Toxic heavy metal and metalloid(THMM)contamination poses a major global challenge,threatening human health and sustainable agriculture.The crucial role of the Cytochrome P450(CYP)gene family in plant tolerance to THMM...Toxic heavy metal and metalloid(THMM)contamination poses a major global challenge,threatening human health and sustainable agriculture.The crucial role of the Cytochrome P450(CYP)gene family in plant tolerance to THMMs has been recently highlighted,but there is still a lack of comprehensive understanding,especially in relation to metabolites.This study delved into the identification of CYP genes that are linked to the tolerance mechanisms of plants in response to heavy metal stress.The findings highlight the significant metabolic pathways that contribute to this resilience,using rice and Arabidopsis as exemplars.THMM exposure changed CYP gene expression in plants,and THMM antidotes mitigated its downregulation and that of flavonoid biosynthesis genes.CYP genes involved in THMM responses were predominantly enriched in the pathways associated with flavonoid synthesis,indicating functional adaptations to distinct stresses.Notably,anthocyanin(Ant)accumulation,a type of flavonoid,affected the uptake of various heavy metals in Brassica rapa,with flavonoid biosynthesis-associated genes correlating with Cd or As tolerance and Ant content.These findings highlight the critical importance of flavonoid metabolism and the intricate network of biosynthesis genes in bolstering plant resilience against heavy metal stress.This enhanced understanding paves the way for significant advancements in phytoremediation technologies,offering innovative solutions for soil and water decontamination.展开更多
Plant tissue culture represents an advanced biotechnological technique for propagating and conserving threatened plant species efficiently.This method enables the rapid production of genetically identical plants under...Plant tissue culture represents an advanced biotechnological technique for propagating and conserving threatened plant species efficiently.This method enables the rapid production of genetically identical plants under controlled sterile laboratory conditions(in vitro).Its applications span forestry,horticulture,and,crucially,plant breeding.Nanoparticles have emerged as innovative tools to address limitations in conventional plant tissue culture,offering diverse functionalities based on their unique physicochemical properties.This review focuses on the utilization of nanotechnology in enhancing various aspects of plant tissue culture.Nanoparticles,such as silver and zinc oxide,have demonstrated significant roles as antimicrobial agents and anti-browning agents.They also serve as elicitors,stimulating callus proliferation,root elongation,rapid shoot formation,and the enhanced production of bioactive compounds on a large scale.Furthermore,nanoparticles contribute to mitigating oxidative stress within cells,thereby promoting increased callus formation,elongated roots,and elevated production of secondary metabolites.Their influence extends to somaclonal variation and genetic transformation processes within plant tissue culture.These contributions collectively underscore the potential of nanoparticles to foster more efficient,sustainable,and scalable biotechnological solutions in in vitro culture.The implications extend to reducing resource dependency and mitigating environmental impacts,positioning nanotechnology as a transformative approach in sustainable plant biotechnology.展开更多
In plant pathology,the correct naming of a species is essential for determining the causal agents of disease.Species names not only serve the general purpose of concise communication,but also are critical for effectiv...In plant pathology,the correct naming of a species is essential for determining the causal agents of disease.Species names not only serve the general purpose of concise communication,but also are critical for effective plant quarantine,prevent-ing the introduction of new pathogens into a territory.Many phytopathogenic genera have multiple species and,in several genera,disagreements between the multiple prevailing species concept definitions result in numerous cryptic species.Some of these species were previously called by various names;forma speciales(specialised forms),subspecies,or pathotypes.However,based on new molecular evidence they are being assigned into new species.The frequent name changes and lack of consistent criteria to delineate cryptic species,species,subspecies,forms,and races create increasing confusion,often making communication among biologists arduous.Furthermore,such ambiguous information can convey misleading evo-lutionary concepts and species boundaries.The aim of this paper is to review these concepts,clarify their use,and evaluate them by referring to existing examples.We specifically address the question,“Do plant pathogens require a different ranking system?”We conclude that it is necessary to identify phytopathogens to species level based on data from multiple approaches.Furthermore,this identification must go beyond species level to clearly classify hitherto known subspecies,forms and races.In addition,when naming phytopathogenic genera,plant pathologists should provide more information about geographic locations and host ranges as well as host specificities for individual species,cryptic species,forms or races.When describing a new phytopathogen,we suggest that authors provide at least three representative strains together with pathogenicity test results.If Koch’s postulates cannot be fulfilled,it is necessary to provide complementary data such as associated disease severity on the host plant.Moreover,more sequenced collections of species causing diseases should be published in order to stabilise the boundaries of cryptic species,species,subspecies,forms,and races.展开更多
In agricultural farms in Indiawhere the staple diet formost of the households is potato,plant leaf diseases,namely Potato Early Blight(PEB)and Potato Late Blight(PLB),are quite common.The class label Plant Healthy(PH)...In agricultural farms in Indiawhere the staple diet formost of the households is potato,plant leaf diseases,namely Potato Early Blight(PEB)and Potato Late Blight(PLB),are quite common.The class label Plant Healthy(PH)is also used.If these diseases are not identified early,they can causemassive crop loss and thereby incur huge economic losses to the farmers in the agricultural domain and can impact the gross domestic product of the nation.This paper presents a hybrid approach for potato plant disease severity estimation and classification of diseased and healthy leaves,combining the strengths of classical image processing,computer vision,and deep learning.We propose a pipeline that initially employs OpenCV’s cv2 led color-based image segmentation to isolate and highlight diseased brown,yellowcolored lesions or regions and healthy green colored lesion areas associated with various potato leaf diseases.Adaptive Thresholding for illumination and texture feature extraction and U-Net Segmentation for mask refinement for severity estimation.It has a mathematical framework for quantifying the severity based on the spatial area distribution of these regions.This allows for both visual representation of the segmented regions in the form of overlay masks and quantification of distinct disease severity.We detail the implementation of the approach,including color space selection,segmentation strategies,mask creation,area calculation,and a potential mathematical model for severity calculation.Overlay masks generated are then used as input to a CBAM-EfficientNetB0 model,leveraging transfer learning for improved classification accuracy and efficiency.For the Plant Village dataset,the test accuracy achieved is 0.99,whereas the test loss is 0.02,respectively.For the Plant Doc dataset,the test accuracy achieved is 0.97,whereas the test loss is 0.06,respectively.Also,the CBAM attention mechanism model lays emphasis on relevant features within the lesions and overall image context.The results achieved with the Plant Village dataset are slightly better in comparison to the Plant Doc dataset.展开更多
Remodeling plant intracellular nucleotide-binding leucine-rich repeat immune receptors(NLRs)to engineer synthetic disease-resistance genes has emerged as a promising approach to achieving broad-spectrum disease resist...Remodeling plant intracellular nucleotide-binding leucine-rich repeat immune receptors(NLRs)to engineer synthetic disease-resistance genes has emerged as a promising approach to achieving broad-spectrum disease resistance.But strategies for expanding NLR recognition spectra[[1],[2],[3],[4],[5]]are often limited by the rapid evolution of pathogens and pests.In our recent study,we developed an innovative strategy to engineer broad-spectrum,durable and complete disease resistance in plants by remodeling autoactive NLRs into protease-activated switches[6].展开更多
This study explores the broad-spectrum application of OsRALF26,a small secreted peptide belonging to the rapid alkalinization factor(RALF)family in rice.We found that the rice genome carries numerous lineage-specific ...This study explores the broad-spectrum application of OsRALF26,a small secreted peptide belonging to the rapid alkalinization factor(RALF)family in rice.We found that the rice genome carries numerous lineage-specific OsRALFs,suggesting that this evolutionary expansion could be the result of an arms race with pathogens.Among them,we focused on the Oryza-specific Os RALF26 and its closest homolog,OsRALF27,analyzing their effects across a range of plant species from monocots to dicots.The exogenous application of OsRALF26 significantly reduced bacterial populations in rice challenged with Xanthomonas oryzae pv.oryzae(Xoo)and in Arabidopsis and tomato challenged with Pseudomonas syringae pv.tomato DC3000(Pst DC3000),whereas Os RALF27 did not enhance resistance.展开更多
Brown spot(BS)of rice,caused by Bipolaris oryzae,is a serious concern that not only causes quantitative losses but also affects grain quality.To manage this disease,the use of resistant genetic sources and QTLs is an ...Brown spot(BS)of rice,caused by Bipolaris oryzae,is a serious concern that not only causes quantitative losses but also affects grain quality.To manage this disease,the use of resistant genetic sources and QTLs is an eco-friendly and economical option.In the current study,F_(3) progenies derived from a cross of susceptible parent PMS-18-B(PAU 10845-1-1-1-1)×resistant parent RP Path 77(RP patho-17)were used to identify potential QTLs linked to BS resistance and to associate this resistance with a temporal spike in defense-related enzymes.展开更多
The accuracy of genomic annotation is crucial for subsequent functional investigations;however,computational protocols used in high-throughput annotation of open reading frames(ORFs)can introduce inconsistencies.These...The accuracy of genomic annotation is crucial for subsequent functional investigations;however,computational protocols used in high-throughput annotation of open reading frames(ORFs)can introduce inconsistencies.These inconsistencies,which lead to non-uniform extension or truncation of sequence ends,pose challenges for downstream analyses.Existing strategies to rectify these inconsistencies are time-consuming and labor-intensive,lacking specific approaches.To address this gap,we developed to GC,a tool that integrates genomic annotation with RNA-seq datasets to rectify annotation inconsistencies.Using to GC,we achieved an accuracy of nearly 100%accuracy in correcting inconsistencies in published Phytophthora sojae ORFs.We applied this innovative pipeline to the GPCR-bigrams gene family,which was predicted to have 42 members in the P.sojae genome but lacked experimental validation.By employing to GC,we identified 32 GPCR-bigram ORFs with inconsistencies between previous annotations and to GC-corrected sequences.Notably,among these were 5 genes(GPCR-TKL9,GPCR-TKL15,GPCR-PDE3,GPCR-AC3,and GPCR-AC4)showed substantial inconsistencies.Experimental gene annotation confirmed the effectiveness of to GC,as sequences obtained through cloning matched those annotated by to GC.Importantly,we discovered two novel GPCRs(GPCR-AC3 and GPCR-AC4),which were previously mispredicted as a single gene.CRISPR/Cas9-mediated knockout experiments revealed the involvement of GPCR-AC4 but not GPCR-AC3 in oospore production,further confirming their status as two separate genes.In addition to P.sojae,the reliability of the to GC pipeline in Phytophthora capsici and Pythium ultimum further emphasizes the robustness of this pipeline.Our findings highlight the utility of to GC for reliable gene model correction,facilitating investigations into biological functions and offering potential applications in diverse species analyses.展开更多
In recent years,an unusual wilt disease affecting Pyrus pyrifolia has been observed in various regions of Jiangsu,China.This disease originates from the roots and progresses with distinctive browning patterns along va...In recent years,an unusual wilt disease affecting Pyrus pyrifolia has been observed in various regions of Jiangsu,China.This disease originates from the roots and progresses with distinctive browning patterns along vascular tissues,even extending over two meters above the ground.These symptoms set it apart from recognized pear diseases and typically lead to the death of affected trees within the same or the following year.Furthermore,this disease exhibits a tendency to spread to neighboring trees even after the removal of affected trees,presenting a substantial threat to pear production.To ascertain the causative agent,the present study encompassed pathogen isolation,morphological and molecular identification,as well as validation experiments adhering to Koch's postulates.The fungal isolates obtained were identified as Fusarium cugenangense based on characteristics of the colonies and conidia,in addition to a phylogenetic analysis using DNA sequences of the translation elongation factor 1-alpha(tef1),calmodulin(Ca M),and RNA polymerase second largest subunit(rpb2)genes.Pathogenicity of the isolated F.cugenangense on pear was confirmed by artificial inoculation.By introducing GFP-labeled pathogens into the roots,colonization in stem and leaf tissues was observed via fluorescence microscopy and transmission electron microscopy.Furthermore,these pathogens were successfully reisolated from stems and foliage,conclusively providing evidence of systemic infection within the pear plants.To the best of our knowledge,this is the first report of F.cugenangense causing pear wilt disease in China.展开更多
WRKY transcription factors have many regulatory roles we isolated a rice WRKY gene (OsWRKY31) that is induced in response to biotic and abiotic stresses. In this study, by the rice blast fungus Magnaporthe grisea an...WRKY transcription factors have many regulatory roles we isolated a rice WRKY gene (OsWRKY31) that is induced in response to biotic and abiotic stresses. In this study, by the rice blast fungus Magnaporthe grisea and auxin. This gene encodes a polypeptide of 211 amino-acid residues and belongs to a subgroup of the rice WRKY gene family that probably originated after the divergence of monocot and dicot plants. OsWRKY31 was found to be localized to the nucleus of onion epidermis cells to transiently express OsWRKY31-eGFP fusion protein. Analysis of OsWRKY31 and its mutants fused with a Gal4 DNA-binding domain indicated that OsWRKY31 has transactivation activity in yeast. Overexpression of the OsWRKY31 gene was found to enhance resistance against infection with M. grisea, and the transgenic lines exhibited reduced lateral root formation and elongation compared with wild-type and RNAi plants. The lines with overexpression showed constitutive expression of many defense-related genes, such as PBZI and OsSci2, as well as early auxin-response genes, such as OslAA4 and OsCrll genes. Furthermore, the plants with overexpression were less sensitive to exogenously supplied IBA, NAA and 2,4-1) at high concentrations, suggesting that overexpression of the OsWRKY31 gene might alter the auxin response or transport. These results also suggest that OsWRKY31 might be a common component in the signal transduction pathways of the auxin response and the defense response in rice.展开更多
Plants employ multifaceted mechanisms to fight with numerous pathogens in nature.Resistance(R)genes are the most effective weapons against pathogen invasion since they can specifically recognize the corresponding path...Plants employ multifaceted mechanisms to fight with numerous pathogens in nature.Resistance(R)genes are the most effective weapons against pathogen invasion since they can specifically recognize the corresponding pathogen effectors or associated protein(s)to activate plant immune responses at the site of infection.Up to date,over 70 R genes have been isolated from various plant species.Most R proteins contain conserved motifs such as nucleotide-binding site(NBS),leucine-rich repeat(LRR),Toll-interleukin-1 receptor domain(TIR,homologous to cytoplasmic domains of the Drosophila Toll protein and the manamalian intefleukin-1 receptor),coiled-coil(CC)or leucine zipper(LZ)structure and protein kinase domain(PK).Recent results indicate that these domains play significant roles in R protein interactions with effector proteins from pathogens and in activating signal transduction pathways involved in innate immunity.This review highlights an overview of the recent progress in elucidating the structure,function and evolution of the isolated R genes in different plant-pathogen interaction systems.展开更多
Post-translational modification is central to protein stability and to the modulation of protein activity. Various types of protein modification, such as phosphorylation, methylation, acetylation, myristoylation, glyc...Post-translational modification is central to protein stability and to the modulation of protein activity. Various types of protein modification, such as phosphorylation, methylation, acetylation, myristoylation, glycosylation, and ubiquitination, have been reported. Among them, ubiquitination distinguishes itself from others in that most of the ubiquitinated proteins are targeted to the 26S proteasome for degradation. The ubiquitin/26S proteasome system constitutes the major protein degradation pathway in the cell. In recent years, the importance of the ubiquitination machinery in the control of numerous eukaryotic cellular functions has been increasingly appreciated. Increasing number of E3 ubiquitin ligases and their substrates, including a variety of essential cellular regulators have been identified. Studies in the past several years have revealed that the ubiquitination system is important for a broad range of plant developmental processes and responses to abiotic and biotic stresses. This review discusses recent advances in the functional analysis of ubiquitination-associated proteins from plants and pathogens that play important roles in plant-microbe interactions.展开更多
Wheat leaf rust,caused by Puccinia triticina(Pt),is an important foliar disease that has an important influence on wheat yield.The most economic,safe and effective way to control the disease is growing resistant culti...Wheat leaf rust,caused by Puccinia triticina(Pt),is an important foliar disease that has an important influence on wheat yield.The most economic,safe and effective way to control the disease is growing resistant cultivars.In the present study,a total of 46 wheat landraces and 34 wheat lines with known Lr(leaf rust resistance)genes were inoculated with 16Pt pathotypes for postulating seedling resistance gene(s)in the greenhouse.These cultivars and five wheat differential lines with adult plant resistance(APR)genes(Lr12,Lr22b,Lr34,Lr35 and Lr37)were also evaluated for identification of slow rusting resistance in the field trials in Baoding,Hebei Province of China in the 2014–2015 and 2015–2016 cropping seasons.Furthermore,10 functional molecular markers closely linked to 10 known Lr genes were used to detect all the wheat genotypes.Results showed that most of the landraces were susceptible to most of the Pt pathotypes at seedling stage.Nonetheless,Lr1 was detected only in Hongtangliangmai.The field experimental test of the two environments showed that 38 landraces showed slow rusting resistance.Seven cultivars possessed Lr34 but none of the landraces contained Lr37 and Lr46.Lr genes namely,Lr9,Lr19,Lr24,Lr28,Lr29,Lr47,Lr51 and Lr53 were effective at the whole plant stage.Lr18,Lr36 and Lr45 had lost resistance to part of pathotypes at the seedling stage but showed high resistance at the adult plant stage.Lr34 as a slowing rusting gene showed good resistance in the field.Four race-specific APR genes Lr12,Lr13,Lr35 and Lr37 conferred good resistance in the field experiments.Seven race-specific genes,Lr2b,Lr2c,Lr11,Lr16,Lr26,Lr33 and LrB had lost resistance.The 38 landraces showed slow rusting resistance to wheat leaf rust can be used as resistance resources for wheat resistance breeding in China.展开更多
High-temperature adult-plant (HTAP) resistance expresses when plants grow old and the weather becomes warm. This non-race specific and durable type of resistance has been used successfully in control of wheat stripe r...High-temperature adult-plant (HTAP) resistance expresses when plants grow old and the weather becomes warm. This non-race specific and durable type of resistance has been used successfully in control of wheat stripe rust in the US since early 1960s. This article describes practical procedures for identification and characterization of HTAP resistance and reviews recent studies on discovery of genes conferring HTAP resistance. Recent studies providing insights to the molecular basis for the durability of HTAP resistance will be presented. Strategies for improving levels of HTAP resistance and improving control of stripe rust through combining HTAP resistance with effective all-stage resistance will be discussed.展开更多
Management intensity critically influences the productivity and sustainability of pasture systems through modifying soil microbes, and soil carbon (C) and nutrient dynamics; however, such effects are not well unders...Management intensity critically influences the productivity and sustainability of pasture systems through modifying soil microbes, and soil carbon (C) and nutrient dynamics; however, such effects are not well understood yet ir the southeastern USA. We examined the effects of grazing intensity and grass planting system on soil C and nitrogen (N) dynamics, and microbial biomass and respiration in a long-term field experiment in Goldsboro, North Carolina, USA. A split-plot experiment was initiated in 2003 on a highly sandy soil under treatments of two grass planting systems (ryegrass rotation with sorghum-sudangrass hybrid and ryegrass seeding into a perennial bermudagrass stand) at low and high grazing densities. After 4 years of continuous treatments, soil total C and N contents across the 0 30 cm soil profile were 24.7% and 17.5% higher at the high than at the low grazing intensity, likely through promoting plant productivity and C allocation belowground as well as fecal and urinary inputs. Grass planting system effects were significant only at the low grazing intensity, with soil C, N, and microbial biomass and respiration in the top 10 cm being higher under the ryegrass/bermudagrass than under the ryegrass/sorghum-sudangrass hybrid planting systems. These results suggest that effective management could mitigate potential adverse effects of high grazing intensities on soil properties and facilitate sustainability of pastureland.展开更多
Abiotic stresses including drought,salinity,heat,cold,flooding,and ultraviolet radiation causes crop losses worldwide.In recent times,preventing these crop losses and producing more food and feed to meet the demands o...Abiotic stresses including drought,salinity,heat,cold,flooding,and ultraviolet radiation causes crop losses worldwide.In recent times,preventing these crop losses and producing more food and feed to meet the demands of ever-increasing human populations have gained unprecedented importance.However,the proportion of agricultural lands facing multiple abiotic stresses is expected only to rise under a changing global climate fueled by anthropogenic activities.Identifying the mechanisms developed and deployed by plants to counteract abiotic stresses and maintain their growth and survival under harsh conditions thus holds great significance.Recent investigations have shown that phytohormones,including the classical auxins,cytokinins,ethylene,and gibberellins,and newer members including brassinosteroids,jasmonates,and strigolactones may prove to be important metabolic engineering targets for producing abiotic stress-tolerant crop plants.In this review,we summarize and critically assess the roles that phytohormones play in plant growth and development and abiotic stress tolerance,besides their engineering for conferring abiotic stress tolerance in transgenic crops.We also describe recent successes in identifying the roles of phytohormones under stressful conditions.We conclude by describing the recent progress and future prospects including limitations and challenges of phytohormone engineering for inducing abiotic stress tolerance in crop plants.展开更多
The mitogen-activated protein kinase (MAPK), a key signal transduction component in the MAPK cascade pathway, regulates a variety of physiological activities in eukaryotes. However, little is known of the role MAPK ...The mitogen-activated protein kinase (MAPK), a key signal transduction component in the MAPK cascade pathway, regulates a variety of physiological activities in eukaryotes. However, little is known of the role MAPK plays in phytopathogenic fungi. In this research, we cloned the MAPK gene STK1 from the northern corn leaf blight pathogen Setosphaeria turcica and found that the gene shared high homology with the high osmolality glycerol (HOG) MAPK gene HOG1 of Saccharomy- ces cerevisiae. In addition, gene knockout technology was employed to investigate the function of STKI. Gene knockout mutants (KOs) were found to have altered hyphae morphology and no conidiogenesis, though they did show similar radial growth rate compared to the wild-type strain (WT). Furthermore, microscope observations indicated that STK1 KOs did not form normal appressoria at 48 h post-inoculation on a hydrophobic surface. STK1 KOs had reduced virulence, a significantly altered Helminthosporium turcicum (HT)-toxin composition, and diminished pathogenicity on the leaves of susceptible inbred corn OH43. Mycelium morphology appeared to be significantly swollen and the radial growth rates of STK1 KOs declined in comparison with WT under high osmotic stress. These results suggested that STK1 affects the hyphae development, conidiogenesis, and pathogenicity of S. turcica by regulating appressorium development and HT-toxin biosynthesis. Moreover, the gene appears to be involved in the hypertonic stress response in S. turcica.展开更多
Long non-coding RNA (lncRNA) refers to an over 200 nt functional RNA molecule that will not be translated into protein. Previously thought to be dark matters of the genome, lncRNAs have been gradually recognized as cr...Long non-coding RNA (lncRNA) refers to an over 200 nt functional RNA molecule that will not be translated into protein. Previously thought to be dark matters of the genome, lncRNAs have been gradually recognized as crucial gene regulators. Although tremendous progress has been made in animals and human, the study of lncRNAs in plant is still in its infancy. Here, we reviewed the biogenesis and regulation mechanisms of lncRNAs and summarized the achievements that have been made in plant lncRNA identification and functional characterization. Genome-wide identification has uncovered large amount of lncRNAs in Arabidopsis, Rice, Maize and Wheat, and more information from other plant species will be expected with the aid of deep sequencing technologies. Similar to other species, LncRNA-mediated gene regulation also widely exists in plants, even though only a few functionally characterized examples are available. Up to now, at least four divergent lncRNA-mediated regulation mechanisms have been unraveled, including target mimicry, transcription interference, PRC2 associated histone methylation and DNA methylation. lncRNAs may be involved in the regulation of flowering, male sterility, nutrition metabolism, biotic and abiotic stress response in plants.展开更多
Plant lesion mimic mutants(lmms)generally possess autoimmunity and hypersensitive response(HR)-like cell death in the absence of biotic or abiotic stress.They have attracted much attention because they are useful tool...Plant lesion mimic mutants(lmms)generally possess autoimmunity and hypersensitive response(HR)-like cell death in the absence of biotic or abiotic stress.They have attracted much attention because they are useful tools for deciphering the interaction between defense signaling and growth.Recent studies have identified more than 30 lmms involved in the plant immune response and cell death in rice.Genes underlying these lmms,coding for diverse types of proteins,mainly regulate transcription,protein translation and modification,vesicular trafficking and catalyzation of metabolism.Here,we presented an overview of the most recent advances on the study of lmms in rice and proposed a perspective on potential utilization of LMM genes in agriculture.展开更多
Trichoderma strains are used in agriculture because they provide to the plants the following benefits: i) are rhizosphere competence and establish stable rhizosphere microbial communities; ii) control plant disease ca...Trichoderma strains are used in agriculture because they provide to the plants the following benefits: i) are rhizosphere competence and establish stable rhizosphere microbial communities; ii) control plant disease caused by pathogenic and competitive microflora, by using a variety of mechanisms; iii) improve vegetative growth, root development and yield; iv) make nutrients more available to the plant. In this work we have investigated the ability of T. harzianum T22 and T. atroviride P1 to improve plant growth of locally important horticultural crops: lettuce, tomatoes and peppers and to prevent disease in the greenhouse and field. The effect of the Trichoderma treatment was evaluated by determining the weight of fresh and dry roots and above ground plant biomass, measuring plants height, counting the number of emerged leaves (lettuce, tomatoes and peppers) and quantifying production (tomatoes and peppers). No disease symptoms were found during production, although Fusarium sp. strains pathogenic to tomato were detected in the soil. Compounds containing copper oxychloride are frequently used for fungal disease control in agriculture. In order to investigate the compatibility of T. harzianum T22 and T. atroviride P1 with copper oxychloride applications, the effect on mycelia growth was monitored in both liquid and solid medium. In general, the tests indicated a high level of tolerance of the Trichoderma strains to concentrations of copper oxychloride varying from 0.1 to 5 mmol/L.展开更多
基金supported by the Guizhou Provincial Science and Technology Project(Grant No.[2022]091).
文摘Toxic heavy metal and metalloid(THMM)contamination poses a major global challenge,threatening human health and sustainable agriculture.The crucial role of the Cytochrome P450(CYP)gene family in plant tolerance to THMMs has been recently highlighted,but there is still a lack of comprehensive understanding,especially in relation to metabolites.This study delved into the identification of CYP genes that are linked to the tolerance mechanisms of plants in response to heavy metal stress.The findings highlight the significant metabolic pathways that contribute to this resilience,using rice and Arabidopsis as exemplars.THMM exposure changed CYP gene expression in plants,and THMM antidotes mitigated its downregulation and that of flavonoid biosynthesis genes.CYP genes involved in THMM responses were predominantly enriched in the pathways associated with flavonoid synthesis,indicating functional adaptations to distinct stresses.Notably,anthocyanin(Ant)accumulation,a type of flavonoid,affected the uptake of various heavy metals in Brassica rapa,with flavonoid biosynthesis-associated genes correlating with Cd or As tolerance and Ant content.These findings highlight the critical importance of flavonoid metabolism and the intricate network of biosynthesis genes in bolstering plant resilience against heavy metal stress.This enhanced understanding paves the way for significant advancements in phytoremediation technologies,offering innovative solutions for soil and water decontamination.
基金The corresponding author is also deeply grateful to Ministry of Minority Affairs,Government of India,for providing financial assistance(MANF-JAM-99722)during his research work.
文摘Plant tissue culture represents an advanced biotechnological technique for propagating and conserving threatened plant species efficiently.This method enables the rapid production of genetically identical plants under controlled sterile laboratory conditions(in vitro).Its applications span forestry,horticulture,and,crucially,plant breeding.Nanoparticles have emerged as innovative tools to address limitations in conventional plant tissue culture,offering diverse functionalities based on their unique physicochemical properties.This review focuses on the utilization of nanotechnology in enhancing various aspects of plant tissue culture.Nanoparticles,such as silver and zinc oxide,have demonstrated significant roles as antimicrobial agents and anti-browning agents.They also serve as elicitors,stimulating callus proliferation,root elongation,rapid shoot formation,and the enhanced production of bioactive compounds on a large scale.Furthermore,nanoparticles contribute to mitigating oxidative stress within cells,thereby promoting increased callus formation,elongated roots,and elevated production of secondary metabolites.Their influence extends to somaclonal variation and genetic transformation processes within plant tissue culture.These contributions collectively underscore the potential of nanoparticles to foster more efficient,sustainable,and scalable biotechnological solutions in in vitro culture.The implications extend to reducing resource dependency and mitigating environmental impacts,positioning nanotechnology as a transformative approach in sustainable plant biotechnology.
基金We would like to thank the Thailand Research Fund,Grant RDG6130001 entitled“Impact of climate change on fungal diversity and biogeography in the Greater Mekong Subregion”.Kevin D Hyde thanks Chiang Mai University for the award of a Visiting Professor.Ishara S Manawasinghe thank Prof Marco Thines for guiding the development of this paper by providing valuable ideas and comments.Alan JL Phillips acknowledges the support from UIDB/04046/2020 and UIDP/04046/2020 Centre grants from FCT,Portugal(to BioISI).
文摘In plant pathology,the correct naming of a species is essential for determining the causal agents of disease.Species names not only serve the general purpose of concise communication,but also are critical for effective plant quarantine,prevent-ing the introduction of new pathogens into a territory.Many phytopathogenic genera have multiple species and,in several genera,disagreements between the multiple prevailing species concept definitions result in numerous cryptic species.Some of these species were previously called by various names;forma speciales(specialised forms),subspecies,or pathotypes.However,based on new molecular evidence they are being assigned into new species.The frequent name changes and lack of consistent criteria to delineate cryptic species,species,subspecies,forms,and races create increasing confusion,often making communication among biologists arduous.Furthermore,such ambiguous information can convey misleading evo-lutionary concepts and species boundaries.The aim of this paper is to review these concepts,clarify their use,and evaluate them by referring to existing examples.We specifically address the question,“Do plant pathogens require a different ranking system?”We conclude that it is necessary to identify phytopathogens to species level based on data from multiple approaches.Furthermore,this identification must go beyond species level to clearly classify hitherto known subspecies,forms and races.In addition,when naming phytopathogenic genera,plant pathologists should provide more information about geographic locations and host ranges as well as host specificities for individual species,cryptic species,forms or races.When describing a new phytopathogen,we suggest that authors provide at least three representative strains together with pathogenicity test results.If Koch’s postulates cannot be fulfilled,it is necessary to provide complementary data such as associated disease severity on the host plant.Moreover,more sequenced collections of species causing diseases should be published in order to stabilise the boundaries of cryptic species,species,subspecies,forms,and races.
基金done under Department of Biotechnology(DBT)project titled“Application of Machine Learning for Hyperspectral Imaging and Remote Sensing aimed at Early Detection of Fungal Foliar Diseases and Bacterial Wilt Diseases in Potato Crop”,DBT/Reference.No.BT/PR45388/133/58/2022.
文摘In agricultural farms in Indiawhere the staple diet formost of the households is potato,plant leaf diseases,namely Potato Early Blight(PEB)and Potato Late Blight(PLB),are quite common.The class label Plant Healthy(PH)is also used.If these diseases are not identified early,they can causemassive crop loss and thereby incur huge economic losses to the farmers in the agricultural domain and can impact the gross domestic product of the nation.This paper presents a hybrid approach for potato plant disease severity estimation and classification of diseased and healthy leaves,combining the strengths of classical image processing,computer vision,and deep learning.We propose a pipeline that initially employs OpenCV’s cv2 led color-based image segmentation to isolate and highlight diseased brown,yellowcolored lesions or regions and healthy green colored lesion areas associated with various potato leaf diseases.Adaptive Thresholding for illumination and texture feature extraction and U-Net Segmentation for mask refinement for severity estimation.It has a mathematical framework for quantifying the severity based on the spatial area distribution of these regions.This allows for both visual representation of the segmented regions in the form of overlay masks and quantification of distinct disease severity.We detail the implementation of the approach,including color space selection,segmentation strategies,mask creation,area calculation,and a potential mathematical model for severity calculation.Overlay masks generated are then used as input to a CBAM-EfficientNetB0 model,leveraging transfer learning for improved classification accuracy and efficiency.For the Plant Village dataset,the test accuracy achieved is 0.99,whereas the test loss is 0.02,respectively.For the Plant Doc dataset,the test accuracy achieved is 0.97,whereas the test loss is 0.06,respectively.Also,the CBAM attention mechanism model lays emphasis on relevant features within the lesions and overall image context.The results achieved with the Plant Village dataset are slightly better in comparison to the Plant Doc dataset.
基金supported by the Biological Breeding-National Science and Technology Major Project(2024ZD04077).
文摘Remodeling plant intracellular nucleotide-binding leucine-rich repeat immune receptors(NLRs)to engineer synthetic disease-resistance genes has emerged as a promising approach to achieving broad-spectrum disease resistance.But strategies for expanding NLR recognition spectra[[1],[2],[3],[4],[5]]are often limited by the rapid evolution of pathogens and pests.In our recent study,we developed an innovative strategy to engineer broad-spectrum,durable and complete disease resistance in plants by remodeling autoactive NLRs into protease-activated switches[6].
基金supported by the National Research Foundation of Korea grant funded by the Korea government(Grant Nos.NRF-2020R1A2C1007778 and RS-2024-00454908)。
文摘This study explores the broad-spectrum application of OsRALF26,a small secreted peptide belonging to the rapid alkalinization factor(RALF)family in rice.We found that the rice genome carries numerous lineage-specific OsRALFs,suggesting that this evolutionary expansion could be the result of an arms race with pathogens.Among them,we focused on the Oryza-specific Os RALF26 and its closest homolog,OsRALF27,analyzing their effects across a range of plant species from monocots to dicots.The exogenous application of OsRALF26 significantly reduced bacterial populations in rice challenged with Xanthomonas oryzae pv.oryzae(Xoo)and in Arabidopsis and tomato challenged with Pseudomonas syringae pv.tomato DC3000(Pst DC3000),whereas Os RALF27 did not enhance resistance.
基金supported by Punjab Agricultural University,Ludhiana,India,for providing the infrastructure and other facilities for conducting experiments.All other forms of support and financial assistance are duly acknowledged.
文摘Brown spot(BS)of rice,caused by Bipolaris oryzae,is a serious concern that not only causes quantitative losses but also affects grain quality.To manage this disease,the use of resistant genetic sources and QTLs is an eco-friendly and economical option.In the current study,F_(3) progenies derived from a cross of susceptible parent PMS-18-B(PAU 10845-1-1-1-1)×resistant parent RP Path 77(RP patho-17)were used to identify potential QTLs linked to BS resistance and to associate this resistance with a temporal spike in defense-related enzymes.
基金supported by the grants to Min Qiu and Ming Wang from the National Natural Science Foundation of China(32100160 and 32100044)the grants to Ming Wang from the Jiangsu“Innovative and Entrepreneurial Talent”Program,China(JSSCRC2021510)the grants to Yuanchao Wang from the Chinese Modern Agricultural Industry Technology System(CARS-004-PS14)。
文摘The accuracy of genomic annotation is crucial for subsequent functional investigations;however,computational protocols used in high-throughput annotation of open reading frames(ORFs)can introduce inconsistencies.These inconsistencies,which lead to non-uniform extension or truncation of sequence ends,pose challenges for downstream analyses.Existing strategies to rectify these inconsistencies are time-consuming and labor-intensive,lacking specific approaches.To address this gap,we developed to GC,a tool that integrates genomic annotation with RNA-seq datasets to rectify annotation inconsistencies.Using to GC,we achieved an accuracy of nearly 100%accuracy in correcting inconsistencies in published Phytophthora sojae ORFs.We applied this innovative pipeline to the GPCR-bigrams gene family,which was predicted to have 42 members in the P.sojae genome but lacked experimental validation.By employing to GC,we identified 32 GPCR-bigram ORFs with inconsistencies between previous annotations and to GC-corrected sequences.Notably,among these were 5 genes(GPCR-TKL9,GPCR-TKL15,GPCR-PDE3,GPCR-AC3,and GPCR-AC4)showed substantial inconsistencies.Experimental gene annotation confirmed the effectiveness of to GC,as sequences obtained through cloning matched those annotated by to GC.Importantly,we discovered two novel GPCRs(GPCR-AC3 and GPCR-AC4),which were previously mispredicted as a single gene.CRISPR/Cas9-mediated knockout experiments revealed the involvement of GPCR-AC4 but not GPCR-AC3 in oospore production,further confirming their status as two separate genes.In addition to P.sojae,the reliability of the to GC pipeline in Phytophthora capsici and Pythium ultimum further emphasizes the robustness of this pipeline.Our findings highlight the utility of to GC for reliable gene model correction,facilitating investigations into biological functions and offering potential applications in diverse species analyses.
基金supported by the Jiangsu Agricultural Science and Technology Innovation Fund,China(CX(23)1011)the Earmarked Fund for China Agriculture Research System(CARS-28)+3 种基金the National Natural Science Foundation of China(31901837)the China Postdoctoral Science Foundation(2020M671389)the Basal Research Fund for the Jiangsu Academy of Agricultural Sciences,China(ZX(23)3016)the Yafu Technology Service Project,China(KF(23)1106)。
文摘In recent years,an unusual wilt disease affecting Pyrus pyrifolia has been observed in various regions of Jiangsu,China.This disease originates from the roots and progresses with distinctive browning patterns along vascular tissues,even extending over two meters above the ground.These symptoms set it apart from recognized pear diseases and typically lead to the death of affected trees within the same or the following year.Furthermore,this disease exhibits a tendency to spread to neighboring trees even after the removal of affected trees,presenting a substantial threat to pear production.To ascertain the causative agent,the present study encompassed pathogen isolation,morphological and molecular identification,as well as validation experiments adhering to Koch's postulates.The fungal isolates obtained were identified as Fusarium cugenangense based on characteristics of the colonies and conidia,in addition to a phylogenetic analysis using DNA sequences of the translation elongation factor 1-alpha(tef1),calmodulin(Ca M),and RNA polymerase second largest subunit(rpb2)genes.Pathogenicity of the isolated F.cugenangense on pear was confirmed by artificial inoculation.By introducing GFP-labeled pathogens into the roots,colonization in stem and leaf tissues was observed via fluorescence microscopy and transmission electron microscopy.Furthermore,these pathogens were successfully reisolated from stems and foliage,conclusively providing evidence of systemic infection within the pear plants.To the best of our knowledge,this is the first report of F.cugenangense causing pear wilt disease in China.
文摘WRKY transcription factors have many regulatory roles we isolated a rice WRKY gene (OsWRKY31) that is induced in response to biotic and abiotic stresses. In this study, by the rice blast fungus Magnaporthe grisea and auxin. This gene encodes a polypeptide of 211 amino-acid residues and belongs to a subgroup of the rice WRKY gene family that probably originated after the divergence of monocot and dicot plants. OsWRKY31 was found to be localized to the nucleus of onion epidermis cells to transiently express OsWRKY31-eGFP fusion protein. Analysis of OsWRKY31 and its mutants fused with a Gal4 DNA-binding domain indicated that OsWRKY31 has transactivation activity in yeast. Overexpression of the OsWRKY31 gene was found to enhance resistance against infection with M. grisea, and the transgenic lines exhibited reduced lateral root formation and elongation compared with wild-type and RNAi plants. The lines with overexpression showed constitutive expression of many defense-related genes, such as PBZI and OsSci2, as well as early auxin-response genes, such as OslAA4 and OsCrll genes. Furthermore, the plants with overexpression were less sensitive to exogenously supplied IBA, NAA and 2,4-1) at high concentrations, suggesting that overexpression of the OsWRKY31 gene might alter the auxin response or transport. These results also suggest that OsWRKY31 might be a common component in the signal transduction pathways of the auxin response and the defense response in rice.
基金This work was supported by grants from the Natural Science Foundation of China(No.30470990,No.30571063)the"948"Project from the Minister of Agriculture in China,the"973"Project from the Minister of Science and Technology(No.2006CB101904)+1 种基金Hunan Natural Science Foundation(No.06JJ10006)Scientific Research Fund of Hunan Provincial Education department(No.04A024).
文摘Plants employ multifaceted mechanisms to fight with numerous pathogens in nature.Resistance(R)genes are the most effective weapons against pathogen invasion since they can specifically recognize the corresponding pathogen effectors or associated protein(s)to activate plant immune responses at the site of infection.Up to date,over 70 R genes have been isolated from various plant species.Most R proteins contain conserved motifs such as nucleotide-binding site(NBS),leucine-rich repeat(LRR),Toll-interleukin-1 receptor domain(TIR,homologous to cytoplasmic domains of the Drosophila Toll protein and the manamalian intefleukin-1 receptor),coiled-coil(CC)or leucine zipper(LZ)structure and protein kinase domain(PK).Recent results indicate that these domains play significant roles in R protein interactions with effector proteins from pathogens and in activating signal transduction pathways involved in innate immunity.This review highlights an overview of the recent progress in elucidating the structure,function and evolution of the isolated R genes in different plant-pathogen interaction systems.
文摘Post-translational modification is central to protein stability and to the modulation of protein activity. Various types of protein modification, such as phosphorylation, methylation, acetylation, myristoylation, glycosylation, and ubiquitination, have been reported. Among them, ubiquitination distinguishes itself from others in that most of the ubiquitinated proteins are targeted to the 26S proteasome for degradation. The ubiquitin/26S proteasome system constitutes the major protein degradation pathway in the cell. In recent years, the importance of the ubiquitination machinery in the control of numerous eukaryotic cellular functions has been increasingly appreciated. Increasing number of E3 ubiquitin ligases and their substrates, including a variety of essential cellular regulators have been identified. Studies in the past several years have revealed that the ubiquitination system is important for a broad range of plant developmental processes and responses to abiotic and biotic stresses. This review discusses recent advances in the functional analysis of ubiquitination-associated proteins from plants and pathogens that play important roles in plant-microbe interactions.
基金supported by the National Key Research and Development Program of China(2017YFD0300906-07)
文摘Wheat leaf rust,caused by Puccinia triticina(Pt),is an important foliar disease that has an important influence on wheat yield.The most economic,safe and effective way to control the disease is growing resistant cultivars.In the present study,a total of 46 wheat landraces and 34 wheat lines with known Lr(leaf rust resistance)genes were inoculated with 16Pt pathotypes for postulating seedling resistance gene(s)in the greenhouse.These cultivars and five wheat differential lines with adult plant resistance(APR)genes(Lr12,Lr22b,Lr34,Lr35 and Lr37)were also evaluated for identification of slow rusting resistance in the field trials in Baoding,Hebei Province of China in the 2014–2015 and 2015–2016 cropping seasons.Furthermore,10 functional molecular markers closely linked to 10 known Lr genes were used to detect all the wheat genotypes.Results showed that most of the landraces were susceptible to most of the Pt pathotypes at seedling stage.Nonetheless,Lr1 was detected only in Hongtangliangmai.The field experimental test of the two environments showed that 38 landraces showed slow rusting resistance.Seven cultivars possessed Lr34 but none of the landraces contained Lr37 and Lr46.Lr genes namely,Lr9,Lr19,Lr24,Lr28,Lr29,Lr47,Lr51 and Lr53 were effective at the whole plant stage.Lr18,Lr36 and Lr45 had lost resistance to part of pathotypes at the seedling stage but showed high resistance at the adult plant stage.Lr34 as a slowing rusting gene showed good resistance in the field.Four race-specific APR genes Lr12,Lr13,Lr35 and Lr37 conferred good resistance in the field experiments.Seven race-specific genes,Lr2b,Lr2c,Lr11,Lr16,Lr26,Lr33 and LrB had lost resistance.The 38 landraces showed slow rusting resistance to wheat leaf rust can be used as resistance resources for wheat resistance breeding in China.
文摘High-temperature adult-plant (HTAP) resistance expresses when plants grow old and the weather becomes warm. This non-race specific and durable type of resistance has been used successfully in control of wheat stripe rust in the US since early 1960s. This article describes practical procedures for identification and characterization of HTAP resistance and reviews recent studies on discovery of genes conferring HTAP resistance. Recent studies providing insights to the molecular basis for the durability of HTAP resistance will be presented. Strategies for improving levels of HTAP resistance and improving control of stripe rust through combining HTAP resistance with effective all-stage resistance will be discussed.
基金Supported by the USDA-NRI,USA(No.NRI-2007-03307)the USDA Southern Region SARE Program,USA(No.2012-02978)+2 种基金the China Scholarship Council(No.[2006]3085)the National Natural Science Foundation of China(No.41201259)the Natural Science Foundation of Shaanxi Province,China(No.2013JQ5001)
文摘Management intensity critically influences the productivity and sustainability of pasture systems through modifying soil microbes, and soil carbon (C) and nutrient dynamics; however, such effects are not well understood yet ir the southeastern USA. We examined the effects of grazing intensity and grass planting system on soil C and nitrogen (N) dynamics, and microbial biomass and respiration in a long-term field experiment in Goldsboro, North Carolina, USA. A split-plot experiment was initiated in 2003 on a highly sandy soil under treatments of two grass planting systems (ryegrass rotation with sorghum-sudangrass hybrid and ryegrass seeding into a perennial bermudagrass stand) at low and high grazing densities. After 4 years of continuous treatments, soil total C and N contents across the 0 30 cm soil profile were 24.7% and 17.5% higher at the high than at the low grazing intensity, likely through promoting plant productivity and C allocation belowground as well as fecal and urinary inputs. Grass planting system effects were significant only at the low grazing intensity, with soil C, N, and microbial biomass and respiration in the top 10 cm being higher under the ryegrass/bermudagrass than under the ryegrass/sorghum-sudangrass hybrid planting systems. These results suggest that effective management could mitigate potential adverse effects of high grazing intensities on soil properties and facilitate sustainability of pastureland.
文摘Abiotic stresses including drought,salinity,heat,cold,flooding,and ultraviolet radiation causes crop losses worldwide.In recent times,preventing these crop losses and producing more food and feed to meet the demands of ever-increasing human populations have gained unprecedented importance.However,the proportion of agricultural lands facing multiple abiotic stresses is expected only to rise under a changing global climate fueled by anthropogenic activities.Identifying the mechanisms developed and deployed by plants to counteract abiotic stresses and maintain their growth and survival under harsh conditions thus holds great significance.Recent investigations have shown that phytohormones,including the classical auxins,cytokinins,ethylene,and gibberellins,and newer members including brassinosteroids,jasmonates,and strigolactones may prove to be important metabolic engineering targets for producing abiotic stress-tolerant crop plants.In this review,we summarize and critically assess the roles that phytohormones play in plant growth and development and abiotic stress tolerance,besides their engineering for conferring abiotic stress tolerance in transgenic crops.We also describe recent successes in identifying the roles of phytohormones under stressful conditions.We conclude by describing the recent progress and future prospects including limitations and challenges of phytohormone engineering for inducing abiotic stress tolerance in crop plants.
基金supported by the National Natural Science Foundation of China (31171805 and 31371897)
文摘The mitogen-activated protein kinase (MAPK), a key signal transduction component in the MAPK cascade pathway, regulates a variety of physiological activities in eukaryotes. However, little is known of the role MAPK plays in phytopathogenic fungi. In this research, we cloned the MAPK gene STK1 from the northern corn leaf blight pathogen Setosphaeria turcica and found that the gene shared high homology with the high osmolality glycerol (HOG) MAPK gene HOG1 of Saccharomy- ces cerevisiae. In addition, gene knockout technology was employed to investigate the function of STKI. Gene knockout mutants (KOs) were found to have altered hyphae morphology and no conidiogenesis, though they did show similar radial growth rate compared to the wild-type strain (WT). Furthermore, microscope observations indicated that STK1 KOs did not form normal appressoria at 48 h post-inoculation on a hydrophobic surface. STK1 KOs had reduced virulence, a significantly altered Helminthosporium turcicum (HT)-toxin composition, and diminished pathogenicity on the leaves of susceptible inbred corn OH43. Mycelium morphology appeared to be significantly swollen and the radial growth rates of STK1 KOs declined in comparison with WT under high osmotic stress. These results suggested that STK1 affects the hyphae development, conidiogenesis, and pathogenicity of S. turcica by regulating appressorium development and HT-toxin biosynthesis. Moreover, the gene appears to be involved in the hypertonic stress response in S. turcica.
文摘Long non-coding RNA (lncRNA) refers to an over 200 nt functional RNA molecule that will not be translated into protein. Previously thought to be dark matters of the genome, lncRNAs have been gradually recognized as crucial gene regulators. Although tremendous progress has been made in animals and human, the study of lncRNAs in plant is still in its infancy. Here, we reviewed the biogenesis and regulation mechanisms of lncRNAs and summarized the achievements that have been made in plant lncRNA identification and functional characterization. Genome-wide identification has uncovered large amount of lncRNAs in Arabidopsis, Rice, Maize and Wheat, and more information from other plant species will be expected with the aid of deep sequencing technologies. Similar to other species, LncRNA-mediated gene regulation also widely exists in plants, even though only a few functionally characterized examples are available. Up to now, at least four divergent lncRNA-mediated regulation mechanisms have been unraveled, including target mimicry, transcription interference, PRC2 associated histone methylation and DNA methylation. lncRNAs may be involved in the regulation of flowering, male sterility, nutrition metabolism, biotic and abiotic stress response in plants.
基金the National Natural Science Foundation of China(Grant Nos.31701779 and 31922066)the Applied Basic Research Programs of Science and Technology Department from Sichuan Province(Grant No.2019YJ0432)China Postdoctoral Science Foundation(Grant No.2017M612984).
文摘Plant lesion mimic mutants(lmms)generally possess autoimmunity and hypersensitive response(HR)-like cell death in the absence of biotic or abiotic stress.They have attracted much attention because they are useful tools for deciphering the interaction between defense signaling and growth.Recent studies have identified more than 30 lmms involved in the plant immune response and cell death in rice.Genes underlying these lmms,coding for diverse types of proteins,mainly regulate transcription,protein translation and modification,vesicular trafficking and catalyzation of metabolism.Here,we presented an overview of the most recent advances on the study of lmms in rice and proposed a perspective on potential utilization of LMM genes in agriculture.
文摘Trichoderma strains are used in agriculture because they provide to the plants the following benefits: i) are rhizosphere competence and establish stable rhizosphere microbial communities; ii) control plant disease caused by pathogenic and competitive microflora, by using a variety of mechanisms; iii) improve vegetative growth, root development and yield; iv) make nutrients more available to the plant. In this work we have investigated the ability of T. harzianum T22 and T. atroviride P1 to improve plant growth of locally important horticultural crops: lettuce, tomatoes and peppers and to prevent disease in the greenhouse and field. The effect of the Trichoderma treatment was evaluated by determining the weight of fresh and dry roots and above ground plant biomass, measuring plants height, counting the number of emerged leaves (lettuce, tomatoes and peppers) and quantifying production (tomatoes and peppers). No disease symptoms were found during production, although Fusarium sp. strains pathogenic to tomato were detected in the soil. Compounds containing copper oxychloride are frequently used for fungal disease control in agriculture. In order to investigate the compatibility of T. harzianum T22 and T. atroviride P1 with copper oxychloride applications, the effect on mycelia growth was monitored in both liquid and solid medium. In general, the tests indicated a high level of tolerance of the Trichoderma strains to concentrations of copper oxychloride varying from 0.1 to 5 mmol/L.
