Tea plant(Camellia sinensis(L.)O.Kuntze)is a cold-sensitive leaf-harvesting crop whose growth,yield,and processed tea quality are all inhibited by low temperatures.Therefore,identifying the regulatory genes involved i...Tea plant(Camellia sinensis(L.)O.Kuntze)is a cold-sensitive leaf-harvesting crop whose growth,yield,and processed tea quality are all inhibited by low temperatures.Therefore,identifying the regulatory genes involved in tea plant growth and freezing tolerance is crucial for genetic improvement.WRKY transcription factors regulate various plant processes,including growth and development,stress responses,and metabolite biosynthesis.However,the molecular network through which WRKY coordinates these pathways in tea plants remains unclear.In this study,we revealed that CsWRKY57L,a cold-inducible WRKY IIc subfamily member,positively regulated freezing tolerance by directly promoting flavonoid accumulation in tea plants.Transient suppression of CsWRKY57L weakened the freezing tolerance of tea plants by reducing flavonoid content and suppressing the C-repeat-binding factor(CBF)-cold-responsive(COR)gene pathway.In contrast,heterologous overexpression of CsWRKY57L in Arabidopsis had the opposite effect.Additionally,overexpression of CsWRKY57L inhibited reproductive development and accelerated senescence in Arabidopsis.Interaction analysis revealed that CsWRKY57L directly binds to the promoters of CsSWEET1a,CsSWEET15,and AtSWEET15,which encode sugar transporters essential for plant reproductive development,and inhibits their transcription.Overall,the study revealed a dual role of CsWRKY57L in promoting freezing tolerance via flavonoid biosynthesis and inhibiting reproductive development by regulating SWEETs expression.This study uncovers a novel mechanism whereby CsWRKY57L coordinately regulates both stress responses and growth in tea plants,providing a molecular basis for breeding low-temperature-tolerant varieties with restricted reproductive development.展开更多
Ammonium toxicity in plants remains poorly understood despite extensive research.While nitrate is known to benefit plant growth,the synergistic effects of nitrate in mitigating ammonium toxicity,even at low concentrat...Ammonium toxicity in plants remains poorly understood despite extensive research.While nitrate is known to benefit plant growth,the synergistic effects of nitrate in mitigating ammonium toxicity,even at low concentrations,are not fully elucidated.This review delves into the physiological and molecular nature of this phenomenon.To date,nitrate-dependent alleviation of ammonium toxicity is the result of cumulative consequences of the role of nitrate as a nutrient and signal in plant performance.The ability to counteract the ammonium-induced acidification through nitrate uptake and metabolism,the enhancement of potassium uptake as an essential nitrate counterion,and the nitratedependent signaling of key factors involved in ammonium assimilation,ROS scavenging,and growth hormone biosynthesis,are the most relevant hallmarks.In addition,evidence suggests that the availability of nitrate and ammonium has driven ecological selection in plants,determining current N preferences,and may have led to the selection of nitrate-dependent and ammonium-sensitive domesticated crops and the inefficient use of N fertilizers in agriculture.As ammonium toxicity limits N fertilization options and reduces agricultural yields,when it could be a more sustainable and cheaper alternative to nitrate,this review provides a better understanding of how plants use nitrate to counteract the problematic aspects of ammonium nutrition.展开更多
Soil compaction often imposes stress on root development and plant survival.However,root anatomical responses that enable persistent root growth and functioning under soil compaction remain unclear.We grew 10 herbaceo...Soil compaction often imposes stress on root development and plant survival.However,root anatomical responses that enable persistent root growth and functioning under soil compaction remain unclear.We grew 10 herbaceous species differing substantially in lateral root diameter,in soils with low(1.0 g cm^(-3))and high(1.4 g cm^(-3))bulk density,and assessed root traits including root biomass,anatomical structures,and respiration rates.Greater root thickening upon soil compaction was found in species with thicker first-order lateral roots,mainly due to larger cortical cell size.Both xylem vessel diameter and wall thickness increased more in compacted soils in these species.Despite these anatomical shifts,root respiration rate responded little to soil compaction across most species,likely due to the opposite investment in cortical cells and xylem vessels.Notably,root biomass,independent of root respiration rate and anatomical structures,determined whole-plant growth under soil compaction.Our study reveals two independent strategies of root response to soil compaction:anatomical remodeling for mechanical and metabolic maintenance,and root biomass investment for resource acquisition.These findings offer new insights for breeding and selecting species tolerant to soil compaction and highlight multidimensional strategies of plant adaptation to physical stress.展开更多
The Qinghai-Tibet Plateau(QTP)is the highest and one of the most extensive plateaus in the world.Investigating naturalized non-native plant species composition,phylogenetic relationships among naturalized plant specie...The Qinghai-Tibet Plateau(QTP)is the highest and one of the most extensive plateaus in the world.Investigating naturalized non-native plant species composition,phylogenetic relationships among naturalized plant species,and phylogenetic relationships between native and naturalized plant species on the plateau is of great importance.Here,we analyze a comprehensive dataset including all species of native and naturalized vascular plants known to occur in the core part of the QTP.We use net relatedness index(NRI)and nearest taxon index(NTI),which reflect deep and shallow evolutionary histories,respectively,to quantify phylogenetic relatedness among angiosperm species.The QTP included in this study(1,448,815 km^(2))has 9086 and 314 species of native and naturalized non-native vascular plants,respectively.We find that the naturalized angiosperm species are phylogenetically clustered with respect to the species pool including all native and naturalized angiosperm species on the QTP included in this study,regardless of whether NRI or NTI is used.For the eight regions within the QTP included in this study,NRI and NTI of naturalized angiosperms are positive in seven regions with respect to their respective regional species pools,reflecting phylogenetic clustering.Thus,naturalized angiosperm species are a phylogenetically clustered subset of all angiosperm species on the QTP,regardless of whether the studied plateau as a whole or its constituent regions are considered.展开更多
Cold stress widely impairs the quality and yield of tea plants. The miR164 family and its target NAC transcription factor have been identified as crucial regulators in response to cold stress. However, the role of miR...Cold stress widely impairs the quality and yield of tea plants. The miR164 family and its target NAC transcription factor have been identified as crucial regulators in response to cold stress. However, the role of miR164 and CsNAC in cold tolerance in tea plants was little understood. In our study, the expression level of CsMIR164a was significantly reduced under cold stress and significantly and negatively correlated with that of CsNAC1.5' RACE and GUS histochemical assays showed that CsNAC1 was cleaved by CsMIR164a. The CsMIR164a-silenced tea leaves promoted the expression levels of CsNAC1 and CsCBFs and exhibited greater cold tolerance. Also, the overexpression of CsNAC1 enhanced cold tolerance in transgenic Arabidopsis plants by promoting the expression levels of AtCBFs. In contrast, the heterologous overexpression of CsMIR164a in Arabidopsis decreased the expression level of AtNACs and AtCBFs and thus impaired cold tolerance. Additionally, silencing of CsNAC1 impaired the expression levels of CsCBFs, resulting in greater cold sensitivity in tea leaves. Our present study demonstrated that the miR164a-CsNAC1 module may play a negative role in the cold tolerance of tea plants via the CsCBF-dependent pathway.展开更多
Conventional agrochemical plant biostimulants have been used to increase crop yield and stress resistance,andthis strategy continues to be integral to today's farming.While effective,the large-scale implantations ...Conventional agrochemical plant biostimulants have been used to increase crop yield and stress resistance,andthis strategy continues to be integral to today's farming.While effective,the large-scale implantations of theseproducts are not without environmental,ecological,and cost concerns and the associated climate-change challenges.To alleviate this long-standing pressure on agriculture,designing and developing more biocompatible andsustainable plant stimulants are among the primary focuses of agricultural management.Over the recent decades,the field has witnessed significant progress in emerging naturally derived or nature-inspired nano-biostimulantswith large-active-surface areas,including bio-compounds,biopolymers,and nanocarbons.However,the extraction/preparation of these products may apply additional costs or require specific equipment.More recently,thefield's attention has shifted to the sustainable application of chemical-additive-free biostimulants towards practicalapplications in nano-agriculture.Herein,we rationally designed and reported the first evidence and elucidationon biostimulant impacts of plant-self-derived nano-extracts from donor Arabidopsis thaliana as a model forinducing mirror biostimulant activities in conspecific host seeds,seedlings,and plants.Moreover,we assessed theeffect of donor plants'age on short,mid-,and long-term biocompatibility,growth,and development/maturationof the recipient plants for up to around 30 days.As a proof-of-concept,we found these autologous bio-extractscould effectively promote seed sprouting,seedling germination,and the development of soil-drenched plantsof the same types.Our transmission-electron microscopy characterization of root/shoot pieces shows the presenceof multiple phyto-compounds,including microtubules/actin filaments,cell vacuoles,Golgi stacks/endoplasmicreticulum,cell wall polysaccharide-based cellulose fibers,and organic amorphous nanoparticles and clusters ofcarbon quantum dots in the structure of these extracts.This personalized plant stimulation may induce furthergrowth/defense-related mechanisms,setting new paradigms toward reducing the agrochemical inputs.展开更多
Anthropogenic disturbances are causing significant impacts on plant distribution worldwide,and many of these effects are driven by changes in the recruitment patterns of plant species.Global warming and land-use chang...Anthropogenic disturbances are causing significant impacts on plant distribution worldwide,and many of these effects are driven by changes in the recruitment patterns of plant species.Global warming and land-use change are two major disturbances leading to changes in germination strategies by changing both soil temperature regimes and light quality reaching the seeds due to soil disturbance.Investigating the range,overlap,and redundancy of niche germination of co-occurring plant species allows us to understand whether endemic species are threatened either by native non-endemic or by alien species,especially in an ecosystem of restricted distribution such as the campo rupestre.Employing a systematic review,this study aimed to evaluate the effect of temperature increase and seed burial on the germination of endemic and non-endemic species in the campo rupestre in Brazil.We performed a metaanalysis using increased temperature and darkness as proxies for the impact of disturbance on germination patterns.In this context,we hypothesized that:increased temperature and darkness negatively influence the germination of native species and positively influence the germination of alien species in the campo rupestre.Specifically,we expect the negative effect to be more pronounced in endemic species than in native non-endemic species.Moreover,we intend to describe the role of seed size in the germination of native and alien species from campo rupestre in the context of increased temperature and darkness.Our analysis showed that increased temperature influenced the germination of alien species by ca.55%,while it did not influence the germination of endemic or native non-endemic species.Furthermore,the germination of alien species under higher temperatures was promoted by increasing seed size.Darkness negatively influenced seed germination of native species,independent of their distribution.Moreover,under darkness conditions,the germination of endemic seeds decreased with seed size.Through their direct effects on germination strategies,we conclude that warming temperatures and land-use change can lead to a long-term displacement of endemic species by native non-endemic and alien species in campo rupestre,thus compromising ecosystem services and conservation of these fragile physiognomies in the near future.展开更多
Myeloblastosis(MYB)transcription factors,particularly those in the R2R3 MYB subclass,are pivotal in plant growth,development,and environmental stress responses.As one of the largest transcription factor families in pl...Myeloblastosis(MYB)transcription factors,particularly those in the R2R3 MYB subclass,are pivotal in plant growth,development,and environmental stress responses.As one of the largest transcription factor families in plants,the MYB family significantly regulates plant secondary metabolism,including the biosynthetic pathways for phenylpropanoids,which are crucial for stress resistance.This review presents a comprehensive overview of MYB transcription factor classification and their regulatory mechanisms in plant metabolism and stress responses.We discuss the roles of MYB transcription factors in biotic stress resistance,such as defense against pathogens and pests,and in abiotic stress tolerance,including responses to drought and salinity.Special attention is given to the interactions of R2R3 MYB with other transcription factors and co-repressors,focusing on how these synergistic or antagonistic relationships modulate physiological processes.The multifunctional role of R2R3 MYBs in stress responses positions them as promising targets for enhancing crop resilience through genetic breeding.Furthermore,this review highlights potential applications of MYB transcription factors in developing stress-resistant crops and their utility in plant resistant breeding programs.展开更多
Heat stress causes overgrowth,leaf dryness and fruit malformation,which negatively impacts cucumber quality and yield.Yet,in spite of the devastating consequences of this abiotic stress,few genes for heat tolerance in...Heat stress causes overgrowth,leaf dryness and fruit malformation,which negatively impacts cucumber quality and yield.Yet,in spite of the devastating consequences of this abiotic stress,few genes for heat tolerance in cucumber have been identified.Here,the heat injury indices of 88 cucumber accessions representing diverse ecotypes were collected in two open-field environments,with naturally occurring high temperatures over two years.Seventeen of the 88 accessions were identified as highly heat-tolerant.Using a genome-wide association study,five loci(gHII3.1,gHII3.2,gHII3.3,gHII4.1 and gHII6.1)on three chromosomes associated with heat tolerance were detected.Pairwise linkage disequilibrium correlation,sequence polymorphisms,and qRT-PCR analyses at these loci,identified five candidate genes predicted to be casual for heat stress response in cucumber.CsaV3_3G04883,CsaV3_4G029050 and CsaV3_6G005370 each had nonsynonymous SNPs,and were significantly up-regulated by heat stress in the heat-tolerant genotypes.CsaV3_3G031890 was also induced by heat stress,but in the heatsensitive genotypes,and sequence polymorphism was only found in the promoter region.Identifying these candidate genes lays a foundation for understanding cucumber thermotolerance mechanisms.Our study is one of the few to examine heat stress in adult cucumber plants and it therefore fills a critical gap in knowledge.It is also an important first-step towards accelerating the breeding of robust heat-tolerant varieties.展开更多
The global rise in animal protein consumption has significantly amplified the demand for fodder.A comprehensive understanding of the diversity and characteristics of existing fodder resources is essential for balanced...The global rise in animal protein consumption has significantly amplified the demand for fodder.A comprehensive understanding of the diversity and characteristics of existing fodder resources is essential for balanced nutritional fodder production.This study investigates the diversity and composition of fodder plants and identifies key species for cattle in Zhaotong City,Yunnan,China,while documenting indigenous knowledge on their usage and selection criteria.Ethnobotanical surveys were conducted in 19 villages across seven townships with 140 informants.Data were collected through semi-structured interviews,free listing,and participatory observation,and analyzed using Relative Frequency Citation.A total of 125 taxa(including 106 wild and 19 cultivated)were reported.The most cited family is Poaceae(27 taxa,21.43%),followed by Asteraceae(17 taxa,13.49%),Fabaceae(14 taxa,11.11%),Polygonaceae(9 taxa,7.14%)and Lamiaceae(4 taxa,3.17%).The whole plant(66.04%)and herbaceous plants(84.80%)were the most used parts and life forms.The most cited species were Zea mays,Brassica rapa,Solanum tuberosum,Eragrostis nigra,and Artemisia dubia.Usage of diverse fodder resources reflects local wisdom in managing resource availability and achieving balanced nutrition while coping with environmental and climatic risks.Preferences for certain taxonomic groups are due to their quality as premier fodder resources.To promote integrated crop-livestock farming,we suggest further research into highly preferred fodder species,focusing on nutritional assessment,digestibility,meat quality impacts,and potential as antibiotic alternatives.Establishing germplasm and gene banks for fodder resources is also recommended.展开更多
The members of the fourth subgroup of R2R3-MYB(Sg4 members)are well-known inhibitors of phenylpropanoid and lignin synthesis pathways.The C2 domain is closely related to the transcriptional inhibitory activity of Sg4 ...The members of the fourth subgroup of R2R3-MYB(Sg4 members)are well-known inhibitors of phenylpropanoid and lignin synthesis pathways.The C2 domain is closely related to the transcriptional inhibitory activity of Sg4 members.Phosphorylation modification enhances the transcriptional inhibitory activity of Sg4 members.Here,we identified a phosphorylation site on the C2 domain of Cs MYB4a from tea plants(Camellia sinensis).A mitogen-activated protein kinase(MAPK),named Cs MPK3-2,phosphorylated this site on the C2 domain of Cs MYB4a.Further experiments revealed that phosphorylation of Cs MYB4a weakened its ability to inhibit the gene expression of PAL,C4H,and 4CL in the phenylpropanoid pathway and activated the expression of transcription factor YABBY5,maintaining the adaxial-abaxial polarity of the leaf.Knocking out Nt YAB5 in Cs MYB4a transgenic tobacco partially repaired the leaf wrinkling phenotype caused by Cs MYB4a.The C1 domain exhibited an activation function when the C2 domain of Cs MYB4a was phosphorylated by Cs MPK3-2,causing this reversal phenomenon.These results enrich our understanding of the regulatory diversity of Sg4 members.展开更多
Canonical small RNAs in plants,including micro RNAs and small interfering RNAs,are key triggers of RNA interference and regulate nearly every major biological process in plants.To establish systemic silencing,small RN...Canonical small RNAs in plants,including micro RNAs and small interfering RNAs,are key triggers of RNA interference and regulate nearly every major biological process in plants.To establish systemic silencing,small RNAs undergo both short-distance intracellular trafficking or intercellular communication and longdistance transport from one organ to another,even across parasites or pathogens.This enables the delivery of effector molecules throughout the plant,promoting the spread of gene silencing.Biologically,the spatiotemporal regulation of small RNAs results in gradient distributions within cells or along the direction of organogenesis.Furthermore,the spreading capacity of small RNAs,generated in somatic or nurse cells,can guide target gene silencing in germlines in plants.In this review,we summarize recent advances in understanding the regulation and functional roles of local trafficking and long-distance transport of plant small RNAs in developmental polarity,the maintenance of cell identity,and with a particular focus,the mechanisms of small RNA movement and delivery between companion cells and gametes in plants.Additionally,we discuss the methods and challenges of monitoring small RNA transport in vivo through live imaging,as well as the potential applications of small RNA transport and delivery in the development of RNA-based pesticides.展开更多
The production of crops is badly affected by climate change globally.Mitigation of adverse effects of climate change is in need of time through different management practices such as developing tolerant genetic resour...The production of crops is badly affected by climate change globally.Mitigation of adverse effects of climate change is in need of time through different management practices such as developing tolerant genetic resources,hormonal applications to boost defense systems,nanoparticles,and balanced fertilization.The nano-hormonal syn-ergy had the potential to mitigate the adverse effects of climate change by modulation of morpho-physiological and biochemical activities.Plant growth,yield,and quality can be enhanced with the supplementation of nano-hormonal interactions.Therefore,the current study explores the synergy between nanoparticles and phytohormonal use.The nanoparticles,even in low concentrations,had an excellent capability to improve the endogenous hormones contributing to the regulation of plant responses under stress conditions.Nano-hormonal interaction improved the plant tolerance against climate change by activation of signaling molecules and the plant defense system.Nano-hormonal contact triggers several enzymic and non-enzymatic activities that can scavenge toxic substances generated within the plants.The reduction in electrolyte leakage,malondialdehyde(MDA),and hydrogen peroxide(H_(2)O_(2))was due to the supplementation of nano-hormonal exchange.The optimum production of reactive oxygen species(ROS)is necessary for normal plant growth and various developmental processes.However,the overproduction of ROS can be eliminated with nano-hormonal synergy.However,inappropriate applications can cause phytotoxicity such as germination inhibition,root malformation,and chlorosis.The optimum doses can vary depending on the kind of crop and stress conditions.The nano-hormonal interface is beneficial for crop growth,yield,and quality.Moreover,these are also effective in repairing plants damaged from adverse climatic conditions.Hence,these are effective for sustainable agriculture production.展开更多
Medicinal and dietary plants provide numerous nutritional and functional compounds and also have various potential health benefits to humanity.The specific and efficient techniques for accurate identification of nutri...Medicinal and dietary plants provide numerous nutritional and functional compounds and also have various potential health benefits to humanity.The specific and efficient techniques for accurate identification of nutritional compounds and functional metabolites is crucial for the development of functional foods from medicinal and dietary plants.Nuclear magnetic resonance(NMR)and mass spectrometry(MS)are indispensable and essential technologies that provide an unsurpassed wealth of untargeted identification,quantitative and qualitative analysis,and structural information in the study of food and plant products.In the past decade,the rapid development of modern analytical technology has led to the emergence of new approaches and strategies for natural products discovery.Especially the application of novel NMRand MS-based identification and dereplication strategies aided by artificial intelligence and machine learning algorithms have brought about a significant shift in the natural products discovery process.These developments and changes in the natural products filed have given us insights into how to accurately target and mining nutritional,functional,and bioactive compounds.Thus,we have summarized recent research on novel NMR and MS based strategies and methods focusing on functional compounds,accurate identification and efficient discovery mainly in medicinal and dietary plants.This review could provide a comprehensive perspective for a better understanding of novel strategies and methods based on NMR and MS technologies,which could provide valuable insights and ideas for functional compounds mining.展开更多
The ability of plants to tolerate cold is a complex process.When temperatures drop or freeze,plant tissues can develop ice,which dehydrates the cells.However,plants can protect themselves by preventing ice formation.T...The ability of plants to tolerate cold is a complex process.When temperatures drop or freeze,plant tissues can develop ice,which dehydrates the cells.However,plants can protect themselves by preventing ice formation.This intricate response to cold stress is regulated by hormones,photoperiod,light,and various factors,in addition to genetic influences.In autumn,plants undergo morphological,physiological,biochemical,and molecular changes to prepare for the low temperatures of winter.Understanding cellular stress responses is crucial for genetic manipulation aimed at enhancing cold resistance.Early autumn frosts or late spring chills can cause significant damage to plants,making it essential to adapt in autumn to survive winter conditions.While the general process of acclimatization is similar across many plant species,variations exist depending on the specific type of plant and regional conditions.Different plant organs exhibit varying degrees of damage from cold stress,and by applying agricultural principles,potential damage can be largely controlled.Timely reinforcement and stress prevention can minimize cold-related damage.Research has shown that in temperate climates,low temperatures restrict plant growth and yield.However,the intricate structural systems involved remain poorly understood.Over the past decade,studies have focused on the molecular mechanisms that enable plants to adapt to and resist cold stress.The gene signaling system is believed to play a crucial role in cold adaptation,and researchers have prioritized this area in their investigations.This study critically examines plant responses to cold stress through physiological adaptations,including calcium signaling dynamics,membrane lipid modifications,and adjustments in antioxidant systems.These mechanisms activate downstream gene expression and molecular functions,leading to key resistance strategies.Additionally,we explore the regulatory roles of endogenous phytohormones and secondary metabolites in cold stress responses.This review aims to enhance our foundational understanding of the mechanisms behind plant cold adaptation.展开更多
Heavy metal(HM)accumulation in soil poses a major hazard to both ecological health and plant growth progressions.Cadmium(Cd),lead(Pb),copper(Cu),chromium(Cr),arsenic(As),zinc(Zn),and nickel(Ni)are examples of HMs that...Heavy metal(HM)accumulation in soil poses a major hazard to both ecological health and plant growth progressions.Cadmium(Cd),lead(Pb),copper(Cu),chromium(Cr),arsenic(As),zinc(Zn),and nickel(Ni)are examples of HMs that negatively impact the growth and development of plants,resulting in lower agricultural output and food safety concerns.Biochar(BC),a substance rich in carbon that is formed by pyrolyzing natural biomass,has demonstrated remarkable promise in reducing HM stress in polluted soils.Research has shown that BC effectively lowers plant uptake of metals,and enhances soil qualities,and encourages microbial activity.Besides,BC improves the fertility of soil,retention of water,and nutrient absorption,while it interacts with soil microbes to help mitigate the negative effects.However,a number of variables affect how effective BC is as a soil supplement,including the kind of BC used,the soil’s characteristics,and the metal’s qualities.This review delves into the mechanisms of BC’s interactions with HMs,its potential to mitigate stress caused by different metals,and the factors that influence its efficiency.Furthermore,it draws attention to the drawbacks and difficulties associated with using BC in heavy-metal-contaminated soils,offering suggestions for future studies focused on maximizing its utilization for long-term soil rehabilitation and sustainable agriculture.展开更多
Melatonin is a multifunctional molecule found in all organisms that has been shown to play a crucial role in plant growth, development, and stress response. Plant melatonin is typically synthesized in organelles terme...Melatonin is a multifunctional molecule found in all organisms that has been shown to play a crucial role in plant growth, development, and stress response. Plant melatonin is typically synthesized in organelles termed chloroplasts, and the mechanisms of its synthesis and metabolic pathways have been extensively studied. Melatonin serves a significant regulatory function in plant growth and development, influencing the morphological and physiological characteristics of plants by modulating biological processes. While studies on plant melatonin receptors are in their early stages compared to studies in animal receptors, the binding mechanism with melatonin is now recognized as the key initiating step that triggers a series of downstream protective effects. This suggests that melatonin in plants may exert its effects through two main modes of target binding. The CAND2/PMTR1 protein binds to melatonin with a high degree of affinity. This binding activates downstream heterotrimeric G proteins, which trigger rapid intracellular signaling cascades. These cascades include activating the MAPK pathway and modulating ion channel activity. This action swiftly regulates stomatal closure in response to physiological processes such as drought stress. Additionally, melatonin has been demonstrated to regulate the plant stress response through two main mechanisms. First, it directly inhibits the accumulation of reactive oxygen species. Second, it indirectly influences the stress response pathways. This paper examines plant melatonin from three perspectives: the synthesis pathways of melatonin, its effects on plant growth, and its applications in plants under stress. Finally, the prospects for melatonin study and its applications in plants are discussed.展开更多
Global warming is making plants more susceptible to heat stress.Hence,adjustments to crop production systems are required for global food security.Heat stress(HS)poses a threat to the quality of ecosystems and global ...Global warming is making plants more susceptible to heat stress.Hence,adjustments to crop production systems are required for global food security.Heat stress(HS)poses a threat to the quality of ecosystems and global food security due to its adverse effects on plant development.The degree to which HS affects physiological disruptions,physical harm,and biochemical changes at various growth stages directly correlates with its effects on physiological functions,plant growth,and crop production.One promising approach is soil modification using biochar,which enhances soil health and promotes the development of microbial communities,ultimately improving plant heat tolerance.Biochar enhances soil structure,improves moisture retention,and increases nutrient availability in hot weather,thereby promoting plant growth and enhancing crop yields.Additionally,biochar,with its porous structure and ability to provide a liming effect,increases the diversity and activity of soil microbes,thereby fostering advantageous symbiotic relationships.These microbial communities support nutrient cycling,root growth,and general soil health,strengthening biochar’s position as a long-term solution for climate-resilient farming.Earlier research concentrated on the connection between biochar and heat stress or microbial populations;however,this review uniquely combines all three elements,providing a fresh viewpoint on their interrelated functions in enhancing plant adaptability.Furthermore,this study demonstrates the potential of biochar as a sustainable component for improving soil and supporting crops that adapt to heat stress.It examines the processes underlying these interactions and provides recommendations for future research strategies.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.32072630,32372774,and U22A20499)the earmarked fund for CARS(Grant No.CARS-19-01A).
文摘Tea plant(Camellia sinensis(L.)O.Kuntze)is a cold-sensitive leaf-harvesting crop whose growth,yield,and processed tea quality are all inhibited by low temperatures.Therefore,identifying the regulatory genes involved in tea plant growth and freezing tolerance is crucial for genetic improvement.WRKY transcription factors regulate various plant processes,including growth and development,stress responses,and metabolite biosynthesis.However,the molecular network through which WRKY coordinates these pathways in tea plants remains unclear.In this study,we revealed that CsWRKY57L,a cold-inducible WRKY IIc subfamily member,positively regulated freezing tolerance by directly promoting flavonoid accumulation in tea plants.Transient suppression of CsWRKY57L weakened the freezing tolerance of tea plants by reducing flavonoid content and suppressing the C-repeat-binding factor(CBF)-cold-responsive(COR)gene pathway.In contrast,heterologous overexpression of CsWRKY57L in Arabidopsis had the opposite effect.Additionally,overexpression of CsWRKY57L inhibited reproductive development and accelerated senescence in Arabidopsis.Interaction analysis revealed that CsWRKY57L directly binds to the promoters of CsSWEET1a,CsSWEET15,and AtSWEET15,which encode sugar transporters essential for plant reproductive development,and inhibits their transcription.Overall,the study revealed a dual role of CsWRKY57L in promoting freezing tolerance via flavonoid biosynthesis and inhibiting reproductive development by regulating SWEETs expression.This study uncovers a novel mechanism whereby CsWRKY57L coordinately regulates both stress responses and growth in tea plants,providing a molecular basis for breeding low-temperature-tolerant varieties with restricted reproductive development.
基金funding from Deutsche Forschungsgemeinschaft (DFG)supported by an MCIN Ry C Programme MCIN/ AEI/10.13039/501100011033+2 种基金by the ‘European Union Next Generation EU/PRTR’ under grant no. RYC2021-032345-Isupported by the AEI (grant no. PID2019-107463RJ-I00/ AEI/10.13039/501100011033)the Regional Research and Development Programme of the Government of Navarre (call 2019, project Nitro Healthy, PC068)
文摘Ammonium toxicity in plants remains poorly understood despite extensive research.While nitrate is known to benefit plant growth,the synergistic effects of nitrate in mitigating ammonium toxicity,even at low concentrations,are not fully elucidated.This review delves into the physiological and molecular nature of this phenomenon.To date,nitrate-dependent alleviation of ammonium toxicity is the result of cumulative consequences of the role of nitrate as a nutrient and signal in plant performance.The ability to counteract the ammonium-induced acidification through nitrate uptake and metabolism,the enhancement of potassium uptake as an essential nitrate counterion,and the nitratedependent signaling of key factors involved in ammonium assimilation,ROS scavenging,and growth hormone biosynthesis,are the most relevant hallmarks.In addition,evidence suggests that the availability of nitrate and ammonium has driven ecological selection in plants,determining current N preferences,and may have led to the selection of nitrate-dependent and ammonium-sensitive domesticated crops and the inefficient use of N fertilizers in agriculture.As ammonium toxicity limits N fertilization options and reduces agricultural yields,when it could be a more sustainable and cheaper alternative to nitrate,this review provides a better understanding of how plants use nitrate to counteract the problematic aspects of ammonium nutrition.
基金funded by the National Natural Science Foundation of China(32471824,32171746,31870522,42477227,and 32560282)the leading talents of basic research in Henan Province(24XM0375)+6 种基金Excellent Youth Creative Research Group Project in Henan Province(252300421002)Foreign Scientists Studio in Henan Province(GZS2025011)MOHRSS National Foreign Expert Individual Projectsand(110000264820258001)Natural Science Foundation of Henan(242300420604)supported by the Guangdong Provincial Key Laboratory of Soil and Groundwater Pollution Control(2023B1212060002)the High-level University Special Fund(G03050K001)the China Postdoctoral Science Foundation(No.2021M690922).
文摘Soil compaction often imposes stress on root development and plant survival.However,root anatomical responses that enable persistent root growth and functioning under soil compaction remain unclear.We grew 10 herbaceous species differing substantially in lateral root diameter,in soils with low(1.0 g cm^(-3))and high(1.4 g cm^(-3))bulk density,and assessed root traits including root biomass,anatomical structures,and respiration rates.Greater root thickening upon soil compaction was found in species with thicker first-order lateral roots,mainly due to larger cortical cell size.Both xylem vessel diameter and wall thickness increased more in compacted soils in these species.Despite these anatomical shifts,root respiration rate responded little to soil compaction across most species,likely due to the opposite investment in cortical cells and xylem vessels.Notably,root biomass,independent of root respiration rate and anatomical structures,determined whole-plant growth under soil compaction.Our study reveals two independent strategies of root response to soil compaction:anatomical remodeling for mechanical and metabolic maintenance,and root biomass investment for resource acquisition.These findings offer new insights for breeding and selecting species tolerant to soil compaction and highlight multidimensional strategies of plant adaptation to physical stress.
基金supported by grants from the Second Tibetan Plateau Scientific Expedition and Research(STEP)program(2019QZKK0502)the Strategic Priority Research Program of Chinese Academy of Sciences(XDA20050203)+4 种基金the National Natural Science Foundation of China-Yunnan joint fund to support key projects(U1802232)the Major Program for Basic Research Project of Yunnan Province(202101BC070002)the Yunnan Young&Elite Talents Project(YNWR-QNBJ-2019-033)the Ten Thousand Talents Program of Yunnan Province(202005AB160005)the Chinese Academy of Sciences“Light of West China”Program.
文摘The Qinghai-Tibet Plateau(QTP)is the highest and one of the most extensive plateaus in the world.Investigating naturalized non-native plant species composition,phylogenetic relationships among naturalized plant species,and phylogenetic relationships between native and naturalized plant species on the plateau is of great importance.Here,we analyze a comprehensive dataset including all species of native and naturalized vascular plants known to occur in the core part of the QTP.We use net relatedness index(NRI)and nearest taxon index(NTI),which reflect deep and shallow evolutionary histories,respectively,to quantify phylogenetic relatedness among angiosperm species.The QTP included in this study(1,448,815 km^(2))has 9086 and 314 species of native and naturalized non-native vascular plants,respectively.We find that the naturalized angiosperm species are phylogenetically clustered with respect to the species pool including all native and naturalized angiosperm species on the QTP included in this study,regardless of whether NRI or NTI is used.For the eight regions within the QTP included in this study,NRI and NTI of naturalized angiosperms are positive in seven regions with respect to their respective regional species pools,reflecting phylogenetic clustering.Thus,naturalized angiosperm species are a phylogenetically clustered subset of all angiosperm species on the QTP,regardless of whether the studied plateau as a whole or its constituent regions are considered.
基金supported by the Anhui University Collaborative Innovation Project, China (GXXT-2020080)the Scientific Research Project of Anhui Provincial Colleges and Universities, China (2023AH040136)。
文摘Cold stress widely impairs the quality and yield of tea plants. The miR164 family and its target NAC transcription factor have been identified as crucial regulators in response to cold stress. However, the role of miR164 and CsNAC in cold tolerance in tea plants was little understood. In our study, the expression level of CsMIR164a was significantly reduced under cold stress and significantly and negatively correlated with that of CsNAC1.5' RACE and GUS histochemical assays showed that CsNAC1 was cleaved by CsMIR164a. The CsMIR164a-silenced tea leaves promoted the expression levels of CsNAC1 and CsCBFs and exhibited greater cold tolerance. Also, the overexpression of CsNAC1 enhanced cold tolerance in transgenic Arabidopsis plants by promoting the expression levels of AtCBFs. In contrast, the heterologous overexpression of CsMIR164a in Arabidopsis decreased the expression level of AtNACs and AtCBFs and thus impaired cold tolerance. Additionally, silencing of CsNAC1 impaired the expression levels of CsCBFs, resulting in greater cold sensitivity in tea leaves. Our present study demonstrated that the miR164a-CsNAC1 module may play a negative role in the cold tolerance of tea plants via the CsCBF-dependent pathway.
基金Deutsche Forschungsgemeinschaft(DFG,German Research Foundation)grant number 525793193Prof.Stefan Eimer and Ms.Marion Basoglu at Goethe University for their assistance in TEM characterization+1 种基金Mr.Holger Schranz for his help in plant cultivation and maintenanceProf.Bruno M.Moerschbacher from the Institute of Plant Biology and Biotechnology at the Münster University。
文摘Conventional agrochemical plant biostimulants have been used to increase crop yield and stress resistance,andthis strategy continues to be integral to today's farming.While effective,the large-scale implantations of theseproducts are not without environmental,ecological,and cost concerns and the associated climate-change challenges.To alleviate this long-standing pressure on agriculture,designing and developing more biocompatible andsustainable plant stimulants are among the primary focuses of agricultural management.Over the recent decades,the field has witnessed significant progress in emerging naturally derived or nature-inspired nano-biostimulantswith large-active-surface areas,including bio-compounds,biopolymers,and nanocarbons.However,the extraction/preparation of these products may apply additional costs or require specific equipment.More recently,thefield's attention has shifted to the sustainable application of chemical-additive-free biostimulants towards practicalapplications in nano-agriculture.Herein,we rationally designed and reported the first evidence and elucidationon biostimulant impacts of plant-self-derived nano-extracts from donor Arabidopsis thaliana as a model forinducing mirror biostimulant activities in conspecific host seeds,seedlings,and plants.Moreover,we assessed theeffect of donor plants'age on short,mid-,and long-term biocompatibility,growth,and development/maturationof the recipient plants for up to around 30 days.As a proof-of-concept,we found these autologous bio-extractscould effectively promote seed sprouting,seedling germination,and the development of soil-drenched plantsof the same types.Our transmission-electron microscopy characterization of root/shoot pieces shows the presenceof multiple phyto-compounds,including microtubules/actin filaments,cell vacuoles,Golgi stacks/endoplasmicreticulum,cell wall polysaccharide-based cellulose fibers,and organic amorphous nanoparticles and clusters ofcarbon quantum dots in the structure of these extracts.This personalized plant stimulation may induce furthergrowth/defense-related mechanisms,setting new paradigms toward reducing the agrochemical inputs.
基金financial support from CNPq/Peld CRSC,Fapemig,CAPES,Anglo American,and Vale.
文摘Anthropogenic disturbances are causing significant impacts on plant distribution worldwide,and many of these effects are driven by changes in the recruitment patterns of plant species.Global warming and land-use change are two major disturbances leading to changes in germination strategies by changing both soil temperature regimes and light quality reaching the seeds due to soil disturbance.Investigating the range,overlap,and redundancy of niche germination of co-occurring plant species allows us to understand whether endemic species are threatened either by native non-endemic or by alien species,especially in an ecosystem of restricted distribution such as the campo rupestre.Employing a systematic review,this study aimed to evaluate the effect of temperature increase and seed burial on the germination of endemic and non-endemic species in the campo rupestre in Brazil.We performed a metaanalysis using increased temperature and darkness as proxies for the impact of disturbance on germination patterns.In this context,we hypothesized that:increased temperature and darkness negatively influence the germination of native species and positively influence the germination of alien species in the campo rupestre.Specifically,we expect the negative effect to be more pronounced in endemic species than in native non-endemic species.Moreover,we intend to describe the role of seed size in the germination of native and alien species from campo rupestre in the context of increased temperature and darkness.Our analysis showed that increased temperature influenced the germination of alien species by ca.55%,while it did not influence the germination of endemic or native non-endemic species.Furthermore,the germination of alien species under higher temperatures was promoted by increasing seed size.Darkness negatively influenced seed germination of native species,independent of their distribution.Moreover,under darkness conditions,the germination of endemic seeds decreased with seed size.Through their direct effects on germination strategies,we conclude that warming temperatures and land-use change can lead to a long-term displacement of endemic species by native non-endemic and alien species in campo rupestre,thus compromising ecosystem services and conservation of these fragile physiognomies in the near future.
基金supported by the Faculty Startup Fund from Jining Medical University,the Shandong Provincial Natural Science Foundation,China(Grant No.ZR2023QC309)the National Natural Science Foundation of China(Grant No.32102236)。
文摘Myeloblastosis(MYB)transcription factors,particularly those in the R2R3 MYB subclass,are pivotal in plant growth,development,and environmental stress responses.As one of the largest transcription factor families in plants,the MYB family significantly regulates plant secondary metabolism,including the biosynthetic pathways for phenylpropanoids,which are crucial for stress resistance.This review presents a comprehensive overview of MYB transcription factor classification and their regulatory mechanisms in plant metabolism and stress responses.We discuss the roles of MYB transcription factors in biotic stress resistance,such as defense against pathogens and pests,and in abiotic stress tolerance,including responses to drought and salinity.Special attention is given to the interactions of R2R3 MYB with other transcription factors and co-repressors,focusing on how these synergistic or antagonistic relationships modulate physiological processes.The multifunctional role of R2R3 MYBs in stress responses positions them as promising targets for enhancing crop resilience through genetic breeding.Furthermore,this review highlights potential applications of MYB transcription factors in developing stress-resistant crops and their utility in plant resistant breeding programs.
基金supported by Beijing Joint Research Program for Germplasm Innovation and New Variety Breeding(Grant No.G20220628003-03)Chongqing Municipal People's Government and Chinese Academy of Agricultural Sciences strategic cooperation project,Key-Area Research and Development Program of Guangdong Province(Grant No.2020B020220001)+3 种基金the Earmarked Fund for Modern Agro-industry Technology Research System(Grant No.CARS-23)Science and Technology Innovation Program of the Chinese Academy of Agricultural Science(Grant No.CAAS-ASTIP-IVFCAAS)Central public-interest Scientific Institution Basal Research Fund(Grant No.Y2017PT52)the Key Laboratory of Biology and Genetic Improvement of Horticultural Crops,Ministry of Agriculture,P.R.China。
文摘Heat stress causes overgrowth,leaf dryness and fruit malformation,which negatively impacts cucumber quality and yield.Yet,in spite of the devastating consequences of this abiotic stress,few genes for heat tolerance in cucumber have been identified.Here,the heat injury indices of 88 cucumber accessions representing diverse ecotypes were collected in two open-field environments,with naturally occurring high temperatures over two years.Seventeen of the 88 accessions were identified as highly heat-tolerant.Using a genome-wide association study,five loci(gHII3.1,gHII3.2,gHII3.3,gHII4.1 and gHII6.1)on three chromosomes associated with heat tolerance were detected.Pairwise linkage disequilibrium correlation,sequence polymorphisms,and qRT-PCR analyses at these loci,identified five candidate genes predicted to be casual for heat stress response in cucumber.CsaV3_3G04883,CsaV3_4G029050 and CsaV3_6G005370 each had nonsynonymous SNPs,and were significantly up-regulated by heat stress in the heat-tolerant genotypes.CsaV3_3G031890 was also induced by heat stress,but in the heatsensitive genotypes,and sequence polymorphism was only found in the promoter region.Identifying these candidate genes lays a foundation for understanding cucumber thermotolerance mechanisms.Our study is one of the few to examine heat stress in adult cucumber plants and it therefore fills a critical gap in knowledge.It is also an important first-step towards accelerating the breeding of robust heat-tolerant varieties.
基金supported by the Strategic Priority Research Program of Chinese Academy of Sciences(Grant No.XDA26050301-02)。
文摘The global rise in animal protein consumption has significantly amplified the demand for fodder.A comprehensive understanding of the diversity and characteristics of existing fodder resources is essential for balanced nutritional fodder production.This study investigates the diversity and composition of fodder plants and identifies key species for cattle in Zhaotong City,Yunnan,China,while documenting indigenous knowledge on their usage and selection criteria.Ethnobotanical surveys were conducted in 19 villages across seven townships with 140 informants.Data were collected through semi-structured interviews,free listing,and participatory observation,and analyzed using Relative Frequency Citation.A total of 125 taxa(including 106 wild and 19 cultivated)were reported.The most cited family is Poaceae(27 taxa,21.43%),followed by Asteraceae(17 taxa,13.49%),Fabaceae(14 taxa,11.11%),Polygonaceae(9 taxa,7.14%)and Lamiaceae(4 taxa,3.17%).The whole plant(66.04%)and herbaceous plants(84.80%)were the most used parts and life forms.The most cited species were Zea mays,Brassica rapa,Solanum tuberosum,Eragrostis nigra,and Artemisia dubia.Usage of diverse fodder resources reflects local wisdom in managing resource availability and achieving balanced nutrition while coping with environmental and climatic risks.Preferences for certain taxonomic groups are due to their quality as premier fodder resources.To promote integrated crop-livestock farming,we suggest further research into highly preferred fodder species,focusing on nutritional assessment,digestibility,meat quality impacts,and potential as antibiotic alternatives.Establishing germplasm and gene banks for fodder resources is also recommended.
基金supported by the joint funds of National Natural Science Foundation of China(Grant Nos.U21A20232,32372756,32072621)。
文摘The members of the fourth subgroup of R2R3-MYB(Sg4 members)are well-known inhibitors of phenylpropanoid and lignin synthesis pathways.The C2 domain is closely related to the transcriptional inhibitory activity of Sg4 members.Phosphorylation modification enhances the transcriptional inhibitory activity of Sg4 members.Here,we identified a phosphorylation site on the C2 domain of Cs MYB4a from tea plants(Camellia sinensis).A mitogen-activated protein kinase(MAPK),named Cs MPK3-2,phosphorylated this site on the C2 domain of Cs MYB4a.Further experiments revealed that phosphorylation of Cs MYB4a weakened its ability to inhibit the gene expression of PAL,C4H,and 4CL in the phenylpropanoid pathway and activated the expression of transcription factor YABBY5,maintaining the adaxial-abaxial polarity of the leaf.Knocking out Nt YAB5 in Cs MYB4a transgenic tobacco partially repaired the leaf wrinkling phenotype caused by Cs MYB4a.The C1 domain exhibited an activation function when the C2 domain of Cs MYB4a was phosphorylated by Cs MPK3-2,causing this reversal phenomenon.These results enrich our understanding of the regulatory diversity of Sg4 members.
基金supported by the National Key Research and Development Program of China(2024YFF100303)the National Natural Science Foundation of China(32025005)。
文摘Canonical small RNAs in plants,including micro RNAs and small interfering RNAs,are key triggers of RNA interference and regulate nearly every major biological process in plants.To establish systemic silencing,small RNAs undergo both short-distance intracellular trafficking or intercellular communication and longdistance transport from one organ to another,even across parasites or pathogens.This enables the delivery of effector molecules throughout the plant,promoting the spread of gene silencing.Biologically,the spatiotemporal regulation of small RNAs results in gradient distributions within cells or along the direction of organogenesis.Furthermore,the spreading capacity of small RNAs,generated in somatic or nurse cells,can guide target gene silencing in germlines in plants.In this review,we summarize recent advances in understanding the regulation and functional roles of local trafficking and long-distance transport of plant small RNAs in developmental polarity,the maintenance of cell identity,and with a particular focus,the mechanisms of small RNA movement and delivery between companion cells and gametes in plants.Additionally,we discuss the methods and challenges of monitoring small RNA transport in vivo through live imaging,as well as the potential applications of small RNA transport and delivery in the development of RNA-based pesticides.
文摘The production of crops is badly affected by climate change globally.Mitigation of adverse effects of climate change is in need of time through different management practices such as developing tolerant genetic resources,hormonal applications to boost defense systems,nanoparticles,and balanced fertilization.The nano-hormonal syn-ergy had the potential to mitigate the adverse effects of climate change by modulation of morpho-physiological and biochemical activities.Plant growth,yield,and quality can be enhanced with the supplementation of nano-hormonal interactions.Therefore,the current study explores the synergy between nanoparticles and phytohormonal use.The nanoparticles,even in low concentrations,had an excellent capability to improve the endogenous hormones contributing to the regulation of plant responses under stress conditions.Nano-hormonal interaction improved the plant tolerance against climate change by activation of signaling molecules and the plant defense system.Nano-hormonal contact triggers several enzymic and non-enzymatic activities that can scavenge toxic substances generated within the plants.The reduction in electrolyte leakage,malondialdehyde(MDA),and hydrogen peroxide(H_(2)O_(2))was due to the supplementation of nano-hormonal exchange.The optimum production of reactive oxygen species(ROS)is necessary for normal plant growth and various developmental processes.However,the overproduction of ROS can be eliminated with nano-hormonal synergy.However,inappropriate applications can cause phytotoxicity such as germination inhibition,root malformation,and chlorosis.The optimum doses can vary depending on the kind of crop and stress conditions.The nano-hormonal interface is beneficial for crop growth,yield,and quality.Moreover,these are also effective in repairing plants damaged from adverse climatic conditions.Hence,these are effective for sustainable agriculture production.
基金financially supported by the National Key R&D Program of China(2022YFF1100301)Major Science and Technology Project of Henan Province(231100310200)+1 种基金National Natural Science Foundation of China(32370426)Yunnan Province Science and Technology Department(202305AH340005),and Dr Plant。
文摘Medicinal and dietary plants provide numerous nutritional and functional compounds and also have various potential health benefits to humanity.The specific and efficient techniques for accurate identification of nutritional compounds and functional metabolites is crucial for the development of functional foods from medicinal and dietary plants.Nuclear magnetic resonance(NMR)and mass spectrometry(MS)are indispensable and essential technologies that provide an unsurpassed wealth of untargeted identification,quantitative and qualitative analysis,and structural information in the study of food and plant products.In the past decade,the rapid development of modern analytical technology has led to the emergence of new approaches and strategies for natural products discovery.Especially the application of novel NMRand MS-based identification and dereplication strategies aided by artificial intelligence and machine learning algorithms have brought about a significant shift in the natural products discovery process.These developments and changes in the natural products filed have given us insights into how to accurately target and mining nutritional,functional,and bioactive compounds.Thus,we have summarized recent research on novel NMR and MS based strategies and methods focusing on functional compounds,accurate identification and efficient discovery mainly in medicinal and dietary plants.This review could provide a comprehensive perspective for a better understanding of novel strategies and methods based on NMR and MS technologies,which could provide valuable insights and ideas for functional compounds mining.
文摘The ability of plants to tolerate cold is a complex process.When temperatures drop or freeze,plant tissues can develop ice,which dehydrates the cells.However,plants can protect themselves by preventing ice formation.This intricate response to cold stress is regulated by hormones,photoperiod,light,and various factors,in addition to genetic influences.In autumn,plants undergo morphological,physiological,biochemical,and molecular changes to prepare for the low temperatures of winter.Understanding cellular stress responses is crucial for genetic manipulation aimed at enhancing cold resistance.Early autumn frosts or late spring chills can cause significant damage to plants,making it essential to adapt in autumn to survive winter conditions.While the general process of acclimatization is similar across many plant species,variations exist depending on the specific type of plant and regional conditions.Different plant organs exhibit varying degrees of damage from cold stress,and by applying agricultural principles,potential damage can be largely controlled.Timely reinforcement and stress prevention can minimize cold-related damage.Research has shown that in temperate climates,low temperatures restrict plant growth and yield.However,the intricate structural systems involved remain poorly understood.Over the past decade,studies have focused on the molecular mechanisms that enable plants to adapt to and resist cold stress.The gene signaling system is believed to play a crucial role in cold adaptation,and researchers have prioritized this area in their investigations.This study critically examines plant responses to cold stress through physiological adaptations,including calcium signaling dynamics,membrane lipid modifications,and adjustments in antioxidant systems.These mechanisms activate downstream gene expression and molecular functions,leading to key resistance strategies.Additionally,we explore the regulatory roles of endogenous phytohormones and secondary metabolites in cold stress responses.This review aims to enhance our foundational understanding of the mechanisms behind plant cold adaptation.
文摘Heavy metal(HM)accumulation in soil poses a major hazard to both ecological health and plant growth progressions.Cadmium(Cd),lead(Pb),copper(Cu),chromium(Cr),arsenic(As),zinc(Zn),and nickel(Ni)are examples of HMs that negatively impact the growth and development of plants,resulting in lower agricultural output and food safety concerns.Biochar(BC),a substance rich in carbon that is formed by pyrolyzing natural biomass,has demonstrated remarkable promise in reducing HM stress in polluted soils.Research has shown that BC effectively lowers plant uptake of metals,and enhances soil qualities,and encourages microbial activity.Besides,BC improves the fertility of soil,retention of water,and nutrient absorption,while it interacts with soil microbes to help mitigate the negative effects.However,a number of variables affect how effective BC is as a soil supplement,including the kind of BC used,the soil’s characteristics,and the metal’s qualities.This review delves into the mechanisms of BC’s interactions with HMs,its potential to mitigate stress caused by different metals,and the factors that influence its efficiency.Furthermore,it draws attention to the drawbacks and difficulties associated with using BC in heavy-metal-contaminated soils,offering suggestions for future studies focused on maximizing its utilization for long-term soil rehabilitation and sustainable agriculture.
基金supported by National College Student Innovation and Entrepreneurship Train-ing Program(202410376009)Anhui Province College Student Innovation and Entrepreneurship Training Program(S202310376057,S202510376030)+2 种基金Quality Engineering Project of West Anhui University(wxxy2024011)Quality Engineering Project of Anhui Province(2024zybj032)Development of Big Data Integration and Analysis Platform for Traditional Chinese Medicine Genomics(0045025050).
文摘Melatonin is a multifunctional molecule found in all organisms that has been shown to play a crucial role in plant growth, development, and stress response. Plant melatonin is typically synthesized in organelles termed chloroplasts, and the mechanisms of its synthesis and metabolic pathways have been extensively studied. Melatonin serves a significant regulatory function in plant growth and development, influencing the morphological and physiological characteristics of plants by modulating biological processes. While studies on plant melatonin receptors are in their early stages compared to studies in animal receptors, the binding mechanism with melatonin is now recognized as the key initiating step that triggers a series of downstream protective effects. This suggests that melatonin in plants may exert its effects through two main modes of target binding. The CAND2/PMTR1 protein binds to melatonin with a high degree of affinity. This binding activates downstream heterotrimeric G proteins, which trigger rapid intracellular signaling cascades. These cascades include activating the MAPK pathway and modulating ion channel activity. This action swiftly regulates stomatal closure in response to physiological processes such as drought stress. Additionally, melatonin has been demonstrated to regulate the plant stress response through two main mechanisms. First, it directly inhibits the accumulation of reactive oxygen species. Second, it indirectly influences the stress response pathways. This paper examines plant melatonin from three perspectives: the synthesis pathways of melatonin, its effects on plant growth, and its applications in plants under stress. Finally, the prospects for melatonin study and its applications in plants are discussed.
文摘Global warming is making plants more susceptible to heat stress.Hence,adjustments to crop production systems are required for global food security.Heat stress(HS)poses a threat to the quality of ecosystems and global food security due to its adverse effects on plant development.The degree to which HS affects physiological disruptions,physical harm,and biochemical changes at various growth stages directly correlates with its effects on physiological functions,plant growth,and crop production.One promising approach is soil modification using biochar,which enhances soil health and promotes the development of microbial communities,ultimately improving plant heat tolerance.Biochar enhances soil structure,improves moisture retention,and increases nutrient availability in hot weather,thereby promoting plant growth and enhancing crop yields.Additionally,biochar,with its porous structure and ability to provide a liming effect,increases the diversity and activity of soil microbes,thereby fostering advantageous symbiotic relationships.These microbial communities support nutrient cycling,root growth,and general soil health,strengthening biochar’s position as a long-term solution for climate-resilient farming.Earlier research concentrated on the connection between biochar and heat stress or microbial populations;however,this review uniquely combines all three elements,providing a fresh viewpoint on their interrelated functions in enhancing plant adaptability.Furthermore,this study demonstrates the potential of biochar as a sustainable component for improving soil and supporting crops that adapt to heat stress.It examines the processes underlying these interactions and provides recommendations for future research strategies.
