Carotenoids are lipophilic isoprenoid pigments with essential roles in plants.While the cultivated allotetraploid cottons exhibit distinct mature anther coloration—yellow in Gossypium barbadense versus predominantly ...Carotenoids are lipophilic isoprenoid pigments with essential roles in plants.While the cultivated allotetraploid cottons exhibit distinct mature anther coloration—yellow in Gossypium barbadense versus predominantly white in G.hirsutum—the genetic basis of this divergence remains unclear.The purpose of this study was to identify the genetic basis of anther-color variation in cotton(Gossypium)species.We firstly identified carotenoids as the primary pigments underlying yellow-anthers coloration.Comparative transcriptomics of anthers revealed that the carotenoid biosynthesis gene GbPSY4 was expressed as a key regulator in G.barbadense.Functional validation via tissue-specific expression,subcellular localization,in vivo enzymatic assays,and virus-induced gene silencing confirmed its role in carotenoid biosynthesis and yellow pigmentation.Genome-wide association studies in a G.hirsutum population revealed GhPSY4_At,an ortholog of GbPSY4,as the causal gene of anther-color variation.We conclude that PSY4-regulated carotenoid biosynthesis governs yellow pigmentation.Furthermore,a finding that G.hirsutum accessions with yellow anthers showed greater pollen viability under high-temperature stress than those with white anthers suggests that the same pathway that governs yellow pigmentation influences heat tolerance.PSY4 is a promising target for breeding stress-tolerant cotton varieties.展开更多
Post-translational modifications(PTMs)regulate the occurrence and development of cancer,and lactylation modification is a new form of PTMs.Recent studies have found that lactic acid modification can regulate the immun...Post-translational modifications(PTMs)regulate the occurrence and development of cancer,and lactylation modification is a new form of PTMs.Recent studies have found that lactic acid modification can regulate the immune tolerance of cancer cells.The classical theory holds that prostate apoptosis response-4(PAR-4)is a tumor suppressor protein.However,our recent research has found that PAR-4 has a biological function of promoting cancer in hepatocellular carcinoma(HCC),and our analysis shows that PAR-4 can be modified of lactic acid.These research evidences suggest that PAR-4 lactylation modification may drive immune tolerance in HCC.Therefore,inhibiting PAR-4 lactylation modification is very likely to increase the sensitivity of HCC to immunotherapy.展开更多
Watermelon(Citrullus lanatus) is sensitive to salt stress. For breeding applications, it is of great significance to explore the genetic mechanism underlying salt tolerance in watermelon by analyzing the dehydration r...Watermelon(Citrullus lanatus) is sensitive to salt stress. For breeding applications, it is of great significance to explore the genetic mechanism underlying salt tolerance in watermelon by analyzing the dehydration responsive element-binding(DREB) factor family members.However, they are rarely studied in watermelon. In this study, we identified ClaDREB gene family members in watermelon based on whole genome data;analyzed the physicochemical properties, evolution, and phylogeny;and studied their expression patterns under salt stress in two watermelon varieties with varying salt tolerance. In total, 57 DREB family members were identified in watermelon, and most of them were located in the nucleus. ClaDREBs were divided into six subgroups Ⅰ-Ⅵ. The promoter region of ClaDREBs from subgroup Ⅱ contained many defense-related and stress responsive elements. Among them, ClaDREB14 was significantly upregulated by salt stress and exhibited differential expression in salt-tolerant and salt-sensitive varieties. Moreover, overexpression of ClaDREB14 in watermelon roots significantly improved the salt tolerance of transgenic plants;mainly, it significantly increased the activities of POD, SOD, and CAT and significantly reduced MDA content.However, the results from gene-edited watermelon roots obtained using CRISPR/Cas9 vectors showed the opposite trend. Furthermore, we demonstrated that ClaDREB14 directly binds to the cis-acting element ACCGAC in the promoter region of ClaPOD6 and promotes its expression.Therefore, ClaDREB14 may enhance salt tolerance by increasing the activity of antioxidant enzymes in watermelon roots. This study provided valuable information on the DREB gene family in watermelon and laid the foundation for future functional validation and genetic engineering applications.展开更多
Structural variation is an important source of genetic variation in wheat and have been important in the evolution of the wheat's genome.Few studies have examined the relationship between structural variations and...Structural variation is an important source of genetic variation in wheat and have been important in the evolution of the wheat's genome.Few studies have examined the relationship between structural variations and agronomy and drought tolerance.The present study identified structural chromosome variations(SCVs)in a doubled haploid(DH)population and backcross introgression lines(BC5F3)derived from Jinmai 47 and Jinmai 84 using fluorescence in situ hybridization(FISH).There are one simple translocation,10 present/absent variations(PAVs),and one copy number variation(CNV)between Jinmai 47 and Jinmai 84,which distributed in 10 chromosomes.Eight SCVs were associated with 15 agronomic traits.A PAV recombination occurred on chromosome 2A,which was associated with grain number per spike(GNS).The 1BL/1RS translocation and PAV.2D were associated with significant reductions in plant height,deriving from the effects on LI2-LI4,LI2-LI4 and UI,respectively respectively.PAV.2D was also contributed to an increase of 3.13%for GNS,1BL/1RS significantly increased spikelet number,grain length(GL),and grain thickness(GT).The effect of PAV.4A.1 on GL,PAV.6A on spike length(SL)and thousand-grain weight(TGW),PAV.6B on SL,GT and TGW were identified and verified.PAVs on chromosomes 2A,6A,1D,2D,and a CNV on chromosome 4B were associated with the drought tolerance coefficients.Additive and interaction effects among SCVs were observed.Many previously cloned key genes and yield-related QTL were found in polymorphic regions of PAV.2B,PAV.2D,and CNV.4B.Altogether,this study confirmed the genetic effect of SCVs on agronomy and drought tolerance,and identification of these SCVs will facilitate genetic improvement of wheat through marker-assisted selection.展开更多
Ceratitis capitata(Wiedemann)is a cosmopolitan pest of economic importance.It is controlled by using the Sterile Insect Technique(SIT),which involves rearing and release of sterile males destined to mate with wild fem...Ceratitis capitata(Wiedemann)is a cosmopolitan pest of economic importance.It is controlled by using the Sterile Insect Technique(SIT),which involves rearing and release of sterile males destined to mate with wild females,causing generation-to-generation suppression.Medflies are colonized by microorganisms,primarily the Enterobacteriaceae,with the genera Klebsiella and Enterobacter being the most common.Such microbiota contributes to host fitness.During the SIT,diet with antibiotics and irradiation for sterility of adults alter microbiota.We aimed to determine the role of Medfly microbiota on resistance to abiotic stress conditions,evaluating its function under:(i)starvation,(ii)elevated temperatures,and(iii)dry environments.These conditions simulate challenges Medfly may encounter after release,which differ from controlled rearing environments.We compared adult survival between symbiotic and aposymbiotic individuals,under starvation,two thermal regimes(25 and 30℃)or two humidity regimes(20%-25%and 80%-90%R.H.).Aposymbiotic individuals were obtained after providing them with water containing a mixture of antibiotics and methylparaben.Treatment with antimicrobials effectively reduced the gut microbiota.While starvation had no significant effect on survival,a higher proportion of aposymbiotic individuals died earlier at 30℃ and under dry humidity,with the effect being more pronounced after 48 h.Our results suggest that microbiota plays a role in adaptation of Medfly under environmental stress.We report for the presence of a culturable yeast in the digestive tract of C.capitata,Zygosaccharomyces rouxii.Providing a probiotic adult diet with bacteria and Z.rouxii prior to release could improve SIT outcomes under adverse conditions.展开更多
OBJECTIVE:To investigate the effects of Jinlida granules(津力达颗粒,JLD)on body weight,glucose tolerance,intestinal inflammation and barrier function in high-fat diet(HFD)-induced obese rats and explore the regulation...OBJECTIVE:To investigate the effects of Jinlida granules(津力达颗粒,JLD)on body weight,glucose tolerance,intestinal inflammation and barrier function in high-fat diet(HFD)-induced obese rats and explore the regulation of the gut microbiota as a potential treatment mechanism.METHODS:Sprague-Dawley rats were divided into control,HFD,low-dose JLD(L-JLD),high-dose JLD(HJLD),and sitagliptin groups.The rats,with the exception of those in the control group,were fed a HFD to establish an obesity model while simultaneously receiving 0.5%carboxymethyl cellulose,L-JLD,H-JLD or sitagliptin for 25 weeks.We assessed body weight,conducted oral glucose tolerance tests,and analysed faecal samples using metagenomic sequencing.Haematoxylin-eosin(HE),Masson and immunohistochemical(IHC)staining were employed to evaluate histological changes in the colon tissue.Immunofluorescence(IF)staining was used to measure the expression levels of Zonula occludens-1(ZO-1)and Claudin-1 in colon tissue.The colon tissue was also subjected to transcriptomic evaluation.RESULTS:JLD treatment significantly reduced body weight and enhanced glucose tolerance in obese rats.It alleviated colonic tissue damage,decreased collagen deposition,inhibited macrophage infiltration,and increased the expression of the tight junction proteins ZO-1 and Claudin-1.Metagenomic analysis revealed JLDinduced shifts in the gut microbiota composition(increasing the abundance of Turicibacter,Faecalibaculum,Coriobacteriaceae and Lactobacillus reuteri),enriching beneficial bacteria and metabolic pathways(increasing the biosynthesis of various secondary metabolites,ascorbate and aldarate metabolism,oxidative phosphorylation,C5-branched dibasic acid metabolism and beta-alanine metabolism).Transcriptomic analysis revealed downregulation of inflammatory and immune pathways(inhibition of the tumour necrosis factor signalling pathway,advanced glycation end products-receptor for advanced glycation end products signalling pathway,toll-like receptor signalling pathway,and interleukin-17 signalling pathway),suggesting a comprehensive modulatory effect of JLD on intestinal health and metabolic function.CONCLUSIONS:JLD granules effectively improve glucose tolerance and ameliorate obesity-related intestinal dysfunctions in HFD-induced obese rats.These benefits are likely mediated through the modulation of the gut microbiota,the suppression of intestinal inflammation,the enhancement of barrier function,and the attenuation of proinflammatory pathways.Our findings offer novel insights into the therapeutic potential of JLD,emphasizing its role in integrating gut microbiota management into the treatment of metabolic disorders.展开更多
Wild edible plants have evolved in response to persistent and often severe environmental pressures,including salinity,drought,extreme temperatures,high light intensity and nutrient-poor soils.Despite the considerable ...Wild edible plants have evolved in response to persistent and often severe environmental pressures,including salinity,drought,extreme temperatures,high light intensity and nutrient-poor soils.Despite the considerable physiological flexibility and adaptive capacity exhibited by these species,they remain underrepresented in contemporary plant stress research,which has traditionally focused on a limited number of model species and major crops.The present review proposes a conceptual framework that positions wild edible plants as physiological and ecological reference systems for studying naturally evolved plant stress tolerance,rather than as alternative genetic model species.The synthesis of current knowledge on the ecological contexts that shape their stress adaptation is conducted,and the major abiotic stressors influencing wild edible plants across diverse environments are examined.This study focuses on the physiological mechanisms involved in water regulation,osmotic adjustment,photosynthetic performance,and antioxidant defence.The role of metabolic plasticity and stress-induced production of secondary metabolites is also discussed,highlighting how chronic or moderate environmental stress may,under specific conditions,enhance nutritional and functional attributes without necessarily compromising metabolic stability.Furthermore,the potential of wild edible plants as reservoirs of stress-resilient traits relevant to sustainable agriculture,crop diversification,and functional food systems in marginal environments is evaluated.The identification of key research gaps is the final stage of the research process.These gaps include the limited application of omics-based approaches,the lack of standardised experimental methodologies,and the scarcity of direct comparative studies between wild edible and domesticated plant species.The present review underscores the potential benefits and current constraints associated with the utilisation of wild edible plants in promoting plant stress biology and informing climate-resilient agricultural strategies.展开更多
Low temperature is a major abiotic stress factor inducing the accumulation of dehydrins in plants.Dehydrins are hydrophilic,heat-stable proteins implicated in plant stress responses;however,their synthesis under cold ...Low temperature is a major abiotic stress factor inducing the accumulation of dehydrins in plants.Dehydrins are hydrophilic,heat-stable proteins implicated in plant stress responses;however,their synthesis under cold conditions during the early stages of wheat development has not been sufficiently studied.This study investigated the relationship between cold-induced dehydrin accumulation in etiolated seedlings and frost tolerance in wheat cultivars differing in their level of frost tolerance.Three-day-old seedlings of high frost-tolerant(high-FT)cultivars(Antonivka,Doskonala,and Nordika)and low frost-tolerant(low-FT)cultivars(Tobak,Tonnage,and Altigo)of Triticum aestivum L.were hardened at+3℃ for six days.Dehydrin accumulation was analyzed by electrophoretic separation,while frost tolerance was assessed based on seedling survival following freezing at−4,−9,and−12℃.Cold-induced oxidative damage was evaluated by determining malondialdehyde(MDA)content in seedling shoots after freezing at−4℃.In control seedlings,dehydrins were barely detectable in all cultivars.Cold hardening at+3℃ induced pronounced accumulation of dehydrins with molecular masses of approximately 46,49.6,and 68 kDa in both high-FT and low-FT cultivars.In contrast,low-molecular-weight dehydrins(14–16 kDa)were detected predominantly in high-FT cultivars.Seedling survival after freezing at−12℃ showed a strong positive correlation with total dehydrin content(r=0.82).Even stronger correlations were observed between the content of low-molecular-weight dehydrins(14–16 kDa)and seedling survival after freezing at−9 and−12℃(r=0.84 and 0.94,respectively).An inverse correlation was found between 14–16 kDa dehydrin content and MDA accumulation following freezing at−4℃(r=−0.87).These results indicate that low-molecular-weight dehydrins play an important role in protecting etiolated wheat seedlings from cold-induced oxidative stress and may serve as reliable biochemical markers of frost tolerance.展开更多
HVA22 is a gene induced by abscisic acid(ABA)and abiotic stress.Previous transcriptome data of salt-tolerant Tritipyrum“Y1805”revealed that HVA22 was significantly upregulated under salt stress.Gene TtHVA22 was succ...HVA22 is a gene induced by abscisic acid(ABA)and abiotic stress.Previous transcriptome data of salt-tolerant Tritipyrum“Y1805”revealed that HVA22 was significantly upregulated under salt stress.Gene TtHVA22 was successfully amplified from“Y1805”,with an open reading frame of 468 bp and encoding a protein of 156 amino acids.Gene TtHVA22 was transformed into bread wheat“1718”via coleoptile method.The relative expression level of TtHVA22 in roots was remarkably higher than in stems and leaves under salt stress.During the seedling stage,the TtHVA22 overexpression(OE)line exhibited less leaf wilting under salt stress than wild-type(WT)plants.Under salt stress and recovery conditions,TtHVA22 OE significantly increased root length,plant height,fresh weight,and dry weight compared to WT plants.Additionally,the levels of ABA,soluble sugars,soluble proteins,proline,pyruvate,and photosynthetic pigments and peroxidase activity were significantly higher in the OE lines than in the WT plants;however,their malondialdehyde content and relative conductivity were opposite.Two years of field data demonstrated that stem diameter and grain yield per plant were significantly greater in the OE lines than the WT plants.Therefore,wheat salt tolerance was improved in the TtHVA22 OE lines by osmotic regulation,antioxidation,and chlorophyll stabilization.展开更多
Cold stress represents a critical constraint on crop productivity,particularly in temperate climates.Despite the established role of abscisic acid(ABA)in cold stress responses,the precise mechanisms through which tran...Cold stress represents a critical constraint on crop productivity,particularly in temperate climates.Despite the established role of abscisic acid(ABA)in cold stress responses,the precise mechanisms through which transcription factors mediate ABAdependent cold tolerance remain elusive.Here,we identify VaMYB4a,a MYB transcription factor from Vitis amurensis Rupr.(Amur grape),as a key regulator of cold tolerance.It integrates ABA signaling with the CBF(C-repeat binding factors)-COR(cold-regulated)pathway to orchestrate cold stress adaptation.Through a combination of overexpression and CRISPR/Cas9-mediated knockout lines in Arabidopsis thaliana,grape callus,and Vitis vinifera L.seedlings,we demonstrate that VaMYB4a enhances freezing tolerance by promoting osmotic regulation,reactive oxygen species(ROS)scavenging,and stomatal closure.VaMYB4a functions as a homo-dimer,with its C-terminal domain being essential for transcriptional activation.Mechanistically,VaMYB4a directly upregulates CBF and COR genes while fine-tuning ABA signaling components such as ABI1 and ABF4.Notably,ABA exhibits a dual role:enhancing VaMYB4a-mediated freezing tolerance under short-term stress but attenuating its effects during prolonged cold exposure,revealing an intricate regulatory crosstalk between cold and hormonal pathways.Our work not only advances the molecular understanding of cold adaptation but also provides a promising genetic target for developing stress-resilient grape varieties to mitigate the impacts of climate change.展开更多
The large and complex genome of bread wheat,characterized by hexaploidy and a high proportion of repetitive elements(Figure 1),has long been recognized as a barrier for gene discovery.Along with recent advancements in...The large and complex genome of bread wheat,characterized by hexaploidy and a high proportion of repetitive elements(Figure 1),has long been recognized as a barrier for gene discovery.Along with recent advancements in the acquisition of genomic information of bread wheat(Xiao et al.,2022),however,increasing evidence suggests that these genomic features offer great potential for both generating and conserving specific genic resources,in particular those pertaining to abiotic stress tolerance.展开更多
Prohibitin(PHB)plays critical roles in plant growth and development.In this study,we utilized CRISPR/Cas9 gene-editing technology to generate homozygous OsPHB2 knockout transgenic plants,designated cr-osphb2.The cr-os...Prohibitin(PHB)plays critical roles in plant growth and development.In this study,we utilized CRISPR/Cas9 gene-editing technology to generate homozygous OsPHB2 knockout transgenic plants,designated cr-osphb2.The cr-osphb2 line exhibited wider leaves,dwarfism,and shorter panicles.Subcellular localization results indicated that OsPHB2 localizes to mitochondria.Under salt stress conditions,cr-osphb2 exhibited enhanced tolerance.Haplotype(Hap)analysis identified three major Haps(Hap1,Hap2,and Hap3)of OsPHB2,among which Hap2 was associated with a greater number of effective panicles and higher yield,indicating its potential value for breeding applications.Collectively,our findings demonstrate that OsPHB2 plays an important role in regulating growth,development,and salt stress responses in rice.展开更多
As one of the main chronic diseases in modern society,coronary heart disease,as a major disease that affects people’s lives and health,has the characteristics of hidden onset and sudden onset.Coronary heart disease h...As one of the main chronic diseases in modern society,coronary heart disease,as a major disease that affects people’s lives and health,has the characteristics of hidden onset and sudden onset.Coronary heart disease has relatively clear risk factors.Among them,blood lipid levels and blood sugar levels,as two main risk factors,play an important role in promoting the onset of coronary heart disease.The two complement each other in a vicious cycle,synergize and promote each other,promote the process of coronary atherosclerosis,thereby causing coronary heart disease.Multiple components in blood lipids and poor management of long-term blood sugar levels play a major role in specific clinical problems.This article reviews the different components of blood lipids and the effects of hyperglycemia on coronary heart disease,and initially expounds the mechanism by which blood lipids and blood sugar levels synergize each other to aggravate the risk of coronary heart disease,and combines them with relevant clinical issues,in order to help clinicians guide the prevention of coronary heart disease in terms of blood lipids and blood sugar levels.展开更多
Source-sink coordination serves as the foundation for improving crop yield.Current research primarily focuses on individual factors,such as increasing the source or expanding the sink,which often leads to disrupted so...Source-sink coordination serves as the foundation for improving crop yield.Current research primarily focuses on individual factors,such as increasing the source or expanding the sink,which often leads to disrupted source-sink balance,causing trade-offs among photosynthesis,yield,and stress response.To address these limitations,we present an integrated synthetic biological framework that synergistically enhances photosynthetic efficiency(source capacity),sink optimization,and abiotic stress tolerance.We developed an editing-overexpression coupling(EOC)vector system enabling simultaneous overexpression of four photosynthesis-enhancing genes(Cyt c6,PsbA,FBPase,OsMGT3),knockout of three yield-limiting genes(GS3,Gn1a,OsAAP5),and self-excision of selection markers,gene-editing modules,and fragment deletion cassettes.Field evaluations of CFMP-gga transgenic lines revealed significant physiological improvements,including 13%–17%increase in photosynthetic rates,improved chlorophyll fluorescence parameters,and increased stomatal conductance.These enhancements translated into remarkable agronomic gains,including 18.7%–22.3%higher grain yield,23.1%–26.1%increased biomass,and improved panicle architecture(increased grain size and grain number per panicle).The engineered lines maintained superior thermotolerance(under 42°C stress)and alkali tolerance(at pH 10)compared to wild-type controls.This study provides a strategy for enhancing crop yield by demonstrating that coordinated multi-gene regulation of source-sink dynamics,coupled with stress resilience engineering,achieves concurrent improvements.展开更多
Global warming impacts plant growth and development,which in turn threatens food security.Plants can clearly respond to warm-temperature(such as by thermomorphogenesis)and high-temperature stresses.At the molecular le...Global warming impacts plant growth and development,which in turn threatens food security.Plants can clearly respond to warm-temperature(such as by thermomorphogenesis)and high-temperature stresses.At the molecular level,many small molecules play crucial roles in balancing growth and defense,and stable high yields can be achieved by fine-tuning the responses to external stimuli.Therefore,it is essential to understand the molecular mechanisms underlying plant growth in response to heat stress and how plants can adjust their biological processes to survive heat stress conditions.In this review,we summarize the heat-responsive genetic networks in plants and crop plants based on recent studies.We focus on how plants sense the elevated temperatures and initiate the cellular and metabolic responses that allow them to adapt to the adverse growing conditions.We also describe the trade-off between plant growth and responses to heat stress.Specifically,we address the regulatory network of plant responses to heat stress,which will facilitate the discovery of novel thermotolerance genes and provide new opportunities for agricultural applications.展开更多
The chalcone isomerase gene OsCHI,one of the key genes in the flavonoid biosynthesis pathway,plays an important role in rice(Oryza sativa)resistance to abiotic stresses.This study reveals how the chalcone isomerase ge...The chalcone isomerase gene OsCHI,one of the key genes in the flavonoid biosynthesis pathway,plays an important role in rice(Oryza sativa)resistance to abiotic stresses.This study reveals how the chalcone isomerase gene family member OsCHI3 participates in rice responses to drought stress through the regulation of flavonoid biosynthesis.Overexpression of OsCHI3 increased the tolerance of rice to drought stress.In contrast,CRISPR/Cas9-mediated deletion of OsCHI3 reduced the drought tolerance of rice,an effect that is reversed by exogenous ABA treatment.Transcriptomic and physiological biochemical analyses indicated that flavonoids regulated by OsCHI3 not only scavenge reactive oxygen species(ROS)but also increase drought tolerance in rice by stimulating ABA biosynthesis through the regulation of OsNCED1 and OsABA8ox3 expression.These findings demonstrate that OsCHI3 increases drought stress tolerance in rice by activating the antioxidant defense system and the ABA metabolic pathway,providing new clues for drought-resistant rice breeding research.展开更多
The leucine-rich repeat(LRR)protein family is involved in a variety of fundamental metabolic and signaling processes in plants,including growth and defense responses.LRR proteins can be divided into two categories:tho...The leucine-rich repeat(LRR)protein family is involved in a variety of fundamental metabolic and signaling processes in plants,including growth and defense responses.LRR proteins can be divided into two categories:those containing LRR domains along with other structural elements,which are further subdivided into five groups,LRR receptor-like kinases,LRR receptor-like proteins,nucleotide-binding site LRR proteins,LRR-extensin proteins,and polygalacturonase-inhibiting proteins,and those containing only LRR domains.Functionally,various LRR proteins are primarily involved in plant development and responses to environmental stress.Notably,the LRR protein family plays a central role in signal transduction pathways related to stress adaptation.In this review,we classify and analyze the functions of LRR proteins in plants.While extensive research has been conducted on the roles of LRR proteins in disease resistance signaling,these proteins also play important roles in abiotic stress responses.This review highlights recent advances in understanding how LRR proteins mediate responses to biotic and abiotic stresses.Building upon these insights,further exploration of the roles of LRR proteins in abiotic stress resistance may aid efforts to develop rice varieties with enhanced stress and disease tolerance.展开更多
Potato(Solanum tuberosum)is a globally important staple crop.However,cultivated potato varieties are highly sensitive to low temperatures.The molecular mechanisms underlying freezing resistance in potatoes remain poor...Potato(Solanum tuberosum)is a globally important staple crop.However,cultivated potato varieties are highly sensitive to low temperatures.The molecular mechanisms underlying freezing resistance in potatoes remain poorly understood.Through comparative metabolome and transcriptome analyses of freezing-tolerant(CM,Solanum commersonii)and freezing-sensitive(DM,DM1-3516R44)varieties,we identified a coldinduced UDP-glycosyltransferase gene,ScUGT73B4,which is associated with the accumulation of glycosylated flavonoids in wild CM varieties.Overexpression of ScUGT73B4 led to increased accumulation of glycosylated flavonoids and enhanced antioxidant capacity,resulting in improved freezing tolerance in potato plantlets.These findings reveal a UDP-glycosyltransferase in the flavonoid pathway and offer a potential valuable genetic resource for breeding potatoes with improved freezing tolerance.展开更多
Salt stress significantly inhibits crop growth and development,and mitigating this can enhance salt tolerance in various crops.Previous studies have shown that regulating saccharide biosynthesis is a key aspect of pla...Salt stress significantly inhibits crop growth and development,and mitigating this can enhance salt tolerance in various crops.Previous studies have shown that regulating saccharide biosynthesis is a key aspect of plant salt tolerance;however,the underlying molecular mechanisms remain largely unexplored.In this study,we demonstrate that overexpression of a salt-inducible galactinol synthase gene,ZmGolS1,alleviates salt-induced growth inhibition,likely by promoting raffinose synthesis.Additionally,we show that natural variation in ZmGolS1 transcript levels contributes to the diversity of raffinose content and salt tolerance in maize.We further reveal that ZmRR18,a type-B response regulator transcription factor,binds to the AATC element in the promoter of ZmGolS1,with this binding increases the transcript levels of ZmGolS1 under salt conditions.Moreover,a single nucleotide polymorphism(termed SNP-302T)within the ZmGolS1 promoter significantly reduces its binding affinity for ZmRR18,resulting in decreased ZmGolS1 expression and diminished raffinose content,ultimately leading to a salt-hypersensitive phenotype.Collectively,our findings reveal the molecular mechanisms by which the ZmRR18-ZmGolS1 module enhances raffinose biosynthesis,thereby promoting maize growth under salt conditions.This research provides important insights into salt tolerance mechanisms associated with saccharide biosynthesis and identifies valuable genetic loci for breeding salt-tolerant maize varieties.展开更多
Frequent drought events severely restrict global crop productivity,especially those occurring in the reproductive stages.Moderate drought priming during the earlier growth stages is a promising strategy for allowing p...Frequent drought events severely restrict global crop productivity,especially those occurring in the reproductive stages.Moderate drought priming during the earlier growth stages is a promising strategy for allowing plants to resist recurrent severe drought stress.However,the underlying mechanisms remain unclear.Here,we subjected wheat plants to drought priming during the vegetative growth stage and to severe drought stress at 10 days after anthesis.We then collected leaf samples at the ends of the drought priming and recovery periods,and at the end of drought stress for transcriptome sequencing in combination with phenotypic and physiological analyses.The drought-primed wheat plants maintained a lower plant temperature,with higher stomatal openness and photosynthesis,thereby resulting in much lower 1,000-grain weight and grain yield losses under the later drought stress than the non-primed plants.Interestingly,416 genes,including 27 transcription factors(e.g.,MYB,NAC,HSF),seemed to be closely related to the improved drought tolerance as indicated by the dynamic transcriptome analysis.Moreover,the candidate genes showed six temporal expression patterns and were significantly enriched in several stress response related pathways,such as plant hormone signal transduction,starch and sucrose metabolism,arginine and proline metabolism,inositol phosphate metabolism,and wax synthesis.These findings provide new insights into the physiological and molecular mechanisms of the long-term effects of early drought priming that can effectively improve drought tolerance in wheat,and may provide potential approaches for addressing the challenges of increasing abiotic stresses and securing food safety under global warming scenarios.展开更多
基金the National Natural Science Foundation of China(32170271,32470277)the Project of Sanya Yazhou Bay Science and Technology City(SCKJ-JYRC-2023-52)the Natural Science Foundation of Henan Province(252300421076,222300420024).
文摘Carotenoids are lipophilic isoprenoid pigments with essential roles in plants.While the cultivated allotetraploid cottons exhibit distinct mature anther coloration—yellow in Gossypium barbadense versus predominantly white in G.hirsutum—the genetic basis of this divergence remains unclear.The purpose of this study was to identify the genetic basis of anther-color variation in cotton(Gossypium)species.We firstly identified carotenoids as the primary pigments underlying yellow-anthers coloration.Comparative transcriptomics of anthers revealed that the carotenoid biosynthesis gene GbPSY4 was expressed as a key regulator in G.barbadense.Functional validation via tissue-specific expression,subcellular localization,in vivo enzymatic assays,and virus-induced gene silencing confirmed its role in carotenoid biosynthesis and yellow pigmentation.Genome-wide association studies in a G.hirsutum population revealed GhPSY4_At,an ortholog of GbPSY4,as the causal gene of anther-color variation.We conclude that PSY4-regulated carotenoid biosynthesis governs yellow pigmentation.Furthermore,a finding that G.hirsutum accessions with yellow anthers showed greater pollen viability under high-temperature stress than those with white anthers suggests that the same pathway that governs yellow pigmentation influences heat tolerance.PSY4 is a promising target for breeding stress-tolerant cotton varieties.
基金supported by the National Natural Science Foundation of China(Nos.82573045,82460602,82560459)the Hainan Provincial Graduate Student Innovative Research Project(No.Qhys2024-440).
文摘Post-translational modifications(PTMs)regulate the occurrence and development of cancer,and lactylation modification is a new form of PTMs.Recent studies have found that lactic acid modification can regulate the immune tolerance of cancer cells.The classical theory holds that prostate apoptosis response-4(PAR-4)is a tumor suppressor protein.However,our recent research has found that PAR-4 has a biological function of promoting cancer in hepatocellular carcinoma(HCC),and our analysis shows that PAR-4 can be modified of lactic acid.These research evidences suggest that PAR-4 lactylation modification may drive immune tolerance in HCC.Therefore,inhibiting PAR-4 lactylation modification is very likely to increase the sensitivity of HCC to immunotherapy.
基金funded by grants fromthe China Agriculture Research System of MOF and MARA(CARS-25)the Key Research and Development Program of Xinjiang Uygur autonomous region(Grant No.2023B02017)+3 种基金the Agricultural Science and Technology Innovation Program(CAAS-ASTIP-2021-ZFRI,CAAS-ASTIP-2024-WRI)the Basic Research Funds of Chinese Academy of Agricultural Sciences(Grant No.1610192023201)Natural Science Foundation of Henan Province(Grant No.252300421694)Joint Research on Agricultural Variety Improvement of Henan Province(Grant No.2022010503).
文摘Watermelon(Citrullus lanatus) is sensitive to salt stress. For breeding applications, it is of great significance to explore the genetic mechanism underlying salt tolerance in watermelon by analyzing the dehydration responsive element-binding(DREB) factor family members.However, they are rarely studied in watermelon. In this study, we identified ClaDREB gene family members in watermelon based on whole genome data;analyzed the physicochemical properties, evolution, and phylogeny;and studied their expression patterns under salt stress in two watermelon varieties with varying salt tolerance. In total, 57 DREB family members were identified in watermelon, and most of them were located in the nucleus. ClaDREBs were divided into six subgroups Ⅰ-Ⅵ. The promoter region of ClaDREBs from subgroup Ⅱ contained many defense-related and stress responsive elements. Among them, ClaDREB14 was significantly upregulated by salt stress and exhibited differential expression in salt-tolerant and salt-sensitive varieties. Moreover, overexpression of ClaDREB14 in watermelon roots significantly improved the salt tolerance of transgenic plants;mainly, it significantly increased the activities of POD, SOD, and CAT and significantly reduced MDA content.However, the results from gene-edited watermelon roots obtained using CRISPR/Cas9 vectors showed the opposite trend. Furthermore, we demonstrated that ClaDREB14 directly binds to the cis-acting element ACCGAC in the promoter region of ClaPOD6 and promotes its expression.Therefore, ClaDREB14 may enhance salt tolerance by increasing the activity of antioxidant enzymes in watermelon roots. This study provided valuable information on the DREB gene family in watermelon and laid the foundation for future functional validation and genetic engineering applications.
基金supported by the Science and Technology Major Project of Shanxi Province,China(202201140601025-2,202302140601001)the Agricultural Science Research Project of Shanxi Agricultural University,China(2023BQ108)+1 种基金the Senior Foreign Experts Introducing Project,China(G202204011L)the Science and Technology Innovation Young Talent Team of Shanxi Province,China(202204051001019)。
文摘Structural variation is an important source of genetic variation in wheat and have been important in the evolution of the wheat's genome.Few studies have examined the relationship between structural variations and agronomy and drought tolerance.The present study identified structural chromosome variations(SCVs)in a doubled haploid(DH)population and backcross introgression lines(BC5F3)derived from Jinmai 47 and Jinmai 84 using fluorescence in situ hybridization(FISH).There are one simple translocation,10 present/absent variations(PAVs),and one copy number variation(CNV)between Jinmai 47 and Jinmai 84,which distributed in 10 chromosomes.Eight SCVs were associated with 15 agronomic traits.A PAV recombination occurred on chromosome 2A,which was associated with grain number per spike(GNS).The 1BL/1RS translocation and PAV.2D were associated with significant reductions in plant height,deriving from the effects on LI2-LI4,LI2-LI4 and UI,respectively respectively.PAV.2D was also contributed to an increase of 3.13%for GNS,1BL/1RS significantly increased spikelet number,grain length(GL),and grain thickness(GT).The effect of PAV.4A.1 on GL,PAV.6A on spike length(SL)and thousand-grain weight(TGW),PAV.6B on SL,GT and TGW were identified and verified.PAVs on chromosomes 2A,6A,1D,2D,and a CNV on chromosome 4B were associated with the drought tolerance coefficients.Additive and interaction effects among SCVs were observed.Many previously cloned key genes and yield-related QTL were found in polymorphic regions of PAV.2B,PAV.2D,and CNV.4B.Altogether,this study confirmed the genetic effect of SCVs on agronomy and drought tolerance,and identification of these SCVs will facilitate genetic improvement of wheat through marker-assisted selection.
基金Fund for Scientific and Technological Research of Argentina(FONCyT PICT 2018 number 03521).
文摘Ceratitis capitata(Wiedemann)is a cosmopolitan pest of economic importance.It is controlled by using the Sterile Insect Technique(SIT),which involves rearing and release of sterile males destined to mate with wild females,causing generation-to-generation suppression.Medflies are colonized by microorganisms,primarily the Enterobacteriaceae,with the genera Klebsiella and Enterobacter being the most common.Such microbiota contributes to host fitness.During the SIT,diet with antibiotics and irradiation for sterility of adults alter microbiota.We aimed to determine the role of Medfly microbiota on resistance to abiotic stress conditions,evaluating its function under:(i)starvation,(ii)elevated temperatures,and(iii)dry environments.These conditions simulate challenges Medfly may encounter after release,which differ from controlled rearing environments.We compared adult survival between symbiotic and aposymbiotic individuals,under starvation,two thermal regimes(25 and 30℃)or two humidity regimes(20%-25%and 80%-90%R.H.).Aposymbiotic individuals were obtained after providing them with water containing a mixture of antibiotics and methylparaben.Treatment with antimicrobials effectively reduced the gut microbiota.While starvation had no significant effect on survival,a higher proportion of aposymbiotic individuals died earlier at 30℃ and under dry humidity,with the effect being more pronounced after 48 h.Our results suggest that microbiota plays a role in adaptation of Medfly under environmental stress.We report for the presence of a culturable yeast in the digestive tract of C.capitata,Zygosaccharomyces rouxii.Providing a probiotic adult diet with bacteria and Z.rouxii prior to release could improve SIT outcomes under adverse conditions.
基金Supported by the National Key Research and Development Program'Modernization Research of Traditional Chinese Medicine':Cardiovascular Event Chain(Metabolic Syndrome,Atherosclerosis,Myocardial Infarction,Arrhythmia,Heart Failure)(No.2017YFC700500)the Key R&D Program of Hebei:Traditional Chinese Medicine Innovation Project:Clinical Research on the Treatment of Diabetes Foot with Collateral Drugs and the Mechanism of Its Influence on Collateral Vessel Reconstruction(No.223777155D)+1 种基金the Scientific Research Project of Hebei Provincial Administration of Traditional Chinese Medicine:Clinical Study on Jinlida Granules in Treating Intestinal Dysfunction of diabetes and Its Effect on Short Chain Fatty Acids(No.2023179)the Scientific Research Project of Hebei Provincial Administration of Traditional Chinese Medicine:Clinical Study on Tongluo Therapy for Diabetes Foot and Its Influence on Microcirculation(No.2018200)。
文摘OBJECTIVE:To investigate the effects of Jinlida granules(津力达颗粒,JLD)on body weight,glucose tolerance,intestinal inflammation and barrier function in high-fat diet(HFD)-induced obese rats and explore the regulation of the gut microbiota as a potential treatment mechanism.METHODS:Sprague-Dawley rats were divided into control,HFD,low-dose JLD(L-JLD),high-dose JLD(HJLD),and sitagliptin groups.The rats,with the exception of those in the control group,were fed a HFD to establish an obesity model while simultaneously receiving 0.5%carboxymethyl cellulose,L-JLD,H-JLD or sitagliptin for 25 weeks.We assessed body weight,conducted oral glucose tolerance tests,and analysed faecal samples using metagenomic sequencing.Haematoxylin-eosin(HE),Masson and immunohistochemical(IHC)staining were employed to evaluate histological changes in the colon tissue.Immunofluorescence(IF)staining was used to measure the expression levels of Zonula occludens-1(ZO-1)and Claudin-1 in colon tissue.The colon tissue was also subjected to transcriptomic evaluation.RESULTS:JLD treatment significantly reduced body weight and enhanced glucose tolerance in obese rats.It alleviated colonic tissue damage,decreased collagen deposition,inhibited macrophage infiltration,and increased the expression of the tight junction proteins ZO-1 and Claudin-1.Metagenomic analysis revealed JLDinduced shifts in the gut microbiota composition(increasing the abundance of Turicibacter,Faecalibaculum,Coriobacteriaceae and Lactobacillus reuteri),enriching beneficial bacteria and metabolic pathways(increasing the biosynthesis of various secondary metabolites,ascorbate and aldarate metabolism,oxidative phosphorylation,C5-branched dibasic acid metabolism and beta-alanine metabolism).Transcriptomic analysis revealed downregulation of inflammatory and immune pathways(inhibition of the tumour necrosis factor signalling pathway,advanced glycation end products-receptor for advanced glycation end products signalling pathway,toll-like receptor signalling pathway,and interleukin-17 signalling pathway),suggesting a comprehensive modulatory effect of JLD on intestinal health and metabolic function.CONCLUSIONS:JLD granules effectively improve glucose tolerance and ameliorate obesity-related intestinal dysfunctions in HFD-induced obese rats.These benefits are likely mediated through the modulation of the gut microbiota,the suppression of intestinal inflammation,the enhancement of barrier function,and the attenuation of proinflammatory pathways.Our findings offer novel insights into the therapeutic potential of JLD,emphasizing its role in integrating gut microbiota management into the treatment of metabolic disorders.
文摘Wild edible plants have evolved in response to persistent and often severe environmental pressures,including salinity,drought,extreme temperatures,high light intensity and nutrient-poor soils.Despite the considerable physiological flexibility and adaptive capacity exhibited by these species,they remain underrepresented in contemporary plant stress research,which has traditionally focused on a limited number of model species and major crops.The present review proposes a conceptual framework that positions wild edible plants as physiological and ecological reference systems for studying naturally evolved plant stress tolerance,rather than as alternative genetic model species.The synthesis of current knowledge on the ecological contexts that shape their stress adaptation is conducted,and the major abiotic stressors influencing wild edible plants across diverse environments are examined.This study focuses on the physiological mechanisms involved in water regulation,osmotic adjustment,photosynthetic performance,and antioxidant defence.The role of metabolic plasticity and stress-induced production of secondary metabolites is also discussed,highlighting how chronic or moderate environmental stress may,under specific conditions,enhance nutritional and functional attributes without necessarily compromising metabolic stability.Furthermore,the potential of wild edible plants as reservoirs of stress-resilient traits relevant to sustainable agriculture,crop diversification,and functional food systems in marginal environments is evaluated.The identification of key research gaps is the final stage of the research process.These gaps include the limited application of omics-based approaches,the lack of standardised experimental methodologies,and the scarcity of direct comparative studies between wild edible and domesticated plant species.The present review underscores the potential benefits and current constraints associated with the utilisation of wild edible plants in promoting plant stress biology and informing climate-resilient agricultural strategies.
基金the project“Comprehensive scientific study of mechanisms of resistance of crop plants to biotic,abiotic,and anthropogenic stress,use of genetic diversity,and creation of stress-resistant cultivars and hybrids”,funded by the Ministry of Education and Science of Ukraine(registration number 0125U003530)supported by the Ministry of Agriculture of the Czech Republic,Grant number QL26010208.
文摘Low temperature is a major abiotic stress factor inducing the accumulation of dehydrins in plants.Dehydrins are hydrophilic,heat-stable proteins implicated in plant stress responses;however,their synthesis under cold conditions during the early stages of wheat development has not been sufficiently studied.This study investigated the relationship between cold-induced dehydrin accumulation in etiolated seedlings and frost tolerance in wheat cultivars differing in their level of frost tolerance.Three-day-old seedlings of high frost-tolerant(high-FT)cultivars(Antonivka,Doskonala,and Nordika)and low frost-tolerant(low-FT)cultivars(Tobak,Tonnage,and Altigo)of Triticum aestivum L.were hardened at+3℃ for six days.Dehydrin accumulation was analyzed by electrophoretic separation,while frost tolerance was assessed based on seedling survival following freezing at−4,−9,and−12℃.Cold-induced oxidative damage was evaluated by determining malondialdehyde(MDA)content in seedling shoots after freezing at−4℃.In control seedlings,dehydrins were barely detectable in all cultivars.Cold hardening at+3℃ induced pronounced accumulation of dehydrins with molecular masses of approximately 46,49.6,and 68 kDa in both high-FT and low-FT cultivars.In contrast,low-molecular-weight dehydrins(14–16 kDa)were detected predominantly in high-FT cultivars.Seedling survival after freezing at−12℃ showed a strong positive correlation with total dehydrin content(r=0.82).Even stronger correlations were observed between the content of low-molecular-weight dehydrins(14–16 kDa)and seedling survival after freezing at−9 and−12℃(r=0.84 and 0.94,respectively).An inverse correlation was found between 14–16 kDa dehydrin content and MDA accumulation following freezing at−4℃(r=−0.87).These results indicate that low-molecular-weight dehydrins play an important role in protecting etiolated wheat seedlings from cold-induced oxidative stress and may serve as reliable biochemical markers of frost tolerance.
基金supported by the National Natural Science Foundation of China(32160442 and 32560458)。
文摘HVA22 is a gene induced by abscisic acid(ABA)and abiotic stress.Previous transcriptome data of salt-tolerant Tritipyrum“Y1805”revealed that HVA22 was significantly upregulated under salt stress.Gene TtHVA22 was successfully amplified from“Y1805”,with an open reading frame of 468 bp and encoding a protein of 156 amino acids.Gene TtHVA22 was transformed into bread wheat“1718”via coleoptile method.The relative expression level of TtHVA22 in roots was remarkably higher than in stems and leaves under salt stress.During the seedling stage,the TtHVA22 overexpression(OE)line exhibited less leaf wilting under salt stress than wild-type(WT)plants.Under salt stress and recovery conditions,TtHVA22 OE significantly increased root length,plant height,fresh weight,and dry weight compared to WT plants.Additionally,the levels of ABA,soluble sugars,soluble proteins,proline,pyruvate,and photosynthetic pigments and peroxidase activity were significantly higher in the OE lines than in the WT plants;however,their malondialdehyde content and relative conductivity were opposite.Two years of field data demonstrated that stem diameter and grain yield per plant were significantly greater in the OE lines than the WT plants.Therefore,wheat salt tolerance was improved in the TtHVA22 OE lines by osmotic regulation,antioxidation,and chlorophyll stabilization.
基金supported by the Ningxia Hui Autonomous Region Key R&D Program,China(2023BCF01003)the National Natural Science Foundation of China(32472711 and 32060672)the Agricultural Breeding Project of Ningxia Hui Autonomous Region,China(NXNYYZ202101)。
文摘Cold stress represents a critical constraint on crop productivity,particularly in temperate climates.Despite the established role of abscisic acid(ABA)in cold stress responses,the precise mechanisms through which transcription factors mediate ABAdependent cold tolerance remain elusive.Here,we identify VaMYB4a,a MYB transcription factor from Vitis amurensis Rupr.(Amur grape),as a key regulator of cold tolerance.It integrates ABA signaling with the CBF(C-repeat binding factors)-COR(cold-regulated)pathway to orchestrate cold stress adaptation.Through a combination of overexpression and CRISPR/Cas9-mediated knockout lines in Arabidopsis thaliana,grape callus,and Vitis vinifera L.seedlings,we demonstrate that VaMYB4a enhances freezing tolerance by promoting osmotic regulation,reactive oxygen species(ROS)scavenging,and stomatal closure.VaMYB4a functions as a homo-dimer,with its C-terminal domain being essential for transcriptional activation.Mechanistically,VaMYB4a directly upregulates CBF and COR genes while fine-tuning ABA signaling components such as ABI1 and ABF4.Notably,ABA exhibits a dual role:enhancing VaMYB4a-mediated freezing tolerance under short-term stress but attenuating its effects during prolonged cold exposure,revealing an intricate regulatory crosstalk between cold and hormonal pathways.Our work not only advances the molecular understanding of cold adaptation but also provides a promising genetic target for developing stress-resilient grape varieties to mitigate the impacts of climate change.
基金supported by the National Key Research and Development Program of China(2023YFF1002200 and 2022YFD1900704-7)the Natural Science Foundation of Jiangsu Province,China(BK20250114)+3 种基金the National Natural Science Foundation of China(32072064)the Major Program of State Key Laboratory of Soil and Sustainable Agriculture(SKLSSA2503)the Science and Technology Demonstration Project of Shandong Province(2024SFGC0402)the Youth Innovation Promotion Association of the Chinese Academy of Sciences(2022314).
文摘The large and complex genome of bread wheat,characterized by hexaploidy and a high proportion of repetitive elements(Figure 1),has long been recognized as a barrier for gene discovery.Along with recent advancements in the acquisition of genomic information of bread wheat(Xiao et al.,2022),however,increasing evidence suggests that these genomic features offer great potential for both generating and conserving specific genic resources,in particular those pertaining to abiotic stress tolerance.
基金supported by the Zhejiang Provincial Natural Science Outstanding Youth Fund Continuation Project,China(Grant No.LRG25C130002)the Innovation Program of the Chinese Academy of Agricultural Sciences(Grant No.CAAS-CSCB-202402)+3 种基金the Zhejiang Provincial Natural Science Foundation,China(Grant No.LD24C130001)the Biological Breeding-National Science and Technology Major Projects of China(Grant No.2023ZD04066)the Central Public-Interest Scientific Institution Basal Research Fund,China(Grant No.Y2025YC96)the Agricultural Science and Technology Innovation Program,China(Grant No.CAAS-ASTIP-2021-CNRRI).
文摘Prohibitin(PHB)plays critical roles in plant growth and development.In this study,we utilized CRISPR/Cas9 gene-editing technology to generate homozygous OsPHB2 knockout transgenic plants,designated cr-osphb2.The cr-osphb2 line exhibited wider leaves,dwarfism,and shorter panicles.Subcellular localization results indicated that OsPHB2 localizes to mitochondria.Under salt stress conditions,cr-osphb2 exhibited enhanced tolerance.Haplotype(Hap)analysis identified three major Haps(Hap1,Hap2,and Hap3)of OsPHB2,among which Hap2 was associated with a greater number of effective panicles and higher yield,indicating its potential value for breeding applications.Collectively,our findings demonstrate that OsPHB2 plays an important role in regulating growth,development,and salt stress responses in rice.
文摘As one of the main chronic diseases in modern society,coronary heart disease,as a major disease that affects people’s lives and health,has the characteristics of hidden onset and sudden onset.Coronary heart disease has relatively clear risk factors.Among them,blood lipid levels and blood sugar levels,as two main risk factors,play an important role in promoting the onset of coronary heart disease.The two complement each other in a vicious cycle,synergize and promote each other,promote the process of coronary atherosclerosis,thereby causing coronary heart disease.Multiple components in blood lipids and poor management of long-term blood sugar levels play a major role in specific clinical problems.This article reviews the different components of blood lipids and the effects of hyperglycemia on coronary heart disease,and initially expounds the mechanism by which blood lipids and blood sugar levels synergize each other to aggravate the risk of coronary heart disease,and combines them with relevant clinical issues,in order to help clinicians guide the prevention of coronary heart disease in terms of blood lipids and blood sugar levels.
基金the National Key Research and Development Program of China(2020YFA0907600)National Natural Science Foundation of China(31100869)+1 种基金Central Public-interest Scientific Institutions Basal Research Fund for Zhang Zhiguo(Y2025YY06)the Fundamental Research Funds for Central Nonprofit Scientific Institutions for Lu Tiegang,and Cui Xuean.
文摘Source-sink coordination serves as the foundation for improving crop yield.Current research primarily focuses on individual factors,such as increasing the source or expanding the sink,which often leads to disrupted source-sink balance,causing trade-offs among photosynthesis,yield,and stress response.To address these limitations,we present an integrated synthetic biological framework that synergistically enhances photosynthetic efficiency(source capacity),sink optimization,and abiotic stress tolerance.We developed an editing-overexpression coupling(EOC)vector system enabling simultaneous overexpression of four photosynthesis-enhancing genes(Cyt c6,PsbA,FBPase,OsMGT3),knockout of three yield-limiting genes(GS3,Gn1a,OsAAP5),and self-excision of selection markers,gene-editing modules,and fragment deletion cassettes.Field evaluations of CFMP-gga transgenic lines revealed significant physiological improvements,including 13%–17%increase in photosynthetic rates,improved chlorophyll fluorescence parameters,and increased stomatal conductance.These enhancements translated into remarkable agronomic gains,including 18.7%–22.3%higher grain yield,23.1%–26.1%increased biomass,and improved panicle architecture(increased grain size and grain number per panicle).The engineered lines maintained superior thermotolerance(under 42°C stress)and alkali tolerance(at pH 10)compared to wild-type controls.This study provides a strategy for enhancing crop yield by demonstrating that coordinated multi-gene regulation of source-sink dynamics,coupled with stress resilience engineering,achieves concurrent improvements.
基金supported by the National Natural Science Foundation of China(32171945,32301760)the Program for Innovative Research Team(in Science and Technology)in University of Henan Province,China(22IRTSTHN023)+2 种基金the Scientific and Technological Research Project of Henan Province,China(242102111116)the National Science Foundation for Postdoctoral Scientists of China(2023M731003)the Postdoctoral Research Subsidize Fund of Henan Province,China(HN2022139)。
文摘Global warming impacts plant growth and development,which in turn threatens food security.Plants can clearly respond to warm-temperature(such as by thermomorphogenesis)and high-temperature stresses.At the molecular level,many small molecules play crucial roles in balancing growth and defense,and stable high yields can be achieved by fine-tuning the responses to external stimuli.Therefore,it is essential to understand the molecular mechanisms underlying plant growth in response to heat stress and how plants can adjust their biological processes to survive heat stress conditions.In this review,we summarize the heat-responsive genetic networks in plants and crop plants based on recent studies.We focus on how plants sense the elevated temperatures and initiate the cellular and metabolic responses that allow them to adapt to the adverse growing conditions.We also describe the trade-off between plant growth and responses to heat stress.Specifically,we address the regulatory network of plant responses to heat stress,which will facilitate the discovery of novel thermotolerance genes and provide new opportunities for agricultural applications.
基金supported by Science and Technology Innovation Program of Hunan province(2024NK1010,2023NK1010,2023ZJ1080)the National Natural Science Foundation of China(U21A20208).
文摘The chalcone isomerase gene OsCHI,one of the key genes in the flavonoid biosynthesis pathway,plays an important role in rice(Oryza sativa)resistance to abiotic stresses.This study reveals how the chalcone isomerase gene family member OsCHI3 participates in rice responses to drought stress through the regulation of flavonoid biosynthesis.Overexpression of OsCHI3 increased the tolerance of rice to drought stress.In contrast,CRISPR/Cas9-mediated deletion of OsCHI3 reduced the drought tolerance of rice,an effect that is reversed by exogenous ABA treatment.Transcriptomic and physiological biochemical analyses indicated that flavonoids regulated by OsCHI3 not only scavenge reactive oxygen species(ROS)but also increase drought tolerance in rice by stimulating ABA biosynthesis through the regulation of OsNCED1 and OsABA8ox3 expression.These findings demonstrate that OsCHI3 increases drought stress tolerance in rice by activating the antioxidant defense system and the ABA metabolic pathway,providing new clues for drought-resistant rice breeding research.
基金supported by the National Natural Science Foundation of China(Grant Nos.32072048 and U2004204)National Key Research and Development Program of China(Grant No.2023YFF1001200)+2 种基金China Rice Research Institute Basal Research Fund(Grant No.CPSIBRF-CNRRI-202404)Academician Workstation of National Nanfan Research Institute(Sanya),Chinese Agricultural Academic Science(CAAS),(Grant Nos.YBXM2422 and YBXM2423)Agricultural Science and Technology Innovation Program of CAAS,China.
文摘The leucine-rich repeat(LRR)protein family is involved in a variety of fundamental metabolic and signaling processes in plants,including growth and defense responses.LRR proteins can be divided into two categories:those containing LRR domains along with other structural elements,which are further subdivided into five groups,LRR receptor-like kinases,LRR receptor-like proteins,nucleotide-binding site LRR proteins,LRR-extensin proteins,and polygalacturonase-inhibiting proteins,and those containing only LRR domains.Functionally,various LRR proteins are primarily involved in plant development and responses to environmental stress.Notably,the LRR protein family plays a central role in signal transduction pathways related to stress adaptation.In this review,we classify and analyze the functions of LRR proteins in plants.While extensive research has been conducted on the roles of LRR proteins in disease resistance signaling,these proteins also play important roles in abiotic stress responses.This review highlights recent advances in understanding how LRR proteins mediate responses to biotic and abiotic stresses.Building upon these insights,further exploration of the roles of LRR proteins in abiotic stress resistance may aid efforts to develop rice varieties with enhanced stress and disease tolerance.
基金supported by the National Natural Science Foundation of China(Grant Nos.U2002204 and 32272725)the China National Key Research and Development Program(Grant No.2022YFF1002500)+2 种基金the China Postdoctoral Science Foundation(Grant No.2024M753583)the Guangdong Major Project of Basic and Applied Basic Research(Grant No.2021B0301030004)Natural Science Foundation of Henan(Grant No.222300420109)。
文摘Potato(Solanum tuberosum)is a globally important staple crop.However,cultivated potato varieties are highly sensitive to low temperatures.The molecular mechanisms underlying freezing resistance in potatoes remain poorly understood.Through comparative metabolome and transcriptome analyses of freezing-tolerant(CM,Solanum commersonii)and freezing-sensitive(DM,DM1-3516R44)varieties,we identified a coldinduced UDP-glycosyltransferase gene,ScUGT73B4,which is associated with the accumulation of glycosylated flavonoids in wild CM varieties.Overexpression of ScUGT73B4 led to increased accumulation of glycosylated flavonoids and enhanced antioxidant capacity,resulting in improved freezing tolerance in potato plantlets.These findings reveal a UDP-glycosyltransferase in the flavonoid pathway and offer a potential valuable genetic resource for breeding potatoes with improved freezing tolerance.
基金support from the National Key R&D Program of China(2022YFF1001601)the National Science Fund for Distinguished Young Scholars(32325037)+2 种基金the National Natural Science Foundation of China(32201718 and 32401756)the Postdoctoral Innovation Talents Support Program(BX20240420)the China Postdoctoral Science Foundation(2024T171011 and 2023M743817).
文摘Salt stress significantly inhibits crop growth and development,and mitigating this can enhance salt tolerance in various crops.Previous studies have shown that regulating saccharide biosynthesis is a key aspect of plant salt tolerance;however,the underlying molecular mechanisms remain largely unexplored.In this study,we demonstrate that overexpression of a salt-inducible galactinol synthase gene,ZmGolS1,alleviates salt-induced growth inhibition,likely by promoting raffinose synthesis.Additionally,we show that natural variation in ZmGolS1 transcript levels contributes to the diversity of raffinose content and salt tolerance in maize.We further reveal that ZmRR18,a type-B response regulator transcription factor,binds to the AATC element in the promoter of ZmGolS1,with this binding increases the transcript levels of ZmGolS1 under salt conditions.Moreover,a single nucleotide polymorphism(termed SNP-302T)within the ZmGolS1 promoter significantly reduces its binding affinity for ZmRR18,resulting in decreased ZmGolS1 expression and diminished raffinose content,ultimately leading to a salt-hypersensitive phenotype.Collectively,our findings reveal the molecular mechanisms by which the ZmRR18-ZmGolS1 module enhances raffinose biosynthesis,thereby promoting maize growth under salt conditions.This research provides important insights into salt tolerance mechanisms associated with saccharide biosynthesis and identifies valuable genetic loci for breeding salt-tolerant maize varieties.
基金supported by the projects of the National Key Research and Development Program of China(2023YFD2300202)the Natural Science Foundation of Jiangsu Province,China(BK20241543)+5 种基金the National Natural Science Foundation of China(32272213,32030076,U1803235,and 32021004)the Fundamental Research Funds for the Central Universities,China(XUEKEN2023013)the Jiangsu Innovation Support Program for International Science and Technology Cooperation Project,China(BZ2023049)the Jiangsu Agriculture Science and Technology Innovation Fund,China(CX(22)1006)the China Agriculture Research System(CARS-03)the Jiangsu Collaborative Innovation Center for Modern Crop Production,China(JCIC-MCP)。
文摘Frequent drought events severely restrict global crop productivity,especially those occurring in the reproductive stages.Moderate drought priming during the earlier growth stages is a promising strategy for allowing plants to resist recurrent severe drought stress.However,the underlying mechanisms remain unclear.Here,we subjected wheat plants to drought priming during the vegetative growth stage and to severe drought stress at 10 days after anthesis.We then collected leaf samples at the ends of the drought priming and recovery periods,and at the end of drought stress for transcriptome sequencing in combination with phenotypic and physiological analyses.The drought-primed wheat plants maintained a lower plant temperature,with higher stomatal openness and photosynthesis,thereby resulting in much lower 1,000-grain weight and grain yield losses under the later drought stress than the non-primed plants.Interestingly,416 genes,including 27 transcription factors(e.g.,MYB,NAC,HSF),seemed to be closely related to the improved drought tolerance as indicated by the dynamic transcriptome analysis.Moreover,the candidate genes showed six temporal expression patterns and were significantly enriched in several stress response related pathways,such as plant hormone signal transduction,starch and sucrose metabolism,arginine and proline metabolism,inositol phosphate metabolism,and wax synthesis.These findings provide new insights into the physiological and molecular mechanisms of the long-term effects of early drought priming that can effectively improve drought tolerance in wheat,and may provide potential approaches for addressing the challenges of increasing abiotic stresses and securing food safety under global warming scenarios.
