Comparison of Newly Synthetic Hexaploid Wheat with Its Donors on SSR Products

Microsatellites or SSRs as powerful genetic markers have widely been used in genetics and evolutionary biology in common wheat. Because of the high polymorphism, newly synthesized hexaploid wheat has been used in the construction of genetic segregation population for SSR markers, However, data on the evolution of microsatellites during the polyploidization event of hexaploid wheat are limited. In this study, 66 pairs of specific to A/B genome SSR patterns among newly synthesized hexaploid wheat, the donor tetraploid wheat and Aegilops tauschii were compared. The results indicated that most SSR markers were conserved during the polyploidization events of newly synthetic hexaploid wheat, from Triticum turgidum and Ae. tauschii. Over 70% A/B genome specific SSR markers could amplify the SSR sequences from the D genome ofAe. tauschii. Most amplified fragments from Ae, tauschii were detected in synthetic hexaploid at corresponding positions with the same sizes and patterns as in its parental Ae. tauschii. This suggested that these SSR markers, specific for A/B genome in common wheat, could amplify SSR products of D genome besides A/B genome in the newly synthesized hexaploid wheat, that is, these SSR primers specific for A/B genome in common wheat were nonspecific for the A/B genome in the synthetic hexaploid wheat. In addition, one amplified Ae. tauschii product was not detected in the newly synthetic hexaploid wheat. An extra-amplified product was found in the newly synthetic hexaploid wheat. These results suggested that caution should be taken when using SSR marker to genotype newly synthetic hexaploid wheat.

Effect of HMW-GS 6 + 8 and 1.5 + 10 from Synthetic Hexaploid Wheat on Wheat Quality Traits

To determine the effect of 6 ＋ 8 and 1.5 ＋ 10 HMW-GS of synthetic hexaploid wheat （SHW） on main quality parameters of wheat, a set of recombinant inbred lines （RILs） derived from the cross between a SHW with N, 6 ＋ 8, 1.5 ＋ 10 HMW-GS and a cultivar Chuanyu 12-1 （CY 12-1） with 1, 7 ＋ 8, 2 ＋ 12 were planted in three environments in 2005 and 2006 and totally 16 quality parameters were tested for each line. Significant differences in all tested quality parameters but flour yield were observed between the two parents. The mean values of the RILs were intermediate to the parents for grain and protein parameters and some farinograph parameters, flour water absorption （FWA）, and farinograph softening （SOF） but beyond parents at dough stability time （DST）, breakdown time （BRT）, quality number （QN）, noodle score （NS）, and loaf volume （LOV）. All of the quality traits, especially in grain hardness （GH）, zeleny sedimentation volume （SED）, and most of farinograph parameters had significant difference between the different HMW-GS components. The effects of different alleles of HMW-GS at same locus （Glu-A1 or Glu-B1 or GIu-D1） on the different quality parameters were also different and affected by the other two loci. For most of parameters tested, 6 ＋ 8 was better than 7 ＋ 8 and there was no difference between 1.5 ＋ 10 and 2 ＋ 12. End-use quality was greatly influenced by components of HMW-GS. The components of 1, 6 ＋ 8, 1.5 ＋ 10 had the highest LOV and bread score （BS） values, whereas the components of 1, 7＋ 8 and 1.5 ＋ 10 had the highest NS values. Noodle score performed a positive linear relationship with falling number （FN） and its relationships to other quality parameters were affected by environments. Loaf volume had a significant negative relationship to SOF and positive associations with most of quality parameters. It could be concluded that HMW-GS 6＋ 8 from SHW had better overall quality characteristics than 7 ＋ 8, whereas the effects of 1.5 ＋ 10 on quality was different in respect to quality parameters and the HMW-GS components. Synthetic hexaploid wheat with subunits 6 ＋ 8 and 1.5 ＋ 10 had the potentials to improve the end-use quality of wheat cultivars.

Identification of QTLs for Yield-Related Traits in the Recombinant Inbred Line Population Derived from the Cross Between a Synthetic Hexaploid Wheat-Derived Variety Chuanmai 42 and a Chinese Elite Variety Chuannong 16

Synthetic hexaploid wheat （SHW） represents a valuable source of new resistances to a range of biotic and abiotic stresses. A recombinant inbred line （RIL） population with 127 recombinant inbred lines derived from a SHW-derived variety Chuanmai 42 crossing with a Chinese spring wheat variety Chuannong 16 was used to map QTLs for agronomic traits including grain yield, grains per square meter, thousand-kernel weight, spikes per square meter, grain number per spike, grains weight per spike, and biomass yield. The population was genotyped using 184 simple-sequence repeat （SSR） markers and 34 sequence-related amplified polymorphism （SRAP） markers. Of 76 QTLs （LOD〉2.5） identified, 42 were found to have a positive effect from Chuanmai 42. The QTL QGy.saas-4D.2 associated with grain yield on chromosome 4D was detected in four of the six environments and the combined analysis, and the mean yield, across six environments, of individuals carrying the Chuanmai 42 allele at this locus was 8.9% higher than that of those lines carrying the Chuannong 16 allele. Seven clusters of the yield-coincident QTLs were detected on 1A, 4A, 3B, 5B, 4D, and 7D.

QTL Mapping for Important Agronomic Traits in Synthetic Hexaploid Wheat Derived from Aegiliops tauschii ssp. tauschii

Aegiliops tauschii is classified into two subspecies： Ae. tauschii ssp. tauschii and Ae. tauschii ssp. strangulata. Novel genetic variations exist in Ae. tauschii ssp. tauschii that can be utilized in wheat improvement. We synthesized a hexaploid wheat genotype（SHW-L1） by crossing an Ae. tauschii ssp. tauschii accession（AS60） with a tetraploid wheat genotype（AS2255）. A population consisting of 171 F8 recombinant inbred lines was developed from SHW-L1 and Chuanmai 32 to identify QTLs associated with agronomic traits. A new genetic map with high density was constructed and used to detect the QTLs for heading date, kernel width, spike length, spikelet number, and thousand kernel weight. A total of 30 putative QTLs were identified for five investigated traits. Thirteen QTLs were located on D genomes of SHW-L1, six of them showed positive effect on agronomic traits. Chromosome region flanked by wPt-6133–wPt-8134 on 2D carried five environment-independent QTLs. Each QTL accounted for more than 10% phenotypic variance. These QTLs were highly consistent across environments and should be used in wheat breeding.

Characterization and Molecular Mapping of a Stripe Rust Resistance Gene in Synthetic Wheat CI110

Stripe rust,caused by Puccinia striiformis f.sp.tritici（Pst）,is one of the most destructive diseases of wheat（Triticum aestivum L.）.To diversify stripe rust-resistant resources for wheat breeding programs,a CIMMYT synthetic wheat line CI110 was identified to be resistant to 28 isolates of Pst,including 6 Chinese prevalent races CYR28-CYR33.Genetic analysis indicated that a single dominant gene was responsible for the stripe rust resistance in CI110,temporarily designated YrC110.A molecular map,harboring YrC110 and 9 linked SSR markers,was constructed through simple sequence repeat（SSR）,and bulked segregant analysis.These linked markers and YrC110 were assigned on the short arm of chromosome 1B using the Chinese Spring nullisomic-tetrasomic and ditelosomic stocks.Gene postulation based on seedling reaction patterns to 30 Pst isolates suggested that the resistance gene YrC110 seemed different from the other known resistance genes tested,such as Yr9,Yr10,Yr15,Yr24,and Yr26/YrCH42.Four SSR markers Xbarc187150,Xgwm18227,Xgwm11223,and Xbarc240292 distinguished YrC110 from Yr10,Yr15,Yr24,and Yr26/YrCH42,and could be used as diagnostic ones for YrC110 in wheat resistant breeding programs against stripe rust.

Detection of Genetic Diversity in Synthetic Hexaploid Wheats Using Microsatellite Markers

Ninety-five synthetic hexaploid wheats （2n = 6x = 42, AABBDD） were analyzed using 45 microsatellite markers to investigate the potential genetic diversity in wheat breeding programs. A total of 326 alleles were detected by these microsatellite primer pairs, with an average of 6.65 alleles per locus. The polymorphic information content （PIC）, Simpson index （SI）, and genetic similarity （GS） coefficient showed that the D genome is of the highest genetic diversity among the A, B, and D genomes in the synthetic hexaploid wheats. The results also indicated that the synthetic hexaploid wheat is an efficient way to enrich wheat genetic backgrounds, especially to use the genetic variations of the D genome from Aegilops squarrosa for wheat improvement. The UPGMA dendogram, based on a similarity matrix by a simple matching coeff＇lcient algorithm, delineated the above accessions into 5 major clusters and was in accordance with the available pedigree information. The results demonstrated the utility of microsatellite markers in detecting DNA polymorphism and estimating genetic diversity.

Quantitative trait loci analysis for root traits in synthetic hexaploid wheat under drought stress conditions

Synthetic hexaploid wheat(SHW),possesses numerous genes for drought that can help breeding for drought-tolerant wheat varieties.We evaluated 10 root traits at seedling stage in 111 F9 recombinant inbred lines derived from a F2 population of a SHW line(SHW-L1)and a common wheat line,under normal(NC)and polyethylene glycol-simulated drought stress conditions(DC).We mapped quantitative trait loci(QTLs)for root traits using an enriched high-density genetic map containing 120370 single nucleotide polymorphisms(SNPs),733 diversity arrays technology markers(DArT)and 119 simple sequence repeats(SSRs).With four replicates per treatment,we identified 19 QTLs for root traits under NC and DC,and 12 of them could be consistently detected with three or four replicates.Two novel QTLs for root fresh weight and root diameter under NC explained 9 and 15.7%of the phenotypic variation respectively,and six novel QTLs for root fresh weight,the ratio of root water loss,total root surface area,number of root tips,and number of root forks under DC explained 8.5–14%of the phenotypic variation.Here seven of eight novel QTLs could be consistently detected with more than three replicates.Results provide essential information for fine-mapping QTLs related to drought tolerance that will facilitate breeding drought-tolerant wheat cultivars.

Synthetic Hexaploid Wheat： Yesterday, Today, and Tomorrow

In recent years, wheat yield per hectare appears to have reached a plateau, leading to concerns for future food security with an increasing world population. Since its invention, synthetic hexaploid wheat （SHW） has been shown to be an effective genetic resource for transferring agronomically important genes from wild relatives to common wheat. It provides new sources for yield potential, drought tolerance, disease resistance, and nutrient-use efficiency when bred conventionally with modern wheat varieties. SHW is becoming more and more important for modern wheat breeding. Here, we review the current status of SHW generation, study, and application, with a particular focus on its contribution to wheat breeding. We also briefly introduce the most recent progress in our understanding of the molecular mechanisms for growth vigor in SHW. Advances in new technologies have made the complete wheat reference genome available, which offers a promising future for the study and applications of SHW in wheat improvement that are essential to meet global food demand.

Application of Synthetic Hexaploid Wheat Derived from T.Durum, Ae.taushii in Common Wheat Breeding for FHB Resistance

The F 1 and F 4 plants of 'synthetic hexaploid wheat/common wheat'crosses and part of their parents were inoculated with Fusarium graminearum to evaluate FHB resistance.The results showed tht the scab resistance in the F 1 varied with the synthetic wheat accessions used as crossing parents.In the F 4,some resistant head lines were generated from the crosses,although their parents had different scab resistance levels.It indicated that synthetic hexaploid wheat are useful in wheat breeding for scab resistance.

Genetic Analysis and Molecular Tagging a Novel Yellow Rust Resistance Gene Derived from Synthetic Hexaploid Wheat Germplasm M08

Yellow rust of wheat （caused by Puccinia striiformis Westend. f. sp. tritici Eriks.） has been periodically epidemic and severely damaged wheat production in China. The development of resistant cultivars could be an effective way to reduce yield losses of wheat caused by yellow rust. Rust reaction tests and genetic analysis indicated that M08, the synthetic hexaploid wheat derived from hybridization between Triticum durum （2n = 6X = 28; genome AABB） and Aegilops tauschii （2n = 2X = 14; genome DD）, showed resistance to current prevailing yellow rust races at seedling stage, which was controlled by a single dominant gene, designated as YrAm. Bulked segregant analysis was used to identify microsatellite markers linked to gene YrAm in an F2 population derived from cross M08 （resistant） × Jinan 17 （susceptible）. Three microsatellite marker loci Xgwm77, Xgwm285, and Xgwml31 located on chromosome 3B were mapped to the YrAm locus. Xgwml31 was the closest marker locus and showed a linkage distance of 7.8 cM to the resistance locus. Thus, it is assumed that YrAm for resistance to yellow rust may be derived from Triticum durum and is located on the long arm of chromosome 3B.

Variations in the quality parameters and gluten proteins in synthetic hexaploid wheats solely expressing the Glu-D1 locus

This study evaluated the quality potential of seven synthetic hexaploid wheats(2 n=6 x=42, AABBDD) expressing only allelic variation at Glu-D1 of Aegilops tauschii(SHWSD). Major quality parameters related to dough strength, gluten proteins(including high-molecular-weight glutenin subunits(HMW-GS) and low-molecular-weight glutenin subunits(LMW-GS), gliadins), and their ratios between SHWSD and the weak gluten wheat control Chuannong 16(CN16) were measured in at least three environments(except STD7). The zeleny sedimentation value(ZSV), dough development time(DDT), dough stability time(DST), and farinograph quality number(FQN) of SHWSD were considered stable under different environments, with their respective ranges being 8.00–17.67 mL, 0.57–1.50 min, 0.73–1.80 min, and 9.50–27.00. The ZSV, DDT, DST, and FQN of SHWSD were smaller than those of CN16, suggesting that SHWSD had a weaker dough strength than CN16. Although SHWSD had a lower gluten index than CN16, its wet and dry gluten contents were similar to or even higher than those of CN16 in all environments tested. The protein content of grains(12.81–18.21%) and flours(14.20–20.31%) in SHWSD was higher than that in CN16. The amount of HMW-GS in SHWSD sharply decreased under the expression of fewer HMW-GS genes, and the LMW-GS, gliadins, and total glutenins were simultaneously increased in SHWSD in comparison with CN16. Moreover, SHWSD had higher ratios of LMWGS/glutenin and gliadin/glutenin but a lower ratio of HMW-GS/glutenin than CN16. These results provide necessary information for the utilization of SHWSD in weak-gluten wheat breeding.

Comparison of Grain Zinc and Iron Concentration between Synthetic Hexaploid Wheats and Their Parents

Deficiencies of iron (Fe) and zinc (Zn) in human food afflict a large proportion of the world’s population. Wheat is a major food source of minerals. One way to enhance bread wheat’s ability to enrich these minerals would be to take advantage of diversity of wild species by creating synthetic hexaploid wheat (SW). In this study, two minerals (Fe and Zn) concentrated in the grain of Aegilops tauschii Coss. (2n = 2x = 14, DD), Triticum turgidum L. (2n = 4x = 28, AABB), and 33 lines of their corresponding SW (2n = 2x = 42, AABBDD) were evaluated. The results showed that Fe concentration was decreased in most of SW lines compared with their parental Aegilops tauschii accessions, while Zn concentration was greatly increased in most of SW lines compared with their parental Aegilops tauschii accessions. Aegilops tauschii had stronger Fe enrichment than Triticum turgidum while they expressed the same ability for Zn enrichment. The genotypic variance based on their physiological performance was analyzed. SW lines showed less genotypic variance of Fe and Zn concentration than Aegilops tauschii. SW lines showed less genotypic variance of Fe concentration than Triticum turgidum L. lines while they had more genotypic variance of Zn concentration than Triticum turgidum L. lines. Regardless of the fact that the traits expressed in wild relatives of wheat may not predict the traits that will be expressed in SW lines derived from them, production of SW could be a powerful method creating genotypes with enhanced trait expression.

利用人工合成小麦基因资源实现产量突破的育种实践

【目的】人工合成小麦是科学家模拟小麦进化过程,利用四倍体小麦与二倍体节节麦杂交、染色体加倍而成的新型六倍体小麦资源,集合了双亲的优良性状,可作为桥梁改良现代小麦。【方法】回顾了四川小麦80多年的育种历程,对利用人工合成小麦基因资源实现产量水平突破的方法技术进行了分析,希望为进一步利用小麦近缘属种育种应用提供参考。【结果】利用大群体有限回交法和重组自交系育种法改良初级人工合成小麦及其衍生系,育成了产量提升近30%的小麦品种川麦42及衍生品种川麦104,维持四川小麦产量台阶20余年。【结论】种质资源发掘、育种方法技术创新,是实现产量新突破有效途径。

人工合成小麦和地方品种穗发芽抗性育种利用效率

【目的】小麦穗发芽是影响小麦产量和品质的重要限制因子。具有抗穗发芽特性的人工合成小麦和地方品种是改良栽培小麦穗发芽抗性的重要基因资源,通过分子标记辅助选择转育人工合成小麦和地方品种穗发芽抗性位点,评价人工合成小麦和地方品种导入系抗穗发芽育种利用效率,筛选抗穗发芽小麦新材料,为小麦穗发芽抗性育种提供数据和材料支撑。【方法】以抗穗发芽的人工合成小麦SYN792和四川地方品种涪陵须须麦为母本,以穗发芽敏感品种川麦45为轮回亲本,构建2个BC1F7群体。2017年,通过整穗发芽鉴定法对2个BC1F7群体的1796个株系进行穗发芽表型初筛,然后利用与人工合成小麦PHS-3D和地方品种PHS-A1穗发芽抗性位点连锁的SSR标记进行分子标记选择,筛选出整穗发芽率(SGR)小于35%且携带PHS-3D和PHS-A1抗性位点的导入系;2018和2019年,连续2年对初筛选出的PHS-3D和PHS-A1导入系进行整穗发芽率、籽粒发芽指数(GI)和产量相关性状鉴定,其中,籽粒发芽鉴定试验设置25℃(18GI)和32℃(19GI)2个发芽温度。通过不同环境下穗发芽抗性和产量数据,分析人工合成小麦和地方品种导入系抗穗发芽育种利用效率,筛选抗穗发芽且综合性状好的优异导入系。【结果】经整穗发芽鉴定初筛,从1796个衍生系中筛选出SGR值小于35%的株系537个;进一步对筛选出的537个株系进行分子标记检测,发现332个株系导入了人工合成小麦PHS-3D和地方品种PHS-A1穗发芽抗性位点,包括人工合成小麦导入系73个、地方品种导入系259个;地方品种PHS-A1导入系的频率显著高于人工合成小麦PHS-3D导入系。2018和2019年通过对332个穗发芽抗性位点导入系穗发芽鉴定发现,不同年份穗发芽指标间均呈极显著正相关,穗发芽指标SGR和GI表现出相对稳定的趋势;人工合成小麦和地方品种导入系的3个穗发芽指标平均值(18GI、18SGR和19SGR)均低于23%,差异不显著。不同发芽温度导入系的GI值差异较大,发芽温度32℃时,人工合成小麦PHS-3D导入系的GI值显著低于地方品种PHS-A1导入系。筛选出的73个人工合成小麦导入系中,红粒系穗发芽指标值均低于白粒系;其中,11个人工合成小麦白粒导入系表现中抗及以上抗性水平,14个红粒导入系在不同发芽温度时GI值均低于35%。2年产量相关性状分析表明,人工合成小麦PHS-3D导入系的千粒重显著高于地方品种PHS-A1导入系,而穗粒数显著小于地方品种PHS-A1导入系。根据产量性状和穗发芽抗性表现,筛选出23个穗发芽抗性和综合性状均较好的优异导入系,包括7个人工合成小麦PHS-3D导入系、16个地方品种PHS-A1导入系;人工合成小麦优异导入系中有2个白粒导入系穗发芽抗性中抗以上,2个红粒导入系不同发芽温度的GI值均低于25%,表现出稳定的穗发芽抗性。【结论】人工合成小麦和地方品种均可用于改良现代栽培小麦穗发芽抗性,利用地方品种进行穗发芽抗性育种改良效率优于人工合成小麦;但人工合成小麦导入系的穗发芽抗性的稳定性优于地方品种导入系。筛选出的23个人工合成小麦和地方品种导入系是小麦穗发芽抗性和产量性状改良的重要基因资源;特别是人工合成小麦白粒导入系(编号5201)和红粒导入系(编号5497和5505)是非常有育种利用价值的穗发芽抗性育种亲本材料。

基于无人机多源影像数据的灌浆期人工合成小麦抗旱性评价

【目的】基于无人机多源影像及产量数据评价人工合成小麦种质的抗旱性,优选高通量抗旱性鉴定指标,发掘抗旱人工合成小麦种质资源,为加快拓展小麦抗旱遗传资源、提升旱地小麦育种水平提供技术支撑和种质材料。【方法】以80份人工合成小麦种质及对照小麦品种新春37为试验材料,在田间进行小区播种,设置干旱和灌溉2种水分处理;利用无人机搭载多光谱及热红外相机采集试验材料灌浆期多源影像进行拼接处理,通过阈值分割等方法提取各试验材料的光谱指数;利用相关性分析和主成分分析鉴选抗旱相关光谱指标,结合单指标及综合评价方法鉴定人工合成小麦种质的抗旱性。【结果】基于无人机多源影像数据提取了80份人工合成小麦种质的19种光谱指数。不同光谱指数抗旱系数与小区产量抗旱指数的相关性分析结果表明,OSAVI的抗旱系数与抗旱指数的关联度最高,NDVI、CIre和NDRE的抗旱系数与抗旱指数的关联度较高。部分光谱指数的抗旱系数间相关性较高,存在冗余信息,通过主成分分析,将19个光谱指数的抗旱系数转换为3个相互独立的综合指标,3个综合指标的贡献度分别为59.6%、12.0%和9.6%。利用加权隶属函数法聚合综合指标,通过公式计算获得各人工合成小麦种质的综合抗旱性度量值。基于抗旱指数鉴定出6份强抗旱人工合成小麦种质,基于综合抗旱性度量值鉴定出5份强抗旱种质,其中,SW004和SW009在2种方法的评价结果中均被评为强抗旱种质。基于OSAVI的抗旱系数对80份人工合成小麦种质进行抗旱性分级,分级结果与基于综合抗旱性度量值的分级结果基本一致。根据OSAVI的抗旱系数鉴定出的6份强抗旱种质中,有5份在基于综合抗旱性度量值分级中也被鉴定为强抗旱种质。【结论】基于无人机多源影像提取的光谱指数NDVI、OSAVI、CIre和NDRE,以及基于光谱指数的综合抗旱性度量值均可用于辅助鉴定小麦种质抗旱性。

种衣剂减量下增施菌剂和肥料对小麦光合、产量、蚜虫及白粉病防控的影响

为探究拌种药剂减量下增施不同类型肥料对麦田蚜虫和白粉病防控及光合和产量的影响,以小麦蚜虫低感品种川麦104和高感品种内麦836为试验材料,采用大田试验,对种衣剂减量20%下,配合施用光合菌剂、微生物菌剂、硅肥或磷酸二氢钾后麦田土壤酶活性、小麦植株光合特性、病虫防治情况和产量性状的变化进行了比较分析。结果表明,拌种药剂减量20%条件下增施微生物菌剂较种衣剂常规用量处理能显著提高孕穗期川麦104的根际土壤的脲酶活性,以及内麦836的根际土壤过氧化氢酶和纤维素酶活性。在孕穗期和抽穗期,低感品种川麦104的麦蚜数量均显著低于内麦836;增施微生物菌剂和硅肥均能显著降低麦蚜和白粉病发生,对蚜虫防效和白粉病防效较常规药剂拌种用量处理分别提高8.0和10.2个百分点。拌种药剂减量20%配合施用光合菌剂、微生物菌剂、硅肥和磷酸二氢钾均能有效提高小麦旗叶氮素含量和SPAD值,改善叶片光合效率。增施硅肥下川麦104和内麦836的产量最高,较常规种衣剂用量处理分别增加16.0%和18.2%,差异均显著。以上结果说明,小麦种子种衣剂减量配合施用硅肥或微生物菌剂可有效提高麦田土壤酶活性,减少蚜虫和白粉病发生,改善小麦叶片光合特性,提高产量。

Comparison on Winter Wheat Yield Estimating Models Based on Radarsat-2 and HJ Satellite in Huaihe River Region

The establishment of crop yield estimating model based on microwave and optical satellite images can conduct the mutual verification of the accuracy of the reported crop yield and the precision of the estimating model. With Shou County and Huaiyuan County of Anhui Province as the experimental fields of winter wheat producing areas, the linear winter wheat yield estimating models were established by adopting backscattering coefficient and Normalized Difference Vegetation Index（NDVI） based on images from the synthetic aperture radar（SAR）—RDARSAT-2 and HJ satellite photographed in mid-April and early May, 2014, and then comparisons were conducted on the accuracy of the yield estimating models. The accuracies of the yield estimating models established using co-polarized（HH） and cross-polarized（HV） modes of SAR in Jiangou Town, Shou County were 68.37% and 74.01%, respectively, while the accuracies in Longkang Town, Huaiyuan County were 63.10%and 69.10%, respectively. Accuracies of yield estimating models established by HJ satellite data were 69.52% and 66.43% in Shou County and Huaiyuan County, respectively. Accuracies of winter yield estimating model based on HJ satellite data and that based on SAR were closed, and the yield difference of winter wheat in the lodging region was analyzed in detail. The model results laid the foundation and accumulated experience for the verification, parameters correction and promotion of the winter wheat yield estimating model.

Integrated application of synthetic community reduces consumption of herbicide in field Phalaris minor control

Herbicide-based weeds control impacts wheat crops as well.SynComs of Pseudomonas strains reduce the need for high-dose herbicides.100%Axial provides less weed control compared to 75%Axial with C4 SynCom.Axial 75%with C4 SynCom promotes wheat growth than the 75%Axial alone.

小麦和玉米秸秆全量还田替代化肥潜力测算

山东省是我国粮食主产区,测算其主要粮食作物小麦和玉米秸秆氮磷钾养分资源量及全量还田利用潜力,可以为山东省小麦和玉米秸秆养分资源合理利用和秸秆还田条件下化肥配施提供科学参考依据。基于2019—2021年山东省统计年鉴数据和文献资料,对山东省各地级市小麦和玉米的播种面积、秸秆产量、秸秆氮磷钾养分资源量和秸秆全量还田的化肥替代潜力进行测算。结果表明:2019—2021年山东省小麦、玉米年均播种面积分别为397.67、387.15万hm^(2),秸秆年均总产量分别为3 465.43、3 165.80万t;小麦秸秆氮磷钾养分资源总量年均分别为11.29、3.94、39.21万t,玉米秸秆氮磷钾养分资源总量年均分别为15.74、7.94、38.16万t;小麦秸秆全量还田当季平均可替代氮肥量为28.38 kg/hm^(2)、平均可替代磷肥量为9.90 kg/hm^(2)、平均可替代钾肥量为98.59 kg/hm^(2),玉米秸秆全量还田当季平均可替代氮肥量为40.65 kg/hm^(2)、平均可替代磷肥量为20.51 kg/hm^(2)、平均可替代钾肥量为98.57 kg/hm^(2)。山东省小麦、玉米秸秆养分资源量较大,合理充分利用秸秆养分资源是实现化肥减施的重要途径。

Quantitative Trait Loci Associated with Micronutrient Concentrations in Two Recombinant Inbred Wheat Lines

Micronutrient malnutrition affects over three billion people worldwide, especially women and children in developing countries. Increasing the bioavailable concentrations of essential elements in the edible portions of crops is an effective resolution to address this issue. To determine the genetic factors controlling micronutrient concentration in wheat, the quantitative trait locus （QTL） analysis for iron, zinc, copper, manganese, and selenium concentrations in two recombinant inbred line populations was performed. In all, 39 QTLs for ifve micronutrient concentrations were identiifed in this study. Of these, 22 alleles from synthetic wheat SHW-L1 and seven alleles from the progeny line of the synthetic wheat Chuanmai 42 showed an increase in micronutrient concentrations. Five QTLs on chromosomes 2A, 3D, 4D, and 5B found in both the populations showed signiifcant phenotypic variation for 2-3 micronutrient concentrations. Our results might help understand the genetic control of micronutrient concentration and allow the utilization of genetic resources of synthetic hexaploid wheat for improving micronutrient efifciency of cultivated wheat by using molecular marker-assisted selection.