With the enhancement of copper (Cu) stress, the germination percentage of wheat seeds decreased gradually. Pretreatment with sodium hydrosulfide (NariS), hydrogen sulfide (H2S) donor alleviated the inhibitory ef...With the enhancement of copper (Cu) stress, the germination percentage of wheat seeds decreased gradually. Pretreatment with sodium hydrosulfide (NariS), hydrogen sulfide (H2S) donor alleviated the inhibitory effect of Cu stress in a dose- dependent manner; whereas little visible symptom was observed in germinating seeds and radicle tips cultured in NariS solutions. It was verified that H2S or HS- rather than other sulfur-containing components derived from NariS attribute to the potential role in promoting seed germination against Cu stress. Further studies showed that NariS could promote amylase and esterase activities, reduce Cu-induced disturbance of plasma membrane integrity in the radicle tips, and sustain lower levels of malondialdehyde and H202 in germinating seeds. Furthermore, NariS pretreatment increased activities of superoxide dismutase and catalase and decreased that of lipoxygenase, but showed no significant effect on ascorbate peroxidase. Alternatively, NariS prevented uptake of Cu and promoted the accumulation of free amino acids in seeds exposed to Cu. In addition, a rapid accumulation of endogenous H2S in seeds was observed at the early stage of germination, and higher level of H2S in NaHS-pretreated seeds. These data indicated that H2S was involved in the mechanism of germinating seeds' responses to Cu stress.展开更多
Drought is a major environmental factor limiting wheat production worldwide,and developing drought-tolerant cultivars is a central challenge for wheat breeders globally.Therefore,it is important to identify genetic co...Drought is a major environmental factor limiting wheat production worldwide,and developing drought-tolerant cultivars is a central challenge for wheat breeders globally.Therefore,it is important to identify genetic components determining drought tolerance in wheat.In this study,we identified a wheat NAC gene(TaNAC071-A)that is tightly associated with drought tolerance by a genome-wide association study.Knockdown of TaNAC071-A in wheat attenuated plant drought tolerance,whereas its overexpression significantly enhanced drought tolerance through improved water-use efficiency and increased expression of stress-responsive genes.This heightened water-saving mechanism mitigated the yield loss caused by water deficit.Further candidate gene association analysis showed that a 108-bp insertion in the promoter of TaNAC071-A alters its expression level and contributes to variation in drought tolerance among wheat accessions.This insertion contains two MYB cis-regulatory elements(CREs)that can be directly bound by the MYB transcription activator,TaMYBL1,thereby leading to increased TaNAC071-A expression and plant drought tolerance.Importantly,introgression of this 108-bp insertion allele,TaNAC071-AIn-693,into drought-sensitive cultivars could improve their drought tolerance,demonstrating that it is a valuable genetic resource for wheat breeding.Taken together,our findings highlight a major breakthrough in determining the genetic basis underlying phenotypic variation in wheat drought tolerance and showcase the potential of exploiting CRE-containing indels for improving important agronomical traits.展开更多
The effects of osmotic stress on the ATPase activity, the contents of —SH group and conjugated polyamines in mitochondrial membrane from wheat seedling [Triticum aestivum L. cv. Yumai No.18(drought-tolerant) and cv. ...The effects of osmotic stress on the ATPase activity, the contents of —SH group and conjugated polyamines in mitochondrial membrane from wheat seedling [Triticum aestivum L. cv. Yumai No.18(drought-tolerant) and cv. Yumai No.9(drought-sensitive)] roots were investigated. The results showed that ATPase activity and —SH group content decreased with polyethylene glycol(PEG) 6000(-0.55 MPa) treatment for 7 d, in concert with the decrease of the ratio of noncovalently conjugated spermidine(NCC-Spd)/noncovalently conjugated putrescine(NCC-Put) and increase of the covalently conjugated putrescine(CC-Put). Osmotic stress injury to Yangmai No.9 seedlings was alleviated greatly with 1 mmol/L exogenous spermidine(Spd), in concert with marked increases of the ratio of NCC-Spd/NCC-Put, —SH group contents and ATPase activity in mitochondrial membrane. Under osmotic stress, the concomitant treatment of Yumai No.18 seedlings with methylglyoxyl bis(guanylhydrazone) (MGBG), an inhibitor of S-adenosyl methionine decarboxylase(SAMDC), and phenanthrolin (o-Phen), an inhibitor of transglutaminase(TGase), caused a significant decrease of the ratio of NCC-Spd / NCC-Put, CC-Put contents, respectively, in concert with the marked decreases of ATPase activity, —SH group content and its tolerance to osmotic stress. All the results above suggested that osmotic stress tolerance of wheat seedlings was associated with the ATPase activity, the contents of —SH group, NCC-Spd and CC-Put in mitochondrial membrane.展开更多
Soil management practices affect rhizosphere microorganisms and enzyme activities, which in turn influence soil ecosystem processes. The objective of this study was to explore the effects of different nitrogen applica...Soil management practices affect rhizosphere microorganisms and enzyme activities, which in turn influence soil ecosystem processes. The objective of this study was to explore the effects of different nitrogen application rates on wheat(Triticum aestivum L.) rhizosphere soil microorganisms and enzyme activities, and their temporal variations in relation to soil fertility under supplemental irrigation conditions in a fluvo-aquic region. For this, we established a split-plot experiment for two consecutive years(2014–2015 and 2015–2016) in the field with three levels of soil moisture: water deficit to no irrigation(W1), medium irrigation to(70±5)% of soil relative moisture after jointing stage(W2), and adequate irrigation to(80±5)% of soil relative moisture after jointing stage(W3);and three levels of nitrogen: 0 kg ha^–1(N1), 195 kg ha^–1(N2) and 270 kg ha^–1(N3). Results showed that irrigation and nitrogen application significantly increased rhizosphere microorganisms and enzyme activities. Soil microbiological properties showed different trends in response to N level;the highest values of bacteria, protease, catalase and phosphatase appeared in N2, while the highest levels of actinobacteria, fungi and urease were observed in N3. In addition, these items performed best under medium irrigation(W2) relative to W1 and W3;particularly the maximum microorganism(bacteria, actinobacteria and fungi) amounts appeared at W2, 5.37×10^7 and 6.35×10^7 CFUs g^–1 higher than those at W3 in 2014–2015 and 2015–2016, respectively;and these changes were similar in both growing seasons. Microbe-related parameters fluctuated over time but their seasonality did not hamper the irrigation and fertilization-induced effects. Further, the highest grain yields of 13 309.2 and 12 885.7 kg ha^–1 were both obtained at W2 N2 in 2014–2015 and 2015–2016, respectively. The selected properties, soil microorganisms and enzymes, were significantly correlated with wheat yield and proved to be valuable indicators of soil qualit展开更多
The quality or structure of a wheat population is significantly affected by the compositions of tillers. Little has been known about the physiological basis for the differences of productive capacity among tillers. Tw...The quality or structure of a wheat population is significantly affected by the compositions of tillers. Little has been known about the physiological basis for the differences of productive capacity among tillers. Two winter wheat cultivars, Shannong 15(SN15) and Shannong 8355(SN8355), were used to investigate the differences of productive capacity among tillers and analyze the physiological mechanisms that determine the superior tiller group. Low-position tillers(early initiated tillers) had a higher yield per spike than high-position tillers(late initiated tillers) in both cultivars, which was due to their more grain number per spike, more fertile spikelet per spike, less sterile spikelet per spike and higher grain weight. According to cluster analysis, tillers of SN15 were classified into 2 groups: superior tiller group including main stem(0), the first primary tiller(I) and the second primary tiller(II); and inferior tiller group including the third primary tiller(III) and the first secondary tiller(I-p). Tillers of SN8355 were classified into 3 groups: superior tiller group(0 and I), intermediate tiller group(II and III) and inferior tiller group(I-p). In comparison with other tiller groups, the superior tiller group had higher photosynthetic rate of flag leaves, higher antioxidant enzyme(SOD, POD and CAT) activities and lower levels of lipid peroxidation in leaves, higher grain filling rate in both superior and inferior grains during grain filling, higher single-stem biological yield and larger single-stem economic coefficient. Correlation analysis showed that yield per spike was positively and significantly correlated with the flag leaf photosynthetic rate, grain filling rate, the antioxidant enzyme activities and soluble protein content(except for SN15 at 5 days post-anthesis(DPA)) of flag leaf, the single-stem biological yield, and the single-stem economic coefficient. Remarkable negative correlation was also found between yield per spike a展开更多
To evaluate the possible genetic interrelationships between flour components and the sedimentation volume(SD),a doubled haploid(DH) population comprising 168 lines were used to identify the conditional quantitativ...To evaluate the possible genetic interrelationships between flour components and the sedimentation volume(SD),a doubled haploid(DH) population comprising 168 lines were used to identify the conditional quantitative trait loci(QTLs) for SD in three environments.Ten additive QTLs and 15 pairs of epistatic QTLs were detected for SD through unconditional and conditional QTL mapping.Three major additive QTLs were detected for SD conditioned on the seven quality traits.Two additive QTLs were found to be independent of these traits.Three additive QTLs were suppressed by three of the seven traits because of non-detection in unconditional mapping.Three pairs of epistatic QTLs were completely affected by the seven traits because of detection in unconditional mapping but no-detection in conditional mapping.Twelve pairs of epistatic QTLs were detected in conditional mapping.Our results indicated that conditional mapping could contribute to a better understanding of the interdependence of different and closely correlated traits at the QTL molecular level,especially some minor QTLs were found.The conditional mapping approach provides new insights that will make it possible to avoid the disadvantages of different traits by breeding through molecular design.展开更多
Wheat(Triticum aestivum,2n=6x=42,AABBDD)is one of the most important staple food crops in the world.Despite the fact that wheat production has significantly increased over the past decades,future wheat production will...Wheat(Triticum aestivum,2n=6x=42,AABBDD)is one of the most important staple food crops in the world.Despite the fact that wheat production has significantly increased over the past decades,future wheat production will face unprecedented challenges from global climate change,increasing world population,and water shortages in arid and semi-arid lands.Furthermore,excessive applications of diverse fertilizers and pesticides are exacerbating environmental pollution and ecological deterioration.To ensure global food and ecosystem security,it is essential to enhance the resilience of wheat production while minimizing environmental pollution through the use of cutting-edge technologies.However,the hexaploid genome and gene redundancy complicate advances in genetic research and precision gene modifications for wheat improvement,thus impeding the breeding of elite wheat cultivars.In this review,we first introduce state-of-the-art genome-editing technologies in crop plants,especially wheat,for both functional genomics and genetic improvement.We then outline applications of other technologies,such as GWAS,high-throughput genotyping and phenotyping,speed breeding,and synthetic biology,in wheat.Finally,we discuss existing challenges in wheat genome editing and future prospects for precision gene modifications using advanced genome-editing technologies.We conclude that the combination of genome editing and other molecular breeding strategies will greatly facilitate genetic improvement ofwheat for sustainable global production.展开更多
Stomatal density and size affect plant water use efficiency, photosynthsis rate and yield. The objective of this study was to gain insights into the variation and genetic basis of stomatal density and size during grai...Stomatal density and size affect plant water use efficiency, photosynthsis rate and yield. The objective of this study was to gain insights into the variation and genetic basis of stomatal density and size during grain filling under drought stress(DS) and well-watered(WW) conditions. The doubled haploid population derived from a cross of wheat cultivars Hanxuan 10(H10), a female parent, and Lumai 14(L14), a male parent, was used for phenotyping at the heading, flowering, and mid- and late grain filling stages along with established amplified fragment length polymorphism(AFLP) and simple sequence repeat(SSR) markers. The stomatal density of doubled haploid(DH) lines was gradually increased, while the stomatal lengths and widths were gradually decreased during grain filling stage. Twenty additive QTLs and 19 pairs of epistatic QTLs for the 3 traits were identified under DS. The other 20 QTLs and 25 pairs epistatic QTLs were obtained under WW. Most QTLs made more than 10% contributions to the total phenotypic variations at one growth stage under DS or WW. Furthermore, QTLs for stomatal density near Xwmc74 and Xgwm291 located on chromosome 5A were tightly linked to previously reported QTLs regulating total number of spikelets per spike, number of sterile spikelets per spike and proportion of fertile spikelets per spike. Qsw-2D-1 was detected across stages, and was in the same marker region as a major QTL for plant height, QPH.cgb-2D.1. These indicate that these QTLs on chromosomes 5A and 2D are involved in regulating these agronomic traits and are valuable for molecular breeding.展开更多
Plant N starvation response is closely associated with the N signaling components that involve transduction of the low-N cues. In this study, we functionally characterized Ta ARR1, a cytokinin(CK) response regulator g...Plant N starvation response is closely associated with the N signaling components that involve transduction of the low-N cues. In this study, we functionally characterized Ta ARR1, a cytokinin(CK) response regulator gene in Triticum aestivum, in mediating the N starvation adaptation in plants. Ta ARR1 harbors two conserved domains specified by plant ARR family members;subcellular localization analysis indicated its target onto nucleus after endoplasmic reticulum assortment. Ta ARR1 displayed modified expression upon the N starvation stressor, showing upregulated expression in roots and leaves over a 27-h N starvation treatment and whose induced transcripts were gradually recovered along with progression of the N recovery treatment. The tobacco lines overexpressing Ta ARR1 displayed improved low-N stress tolerance, displaying enlarged phenotype, increased biomass and N accumulation, and enhanced glutamine synthetase(GS) activities compared with wild type(WT) following the N starvation treatment. Expression analysis on genes encoding the nitrate transporter(NRT) and GS proteins in Nicotiana tabacum revealed that Nt NRT2.2 and Nt GS3 are upregulated in expression in the N-deprived transgenic lines, whose expression patterns were contrasted to other above family genes that were unaltered on transcripts between the transgenic lines and WT. Transgene analysis validated the function of Nt NRT2.2 and Nt GS3 in regulating N accumulation, GS activity, growth traits, and N use efficiency in plants. These results suggested the internal connection between the Ta ARR1-mediated N starvation tolerance and the modified transcription of distinct N acquisitionand assimilation-associated genes. Our investigation together indicates that Ta ARR1 is essential in plant N starvation adaptation due to the gene function in transcriptionally regulating distinct NRT and GS genes that affect plant N uptake and assimilation under the N starvation condition.展开更多
This study examined the biochemical responses of wheat(Triticum aestivum) to the stress of rare earth yttrium(Y) and showed that 25–100 mg/kg Y treatments evidently increased the biomass(root mass,shoot mass and...This study examined the biochemical responses of wheat(Triticum aestivum) to the stress of rare earth yttrium(Y) and showed that 25–100 mg/kg Y treatments evidently increased the biomass(root mass,shoot mass and leaf mass),accompanied by a significant(p0.05) increase in the chlorophyll(CHL) content in wheat leaves.Increased malondialdehyde(MDA) levels were detected in wheat shoots(stem and leaf) and roots too,indicating the presence of poisoning active oxygen species(AOS).The MDA content in wheat roots increased with the augmentation of Y concentration.These results indicated that there was a dose-dependent effect of Y on the changes of MDA content in wheat roots.Although the activities of superoxide dismutases(SOD),peroxidases(POD) and catalases(CAT) in wheat shoots and roots irregularly fluctuated with the increase in Y concentration,25–100 mg/kg Y significantly(p0.01) increased the activities of SOD and POD.In general,the dose-dependent effects of Y on the activity of antioxidant enzymes were insignificant.Our data also indicated that the increase in SOD and POD activities could be used as a good biomarker for the stress induced by low concentrations of Y.展开更多
Expression divergence caused by genetic variation and crosstalks among subgenomes of the allohexaploid bread wheat(Triticum aestivum.L.,BBAADD)is hypothesized to increase its adaptability and/or plasticity.However,the...Expression divergence caused by genetic variation and crosstalks among subgenomes of the allohexaploid bread wheat(Triticum aestivum.L.,BBAADD)is hypothesized to increase its adaptability and/or plasticity.However,the molecular basis of expression divergence remains unclear.Squamosa promoter-binding protein-like(SPL)transcription factors are critical for a wide array of biological processes.In this study,we constructed expression regulatory networks by combining DAP-seq for 40 SPLs,ATACseq,and RNA-seq.Our findings indicate that a group of low-affinity SPL binding regions(SBRs)were targeted by diverse SPLs and caused different sequence preferences around the core GTAC motif.The SBRs including the low-affinity ones are evolutionarily conserved,enriched GWAS signals related to important agricultural traits.However,those SBRs are highly diversified among the cis-regulatory regions(CREs)of syntenic genes,with less than 8%SBRs coexisting in triad genes,suggesting that CRE variations are critical for subgenome differentiations.Knocking out of Ta SPL7A/B/D and Ta SPL15A/B/D subfamily further proved that both high-and low-affinity SBRs played critical roles in the differential expression of genes regulating tiller number and spike sizes.Our results have provided baseline data for downstream networks of SPLs and wheat improvements and revealed that CRE variations are critical sources for subgenome divergence in the allohexaploid wheat.展开更多
Wheat leaf senescence is a developmental process that involves expressional changes in thousands of genes that ultimately impact grain protein content(GPC), grain yield(GY), and nitrogen use efficiency.The onset and r...Wheat leaf senescence is a developmental process that involves expressional changes in thousands of genes that ultimately impact grain protein content(GPC), grain yield(GY), and nitrogen use efficiency.The onset and rate of senescence are strongly influenced by plant hormones and environmental factors e.g. nitrogen availability. At maturity, decrease in nitrogen uptake could enhance N remobilization from leaves and stem to grain, eventually leading to leaf senescence. Early senescence is related to high GPC and somewhat low yield whereas late senescence is often related to high yield and somewhat low GPC. Early or late senescence is principally regulated by up and down-regulation of senescence associated genes. Integration of external and internal factors together with genotypic variation influence senescence associated genes in a developmental age dependent manner. Although regulation of genes involved in senescence has been studied in rice, Arabidopsis, maize, and currently in wheat, there are genotypespecific variations yet to explore. A major effort is needed to understand the interaction of positive and negative senescence regulators in determining the onset of senescence. In wheat, increasing attention has been paid to understand the role of positive senescence regulator, e.g. GPC-1, regulated gene network during early senescence time course. Recently, gene regulatory network involved early to late senescence time course revealed important senescence regulators. However, the known negative senescence regulator Ta NAC-S gene has not been extensively studied in wheat and little is known about its value in breeding. Existing data on senescence-related transcriptome studies and gene regulatory network could effectively be used for functional study in developing nitrogen efficient wheat varieties.展开更多
Objectives:Pigmented wheat has garnered increased attention due to its elevated antioxidant activity.This study aimed to compare the metabolic components and antioxidant properties of purple and white wheat grains.Mat...Objectives:Pigmented wheat has garnered increased attention due to its elevated antioxidant activity.This study aimed to compare the metabolic components and antioxidant properties of purple and white wheat grains.Materials and Methods:Metabolic analysis identified a total of 405 secondary metabolites using three extraction methods:free,acid,and alkali hydrolysis.Results:The results revealed that,compared with white wheat,purple wheat exhibited significantly higher levels of total polyphenols,total flavonoids,and antioxidant activity.Notably,there were substantial variations in 90,80,and 73 secondary metabolites between white and purple wheat under the respective extraction methods.The contents of hispidulin-8-C-(2ʹʹ-O-glucosyl)glucoside,hispidulin-8-C-glucoside,diosmetin6-C-glucoside,and scoparin decreased across all groups,while the contents of peonidin-3-O-glucoside,keracyanin,kuromanin cyanidin-3-Oglucoside,and cyanidin-3-O-(6ʹʹ-O-malonyl)glucoside increased.Conclusions:These findings suggest that pathways associated with anthocyanin,flavone,and flavonol biosynthesis were influenced.Furthermore,each extraction method revealed distinct secondary metabolites.Acid and alkali hydrolysis upregulated 16 and 3 metabolites in purple wheat,and 20 and 3 metabolites in white wheat,respectively.Acid and alkaline hydrolysis also identified indole-3-carboxylic acid,vanillic acid,pyridoxine,and other metabolites with antioxidant and antihypertensive effects in both white and purple wheat.This indicates that acid and alkaline hydrolysis can dissociate a greater variety and quantity of differential metabolites.These findings offer valuable insights for breeders seeking to develop wheat varieties with enhanced functional nutritional value.展开更多
Identifying stable quantitative trait loci(QTLs)for yield-related traits across populations and environments is crucial for wheat breeding and genetic studies.Consensus maps also play important roles in wheat genetic ...Identifying stable quantitative trait loci(QTLs)for yield-related traits across populations and environments is crucial for wheat breeding and genetic studies.Consensus maps also play important roles in wheat genetic and genomic research.In the present study,a wheat consensus map was constructed using a doubled haploid(DH)population derived from Jinghua 1×Xiaobaidongmai(JX),an F_(2)population derived from L43×Shanxibaimai(LS)and the BAAFS Wheat 90K SNP array single nucleotide polymorphism(SNP)array.A total of 44,503 SNP markers were mapped on the constructed consensus map,and they covered 5,437.92 cM across 21 chromosomes.The consensus map showed high collinearity with the individual maps and the wheat reference genome IWGSC RefSeq v2.1.Phenotypic data on eight yield-related traits were collected in the JX population,as well as the F_(2:3)and F_(2:4)populations of LS,in six,two and two environments,respectively,and those data were used for QTL analysis.Inclusive composite interval mapping(ICIM)identified 32 environmentally stable QTLs for the eight yield-related traits.Among them,four QTLs(QPH.baafs-4B,QKNS.baafs-4B,QTGW.baafs-4B,and QSL.baafs-5A.3)were detected across mapping populations and environments,and nine stable QTLs(qKL.baafs-1D,QPH.baafs-2B,QKNS.baafs-3D,QSL.baafs-3D,QKW.baafs-4B,QPH.baafs-5D,QPH.baafs-6A.1,QSL.baafs-6A,and QSL.baafs-6D)are likely to be new.The physical region of 17.25–44.91 Mb on chromosome 4B was associated with six yield-related traits,so it is an important region for wheat yield.The physical region around the dwarfing gene Rht24 contained QTLs for kernel length(KL),kernel width(KW),spike length(SL),and thousand-grain weight(TGW),which are either from a pleiotropic effect of Rht24 or closely linked loci.For the stable QTLs,254 promising candidate genes were identified.Among them,TraesCS5A03G1264300,TraesCS1B03G0624000 and TraesCS6A03G0697000 are particularly noteworthy since their homologous genes have similar functions for the corresponding traits.The constructed consensus map 展开更多
[Objective] The aim of experiment was to provide a new germplasm for wheat breeding by further using desirable genes in 2V chromosome of Haynaldia villosa.[Method] Through hybridization between common wheat(Triticum a...[Objective] The aim of experiment was to provide a new germplasm for wheat breeding by further using desirable genes in 2V chromosome of Haynaldia villosa.[Method] Through hybridization between common wheat(Triticum aestivum)-Haynaldia villosa disomic substitution line and common wheat Nonglin26-3C chromosome of Aegilops triuncialis disomic addition line,the analysis methods such as chromosome C-banding,genomic in situ hybridization and molecular marker technique were comprehensively applied and combined characters investigation.[Result] The wheat-Haynaldia villosa translocation line(T6BS·6BL-2VS)was selected from hybrid progenies to conduct characters investigation,which found some bristles on glume ridge of T6BS·6BL-2VS.[Conclusion] The translocation line induced by gametocidal chromosome was a small segment translocation line and the gene of bristle on glume ridge of Haynaldia villosa was located between the middle and the terminal of 2VS.展开更多
Two winter wheat(Triticum aestivum L.)cultivars, large-spike type Yumai66 and small-spike type Yumai49, were used to study the activities of enzymes involved in starch synthesis in the kernel during grain filling. Sta...Two winter wheat(Triticum aestivum L.)cultivars, large-spike type Yumai66 and small-spike type Yumai49, were used to study the activities of enzymes involved in starch synthesis in the kernel during grain filling. Starch accumulated faster in the kernel of Yumai49 than Yumai66 up to 25 d after anthesis, thereafter starch accumulated faster in the kernel of Yumai66. Starch accumulation in Yumai66 peaked at 20 -25 d after anthesis, while in Yumai49 starch accumulation peaked at 15 -20 d after anthesis and 25 -30 d after anthesis. The first peak was much higher than that of the second. Sucrose content and sucrose synthase activity peaked at 20 and 15 d after anthesis in Yumai66 and Yumai49, respectively. The sucrose content and sucrose synthase activity in Yumai66 were higher than that in Yumai49 during grain filling. ADP-glucose pyro-phosphorylase and starch branching enzyme activity in the kernel of Yumai66 peaked at 20 d after anthesis. while soluble starch synthase activity peaked at 10 and 20 d after anthesis. The second peak was much higher than that of the first.展开更多
The value of different dwarfing genes in winter wheat breeding was studied using 6 near-isogenic lines carrying different Rht dwarfing genes over three years experiment.Results showed that both the Rht1 and Rht2 semi-...The value of different dwarfing genes in winter wheat breeding was studied using 6 near-isogenic lines carrying different Rht dwarfing genes over three years experiment.Results showed that both the Rht1 and Rht2 semi-dwarfing genes had significantlypositive effects on kernel number and grain weight per spike, and had significantlynegative effects on 1000-grain weight comparing to the tall line(rht) and the Rht3 line.The Rht3 dwarfing gene had a significantly negative effect on kernel number per spike,and had positive effect on 1000-grain weight. The combination of the Rht2 and Rht3 geneshowed significantly negative effect on yield components. All of these 5 dwarfing orsemidwarfing genotypes mentioned above had a significantly negative effect on plantheight and no significant effect on the area of flag leaf, spikelets per spike and spikelength.展开更多
基金Supported by the Natural Science Foundation of Anhui Province (070411009)the Innovation Fund from Hefei University of Technology to undergraduate students (XS0637).
文摘With the enhancement of copper (Cu) stress, the germination percentage of wheat seeds decreased gradually. Pretreatment with sodium hydrosulfide (NariS), hydrogen sulfide (H2S) donor alleviated the inhibitory effect of Cu stress in a dose- dependent manner; whereas little visible symptom was observed in germinating seeds and radicle tips cultured in NariS solutions. It was verified that H2S or HS- rather than other sulfur-containing components derived from NariS attribute to the potential role in promoting seed germination against Cu stress. Further studies showed that NariS could promote amylase and esterase activities, reduce Cu-induced disturbance of plasma membrane integrity in the radicle tips, and sustain lower levels of malondialdehyde and H202 in germinating seeds. Furthermore, NariS pretreatment increased activities of superoxide dismutase and catalase and decreased that of lipoxygenase, but showed no significant effect on ascorbate peroxidase. Alternatively, NariS prevented uptake of Cu and promoted the accumulation of free amino acids in seeds exposed to Cu. In addition, a rapid accumulation of endogenous H2S in seeds was observed at the early stage of germination, and higher level of H2S in NaHS-pretreated seeds. These data indicated that H2S was involved in the mechanism of germinating seeds' responses to Cu stress.
基金supported by grants from the National Natural Science Foundation of China(31701418 and 32072002)the Natural Science Basic Research Plan in Shaanxi Province of China(2019JCW-18)and the 111 Project from the Ministry of Education of China(B07049).
文摘Drought is a major environmental factor limiting wheat production worldwide,and developing drought-tolerant cultivars is a central challenge for wheat breeders globally.Therefore,it is important to identify genetic components determining drought tolerance in wheat.In this study,we identified a wheat NAC gene(TaNAC071-A)that is tightly associated with drought tolerance by a genome-wide association study.Knockdown of TaNAC071-A in wheat attenuated plant drought tolerance,whereas its overexpression significantly enhanced drought tolerance through improved water-use efficiency and increased expression of stress-responsive genes.This heightened water-saving mechanism mitigated the yield loss caused by water deficit.Further candidate gene association analysis showed that a 108-bp insertion in the promoter of TaNAC071-A alters its expression level and contributes to variation in drought tolerance among wheat accessions.This insertion contains two MYB cis-regulatory elements(CREs)that can be directly bound by the MYB transcription activator,TaMYBL1,thereby leading to increased TaNAC071-A expression and plant drought tolerance.Importantly,introgression of this 108-bp insertion allele,TaNAC071-AIn-693,into drought-sensitive cultivars could improve their drought tolerance,demonstrating that it is a valuable genetic resource for wheat breeding.Taken together,our findings highlight a major breakthrough in determining the genetic basis underlying phenotypic variation in wheat drought tolerance and showcase the potential of exploiting CRE-containing indels for improving important agronomical traits.
文摘The effects of osmotic stress on the ATPase activity, the contents of —SH group and conjugated polyamines in mitochondrial membrane from wheat seedling [Triticum aestivum L. cv. Yumai No.18(drought-tolerant) and cv. Yumai No.9(drought-sensitive)] roots were investigated. The results showed that ATPase activity and —SH group content decreased with polyethylene glycol(PEG) 6000(-0.55 MPa) treatment for 7 d, in concert with the decrease of the ratio of noncovalently conjugated spermidine(NCC-Spd)/noncovalently conjugated putrescine(NCC-Put) and increase of the covalently conjugated putrescine(CC-Put). Osmotic stress injury to Yangmai No.9 seedlings was alleviated greatly with 1 mmol/L exogenous spermidine(Spd), in concert with marked increases of the ratio of NCC-Spd/NCC-Put, —SH group contents and ATPase activity in mitochondrial membrane. Under osmotic stress, the concomitant treatment of Yumai No.18 seedlings with methylglyoxyl bis(guanylhydrazone) (MGBG), an inhibitor of S-adenosyl methionine decarboxylase(SAMDC), and phenanthrolin (o-Phen), an inhibitor of transglutaminase(TGase), caused a significant decrease of the ratio of NCC-Spd / NCC-Put, CC-Put contents, respectively, in concert with the marked decreases of ATPase activity, —SH group content and its tolerance to osmotic stress. All the results above suggested that osmotic stress tolerance of wheat seedlings was associated with the ATPase activity, the contents of —SH group, NCC-Spd and CC-Put in mitochondrial membrane.
基金supported by the National Technology R&D Program of China (2013BAD07B07, 2015BAD26B01 and 2018YFD0300701)
文摘Soil management practices affect rhizosphere microorganisms and enzyme activities, which in turn influence soil ecosystem processes. The objective of this study was to explore the effects of different nitrogen application rates on wheat(Triticum aestivum L.) rhizosphere soil microorganisms and enzyme activities, and their temporal variations in relation to soil fertility under supplemental irrigation conditions in a fluvo-aquic region. For this, we established a split-plot experiment for two consecutive years(2014–2015 and 2015–2016) in the field with three levels of soil moisture: water deficit to no irrigation(W1), medium irrigation to(70±5)% of soil relative moisture after jointing stage(W2), and adequate irrigation to(80±5)% of soil relative moisture after jointing stage(W3);and three levels of nitrogen: 0 kg ha^–1(N1), 195 kg ha^–1(N2) and 270 kg ha^–1(N3). Results showed that irrigation and nitrogen application significantly increased rhizosphere microorganisms and enzyme activities. Soil microbiological properties showed different trends in response to N level;the highest values of bacteria, protease, catalase and phosphatase appeared in N2, while the highest levels of actinobacteria, fungi and urease were observed in N3. In addition, these items performed best under medium irrigation(W2) relative to W1 and W3;particularly the maximum microorganism(bacteria, actinobacteria and fungi) amounts appeared at W2, 5.37×10^7 and 6.35×10^7 CFUs g^–1 higher than those at W3 in 2014–2015 and 2015–2016, respectively;and these changes were similar in both growing seasons. Microbe-related parameters fluctuated over time but their seasonality did not hamper the irrigation and fertilization-induced effects. Further, the highest grain yields of 13 309.2 and 12 885.7 kg ha^–1 were both obtained at W2 N2 in 2014–2015 and 2015–2016, respectively. The selected properties, soil microorganisms and enzymes, were significantly correlated with wheat yield and proved to be valuable indicators of soil qualit
基金supported by the National Natural Science Foundation of China (31271661)the National Basic Research Program of China (973, 2009CB118602)+1 种基金the Special Fund for Agro-Scientific Research in the Public Interest of China (201203100, 201203029)the National Science and Technology Support Program of China (2012BAD04B05)
文摘The quality or structure of a wheat population is significantly affected by the compositions of tillers. Little has been known about the physiological basis for the differences of productive capacity among tillers. Two winter wheat cultivars, Shannong 15(SN15) and Shannong 8355(SN8355), were used to investigate the differences of productive capacity among tillers and analyze the physiological mechanisms that determine the superior tiller group. Low-position tillers(early initiated tillers) had a higher yield per spike than high-position tillers(late initiated tillers) in both cultivars, which was due to their more grain number per spike, more fertile spikelet per spike, less sterile spikelet per spike and higher grain weight. According to cluster analysis, tillers of SN15 were classified into 2 groups: superior tiller group including main stem(0), the first primary tiller(I) and the second primary tiller(II); and inferior tiller group including the third primary tiller(III) and the first secondary tiller(I-p). Tillers of SN8355 were classified into 3 groups: superior tiller group(0 and I), intermediate tiller group(II and III) and inferior tiller group(I-p). In comparison with other tiller groups, the superior tiller group had higher photosynthetic rate of flag leaves, higher antioxidant enzyme(SOD, POD and CAT) activities and lower levels of lipid peroxidation in leaves, higher grain filling rate in both superior and inferior grains during grain filling, higher single-stem biological yield and larger single-stem economic coefficient. Correlation analysis showed that yield per spike was positively and significantly correlated with the flag leaf photosynthetic rate, grain filling rate, the antioxidant enzyme activities and soluble protein content(except for SN15 at 5 days post-anthesis(DPA)) of flag leaf, the single-stem biological yield, and the single-stem economic coefficient. Remarkable negative correlation was also found between yield per spike a
基金supported by the Natural Science Foundation of Shandong Province,China(ZR2009DQ009)the National Natural Science Foundation of China(30971764 and 31171554)the National Major Projects of Cultivated Transgenic New Varieties Foundation of China(2011ZX08002-003 and 2009ZX08002-017B)
文摘To evaluate the possible genetic interrelationships between flour components and the sedimentation volume(SD),a doubled haploid(DH) population comprising 168 lines were used to identify the conditional quantitative trait loci(QTLs) for SD in three environments.Ten additive QTLs and 15 pairs of epistatic QTLs were detected for SD through unconditional and conditional QTL mapping.Three major additive QTLs were detected for SD conditioned on the seven quality traits.Two additive QTLs were found to be independent of these traits.Three additive QTLs were suppressed by three of the seven traits because of non-detection in unconditional mapping.Three pairs of epistatic QTLs were completely affected by the seven traits because of detection in unconditional mapping but no-detection in conditional mapping.Twelve pairs of epistatic QTLs were detected in conditional mapping.Our results indicated that conditional mapping could contribute to a better understanding of the interdependence of different and closely correlated traits at the QTL molecular level,especially some minor QTLs were found.The conditional mapping approach provides new insights that will make it possible to avoid the disadvantages of different traits by breeding through molecular design.
基金funded by the National Key Research and Development Program of China,China(2020YFE0202300)the Agricultural Science and Technology Innovation Program,China(CAAS-ZDRW202002)+1 种基金the Innovation and Talent Supportive Program of the CAAS,Chinathe National Engineering Laboratory of Crop Molecular Breeding to L.X.
文摘Wheat(Triticum aestivum,2n=6x=42,AABBDD)is one of the most important staple food crops in the world.Despite the fact that wheat production has significantly increased over the past decades,future wheat production will face unprecedented challenges from global climate change,increasing world population,and water shortages in arid and semi-arid lands.Furthermore,excessive applications of diverse fertilizers and pesticides are exacerbating environmental pollution and ecological deterioration.To ensure global food and ecosystem security,it is essential to enhance the resilience of wheat production while minimizing environmental pollution through the use of cutting-edge technologies.However,the hexaploid genome and gene redundancy complicate advances in genetic research and precision gene modifications for wheat improvement,thus impeding the breeding of elite wheat cultivars.In this review,we first introduce state-of-the-art genome-editing technologies in crop plants,especially wheat,for both functional genomics and genetic improvement.We then outline applications of other technologies,such as GWAS,high-throughput genotyping and phenotyping,speed breeding,and synthetic biology,in wheat.Finally,we discuss existing challenges in wheat genome editing and future prospects for precision gene modifications using advanced genome-editing technologies.We conclude that the combination of genome editing and other molecular breeding strategies will greatly facilitate genetic improvement ofwheat for sustainable global production.
基金supported by the National Science and Technology Major Projects for Cultivation of New Transgenic Varieties,Ministry of Agriculture of China(2014ZX0800203B-003)the Natural Science Foundation of Shanxi Province,China(2014011004-3)+1 种基金the Specialized Research Fund for the Doctoral Program of Higher Education,China(20121403110005)a Program of Consultative Group for International Agricultural Research(CGIAR)Project,Generation Challenge Programme(G7010.02.01)
文摘Stomatal density and size affect plant water use efficiency, photosynthsis rate and yield. The objective of this study was to gain insights into the variation and genetic basis of stomatal density and size during grain filling under drought stress(DS) and well-watered(WW) conditions. The doubled haploid population derived from a cross of wheat cultivars Hanxuan 10(H10), a female parent, and Lumai 14(L14), a male parent, was used for phenotyping at the heading, flowering, and mid- and late grain filling stages along with established amplified fragment length polymorphism(AFLP) and simple sequence repeat(SSR) markers. The stomatal density of doubled haploid(DH) lines was gradually increased, while the stomatal lengths and widths were gradually decreased during grain filling stage. Twenty additive QTLs and 19 pairs of epistatic QTLs for the 3 traits were identified under DS. The other 20 QTLs and 25 pairs epistatic QTLs were obtained under WW. Most QTLs made more than 10% contributions to the total phenotypic variations at one growth stage under DS or WW. Furthermore, QTLs for stomatal density near Xwmc74 and Xgwm291 located on chromosome 5A were tightly linked to previously reported QTLs regulating total number of spikelets per spike, number of sterile spikelets per spike and proportion of fertile spikelets per spike. Qsw-2D-1 was detected across stages, and was in the same marker region as a major QTL for plant height, QPH.cgb-2D.1. These indicate that these QTLs on chromosomes 5A and 2D are involved in regulating these agronomic traits and are valuable for molecular breeding.
基金supported by the National Natural Science Foundation of China (31571664 and 31671686)the Key Research and Development Project of Hebei, China (17962901D)
文摘Plant N starvation response is closely associated with the N signaling components that involve transduction of the low-N cues. In this study, we functionally characterized Ta ARR1, a cytokinin(CK) response regulator gene in Triticum aestivum, in mediating the N starvation adaptation in plants. Ta ARR1 harbors two conserved domains specified by plant ARR family members;subcellular localization analysis indicated its target onto nucleus after endoplasmic reticulum assortment. Ta ARR1 displayed modified expression upon the N starvation stressor, showing upregulated expression in roots and leaves over a 27-h N starvation treatment and whose induced transcripts were gradually recovered along with progression of the N recovery treatment. The tobacco lines overexpressing Ta ARR1 displayed improved low-N stress tolerance, displaying enlarged phenotype, increased biomass and N accumulation, and enhanced glutamine synthetase(GS) activities compared with wild type(WT) following the N starvation treatment. Expression analysis on genes encoding the nitrate transporter(NRT) and GS proteins in Nicotiana tabacum revealed that Nt NRT2.2 and Nt GS3 are upregulated in expression in the N-deprived transgenic lines, whose expression patterns were contrasted to other above family genes that were unaltered on transcripts between the transgenic lines and WT. Transgene analysis validated the function of Nt NRT2.2 and Nt GS3 in regulating N accumulation, GS activity, growth traits, and N use efficiency in plants. These results suggested the internal connection between the Ta ARR1-mediated N starvation tolerance and the modified transcription of distinct N acquisitionand assimilation-associated genes. Our investigation together indicates that Ta ARR1 is essential in plant N starvation adaptation due to the gene function in transcriptionally regulating distinct NRT and GS genes that affect plant N uptake and assimilation under the N starvation condition.
基金supported by National Natural Science Foundation of China(21067003,51364015)the Natural Science Foundation of Jiangxi Province(20114BAB203024)the National High-Tech Research and Development Program of China(2012BAC11B07)
文摘This study examined the biochemical responses of wheat(Triticum aestivum) to the stress of rare earth yttrium(Y) and showed that 25–100 mg/kg Y treatments evidently increased the biomass(root mass,shoot mass and leaf mass),accompanied by a significant(p0.05) increase in the chlorophyll(CHL) content in wheat leaves.Increased malondialdehyde(MDA) levels were detected in wheat shoots(stem and leaf) and roots too,indicating the presence of poisoning active oxygen species(AOS).The MDA content in wheat roots increased with the augmentation of Y concentration.These results indicated that there was a dose-dependent effect of Y on the changes of MDA content in wheat roots.Although the activities of superoxide dismutases(SOD),peroxidases(POD) and catalases(CAT) in wheat shoots and roots irregularly fluctuated with the increase in Y concentration,25–100 mg/kg Y significantly(p0.01) increased the activities of SOD and POD.In general,the dose-dependent effects of Y on the activity of antioxidant enzymes were insignificant.Our data also indicated that the increase in SOD and POD activities could be used as a good biomarker for the stress induced by low concentrations of Y.
基金supported by the Central Publicinterest Scientific Institution Basic Research Found(S2022ZD02)the Excellent Young Scientists Fund(Overseas)of National Natural Science Foundation of China+2 种基金the Fundamental Research Funds from the Institute of Crop Sciences,Chinese Academy of Agricultural Sciences(S2020YC07,S2021YC03)the Major Basic Research Program of Shandong Natural Science Foundation(ZR2019ZD15)the Top Talents Program“One Case One Discussion(Yishiyiyi)”of Shandong Province,China。
文摘Expression divergence caused by genetic variation and crosstalks among subgenomes of the allohexaploid bread wheat(Triticum aestivum.L.,BBAADD)is hypothesized to increase its adaptability and/or plasticity.However,the molecular basis of expression divergence remains unclear.Squamosa promoter-binding protein-like(SPL)transcription factors are critical for a wide array of biological processes.In this study,we constructed expression regulatory networks by combining DAP-seq for 40 SPLs,ATACseq,and RNA-seq.Our findings indicate that a group of low-affinity SPL binding regions(SBRs)were targeted by diverse SPLs and caused different sequence preferences around the core GTAC motif.The SBRs including the low-affinity ones are evolutionarily conserved,enriched GWAS signals related to important agricultural traits.However,those SBRs are highly diversified among the cis-regulatory regions(CREs)of syntenic genes,with less than 8%SBRs coexisting in triad genes,suggesting that CRE variations are critical for subgenome differentiations.Knocking out of Ta SPL7A/B/D and Ta SPL15A/B/D subfamily further proved that both high-and low-affinity SBRs played critical roles in the differential expression of genes regulating tiller number and spike sizes.Our results have provided baseline data for downstream networks of SPLs and wheat improvements and revealed that CRE variations are critical sources for subgenome divergence in the allohexaploid wheat.
基金financially supported by Australia Grain Research&Development Corporation Project(UMU00048)Murdoch University International Postgraduate Research Scholarship。
文摘Wheat leaf senescence is a developmental process that involves expressional changes in thousands of genes that ultimately impact grain protein content(GPC), grain yield(GY), and nitrogen use efficiency.The onset and rate of senescence are strongly influenced by plant hormones and environmental factors e.g. nitrogen availability. At maturity, decrease in nitrogen uptake could enhance N remobilization from leaves and stem to grain, eventually leading to leaf senescence. Early senescence is related to high GPC and somewhat low yield whereas late senescence is often related to high yield and somewhat low GPC. Early or late senescence is principally regulated by up and down-regulation of senescence associated genes. Integration of external and internal factors together with genotypic variation influence senescence associated genes in a developmental age dependent manner. Although regulation of genes involved in senescence has been studied in rice, Arabidopsis, maize, and currently in wheat, there are genotypespecific variations yet to explore. A major effort is needed to understand the interaction of positive and negative senescence regulators in determining the onset of senescence. In wheat, increasing attention has been paid to understand the role of positive senescence regulator, e.g. GPC-1, regulated gene network during early senescence time course. Recently, gene regulatory network involved early to late senescence time course revealed important senescence regulators. However, the known negative senescence regulator Ta NAC-S gene has not been extensively studied in wheat and little is known about its value in breeding. Existing data on senescence-related transcriptome studies and gene regulatory network could effectively be used for functional study in developing nitrogen efficient wheat varieties.
基金the Key Research Foundation of Science and Technology Department of Zhejiang Province(No.2021C02057)the Serving Local Economic Development Project of Shandong(Linyi)Institute of Modern Agriculture,Zhejiang University(No.ZDNY-2021-FWLY01005),China.
文摘Objectives:Pigmented wheat has garnered increased attention due to its elevated antioxidant activity.This study aimed to compare the metabolic components and antioxidant properties of purple and white wheat grains.Materials and Methods:Metabolic analysis identified a total of 405 secondary metabolites using three extraction methods:free,acid,and alkali hydrolysis.Results:The results revealed that,compared with white wheat,purple wheat exhibited significantly higher levels of total polyphenols,total flavonoids,and antioxidant activity.Notably,there were substantial variations in 90,80,and 73 secondary metabolites between white and purple wheat under the respective extraction methods.The contents of hispidulin-8-C-(2ʹʹ-O-glucosyl)glucoside,hispidulin-8-C-glucoside,diosmetin6-C-glucoside,and scoparin decreased across all groups,while the contents of peonidin-3-O-glucoside,keracyanin,kuromanin cyanidin-3-Oglucoside,and cyanidin-3-O-(6ʹʹ-O-malonyl)glucoside increased.Conclusions:These findings suggest that pathways associated with anthocyanin,flavone,and flavonol biosynthesis were influenced.Furthermore,each extraction method revealed distinct secondary metabolites.Acid and alkali hydrolysis upregulated 16 and 3 metabolites in purple wheat,and 20 and 3 metabolites in white wheat,respectively.Acid and alkaline hydrolysis also identified indole-3-carboxylic acid,vanillic acid,pyridoxine,and other metabolites with antioxidant and antihypertensive effects in both white and purple wheat.This indicates that acid and alkaline hydrolysis can dissociate a greater variety and quantity of differential metabolites.These findings offer valuable insights for breeders seeking to develop wheat varieties with enhanced functional nutritional value.
基金funded by the Major Project of Agricultural Biological Breeding,China(2022ZD0401902)the Science and Technology Innovation Project of Beijing Academy of Agriculture and Forestry Sciences,China(KJCX20230301 and KJCX20230307)。
文摘Identifying stable quantitative trait loci(QTLs)for yield-related traits across populations and environments is crucial for wheat breeding and genetic studies.Consensus maps also play important roles in wheat genetic and genomic research.In the present study,a wheat consensus map was constructed using a doubled haploid(DH)population derived from Jinghua 1×Xiaobaidongmai(JX),an F_(2)population derived from L43×Shanxibaimai(LS)and the BAAFS Wheat 90K SNP array single nucleotide polymorphism(SNP)array.A total of 44,503 SNP markers were mapped on the constructed consensus map,and they covered 5,437.92 cM across 21 chromosomes.The consensus map showed high collinearity with the individual maps and the wheat reference genome IWGSC RefSeq v2.1.Phenotypic data on eight yield-related traits were collected in the JX population,as well as the F_(2:3)and F_(2:4)populations of LS,in six,two and two environments,respectively,and those data were used for QTL analysis.Inclusive composite interval mapping(ICIM)identified 32 environmentally stable QTLs for the eight yield-related traits.Among them,four QTLs(QPH.baafs-4B,QKNS.baafs-4B,QTGW.baafs-4B,and QSL.baafs-5A.3)were detected across mapping populations and environments,and nine stable QTLs(qKL.baafs-1D,QPH.baafs-2B,QKNS.baafs-3D,QSL.baafs-3D,QKW.baafs-4B,QPH.baafs-5D,QPH.baafs-6A.1,QSL.baafs-6A,and QSL.baafs-6D)are likely to be new.The physical region of 17.25–44.91 Mb on chromosome 4B was associated with six yield-related traits,so it is an important region for wheat yield.The physical region around the dwarfing gene Rht24 contained QTLs for kernel length(KL),kernel width(KW),spike length(SL),and thousand-grain weight(TGW),which are either from a pleiotropic effect of Rht24 or closely linked loci.For the stable QTLs,254 promising candidate genes were identified.Among them,TraesCS5A03G1264300,TraesCS1B03G0624000 and TraesCS6A03G0697000 are particularly noteworthy since their homologous genes have similar functions for the corresponding traits.The constructed consensus map
基金Supported by the National Natural Science Foundation of China(10475041)the Foundation of Nanjing Xiaozhuang University for the Key Discipline Construction(2005NXY01)the Scientific Research Founda-tion for Talents of Nanjing Xiaozhuang University(2008NXY04)~~
文摘[Objective] The aim of experiment was to provide a new germplasm for wheat breeding by further using desirable genes in 2V chromosome of Haynaldia villosa.[Method] Through hybridization between common wheat(Triticum aestivum)-Haynaldia villosa disomic substitution line and common wheat Nonglin26-3C chromosome of Aegilops triuncialis disomic addition line,the analysis methods such as chromosome C-banding,genomic in situ hybridization and molecular marker technique were comprehensively applied and combined characters investigation.[Result] The wheat-Haynaldia villosa translocation line(T6BS·6BL-2VS)was selected from hybrid progenies to conduct characters investigation,which found some bristles on glume ridge of T6BS·6BL-2VS.[Conclusion] The translocation line induced by gametocidal chromosome was a small segment translocation line and the gene of bristle on glume ridge of Haynaldia villosa was located between the middle and the terminal of 2VS.
文摘Two winter wheat(Triticum aestivum L.)cultivars, large-spike type Yumai66 and small-spike type Yumai49, were used to study the activities of enzymes involved in starch synthesis in the kernel during grain filling. Starch accumulated faster in the kernel of Yumai49 than Yumai66 up to 25 d after anthesis, thereafter starch accumulated faster in the kernel of Yumai66. Starch accumulation in Yumai66 peaked at 20 -25 d after anthesis, while in Yumai49 starch accumulation peaked at 15 -20 d after anthesis and 25 -30 d after anthesis. The first peak was much higher than that of the second. Sucrose content and sucrose synthase activity peaked at 20 and 15 d after anthesis in Yumai66 and Yumai49, respectively. The sucrose content and sucrose synthase activity in Yumai66 were higher than that in Yumai49 during grain filling. ADP-glucose pyro-phosphorylase and starch branching enzyme activity in the kernel of Yumai66 peaked at 20 d after anthesis. while soluble starch synthase activity peaked at 10 and 20 d after anthesis. The second peak was much higher than that of the first.
基金supported by the Provincial Natural Science Foundation of Hebei,China(396313).
文摘The value of different dwarfing genes in winter wheat breeding was studied using 6 near-isogenic lines carrying different Rht dwarfing genes over three years experiment.Results showed that both the Rht1 and Rht2 semi-dwarfing genes had significantlypositive effects on kernel number and grain weight per spike, and had significantlynegative effects on 1000-grain weight comparing to the tall line(rht) and the Rht3 line.The Rht3 dwarfing gene had a significantly negative effect on kernel number per spike,and had positive effect on 1000-grain weight. The combination of the Rht2 and Rht3 geneshowed significantly negative effect on yield components. All of these 5 dwarfing orsemidwarfing genotypes mentioned above had a significantly negative effect on plantheight and no significant effect on the area of flag leaf, spikelets per spike and spikelength.
