World crop production requires highly-productive varieties of agricultural crops,which are resistant to pest organisms.Such varieties are also of great importance for the Uzbekistan.Their
Scientific and technological services are necessary for strengthening agriculture.Under the new situation,agricultural research institutes should give full play to their advantages,strive to innovate scientific and te...Scientific and technological services are necessary for strengthening agriculture.Under the new situation,agricultural research institutes should give full play to their advantages,strive to innovate scientific and technological services methods,and improve scientific and technological service levels.Combined with the practice of science and technology work of Institute of Plant Protection of Hebei Academy of Agricultural and Forestry Sciences,this paper made an in-depth analysis on the present situations and existing problems in the scientific and technological services of agricultural research institutes.Based on the analysis,it came up with recommendations including change ideological concepts,strengthening service awareness,adhering to people-oriented principle,enhancing the team building,improving mechanism construction,stimulating innovative vitality,exploring service methods,and enriching service connotation,so as to improve scientific and technological service works.展开更多
China is one of the countries in the world that is severely damaged by crop diseases,pests,and weeds.There are more than 1 700 species of agricultural pests occurring annually,53 of which are on the list of the 100 wo...China is one of the countries in the world that is severely damaged by crop diseases,pests,and weeds.There are more than 1 700 species of agricultural pests occurring annually,53 of which are on the list of the 100 worst pests in the world(Chen and Wang 2014;Wu 2018).Currently,China is still greatly challenged by a growing problem of agricultural pests that th reate n the economy and health and pose ecological risks underthe conditions of global climate change,economic integration,crop structure adjustment and so on.Plant protect!on agai nst crop diseases,in sect pests and noxious weeds is necessary to ensure high-quality crop production and food safety.However,traditional strategies of plant protect!on have mainly involved chemical pesticides.展开更多
In order to have an overview of implementation of the subsidy policy for purchase of plant protection machinery in Fujian Province, based on the questionnaire data on Fujian Province, we use Logit model to conduct emp...In order to have an overview of implementation of the subsidy policy for purchase of plant protection machinery in Fujian Province, based on the questionnaire data on Fujian Province, we use Logit model to conduct empirical analysis of factors influencing farmers' willingness to participate in the subsidy policy for purchase of plant protection machinery. Research results show that there are 69.4% of farmers willing to participate in the subsidy policy for purchase of plant protection machinery; farmers' growing area has a significant impact on the willingness to participate in the subsidy policy for purchase of plant protection machinery, and there is negative correlation; educational level, experience in planting, family farming pure income all have a significant positive impact on the willingness to participate in the subsidy policy.展开更多
The article introduces the main practices and achievements of the Environment and Plant Protection Institute of Chinese Academy of Tropical Agricultural Sciences in promoting the sharing of large-scale instruments and...The article introduces the main practices and achievements of the Environment and Plant Protection Institute of Chinese Academy of Tropical Agricultural Sciences in promoting the sharing of large-scale instruments and equipment in recent years,analyzes the existing problems in the management system,management team,assessment incentives and maintenance guarantee,and proposes improvement measures and suggestions from aspects of improving the sharing management system,strengthening management team building,strengthening sharing assessment and incentives,improving maintenance capabilities and expanding external publicity,to further improve the sharing management of large-scale instruments and equipment.展开更多
【Objectives】Si and microbial application could relieve the crop replanting problems(CRPs).We further studied the change of key microorganisms that are related to the beneficial effects,aiming at provide reference fo...【Objectives】Si and microbial application could relieve the crop replanting problems(CRPs).We further studied the change of key microorganisms that are related to the beneficial effects,aiming at provide reference for the manufacture and application of both microbial agents and Si fertilizer in food lily production.【Methods】A field experiment was conducted over a three-year period,from March 2019 to March 2022.The experimental field had been continuously cultivated with lily for 9 years.Three treatments were established:silicon fertilizer(SF),microbial agents(“Special 8^(TM)”,MF),and combined application of silicon fertilizer and microbial agents(SMF).A control group with blank soil(CK)was also included.At seedling stage of Lanzhou lilies in 2020 and 2021,the shoot and bulb dry weight,and the plant height and stem diameter of Lanzhou lilies were investigated for calculation of seedling index.In July 2020,20 plants were selected in each plot,and root zone soils were sampled at a depth of 20 cm,10 cm away from the roots,and then mixed to form a composite sample.The soil available Si and organic matter content were analyzed,and the fungal community structure and some specific microbial groups in soils were determined with high-throughput sequencing of ITS.【Results】All the three treatments significantly enhanced the lily plant growth and the seedling index,compared to CK.Besides,SF and MF treatments increased the relative abundances(RA)and diversity of fungal communities,and altered the community structures.The RA of some specific groups were found to be significantly correlated with the seedling index and/or soil available Si.Of them,the RA of the genera Fusarium,Dactylonectria,Humicola,Stilbella,and the species Humicola_grisea showed a positive correlation,while that of the genera Mortierella,Stilbella,Holtermanniella,and the species Mortierella_fatshederae showed a negative correlation with seedling index.The genera Fusarium,Stilbella,the species Humicola_grisea,and Dactylonectria_estremocensis showed a positive correlation,while the genura Stilbella,and the species Mortierella fatshederae showed a negative correlation with available Si content.In the co-occurence network of top twenty fungal genera and top sixteen bacterial genera(RA>0.2%),Holtermanniella was the only genus that interacted with the bacteria and negatively correlated with bacterial genus Blastococcus.Holtermanniella was also the most densely connected genera,followed by the genus Fusarium,Didymella and Humicola.In addition,the genus Holtermanniella was the key species connecting fungal and bacterial community in soil.Fungal functional prediction revealed that SF,MF and SMF treatments decreased plant pathogens guilds and increased the beneficial guilds Ectomycorrhizal,plant saprophyte,leaf saprophyte,and arbuscular mycorrhizal compared to CK.【Conclusions】Combined application of silicon fertilizer and microbial agents can alleviate continuous replanting problems of Lanzhou lilies through restoring the fungal community diversity,and promoting plant residue depredation,thus reducing soil born disease incidence.The beneficial genus Humicola and its one species H.grisea acts as bioconversion,and the genus Acremonium acts as plant pathogen inhibitor.展开更多
Asian citrus psyllid(ACP)is a significant pest of citrus crops that can transmit citrus Huanglongbing(HLB)by feeding on the phloem sap of citrus plants,which poses a significant threat to citrus production.Volatile si...Asian citrus psyllid(ACP)is a significant pest of citrus crops that can transmit citrus Huanglongbing(HLB)by feeding on the phloem sap of citrus plants,which poses a significant threat to citrus production.Volatile signal chemicals with plant communication functions can effectively enhance the resistance of recipient plants to herbivorous insects with minimal impacts on plant growth.While(E)-4,8-dimethyl-1,3,7-nonatriene(DMNT),(E,E)-4,8,12-trimethyl-1,3,7,11-tridecene(TMTT),(E)-β-caryophyllene,and dimethyl disulfide(DMDS),are known as signaling molecules in guava-sweet orange communication,whether these four chemical signals can enhance the resistance of Citrus sinensis to feeding by ACP adults with no apparent costs in terms of plant growth remains unclear.Therefore,this study measured the effect of non-damaging induction by DMNT,TMTT,(E)-β-caryophyllene,and DMDS on the ability of C.sinensis to resist feeding by ACP,as well as their impacts on the defensive phytochemicals,defensive enzymes,functional nutrients,Photosystem II's utilization and allocation of light energy,photosynthetic pigments,growth conditions,and leaf stomatal aperture in C.sinensis.The results indicate that non-damaging induction by these four chemicals can enhance the activity of the defensive enzyme polyphenol oxidase(PPO)and increase the contents of total phenols,tannins,and terpenoid defensive phytochemicals within C.sinensis,thereby enhancing the resistance of C.sinensis to ACP feeding.Specifically,DMNT and DMDS exhibit more significant effects in inducing resistance compared to TMTT and(E)-β-caryophyllene.The characteristics of chlorophyll fluorescence parameters and changes in photosynthetic pigments in C.sinensis during different post-exposure induction periods revealed these chemicals can maintain the stability of the photosynthetic system in C.sinensis and regulate its capacity to capture,transmit,and distribute light energy,which significantly enhances the non-photochemical quenching ability of C.sinensis.In addition,detailed measurements of the water content,leaf mass per unit area(LMA),functional nutrients(soluble protein,soluble sugar,and amino acids),and stomatal parameters in C.sinensis leaves further indicated that the non-destructive induction by these chemicals can optimize the levels of functional nutrients in C.sinensis,primarily manifesting as the upregulation of soluble sugars,proline,or soluble proteins,and reduction of stomatal area and aperture,which maintains a stable leaf water content and LMA,thereby enhancing resistance to ACP while sustaining the healthy growth of C.sinensis.These results fully substantiate that the non-damaging induction by the signal chemicals DMNT,TMTT,(E)-β-caryophyllene,and DMDS can enhance the resistance of C.sinensis to ACP feeding while maintaining the balance between pest resistance and growth.This balance prevents any catastrophic effects on the growth of C.sinensis,so these agents can potentially be integrated with other pest management strategies for the collective protection of crops.This study provides theoretical support and assistance for the development of signal chemical inducers for the prevention and management of ACP in agricultural systems.展开更多
The sugar beet cyst nematode(Heterodera schachtii) is one of the most destructive pathogens in sugar beet production, which causes serious economic losses every year. Few molecular details of effectors of H. schachtii...The sugar beet cyst nematode(Heterodera schachtii) is one of the most destructive pathogens in sugar beet production, which causes serious economic losses every year. Few molecular details of effectors of H. schachtii parasitism are known. We analyzed the genome and transcriptome data of H. schachtii and identified multiple potential predicted proteins. After filtering out predicted proteins with high homology to other plant-parasitic nematodes, we performed functional validation of the remaining effector proteins. 37 putative effectors of H. schachtii were screened based on the Nicotiana benthamiana system for identifying the effectors that inhibit plant immune response, eventually determines 13 candidate effectors could inhibit cell death caused by Bax. Among the 13 effectors, nine have the ability to inhibit GPA2/RBP1-induced cell death. All 13 effectortriggered immunity(ETI) suppressor genes were analyzed by qRT-PCR and confirmed to result in a significant downregulation of one or more defense genes during infection compared to empty vector. For in situ hybridization,13 effectors were specifically expressed and located in esophageal gland cells. These data and functional analysis set the stage for further studies on the interaction of H. schachtii with host and H. schachtii parasitic control.展开更多
LysM proteins contain the lysin domain(LysM),bind chitin and are found in various organisms including fungi.In phytopathogenic fungi,certain LysM proteins act as effectors to inhibit host immunity,thus increasing fung...LysM proteins contain the lysin domain(LysM),bind chitin and are found in various organisms including fungi.In phytopathogenic fungi,certain LysM proteins act as effectors to inhibit host immunity,thus increasing fungal virulence.However,our understanding of the LysM protein family in Setosphaeria turcica is limited.In this study,eight StLysM genes are identified and designated as StLysM1 to StLysM8.The analysis of sequence features indicates that five proteins(StLysM1,StLysM2,StLysM5,StLysM6,and StLysM7)are potential effectors.Phylogenetic analysis suggests that the StLysMs are divided into fungal/bacterial and fungus-specific subclasses.Domain architecture analysis reveals that the five StLysM effectors exclusively harbor the LysM domain,whereas the other three StLysM proteins contain additional functional domains.Sequence conservation analysis shows that the fungal-specific LysM domain sequences share the ^(8)GDxTC^(12) and ^(29)WNP^(31) motifs as well as three highly conserved cysteine residues.Conversely,the LysM domain sequences from the bacterial/fungal branch have few conserved sites.Moreover,expression profiling analysis shows that the StLysM1 gene is significantly upregulated during the infection of maize.Yeast secretion assays and transient expression experiments demonstrate that StLysM1 is a secreted protein that can suppress BAX/INF1-induced programmed cell death in Nicotiana benthamiana.Further functional analysis suggests that St Lys M1 cannot interact with itself but it can bind chitin.The transient expression of StLysM1 inhibits the chitin-triggered plant immune response,increasing susceptibility to the phytopathogenic fungus Botrytis cinerea in N.benthamiana.This study reveals that the S.turcica LySM protein family consists of eight members,highlighting the significance of StLysM1 as a vital effector in regulating plant immunity.The results provide insight into StLysMs and establish a foundation for understanding the roles of StLysM proteins in the pathogenic process of S.turcica.展开更多
The world is facing a consistent increase in human population and a noticeable decrease in cultivable lands due to soil salinization,abrupt climatic changes,and less rainfall.These problems have increased the importan...The world is facing a consistent increase in human population and a noticeable decrease in cultivable lands due to soil salinization,abrupt climatic changes,and less rainfall.These problems have increased the importance of finding ecologically sustainable solutions to ensure global food security.Plant growth-promoting rhizobacteria can be advantageous to enhancing plant productivity and safeguarding against environmental stresses.They may assist plants by atmospheric nitrogen fixation,nutrient recycling,phosphate solubilization,iron sequestration via siderophore formation,and production of phytohormones like indole-3-acetic acid and 1-aminocyclopropane-1-carboxylate deaminase.They can also be used as biofertilizers and biocontrol agents as they produce antibiotics,exopolysaccharides,and hydrolytic enzymes.In this review,the connections between microbial populations,as microbial inoculants,and plant systems are highlighted,focusing on the enhancement of plant development,environmental resilience of agricultural systems,ecosystem services,and biological challenges under stressed conditions.This review also emphasizes the use of advanced molecular tools and techniques to effectively characterize potent soil microbial communities,their importance in increasing crop yield in stressed soils,and the prospects for future research.展开更多
The oral secretions of insect herbivores are complex mixtures of organic and inorganic solutes and enzymes that are deposited onto plant tissues during the feeding process.Some specific components of insect oral secre...The oral secretions of insect herbivores are complex mixtures of organic and inorganic solutes and enzymes that are deposited onto plant tissues during the feeding process.Some specific components of insect oral secretions have been shown to confer important functions in mediating plant–insect interactions at the molecular level.In this review,we examined the biochemical studies of insect oral secretions to summarize the current knowledge of their compositions.We then moved beyond the functional studies of components of oral secretions,and focused on the literature that pinpointed specific molecular targets of these compounds.Finally,we highlighted the investigations of oral secretion components in the context of insect physiology,which shed light on the potential evolutionary trajectory of these multi-functional molecules.展开更多
Sharp eyespot(Rhizoctonia cerealis)is a widespread soil-borne fungal disease that poses a severe threat to wheat health,and it is one of the main obstacles to achieving stable and high-quality wheat yields in China.Ou...Sharp eyespot(Rhizoctonia cerealis)is a widespread soil-borne fungal disease that poses a severe threat to wheat health,and it is one of the main obstacles to achieving stable and high-quality wheat yields in China.Our collaborative team has developed a novel,efficient,and low-toxicity fungicide named Y17991(N-(2-(2,4-bis-(trifluoromethyl)phenoxy)phenyl)-3-(difluoromethyl)-1-methyl-1H-pyrazole-4-carboxamide).Preliminary laboratory tests confirmed the significant inhibitory effect of this agent on R.cerealis.Large-area field trials also demonstrated its efficacy,with a disease prevention index of 83.52%,which is 1.97%greater than that of the widely used thifluzamide,and it significantly increased the wheat yield.Moreover,this study explored the impacts of Y17991 on the structure and function of the microbial community in wheat rhizosphere soil.Bacterial communities were more strongly affected than fungal communities.Y17991 significantly modulated key amino acid metabolic pathways and certain biosynthetic processes in diseased wheat rhizospheres,and it also enhanced certain biosynthetic pathways and metabolic activities in healthy wheat rhizospheres.Additionally,the application of Y17991 regulated rhizosphere metabolites,thus exerting significant control over the microbial community.We identified 15 microbial strains potentially involved in the prevention and treatment of R.cerealis,and Y17991 treatment promoted the growth of Pedobacter and Bacillus strains.These strains not only aid in plant growth but they also have the potential for disease prevention.In summary,Y17991 application at a reasonable dose does not cause significant disruption to nontarget rhizosphere microbial communities.In future studies,we will continue to investigate the impacts of Y17991 on nonmicrobial components in soil ecosystems,such as protozoa and nematodes.Our research provides a theoretical basis for the scientific application and promotion of new fungicides and offers a significant reference for establishing a comprehensive system for assessing the ecological impact of pesticides on the environment.展开更多
Recently,the growing use of unmanned aerial vehicles(UAV)for pesticide application has been reported against a wide range of crops with promising results in East Asian countries such as Japan,South Korea and China.Thi...Recently,the growing use of unmanned aerial vehicles(UAV)for pesticide application has been reported against a wide range of crops with promising results in East Asian countries such as Japan,South Korea and China.This UAV-based application technology for agrochemicals is considered as a high efficiency alternative to the conventional manual spray operations and a low-cost choice as compared to the classical manned aerial application.However,the technology adoption rate and the designed optimal sprayer suitable for drone application for small scale farm remains at the development stage in China and also in Japan.This paper reports the current status of drone pesticide application in China and makes comparisons with its neighbor countries Japan and South Korea in terms of different UAV platforms and their implementation in plant protection for different crops.Challenges and opportunities for future development of UAV-based pesticide application technology are also discussed.展开更多
Agricultural areas of land are deteriorating every day owing to population increase, rapid urbanization, and industrialization. To feed today’s huge populations, increased crop production is required from smaller are...Agricultural areas of land are deteriorating every day owing to population increase, rapid urbanization, and industrialization. To feed today’s huge populations, increased crop production is required from smaller areas, which warrants the continuous application of high doses of inorganic fertilizers to agricultural land. These cause damage to soil health and, therefore, nutrient imbalance conditions in arable soils. Under these conditions, the benefits of microbial inoculants (such as Actinobacteria) as replacements for harmful chemicals and promoting ecofriendly sustainable farming practices have been made clear through recent technological advances. There are multifunctional traits involved in the production of different types of bioactive compounds responsible for plant growth promotion, and the biocontrol of phytopathogens has reduced the use of chemical fertilizers and pesticides. There are some well-known groups of nitrogen-fixing Actinobacteria, such as Frankia, which undergo mutualism with plants and offer enhanced symbiotic trade-offs.In addition to nitrogen fixation, increasing availability of major plant nutrients in soil due to the solubilization of immobilized forms of phosphorus and potassium compounds, production of phytohormones, such as indole-3-acetic acid, indole-3-pyruvic acid, gibberellins, and cytokinins, improving organic matter decomposition by releasing cellulases, xylanase, glucanases, lipases, and proteases, and suppression of soil-borne pathogens by the production of siderophores, ammonia, hydrogen cyanide, and chitinase are important features of Actinobacteria useful for combating biotic and abiotic stresses in plants.The positive influence of Actinobacteria on soil fertility and plant health has motivated us to compile this review of important findings associated with sustaining plant productivity in the long run.展开更多
The traditional method of screening plants for disease resistance phenotype is both time-consuming and costly.Genomic selection offers a potential solution to improve efficiency,but accurately predicting plant disease...The traditional method of screening plants for disease resistance phenotype is both time-consuming and costly.Genomic selection offers a potential solution to improve efficiency,but accurately predicting plant disease resistance remains a challenge.In this study,we evaluated eight different machine learning(ML)methods,including random forest classification(RFC),support vector classifier(SVC),light gradient boosting machine(lightGBM),random forest classification plus kinship(RFC_K),support vector classification plus kinship(SVC_K),light gradient boosting machine plus kinship(lightGBM_K),deep neural network genomic prediction(DNNGP),and densely connected convolutional networks(DenseNet),for predicting plant disease resistance.Our results demonstrate that the three plus kinship(K)methods developed in this study achieved high prediction accuracy.Specifically,these methods achieved accuracies of up to 95%for rice blast(RB),85%for rice black-streaked dwarf virus(RBSDV),and 85%for rice sheath blight(RSB)when trained and applied to the rice diversity panel I(RDPI).Furthermore,the plus K models performed well in predicting wheat blast(WB)and wheat stripe rust(WSR)diseases,with mean accuracies of up to 90%and 93%,respectively.To assess the generalizability of our models,we applied the trained plus K methods to predict RB disease resistance in an independent population,rice diversity panel II(RDPII).Concurrently,we evaluated the RB resistance of RDPII cultivars using spray inoculation.Comparing the predictions with the spray inoculation results,we found that the accuracy of the plus K methods reached 91%.These findings highlight the effectiveness of the plus K methods(RFC_K,SVC_K,and lightGBM_K)in accurately predicting plant disease resistance for RB,RBSDV,RSB,WB,and WSR.The methods developed in this study not only provide valuable strategies for predicting disease resistance,but also pave the way for using machine learning to streamline genome-based crop breeding.展开更多
Powdery mildew,caused by Blumeria graminis f.sp.tritici(Bgt),is a devastating disease that seriously threatens wheat yield and quality.To control this disease,host resistance is the most effective measure.Compared wit...Powdery mildew,caused by Blumeria graminis f.sp.tritici(Bgt),is a devastating disease that seriously threatens wheat yield and quality.To control this disease,host resistance is the most effective measure.Compared with the resistance genes from common wheat,alien resistance genes can better withstand infection of this highly variable pathogen.Development of elite alien germplasm resources with powdery mildew resistance and other key breeding traits is an attractive strategy in wheat breeding.In this study,three wheat-rye germplasm lines YT4-1,YT4-2,and YT4-3 were developed through hybridization between octoploid triticale and common wheat,out of which the lines YT4-1 and YT4-2 conferred adult-plant resistance(APR)to powdery mildew while the line YT4-3 was susceptible to powdery mildew during all of its growth stages.Using genomic in situ hybridization,multi-color fluorescence in situ hybridization,multi-color GISH,and molecular marker analysis,YT4-1,YT4-2,and YT4-3 were shown to be cytogenetically stable wheat-rye 6R addition and T1RS.1BL translocation line,6RL ditelosomic addition and T1RS.1BL translocation line,and T1RS.1BL translocation line,respectively.Compared with previously reported wheat-rye derivative lines carrying chromosome 6R,YT4-1 and YT4-2 showed stable APR without undesirable pleiotropic effects on agronomic traits.Therefore,these novel wheat-rye 6R derivative lines are expected to be promising bridge resources in wheat disease breeding.展开更多
Exploring plant behavior at the cellular scale in a minimally invasive manner is critical to understanding plant adaptation to the environment.Phytohormones play vital regulatory roles in multiple aspects of plant gro...Exploring plant behavior at the cellular scale in a minimally invasive manner is critical to understanding plant adaptation to the environment.Phytohormones play vital regulatory roles in multiple aspects of plant growth and development and acclimation to environmental changes.Since the biosynthesis,modification,transportation,and degradation of plant hormones in plants change with time and space,their content level and distribution are highly dynamic.To monitor the production,transport,perception,and distribution of phytohormones within undamaged tissues,we require qualitative and quantitative tools endowed with remarkably high temporal and spatial resolution.Fluorescent probes are regarded as excellent tools for widespread plant imaging because of their high sensitivity and selectivity,reproducibility,real-time in situ detection,and uncomplicated mechanism elucidation.In this review,we provide a systematical overview of the progress in the sensing and imaging of phytohormone fluorescent probes and fluorescently labeled phytohormones to their receptors in plants.Moreover,forthcoming viewpoints and possible applications of these fluorescent probes within the realm of plants are also presented.We hold the conviction that the new perspective brought by this paper can promote the development of fluorescent probes,enabling them to have better detection performance in plant hormone imaging.展开更多
The occurrence, distribution, and rapid molecular detection technology of Heterodera zeae Koshy et al. 1971, have been reported in China. We explored the biological characteristics of H. zeae sampled in Henan Province...The occurrence, distribution, and rapid molecular detection technology of Heterodera zeae Koshy et al. 1971, have been reported in China. We explored the biological characteristics of H. zeae sampled in Henan Province, China to understand its interaction with plants. Cysts and second-stage juveniles(J2s) were identified under an optical and scanning electron microscope, internal transcribed spacer(ITS) phylogenetic tree, and sequence characterized amplified region(SCAR)-PCR analyses. The optimum hatching temperatures of H. zeae were 30°C and 28°C, with cumulative hatching rates of 16.5 and 16.1%, respectively, at 30 days post-hatching(dph). The hatching rate of H. zeae eggs was improved by 20-and 50-time maize soil leachate and root juice, and 10-time root exudates. The hatching rate in 10-time root exudates was the highest(25.9%). The 10-time root exudates of maize and millet produced the highest hatching rate at 30 dph(25.9 and 22.9%, respectively), followed by wheat(19.9%), barley(18.3%), and rice(17.6%). Heterodera zeae developed faster in maize than in other crops. Fourth-stage juveniles(J4s) were detected in maize roots 8 days post-inoculation(dpi) at 28°C but not in other crops. Combined with hatching tests, the Huang–Huai–Hai summer maize region and the south and central-southwest mountainous maize areas are highly suitable for H. zeae in China. This is the first systematically study of the hatching and infection characteristics on different plant hosts of corn cyst nematode H. zeae in temperate regions. This study laid a theoretical foundation for the rapid spread and high environmental adaptability of corn cyst nematode.展开更多
Fusarium graminearum,the primary pathogenic fungus responsible for Fusarium head blight(FHB)in wheat,secretes abundant chemical compounds that interact with host plants.In this study,a secreted protein FgHrip1,isolate...Fusarium graminearum,the primary pathogenic fungus responsible for Fusarium head blight(FHB)in wheat,secretes abundant chemical compounds that interact with host plants.In this study,a secreted protein FgHrip1,isolated from the culture filtrate of F.graminearum,was found to induce typical cell death in tobacco.The FgHrip1 gene was then cloned and expressed in Escherichia coli.Further bioassay analysis showed that the recombinant FgHrip1 induced early defense induction events,such as reactive oxygen species(ROS)production,callose deposition,and up-regulation of defense-related genes in tobacco.Furthermore,FgHrip1 significantly enhanced immunity in tobacco seedlings against Pseudomonas syringae pv.tabaci 6605(Pst.6605)and tobacco mosaic virus(TMV).FgHrip1-treated wheat spikes also exhibited defense-related transcript accumulation and developed immunity against FHB infection.Whereas the expression of FgHrip1 was induced during the infection process,the deletion of the gene impaired the virulence of F.graminearum.Our results suggest that FgHrip1triggers immunity and induces disease resistance in tobacco and wheat,thereby providing new insight into strategy for biocontrol of FHB.展开更多
文摘World crop production requires highly-productive varieties of agricultural crops,which are resistant to pest organisms.Such varieties are also of great importance for the Uzbekistan.Their
文摘Scientific and technological services are necessary for strengthening agriculture.Under the new situation,agricultural research institutes should give full play to their advantages,strive to innovate scientific and technological services methods,and improve scientific and technological service levels.Combined with the practice of science and technology work of Institute of Plant Protection of Hebei Academy of Agricultural and Forestry Sciences,this paper made an in-depth analysis on the present situations and existing problems in the scientific and technological services of agricultural research institutes.Based on the analysis,it came up with recommendations including change ideological concepts,strengthening service awareness,adhering to people-oriented principle,enhancing the team building,improving mechanism construction,stimulating innovative vitality,exploring service methods,and enriching service connotation,so as to improve scientific and technological service works.
文摘China is one of the countries in the world that is severely damaged by crop diseases,pests,and weeds.There are more than 1 700 species of agricultural pests occurring annually,53 of which are on the list of the 100 worst pests in the world(Chen and Wang 2014;Wu 2018).Currently,China is still greatly challenged by a growing problem of agricultural pests that th reate n the economy and health and pose ecological risks underthe conditions of global climate change,economic integration,crop structure adjustment and so on.Plant protect!on agai nst crop diseases,in sect pests and noxious weeds is necessary to ensure high-quality crop production and food safety.However,traditional strategies of plant protect!on have mainly involved chemical pesticides.
基金Supported by Key Project of Fujian Provincial Department of Education(JA11131S)
文摘In order to have an overview of implementation of the subsidy policy for purchase of plant protection machinery in Fujian Province, based on the questionnaire data on Fujian Province, we use Logit model to conduct empirical analysis of factors influencing farmers' willingness to participate in the subsidy policy for purchase of plant protection machinery. Research results show that there are 69.4% of farmers willing to participate in the subsidy policy for purchase of plant protection machinery; farmers' growing area has a significant impact on the willingness to participate in the subsidy policy for purchase of plant protection machinery, and there is negative correlation; educational level, experience in planting, family farming pure income all have a significant positive impact on the willingness to participate in the subsidy policy.
文摘The article introduces the main practices and achievements of the Environment and Plant Protection Institute of Chinese Academy of Tropical Agricultural Sciences in promoting the sharing of large-scale instruments and equipment in recent years,analyzes the existing problems in the management system,management team,assessment incentives and maintenance guarantee,and proposes improvement measures and suggestions from aspects of improving the sharing management system,strengthening management team building,strengthening sharing assessment and incentives,improving maintenance capabilities and expanding external publicity,to further improve the sharing management of large-scale instruments and equipment.
基金Key Research project of Gansu Province of China(22YF7NA108)National Natural Science Foundation of China(31860549)+1 种基金Industry Supporting Project from Education Department of Gansu Province(2023CYZC-49)Major Science and Technology project of Gansu province(24ZDNA006)。
文摘【Objectives】Si and microbial application could relieve the crop replanting problems(CRPs).We further studied the change of key microorganisms that are related to the beneficial effects,aiming at provide reference for the manufacture and application of both microbial agents and Si fertilizer in food lily production.【Methods】A field experiment was conducted over a three-year period,from March 2019 to March 2022.The experimental field had been continuously cultivated with lily for 9 years.Three treatments were established:silicon fertilizer(SF),microbial agents(“Special 8^(TM)”,MF),and combined application of silicon fertilizer and microbial agents(SMF).A control group with blank soil(CK)was also included.At seedling stage of Lanzhou lilies in 2020 and 2021,the shoot and bulb dry weight,and the plant height and stem diameter of Lanzhou lilies were investigated for calculation of seedling index.In July 2020,20 plants were selected in each plot,and root zone soils were sampled at a depth of 20 cm,10 cm away from the roots,and then mixed to form a composite sample.The soil available Si and organic matter content were analyzed,and the fungal community structure and some specific microbial groups in soils were determined with high-throughput sequencing of ITS.【Results】All the three treatments significantly enhanced the lily plant growth and the seedling index,compared to CK.Besides,SF and MF treatments increased the relative abundances(RA)and diversity of fungal communities,and altered the community structures.The RA of some specific groups were found to be significantly correlated with the seedling index and/or soil available Si.Of them,the RA of the genera Fusarium,Dactylonectria,Humicola,Stilbella,and the species Humicola_grisea showed a positive correlation,while that of the genera Mortierella,Stilbella,Holtermanniella,and the species Mortierella_fatshederae showed a negative correlation with seedling index.The genera Fusarium,Stilbella,the species Humicola_grisea,and Dactylonectria_estremocensis showed a positive correlation,while the genura Stilbella,and the species Mortierella fatshederae showed a negative correlation with available Si content.In the co-occurence network of top twenty fungal genera and top sixteen bacterial genera(RA>0.2%),Holtermanniella was the only genus that interacted with the bacteria and negatively correlated with bacterial genus Blastococcus.Holtermanniella was also the most densely connected genera,followed by the genus Fusarium,Didymella and Humicola.In addition,the genus Holtermanniella was the key species connecting fungal and bacterial community in soil.Fungal functional prediction revealed that SF,MF and SMF treatments decreased plant pathogens guilds and increased the beneficial guilds Ectomycorrhizal,plant saprophyte,leaf saprophyte,and arbuscular mycorrhizal compared to CK.【Conclusions】Combined application of silicon fertilizer and microbial agents can alleviate continuous replanting problems of Lanzhou lilies through restoring the fungal community diversity,and promoting plant residue depredation,thus reducing soil born disease incidence.The beneficial genus Humicola and its one species H.grisea acts as bioconversion,and the genus Acremonium acts as plant pathogen inhibitor.
基金supported by the National Natural Science Foundation of China(31971424)。
文摘Asian citrus psyllid(ACP)is a significant pest of citrus crops that can transmit citrus Huanglongbing(HLB)by feeding on the phloem sap of citrus plants,which poses a significant threat to citrus production.Volatile signal chemicals with plant communication functions can effectively enhance the resistance of recipient plants to herbivorous insects with minimal impacts on plant growth.While(E)-4,8-dimethyl-1,3,7-nonatriene(DMNT),(E,E)-4,8,12-trimethyl-1,3,7,11-tridecene(TMTT),(E)-β-caryophyllene,and dimethyl disulfide(DMDS),are known as signaling molecules in guava-sweet orange communication,whether these four chemical signals can enhance the resistance of Citrus sinensis to feeding by ACP adults with no apparent costs in terms of plant growth remains unclear.Therefore,this study measured the effect of non-damaging induction by DMNT,TMTT,(E)-β-caryophyllene,and DMDS on the ability of C.sinensis to resist feeding by ACP,as well as their impacts on the defensive phytochemicals,defensive enzymes,functional nutrients,Photosystem II's utilization and allocation of light energy,photosynthetic pigments,growth conditions,and leaf stomatal aperture in C.sinensis.The results indicate that non-damaging induction by these four chemicals can enhance the activity of the defensive enzyme polyphenol oxidase(PPO)and increase the contents of total phenols,tannins,and terpenoid defensive phytochemicals within C.sinensis,thereby enhancing the resistance of C.sinensis to ACP feeding.Specifically,DMNT and DMDS exhibit more significant effects in inducing resistance compared to TMTT and(E)-β-caryophyllene.The characteristics of chlorophyll fluorescence parameters and changes in photosynthetic pigments in C.sinensis during different post-exposure induction periods revealed these chemicals can maintain the stability of the photosynthetic system in C.sinensis and regulate its capacity to capture,transmit,and distribute light energy,which significantly enhances the non-photochemical quenching ability of C.sinensis.In addition,detailed measurements of the water content,leaf mass per unit area(LMA),functional nutrients(soluble protein,soluble sugar,and amino acids),and stomatal parameters in C.sinensis leaves further indicated that the non-destructive induction by these chemicals can optimize the levels of functional nutrients in C.sinensis,primarily manifesting as the upregulation of soluble sugars,proline,or soluble proteins,and reduction of stomatal area and aperture,which maintains a stable leaf water content and LMA,thereby enhancing resistance to ACP while sustaining the healthy growth of C.sinensis.These results fully substantiate that the non-damaging induction by the signal chemicals DMNT,TMTT,(E)-β-caryophyllene,and DMDS can enhance the resistance of C.sinensis to ACP feeding while maintaining the balance between pest resistance and growth.This balance prevents any catastrophic effects on the growth of C.sinensis,so these agents can potentially be integrated with other pest management strategies for the collective protection of crops.This study provides theoretical support and assistance for the development of signal chemical inducers for the prevention and management of ACP in agricultural systems.
基金supported by the Open Fund of the Key Laboratory of Integrated Pest Management on Crop in Northwestern Oasis,Ministry of Agriculture and Rural Affairsof China(KFJJ202101)the National KeyR&D Program of China(2021YFD1400100)+1 种基金the National Natural Science Foundation of China(31972247)the Tianchi Talent Introduction Program in Xinjiang Uygur Autonomous Region,China and the Science and Technology Innovation Project of the Chinese Academy of Agricultural Sciences.
文摘The sugar beet cyst nematode(Heterodera schachtii) is one of the most destructive pathogens in sugar beet production, which causes serious economic losses every year. Few molecular details of effectors of H. schachtii parasitism are known. We analyzed the genome and transcriptome data of H. schachtii and identified multiple potential predicted proteins. After filtering out predicted proteins with high homology to other plant-parasitic nematodes, we performed functional validation of the remaining effector proteins. 37 putative effectors of H. schachtii were screened based on the Nicotiana benthamiana system for identifying the effectors that inhibit plant immune response, eventually determines 13 candidate effectors could inhibit cell death caused by Bax. Among the 13 effectors, nine have the ability to inhibit GPA2/RBP1-induced cell death. All 13 effectortriggered immunity(ETI) suppressor genes were analyzed by qRT-PCR and confirmed to result in a significant downregulation of one or more defense genes during infection compared to empty vector. For in situ hybridization,13 effectors were specifically expressed and located in esophageal gland cells. These data and functional analysis set the stage for further studies on the interaction of H. schachtii with host and H. schachtii parasitic control.
基金supported by the S&T Program of Hebei,China(23567601H)the Hebei Provincial Central Leading Local Science and Technology Development Fund Project,China(236Z6508G)+1 种基金the Basic Research Funds for Provincial Universities in Hebei Province,China(KY2022037 and KY2021042)the Natural Science Foundation of Hebei Province,China(C2023204100 and C2021204136)。
文摘LysM proteins contain the lysin domain(LysM),bind chitin and are found in various organisms including fungi.In phytopathogenic fungi,certain LysM proteins act as effectors to inhibit host immunity,thus increasing fungal virulence.However,our understanding of the LysM protein family in Setosphaeria turcica is limited.In this study,eight StLysM genes are identified and designated as StLysM1 to StLysM8.The analysis of sequence features indicates that five proteins(StLysM1,StLysM2,StLysM5,StLysM6,and StLysM7)are potential effectors.Phylogenetic analysis suggests that the StLysMs are divided into fungal/bacterial and fungus-specific subclasses.Domain architecture analysis reveals that the five StLysM effectors exclusively harbor the LysM domain,whereas the other three StLysM proteins contain additional functional domains.Sequence conservation analysis shows that the fungal-specific LysM domain sequences share the ^(8)GDxTC^(12) and ^(29)WNP^(31) motifs as well as three highly conserved cysteine residues.Conversely,the LysM domain sequences from the bacterial/fungal branch have few conserved sites.Moreover,expression profiling analysis shows that the StLysM1 gene is significantly upregulated during the infection of maize.Yeast secretion assays and transient expression experiments demonstrate that StLysM1 is a secreted protein that can suppress BAX/INF1-induced programmed cell death in Nicotiana benthamiana.Further functional analysis suggests that St Lys M1 cannot interact with itself but it can bind chitin.The transient expression of StLysM1 inhibits the chitin-triggered plant immune response,increasing susceptibility to the phytopathogenic fungus Botrytis cinerea in N.benthamiana.This study reveals that the S.turcica LySM protein family consists of eight members,highlighting the significance of StLysM1 as a vital effector in regulating plant immunity.The results provide insight into StLysMs and establish a foundation for understanding the roles of StLysM proteins in the pathogenic process of S.turcica.
文摘The world is facing a consistent increase in human population and a noticeable decrease in cultivable lands due to soil salinization,abrupt climatic changes,and less rainfall.These problems have increased the importance of finding ecologically sustainable solutions to ensure global food security.Plant growth-promoting rhizobacteria can be advantageous to enhancing plant productivity and safeguarding against environmental stresses.They may assist plants by atmospheric nitrogen fixation,nutrient recycling,phosphate solubilization,iron sequestration via siderophore formation,and production of phytohormones like indole-3-acetic acid and 1-aminocyclopropane-1-carboxylate deaminase.They can also be used as biofertilizers and biocontrol agents as they produce antibiotics,exopolysaccharides,and hydrolytic enzymes.In this review,the connections between microbial populations,as microbial inoculants,and plant systems are highlighted,focusing on the enhancement of plant development,environmental resilience of agricultural systems,ecosystem services,and biological challenges under stressed conditions.This review also emphasizes the use of advanced molecular tools and techniques to effectively characterize potent soil microbial communities,their importance in increasing crop yield in stressed soils,and the prospects for future research.
基金received financial support from the Shenzhen Science and Technology Program,China(KQTD20180411143628272)the special funds for Science Technology Innovation and Industrial Development of Shenzhen Dapeng New District,China(PT202101-02)。
文摘The oral secretions of insect herbivores are complex mixtures of organic and inorganic solutes and enzymes that are deposited onto plant tissues during the feeding process.Some specific components of insect oral secretions have been shown to confer important functions in mediating plant–insect interactions at the molecular level.In this review,we examined the biochemical studies of insect oral secretions to summarize the current knowledge of their compositions.We then moved beyond the functional studies of components of oral secretions,and focused on the literature that pinpointed specific molecular targets of these compounds.Finally,we highlighted the investigations of oral secretion components in the context of insect physiology,which shed light on the potential evolutionary trajectory of these multi-functional molecules.
基金supported by the National Natural Science Foundation of China(32270296)the Shenzhen Postdoctoral Scientific Research,China(77000-42100004)+1 种基金the Key Basic Research and Development Program of Hubei Province,China(2020BBA052)the Natural Science Foundation of Guangdong Province,China(2024A1515010498)and the Fundamental Research Funds for the Central Universities,Sun Yat-sen University,China.
文摘Sharp eyespot(Rhizoctonia cerealis)is a widespread soil-borne fungal disease that poses a severe threat to wheat health,and it is one of the main obstacles to achieving stable and high-quality wheat yields in China.Our collaborative team has developed a novel,efficient,and low-toxicity fungicide named Y17991(N-(2-(2,4-bis-(trifluoromethyl)phenoxy)phenyl)-3-(difluoromethyl)-1-methyl-1H-pyrazole-4-carboxamide).Preliminary laboratory tests confirmed the significant inhibitory effect of this agent on R.cerealis.Large-area field trials also demonstrated its efficacy,with a disease prevention index of 83.52%,which is 1.97%greater than that of the widely used thifluzamide,and it significantly increased the wheat yield.Moreover,this study explored the impacts of Y17991 on the structure and function of the microbial community in wheat rhizosphere soil.Bacterial communities were more strongly affected than fungal communities.Y17991 significantly modulated key amino acid metabolic pathways and certain biosynthetic processes in diseased wheat rhizospheres,and it also enhanced certain biosynthetic pathways and metabolic activities in healthy wheat rhizospheres.Additionally,the application of Y17991 regulated rhizosphere metabolites,thus exerting significant control over the microbial community.We identified 15 microbial strains potentially involved in the prevention and treatment of R.cerealis,and Y17991 treatment promoted the growth of Pedobacter and Bacillus strains.These strains not only aid in plant growth but they also have the potential for disease prevention.In summary,Y17991 application at a reasonable dose does not cause significant disruption to nontarget rhizosphere microbial communities.In future studies,we will continue to investigate the impacts of Y17991 on nonmicrobial components in soil ecosystems,such as protozoa and nematodes.Our research provides a theoretical basis for the scientific application and promotion of new fungicides and offers a significant reference for establishing a comprehensive system for assessing the ecological impact of pesticides on the environment.
基金the grants of Special Fund for Agro-scientific Research in the Public Interest from the Ministry of Agriculture,China(201203025,201503130)International Co-operation Project“UAV chemical application technique for rice”from the Chinese Ministry of Agriculture and National Natural Science Foundation of China(31470099)+1 种基金China International Science and Technology Cooperation Project(2010DFA34570)“New Technique for Chemical Application”by Chinese State Administration of Foreign Experts Affairs(SGCAST01601710).
文摘Recently,the growing use of unmanned aerial vehicles(UAV)for pesticide application has been reported against a wide range of crops with promising results in East Asian countries such as Japan,South Korea and China.This UAV-based application technology for agrochemicals is considered as a high efficiency alternative to the conventional manual spray operations and a low-cost choice as compared to the classical manned aerial application.However,the technology adoption rate and the designed optimal sprayer suitable for drone application for small scale farm remains at the development stage in China and also in Japan.This paper reports the current status of drone pesticide application in China and makes comparisons with its neighbor countries Japan and South Korea in terms of different UAV platforms and their implementation in plant protection for different crops.Challenges and opportunities for future development of UAV-based pesticide application technology are also discussed.
文摘Agricultural areas of land are deteriorating every day owing to population increase, rapid urbanization, and industrialization. To feed today’s huge populations, increased crop production is required from smaller areas, which warrants the continuous application of high doses of inorganic fertilizers to agricultural land. These cause damage to soil health and, therefore, nutrient imbalance conditions in arable soils. Under these conditions, the benefits of microbial inoculants (such as Actinobacteria) as replacements for harmful chemicals and promoting ecofriendly sustainable farming practices have been made clear through recent technological advances. There are multifunctional traits involved in the production of different types of bioactive compounds responsible for plant growth promotion, and the biocontrol of phytopathogens has reduced the use of chemical fertilizers and pesticides. There are some well-known groups of nitrogen-fixing Actinobacteria, such as Frankia, which undergo mutualism with plants and offer enhanced symbiotic trade-offs.In addition to nitrogen fixation, increasing availability of major plant nutrients in soil due to the solubilization of immobilized forms of phosphorus and potassium compounds, production of phytohormones, such as indole-3-acetic acid, indole-3-pyruvic acid, gibberellins, and cytokinins, improving organic matter decomposition by releasing cellulases, xylanase, glucanases, lipases, and proteases, and suppression of soil-borne pathogens by the production of siderophores, ammonia, hydrogen cyanide, and chitinase are important features of Actinobacteria useful for combating biotic and abiotic stresses in plants.The positive influence of Actinobacteria on soil fertility and plant health has motivated us to compile this review of important findings associated with sustaining plant productivity in the long run.
基金supported by the National Natural Science Foundation of China(32261143468)the National Key Research and Development(R&D)Program of China(2021YFC2600400)+1 种基金the Seed Industry Revitalization Project of Jiangsu Province(JBGS(2021)001)the Project of Zhongshan Biological Breeding Laboratory(BM2022008-02)。
文摘The traditional method of screening plants for disease resistance phenotype is both time-consuming and costly.Genomic selection offers a potential solution to improve efficiency,but accurately predicting plant disease resistance remains a challenge.In this study,we evaluated eight different machine learning(ML)methods,including random forest classification(RFC),support vector classifier(SVC),light gradient boosting machine(lightGBM),random forest classification plus kinship(RFC_K),support vector classification plus kinship(SVC_K),light gradient boosting machine plus kinship(lightGBM_K),deep neural network genomic prediction(DNNGP),and densely connected convolutional networks(DenseNet),for predicting plant disease resistance.Our results demonstrate that the three plus kinship(K)methods developed in this study achieved high prediction accuracy.Specifically,these methods achieved accuracies of up to 95%for rice blast(RB),85%for rice black-streaked dwarf virus(RBSDV),and 85%for rice sheath blight(RSB)when trained and applied to the rice diversity panel I(RDPI).Furthermore,the plus K models performed well in predicting wheat blast(WB)and wheat stripe rust(WSR)diseases,with mean accuracies of up to 90%and 93%,respectively.To assess the generalizability of our models,we applied the trained plus K methods to predict RB disease resistance in an independent population,rice diversity panel II(RDPII).Concurrently,we evaluated the RB resistance of RDPII cultivars using spray inoculation.Comparing the predictions with the spray inoculation results,we found that the accuracy of the plus K methods reached 91%.These findings highlight the effectiveness of the plus K methods(RFC_K,SVC_K,and lightGBM_K)in accurately predicting plant disease resistance for RB,RBSDV,RSB,WB,and WSR.The methods developed in this study not only provide valuable strategies for predicting disease resistance,but also pave the way for using machine learning to streamline genome-based crop breeding.
基金This research was supported by the National Key Research and Development Program of China(2021YFD1200600)the National Natural Science Foundation of China(32272105).
文摘Powdery mildew,caused by Blumeria graminis f.sp.tritici(Bgt),is a devastating disease that seriously threatens wheat yield and quality.To control this disease,host resistance is the most effective measure.Compared with the resistance genes from common wheat,alien resistance genes can better withstand infection of this highly variable pathogen.Development of elite alien germplasm resources with powdery mildew resistance and other key breeding traits is an attractive strategy in wheat breeding.In this study,three wheat-rye germplasm lines YT4-1,YT4-2,and YT4-3 were developed through hybridization between octoploid triticale and common wheat,out of which the lines YT4-1 and YT4-2 conferred adult-plant resistance(APR)to powdery mildew while the line YT4-3 was susceptible to powdery mildew during all of its growth stages.Using genomic in situ hybridization,multi-color fluorescence in situ hybridization,multi-color GISH,and molecular marker analysis,YT4-1,YT4-2,and YT4-3 were shown to be cytogenetically stable wheat-rye 6R addition and T1RS.1BL translocation line,6RL ditelosomic addition and T1RS.1BL translocation line,and T1RS.1BL translocation line,respectively.Compared with previously reported wheat-rye derivative lines carrying chromosome 6R,YT4-1 and YT4-2 showed stable APR without undesirable pleiotropic effects on agronomic traits.Therefore,these novel wheat-rye 6R derivative lines are expected to be promising bridge resources in wheat disease breeding.
基金supported by the National Key Research and Development Program of China(2022YFD1700300,2022YFE0199800)the National Natural Science Foundation of China(32072443,82104065,32061143045)+1 种基金the Natural Science Foundation of Jiangsu Province(BK20201323)the Distinguished Young Research Project of Anhui Higher Education Institution(2022AH020035).
文摘Exploring plant behavior at the cellular scale in a minimally invasive manner is critical to understanding plant adaptation to the environment.Phytohormones play vital regulatory roles in multiple aspects of plant growth and development and acclimation to environmental changes.Since the biosynthesis,modification,transportation,and degradation of plant hormones in plants change with time and space,their content level and distribution are highly dynamic.To monitor the production,transport,perception,and distribution of phytohormones within undamaged tissues,we require qualitative and quantitative tools endowed with remarkably high temporal and spatial resolution.Fluorescent probes are regarded as excellent tools for widespread plant imaging because of their high sensitivity and selectivity,reproducibility,real-time in situ detection,and uncomplicated mechanism elucidation.In this review,we provide a systematical overview of the progress in the sensing and imaging of phytohormone fluorescent probes and fluorescently labeled phytohormones to their receptors in plants.Moreover,forthcoming viewpoints and possible applications of these fluorescent probes within the realm of plants are also presented.We hold the conviction that the new perspective brought by this paper can promote the development of fluorescent probes,enabling them to have better detection performance in plant hormone imaging.
基金This study was financially supported by the National Natural Science Foundation of China(31801717)the Major Science and Technology Projects in Henan Province,China(221100110300)+2 种基金the Special Fund for Young Talents in Henan Agricultural University,China(30500663)the Opening Foundation of the National Key Laboratory of Crop Science on Wheat and Maize,China(SKL2021KF06)the HAU grant for Collaborative Crop Science Research,China(CCSR2022-1)。
文摘The occurrence, distribution, and rapid molecular detection technology of Heterodera zeae Koshy et al. 1971, have been reported in China. We explored the biological characteristics of H. zeae sampled in Henan Province, China to understand its interaction with plants. Cysts and second-stage juveniles(J2s) were identified under an optical and scanning electron microscope, internal transcribed spacer(ITS) phylogenetic tree, and sequence characterized amplified region(SCAR)-PCR analyses. The optimum hatching temperatures of H. zeae were 30°C and 28°C, with cumulative hatching rates of 16.5 and 16.1%, respectively, at 30 days post-hatching(dph). The hatching rate of H. zeae eggs was improved by 20-and 50-time maize soil leachate and root juice, and 10-time root exudates. The hatching rate in 10-time root exudates was the highest(25.9%). The 10-time root exudates of maize and millet produced the highest hatching rate at 30 dph(25.9 and 22.9%, respectively), followed by wheat(19.9%), barley(18.3%), and rice(17.6%). Heterodera zeae developed faster in maize than in other crops. Fourth-stage juveniles(J4s) were detected in maize roots 8 days post-inoculation(dpi) at 28°C but not in other crops. Combined with hatching tests, the Huang–Huai–Hai summer maize region and the south and central-southwest mountainous maize areas are highly suitable for H. zeae in China. This is the first systematically study of the hatching and infection characteristics on different plant hosts of corn cyst nematode H. zeae in temperate regions. This study laid a theoretical foundation for the rapid spread and high environmental adaptability of corn cyst nematode.
基金financed by the National Key Research and Development Program of China(2017YFD0200900)。
文摘Fusarium graminearum,the primary pathogenic fungus responsible for Fusarium head blight(FHB)in wheat,secretes abundant chemical compounds that interact with host plants.In this study,a secreted protein FgHrip1,isolated from the culture filtrate of F.graminearum,was found to induce typical cell death in tobacco.The FgHrip1 gene was then cloned and expressed in Escherichia coli.Further bioassay analysis showed that the recombinant FgHrip1 induced early defense induction events,such as reactive oxygen species(ROS)production,callose deposition,and up-regulation of defense-related genes in tobacco.Furthermore,FgHrip1 significantly enhanced immunity in tobacco seedlings against Pseudomonas syringae pv.tabaci 6605(Pst.6605)and tobacco mosaic virus(TMV).FgHrip1-treated wheat spikes also exhibited defense-related transcript accumulation and developed immunity against FHB infection.Whereas the expression of FgHrip1 was induced during the infection process,the deletion of the gene impaired the virulence of F.graminearum.Our results suggest that FgHrip1triggers immunity and induces disease resistance in tobacco and wheat,thereby providing new insight into strategy for biocontrol of FHB.
