(NER/A/S/2003/00548,NE/E008933/1)CEH Biodiversity research fund to HW(C02875).
文摘Plant Dicer-like(DCL)and Argonaute(AGO)are the key enzymes involved in anti-virus post-transcriptional gene silencing(AV-PTGS).Here we show that AV-PTGS exhibited nucleotide preference by calculating a relative AV-PTGS efficiency on processing viral RNA substrates.In comparison with genome sequences of dicot-infecting Turnip mosaic virus(TuMV)and monocot-infecting Cocksfoot streak virus(CSV),viral-derived small interfering RNAs(vsiRNAs)displayed positive correlations between AV-PTGS efficiency and G+C content(GC%).Further investigations on nucleotide contents revealed that the vsiRNA populations had G-biases.This finding was further supported by our analyses of previously reported vsiRNA populations in diverse plant-virus associations,and AGO associated Arabidopsis endogenous siRNA populations,indicating that plant AGOs operated with G-preference.We further propose a hypothesis that AV-PTGS imposes selection pressure(s)on the evolution of plant viruses.This hypothesis was supported when potyvirus genomes were analysed for evidence of GC elimination,suggesting that plant virus evolution to have low GC%genomes would have a unique function,which is to reduce the host AV-PTGS attack during infections.
基金This work was supported by the National Natural Science Foundation of China(No.21575088)the Natural Science Foundation of Shanghai(No.19ZR1474200).
文摘BCL-2 gene as well as its products is recognized as a promising target for the molecular targeted therapy of tumors.However,due to certain defense measures of tumor cells,the therapeutic effect based on the gene silencing of BCL-2 is greatly reduced.Here we fabricate a smart response nucleic acid therapeutic that could silence the gene effectively through a dual-targeted and cascade-enhanced strategy.In brief,nano-graphene oxide(GO),working as a nano-carrier,is loaded with a well-designed DNAzyme,which can target and silence the BCL-2 mRNA.Furthermore,upon binding with the BCL-2 mRNA,the enzymatic activity of the DNAzyme can be initiated,cutting a substrate oligonucleotide to produce an anti-nucleolin aptamer AS1411.Nucleolin,a nucleolar phosphoprotein,is known as a stabilizer of BCL-2 mRNA.Via binding and inactivating the nucleolin,AS1411 can destabilize BCL-2 mRNA.By this means of simultaneously targeting mRNA and its stabilizer in an integrated system,effective silencing of the BCL-2 gene of tumor cells is achieved at both the cellular and in vivo levels.After being dosed with this nucleic acid therapeutic and without any chemotherapeutics,apoptosis of tumor cells at the cellular level and apparent shrinkage of tumors in vivo are observed.By labeling a molecular beacon on the substrate of DNAzyme,visualization of the enzymatic activity as well as the tumor in vivo can be also achieved.Our work presents a pure bio-therapeutic strategy that has positive implications for enhancing tumor treatment and avoiding side effects of chemotherapeutics.
基金supported by grants from the National Natural Science Foundation of China(nos.81601597,21904119,319009919,21621003,and U1704178)Innovation Talent Support Program of Henan Province(no.19HASTIT006)+2 种基金Key Scientific Research Projects(Education Department of Henan Province,nos.17A350003 and 20A350009)Key Scientific Research Projects(Science and Technology Department of Henan Province,no.192102310147)Postdoctoral Science Foundation of China(nos.2018T110745 and 2017M622380).
文摘Oligonucleotide drugs have been used widely as therapeutic agents for gene therapy,while their instability in biological media and inefficiency for intracellular delivery remain major hurdles for practical in vivo applications.Herein,we report a circular Y-shaped aptamer–DNAzyme conjugate(cYAD)for highly efficient in vivo gene silencing via RNA cleavage,which can been employed in various disease treatments,including cancer,inflammation,as well as viral infections.Systematic studies revealed that cyclization of the DNA structure could improve the stability of oligonucleotide drugs in vivo.Besides,the bivalent aptamer motifs provided a specific and enhanced tumor cell targeting ability for accumulation and retention of the oligonucleotide drugs at the tumor site.As a proof of concept,a widely applicable Na+-dependent fluorescent sensor,NaA43 DNAzyme,was used to inhibit MET gene expression in mice tumor model tissues,which exhibited highly efficient gene silencing performance in vivo,which confirmed our findings with cYAD.This strategy provides a novel approach for the construction of oligonucleotide drugs for practical therapeutic applications.
文摘With the development of bioinformatics,it is easy to obtain information and data about thousands of genes,but the determi nation of the functions of these genes depends on methods for rapid and effective functi on al identification.Virus-induced gene sile ncing(VIGS)is a mature method of gene functional identification developed over the last 20 years,which has been widely used in many research fields involving many species.Fruit quality formation is a complex biological process,which is closely related to ripening.Here,we review the progress and contribution of VIGS to our understanding of fruit biology and its advantages and disadvantages in determining gene function.
基金supported by the Intramural Research Program National Institute on Aginq,NIH。
文摘Toxic aggregated amyloid-βaccumulation is a key pathogenic event in Alzheimer’s disease.Treatment approaches have focused on the suppression,deferral,or dispersion of amyloid-βfibers and plaques.Gene therapy has evolved as a potential therapeutic option for treating Alzheimer’s disease,owing to its rapid advancement over the recent decade.Small interfering ribonucleic acid has recently garnered considerable attention in gene therapy owing to its ability to down-regulate genes with high sequence specificity and an almost limitless number of therapeutic targets,including those that were once considered undruggable.However,lackluster cellular uptake and the destabilization of small interfering ribonucleic acid in its biological environment restrict its therapeutic application,necessitating the development of a vector that can safeguard the genetic material from early destruction within the bloodstream while effectively delivering therapeutic genes across the bloodbrain barrier.Nanotechnology has emerged as a possible solution,and several delivery systems utilizing nanoparticles have been shown to bypass key challenges regarding small interfering ribonucleic acid delivery.By reducing the enzymatic breakdown of genetic components,nanomaterials as gene carriers have considerably enhanced the efficiency of gene therapy.Liposomes,polymeric nanoparticles,magnetic nanoparticles,dendrimers,and micelles are examples of nanocarriers that have been designed,and each has its own set of features.Furthermore,recent advances in the specific delivery of neurotrophic compounds via gene therapy have provided promising results in relation to augmenting cognitive abilities.In this paper,we highlight the use of different nanocarriers in targeted gene delivery and small interfering ribonucleic acid-mediated gene silencing as a potential platform for treating Alzheimer’s disease.
基金This study was funded by the National Natural Science Foundation of China(Nos.31870285,31660076&32160384)the Open Fund for Key Laboratory of Ministry of Education and Science(No.KY[2022]366)Guizhou Province High-Level Innovative Talent Training Program Project(No.[2016]4003).
文摘The phytoene desaturase(PDS)encodes a crucial enzyme in the carotenoid biosynthesis pathway.Silencing or inhibiting PDS expression leads to the appearance of mottled,chlorosis,or albino leaves.In this study,the CDS sequence of EuPDS(Eucommia ulmoides Phytoene Desaturase)was first cloned and then PDS was silenced in Nicotiana benthamiana.Result showed the expression level of EuPDS in leaves was higher than that in the roots and stems.In N.benthamiana leaves,which were treated by Agrobacterium for 24 h,photo-bleaching was shown on the fresh leaves one week after injection and the transcript level of PDS was down-regulated during the period of emersion.This suggested that EuPDS could silence PDS of N.benthamiana,so as to cause the phenotype of leaf whitening.PDS is the main reporter gene involved in virus-induced gene silencing(VIGS).This study offered molecular evidence for identifying PDS gene involved in Carotenoid’s biosynthesis pathway and the regulation networks in E.ulmides.It also laid a useful foundation for study on leaf discoloration mechanism of other woody plants.
基金This work was supported by the Genetically Modified Organisms Breeding Major Project of China(2019ZX08010004–004)the National Natural Science Foundation of China(31901579).
文摘The introduction of Bacillus thuringiensis(Bt)cotton has reduced the burden of pests without harming the environment and human health.However,the efficacy of Bt cotton has decreased due to field-evolved resistance in insect pests over time.In this review,we have discussed various factors that facilitate the evolution of resistance in cotton pests.Currently,different strategies like pyramided cotton expressing two or more distinct Bt toxin genes,refuge strategy,releasing of sterile insects,and gene silencing by RNAi are being used to control insect pests.Pyramided cotton has shown resistance against different cotton pests.The multiple genes pyramiding and silencing(MGPS)approach has been proposed for the management of cotton pests.The genome information of cotton pests is necessary for the development of MGPS-based cotton.The expression cassettes against various essential genes involved in defense,detoxification,digestion,and development of cotton pests will successfully obtain favorable agronomic characters for crop protection and production.The MGPS involves the construction of transformable artificial chromosomes,that can express multiple distinct Bt toxins and RNAi to knockdown various essential target genes to control pests.The evolution of resistance in cotton pests will be delayed or blocked by the synergistic action of high dose of Bt toxins and RNAi as well as compliance of refuge requirement.
基金the National Key Research and Development Program of China(2017YFD0101500)the National Natural Science Foundation of China(31671718)+3 种基金and China Agriculture Research System of MOF and MARA(CARS-04)the Jiangsu Collaborative Innovation Center for Modern Crop Production(JCICMCP)Collaborative Innovation Center for Modern Crop Production co-sponsored by Province and Ministry(CIC-MCP)the Program for Changjiang Scholars and Innovative Research Team in University(PCSIRT_17R55)。
文摘Soybean mosaic virus(SMV)is a member of the genus Potyvirus that extensively impairs global soybean production.The full-length coding sequence of the MADS-box transcription factor Gm CAL was cloned from the SMV-resistant soybean cultivar Kefeng 1.SMV-induced expression analysis indicated that Gm CAL responded quickly to SMV-SC8 infection in Kefeng 1 but not in NN1138-2.Gm CAL was expressed at high levels in flowers and pods but at lower levels in leaves.The gene was localized to the nucleus by subcellular localization assay.Virus-induced gene silencing did not increase the accumulation of SMV in Gm CAL-silenced Kefeng 1 plants(with silencing efficiency~80%)after SC8 inoculation.Gm CAL-silencing plants still conferred resistance to SC8 that might be owing to incomplete silencing of genes with lower expression.SMV content decreased significantly in Gm CAL-overexpressing NN1138-2 plants after SMVSC3,SMV-SC7,and SMV-SC8 inoculation in comparison with a vector control,showing that overexpression of Gm CAL conferred broad-spectrum resistance to multiple SMV strains.These results confirm that Gm CAL,a key regulator but not a specific SC8 resistance gene(Rsc8),is a positive regulatory transcription factor involved in soybean resistance to SMV.
文摘Pre-harvest sprouting (PHS) reduces yields and grain quality, resulting in seriously economic losses in wheat. It has been showed that PHS is significantly correlated to seed dormancy levels. <em>FUSCA3</em> (<em>FUS3</em>) gene is considered to be the key regulator of seed dormancy. However, little information is available about the function of <em>FUS3</em> gene (<em>TaFUS3</em>) in wheat. In this study, three homologous genes were identified in wheat grain, and their functions were investigated by gene silencing. Three full-length DNA (3477, 3534 and 3501 bp) and cDNA (1015, 1012 and 1015 bp) sequences encoding a B3 transcription factor, designated <em>TaFUS3-3A</em>, <em>TaFUS3-3B</em> and <em>TaFUS3-3D</em>, were first isolated from common wheat. The transcription of three <em>TaFUS3</em> genes in seed development and germination process was detected.<em> TaFUS3-3B</em> and<em> TaFUS3-3D</em> had similar expression profiles, and high levels of gene transcripts were detected in seeds at 25 DAP (days after pollination) and after 24 h of imbibition. However, the transcription of <em>TaFUS3-3A </em>was not detected. Silencing of <em>TaFUS3</em> in common wheat spikes resulted in increased seed germination and PHS. Compared with wild-type, the <em>TaFUS3</em>-silenced plants showed increased expression of genes related to GA biosynthesis and ABA metabolism, and decreased expression of genes associated with ABA biosynthesis. Moreover, silencing of <em>TaFUS3</em> in wheat plants led to a decrease in embryo sensitivity to ABA and changed the expression of genes involved in ABA signal transduction. The results of gene silencing indicated that<em> TaFUS3</em> plays a positive role in wheat seed dormancy and PHS-resistance, which might be associated with ABA, GA level and signal transduction.
基金supported by the National Key Research and Development Program of China(2021YFD1401000)the International Science and Technology Cooperation Project of Shaanxi Provincial Key R&D Plan-Key Project(2020KWZ-009)+1 种基金the Shaanxi Innovation Team Project(2018TD-004)the 111 Project of the Ministry of Education of China(B07049).
文摘Although Blufensins(Bln)have important functions in the response of plants to biotic stress the precise functioning of Bln in wheat remains largely unknown.Here we isolated a Bln gene(TaBln4)from Suwon 11 infected by Puccinia striiformis f.sp.tritici(Pst).Expression of TaBln4 increased in host plants at the early stage of infection with a virulent Pst race(CYR31)but was unchanged in response to infection by an avirulent race(CYR23).Transcription levels of TaBln4 were also regulated by hormone and abiotic stresses.Expression of TaBln4 in tobacco leaves suppressed Bax-induced programmed cell death.Knockdown of TaBln4 by virus-induced gene silencing inhibited colonization of race CYR31 by increasing the accumulation of H2O2 and formation of hypersensitive responses(HR).Transient overexpression of TaBln4 by a transient overexpression system(BSMV-VOX)increased the susceptibility of wheat to CYR31.Results from bimolecular fluorescence complementation and pull-down assays demonstrated that TaBLN4 interacted with calmodulin.Taken together,our results suggest that TaBln4 negatively regulates resistance in wheat to Pst in a reactive oxygen species(ROS)-and HR-dependent manner.
文摘Hepatitis B virus(HBV)infection,although preventable by vaccination,remains a global health problem and a major cause of chronic liver disease.Although current treatment strategies suppress viral replication very efficiently,the optimal endpoint of hepatitis B surface antigen(HBsAg)clearance is rarely achieved.Moreover,the thorny problems of persistent chromatin-like covalently closed circular DNA and the presence of integrated HBV DNA in the host genome are ignored.Therefore,the scientific community has focused on developing innovative therapeutic approaches to achieve a functional cure of HBV,defined as undetectable HBV DNA and HBsAg loss over a limited treatment period.A deeper understanding of the HBV life cycle has led to the introduction of novel direct-acting antivirals that exert their function through multiple mechanisms,including inhibition of viral entry,transcriptional silencing,epigenetic manipulation,interference with capsid assembly,and disruption of HBsAg release.In parallel,another category of new drugs aims to restore dysregulated immune function in chronic hepatitis B accompanied by lethargic cellular and humoral responses.Stimulation of innate immunity by pattern-recognition receptor agonists leads to upregulation of antiviral cytokine expression and appears to contribute to HBV containment.Immune checkpoint inhibitors and adoptive transfer of genetically engineered T cells are breakthrough technologies currently being explored that may elicit potent HBV-specific T-cell responses.In addition,several clinical trials are attempting to clarify the role of therapeutic vaccination in this setting.Ultimately,it is increasingly recognized that elimination of HBV requires a treatment regimen based on a combination of multiple drugs.This review describes the rationale for progressive therapeutic interventions and discusses the latest findings in the field of HBV therapeutics.
基金supported by the National Natural Science Foundation of China(Grant No.31601593)the Young Elite Scientist Sponsorship of China Association for Science and Technology(Grant No.YESS20170108)the Natural Science Foundation of Jiangsu Province,China(Grant No.BK20160588).
文摘Transcription factors(TFs)orchestrate the regulation of cellular gene expression and thereby determine cell functionality.In this study,we analyzed the distribution of TFs containing domains,which named as ZnFTFs,both in ascomycete and basidiomycete fungi.We found that ZnFTFs were widely distributed in these fungal species,but there was more expansion of the ZnFTF class in Ascomycota than Basidiomycota.We identified 40 ZnFTFs in Ustilaginoidea virens,and demonstrated the involvement of UvZnFTF1 in vegetative growth,conidiation,pigment biosynthesis and pathogenicity.RNA-Seq analysis suggested that UvZnFTF1 may regulate different nutrient metabolism pathways,the production of secondary metabolites,and the expression of pathogen-host interaction genes and secreted protein-encodi ng genes.Analysis of the distributi on of differe nt fungal TFs in U.virens further dem on strated that UvZnFTFs make up a large TF family and may play essential biological roles in U.virens.
基金supported by the Funds for Creative Research Groups of China (31621005)the National Transgenic Major Project of China (2018ZX0800921B)。
文摘Cotton (Gossypium spp.) is the most important natural textile fiber crop in the world.The ideal plant architecture of cotton is suitable for mechanical harvesting and productivity in modern agricultural production.However,cotton genes regulating plant development and architecture have not been fully identified.We identified a basic helix-loop-helix (b HLH) transcription factor,GhPAS1 (PAGODA1 SUPPRESSOR1) in G.hirsutum (Upland cotton).GhPAS1 was located in the nucleus and showed a strong transcription activation effect.Tissue-specific expression patterns showed that GhPAS1 was highly expressed in floral organs,followed by high expression in early stages of ovule development and rapid fiber elongation.GhPAS1 overexpression in Arabidopsis and BRZ (brassinazole,BR biosynthesis inhibitor) treatment indicated that GhPAS1 positively regulates and responds to the BR (brassinosteroid) signaling pathway and promotes cell elongation.GhPAS1 overexpression in Arabidopsis mediated plant development in addition to increasing plant biomass.Virus-induced gene silencing of GhPAS1 indicated that down-regulation of GhPAS1 inhibited cotton growth and development,as plant height,fruit branch length,and boll size of silenced plants were lower than in control plants.Fiber length and seed yield were also lower in silenced plants.We conclude that GhPAS1,a b HLH transcription factor,regulates plant development and architecture in cotton.These findings may help breeders and researchers develop cotton cultivars with desirable agronomic characteristics.
基金supported by the National Natural Science Foundation(81502688)Beijing Natural Science Foundation Program and Scientific Research Key Program of Beijing Municipal Commission of Education(KM201810025019)+2 种基金a basic-clinical key research Grant(16JL72,17JL67)from Capital Medical Universitythe Importation and Development of High-Caliber Talents Project of Beijing Municipal Institutions(2013–2015)Natural Science Foundation of Capital Medical University(1210020232)。
文摘Graphene oxide(GO) has emerged as a potential drug delivery vector. For siRNA delivery, GO should be modified to endow it with gene delivery ability and targeting effect. However, the cationic materials used previously usually had greater toxicity. In this study, GO was modified with a non-toxicity cationic material(chitosan) and a tumor specific monoclonal antibody(anti-EpCAM) for the delivery of survivin-siRNA(GCE/siRNA). And the vector(GCE) prepared was proved with excellent biosafety and tumor targeting effect. The GCE exhibited superior performance in loading si RNA, maintained stability in different solutions and showed excellent protection effect for survivin-siRNA in vitro. The gene silencing results in vitro showed that the m RNA level and protein level were down-regulated by 48.24% ± 2.50% and 44.12% ± 3.03%, respectively, which was equal with positive control( P > 0.05). It was also demonstrated that GCE/siRNA had a strong antitumor effect in vitro, which was attributed to the efficient antiproliferation, and migration and invasion inhibition effect of GCE/siRNA. The results in vivo indicated that GCE could accumulate siRNA in tumor tissues. The tumor inhibition rate of GCE/siRNA 54.74% ± 5.51% was significantly higher than control 4.87% ±8.49%. Moreover, GCE/siRNA showed no toxicity for blood and main organs, suggesting that it is a biosafety carrier for gene delivery. Taken together, this study provides a novel design strategy for gene delivery system and siRNA formulation.
