Quantitative trait loci mapping of dark-induced senescence in winter wheat (Triticum aestivum)

In order to explore the genetics of dark-induced senescence in winter wheat(Triticum aestivum L.),a quantitative trait loci(QTL)analysis was carried out in a doubled haploid population developed from a cross between the varieties Hanxuan 10(HX)and Lumai 14(LM).The senescence parameters chlorophyll content(Chl a+b,Chl a,and Chl b),original fluorescence(Fo),maximum fluorescence level(Fm),maximum photochemical efficiency(Fv/Fm),and ratio of variable fluorescence to original fluorescence(Fv/Fo)were evaluated in the second leaf of whole three-leaf seedlings subjected to 7 d of darkness.A total of 43 QTLs were identified that were associated with dark-induced senescence using composite interval mapping.These QTLs were mapped to 20 loci distributed on 11 chromosomes:1B,1D,2A,2B,3B,3D,5D,6A,6B,7A,and 7B.The phenotypic variation explained by each QTL ranged from 7.5% to 19.4%.Eleven loci coincided with two or more of the analyzed parameters.In addition,14 loci co-located or were linked with previously reported QTLs regulating flag leaf senescence,tolerance to high light stress,and grain protein content(Gpc),separately.     

小麦多小穗品系10-A单株籽粒产量染色体效应的研究

本文以不分枝普通多小穗品系10-A为被测材料,中国春和阿勃两套单体系列为测验系,对单株籽粒产量进行了单体分析。结果表明,被测系10-A单株籽粒产量受5A、7A、1B、2B、6B、2D和7D等染色体上的基因所控制。其中,5A、7A、2D和7D染色体上的基因表现为增效,1B、2B和6B染色体上的基因表现为减效。就作用强度而言,7A、1B、2D染色体上的基因表现为强效,5A、2B、6B和7D染色体上的基因表现为弱效。Abstract:Monosomic analysis of grain yield per plant was carried out in the common wheat (Triticum aestivam L.) multispikelet line 10-A, by using the monosomic series of the two regular lines, “Chinese Spring ” and “Abbondanza”. The grain yield per plant of the tested line 10-A was found to be controlled by seven pairs of genes, located on the chromosomes 5A、7A、2D、 7D (with increase effect) and 1B、2B、6B (with decrease effect). Of these, the chromosomes 7A、1B and 2D might carry major effect genes, and the chromosomes 5A、2B、6B and 7D might carry minor effect genes.According to analysis of the results in the past studies and the present, I was speculated that the new gene governing grain yield per plant was probably carried on the chromosome 1B of the tested line 10-A.     

Which RhD alleles are risk factors stimulating allo- anti-D?

The aim of this study was to identify the specific RhD alleles that are risk factors for stimulating allo-anti-D and develop a precise strategy for blood transfusion. To confirm the D phenotype, red blood cells suspended in saline should react to serological anti-D from three manufacturers. An antibody screen test, a saline phase test and a micro-column test were conducted to identify allo-anti-D and other allo-antibodies. RhD alleles were genotyped by PCR using sequence-specific primers. Seven hundred subjects who were either pregnant or had undergone transfusion were enrolled in our study; however, 28 samples were excluded because their RhD alleles were normal, as revealed by tests using genotyping kits. A total of 498 cases (74.1%) were RhD-null (lacking exons 1–10 of RhD), 336 were DEL RhD 1227A (20.2%), and 38 were RHD-CE (2-9) -D (5.6%). There were 136 cases (20.2%) with allo-anti-D among the 672 cases, with an allo-anti-D prevalence of 126 cases (25.3%) in 498 cases that were RhD-null, followed by 10 cases (26.3%) among 38 cases with RHD-CE (2-9) -D, and none in 366 cases with RhD1227A. RhD genetic polymorphism was observed in RhD-negative individuals. We concluded that RhD-null and partial D are risk factors for alloimmunization to the D antigen and should be transfused with Rh-negative blood. RHD1227A recipients can be transfused with RhD-positive blood. Pregnant women with the d/d and D-CE(2-9)-D alleles require appropriate anti-D prophylaxis and RhD1227A may induce a higher tolerance.     

Differences in Thermal Preference and Tolerance among Three Phrynocephalus Lizards （Agamidae） with Different Body Sizes and Habitat Use

We acclimated adults of two viviparous(Phrynocephalus guinanensis and P.vlangalii) and one oviparous(P.versicolor) species of toad-headed lizards(Agamidae) to 28 °C,33 °C and 38 °C to examine whether thermal preference(preferred body temperature,Tp) and thermal tolerance(critical thermal minimum,CTMin;critical thermal maximum,CTMax) were affected by acclimation temperature,and correlate with body size and habitat use.Both Tp and CTMax were highest in P.versicolor and lowest in P.vlangalii,with P.guinanensis in between.The two viviparous species did not differ in CTMin and thermal tolerance range,and they both were more resistant to low temperatures and had a wider range of thermal tolerance than the oviparous species.Both CTMin and CTMax shifted upward as acclimation temperature increased in all the three species.Tp was higher in the lizards acclimated to 33 °C than in those to 28 °C or 38 °C.The range of thermal tolerance was wider in the lizards acclimated to 28 °C than in those to 33 °C or 38 °C.The data showed that:1) thermal preference and tolerance were affected by acclimation temperature,and differed among the three species of Phrynocephalus lizards with different body sizes and habitat uses;2) both Tp and CTMax were higher in the species exchanging heat more rapidly with the environment,and CTMin was higher in the species using warmer habitats during the active season;and 3) thermal preference and tolerance might correlat with body size and habitat use in Phrynocephalus lizards.     

Identification of Suspected ABO Subtypes by Genotyping Kits

The aim of study is to use erythrocyte ABO genotyping to assist serological typing in the identification of suspected ABO subtypes. Nine samples with discrepancies in ABO serological forward and reverse typing were subjected to ABO 6–7 exon sequencing, and their respective results were cisAB01O1, Bw12O2, Ael05B, Bel03O1, Ael05O1, B(A)04O1, B(A)02O1, and two cases of O1O2 weak antibody for the reverse typing test. The ABO genotyping and serological ABO forward and reverse typing were combined for subtype identification. In the results of ABO genotyping, cisAB and B(A)04 are only found B gene in genotyping, thus the presence of A subtype B was excluded. The samples with a weak antibody for serological O type in reverse typing were tested ABO genotyping to exclude subtype A or B. We summarized a combination of ABO genotyping and serological typing can be used for identification of suspected ABO blood groups.     

Heat sensitivity of eggs attributes to the reduction in Agasicles hygrophila population

Agasicles hygrophila has been introduced worldwide as a control agent for the invasive weed Alternanthera philoxeroides.However,global warming has potential impact on its controlling efficacy.The aim of this research was to explore the primary factors responsible for the greatly reduced A.hygrophila population in hot summers.To imitate the temperature conditions in summers,different developmental stages of hygrophila were treated with high temperatures from 32.5℃ to 45℃ for 1-5 h.Based on the survival rate,the heat tolerance of each developmental stage was ranked from lowest to highest as follows:egg,1st,2nd,3rd instar larva,adult and pupa.Eggs showed the lowest heat tolerance with 37.5℃ as the critical temperature affecting larval hatching.Heat treatment of the A.hygrophila eggs at 37.5℃ for 1 h decreased the hatch rate to 24%.Our results indicated that when compared with the control at 25℃,1 h treatment at 37.5℃ prolonged the duration of the egg stage,shortened the duration of oviposition and total longevity,and changed the reproductive pattern of A.hygrophila.The net reproductive rate,intrinsic rate and finite rate were all significantly reduced.The results suggest that low heat tolerance of the eggs was the major factor responsible for the reduction of A.hygrophila populations,and the key temperature was 37.5°C.Therefore,appropriate measures should be taken to protect eggs in order to maintain the efficacy of A.hygrophila in the biological control of A.philoxeroides in hot summers.     

Temperature acclimation affects thermal preference and tolerance in three Eremias lizards(Lacertidae)

We acclimated adult males of three Eremias lizards from different latitudes to 28℃,33℃ or 38℃ to examine whether temperature acclimation affects their thermal preference and tolerance and whether thermal preference and tolerance of these lizards correspond with their latitudinal distributions.Overall,selected body temperature(Tsel)and viable temperature range(VTR)were both highest in E.brenchleyi and lowest in E.multiocellata,with E.argus in between;critical thermal minimum(CTMin)was highest in E.multiocell...     

Heat shock response and mammal adaptation to high elevation (hypoxia)

The mammal's high elevation(hypoxia) adaptation was studied by using the immu-nological and the molecular biological methods to understand the significance of Hsp(hypoxia) ad-aptation in the organic high elevation,through the mammal heat shock response.(1) From high ele-vation to low elevation(natural hypoxia) :Western blot and conventional RT-PCR and real-time fluo-rescence quota PCR were adopted.Expression difference of heat shock protein of 70(Hsp70) and natural expression of brain tissue of Hsp70 gene was determined in the cardiac muscle tissue among the different elevation mammals(yak) .(2) From low elevation to high elevation(hypoxia induction) :The mammals(domestic rabbits) from the low elevation were sent directly to the areas with different high elevations like 2300,3300 and 5000 m above sea level to be raised for a period of 3 weeks be-fore being slaughtered and the genetic inductive expression of the brain tissue of Hsp70 was deter-mined with RT-PCR.The result indicated that all of the mammals at different elevations possessed their heat shock response gene.Hsp70 of the high elevation mammal rose abruptly under stress and might be induced to come into being by high elevation(hypoxia) .The speedy synthesis of Hsp70 in the process of heat shock response is suitable to maintain the cells' normal physiological functions under stress.The Hsp70 has its threshold value.The altitude of 5000 m above sea level is the best condition for the heat shock response,and it starts to reduce when the altitude is over 6000 m above sea level.The Hsp70 production quantity and the cell hypoxia bearing capacity have their direct ratio.     

Genetic Relationships Among Five Basic Genomes St,E,A,B and D in Triticeae Revealed by Genomic Southern and in situ Hybridization

The St and E are two important basic genomes in the perennial tribe Triticeae (Poaceae). They exist in many perennialspecies and are very closely related to the A, B and D genomes of bread wheat (Triticum aestivum L.). Genomic Southernhybridization and genomic in situ hybridization (GISH) were used to analyze the genomic relationships between the twogenomes (St and E) and the three basic genomes (A, B and D) of T. aestivum. The semi-quantitative analysis of the Southernhybridization suggested that both St and E genomes are most closely related to the D genome, then the A genome, andrelatively distant to the B genome. GISH analysis using St and E genomic DNA as probes further confirmed the conclusion.St and E are the two basic genomes of Thinopyrum ponticum (StStE~eE~bE~x) and Th. intermedium (StE~eE~b), two perennialspecies successfully used in wheat improvement. Therefore, this paper provides a possible answer as to why most of thespontaneous wheat-Thinopyrum translocations and substitutions usually happen in the D genome, some in the A genomeand rarely in the B genome. This would develop further use of alien species for wheat improvement, especially thosecontaining St or E in their genome components.     

Effects of Chromosome Substitutions on Copper Toxicity Tolerance in Wheat Seedlings

Substitution of wheat (Triticum aestivum L.) chromosomes 7A, 1D, 3A, 3B, 3D, 4A and 4D of cultivar Cappelle Desprez by their homologues of cultivar Bezostaya-1 increased the seedling tolerance to high concentrations of copper (1 M CuSO₄ 5 H₂O). Substitution of chromosome 1A had negative effects on seedling tolerance.     

小麦幼苗耐热性的QTL定位分析

以小麦DH群体(‘旱选10号’ב鲁麦14’)为材料,在高温(热胁迫)及常温(对照)两种条件下考察小麦幼苗的根干重、苗干重、幼苗生物量、叶片叶绿素含量、叶绿素荧光参数及其耐热指数,并应用基于混合线性模型的复合区间作图法分析幼苗性状及其耐热指数QTL的数量、染色体分布及表达情况,以及QTL与环境的互作效应。结果显示:(1)亲本‘旱选10号’的耐热性明显优于‘鲁麦14’,且杂交后代的耐热性出现超亲分离。(2)控制幼苗耐热相关性状的QTL位点在染色体2D、6B、3A、4A、5A和7A上分布较多,而控制幼苗性状耐热指数的QTL在染色体6A、6B、3A、2D、5A和7A上分布较多,QTL位点在染色体上的分布有区域化的趋势。(3)控制幼苗性状的单个加性QTL和上位性QTL解释的表型变异分别平均为2.48%和2.65%;而控制耐热指数的单个加性QTL和上位性QTL解释的表型变异分别平均为8.84%和1.98%。(4)在热胁迫和对照条件下共检测到与幼苗性状及其耐热指数有关的加性效应QTL 13个和上位性效应QTL 28对,分布在除4D和6D以外的19条染色体上。研究表明,控制幼苗性状的QTL以上位性效应为主,而其耐热指数的QTL以加性效应为主。     

Mapping QTLs for chlorophyll content and chlorophyll fluorescence in wheat under heat stress

Heat stress, one of the major abiotic stresses in wheat, affects chlorophyll fluorescence and chlorophyll content and thereby photosynthesis. To identify quantitative trait loci (QTLs) associated with these traits under terminal heat stress, 251 recombinant inbred lines (RILs) derived from a cross HD 2808/HUW510 were phenotyped. Using composite interval mapping, 40 QTLs were identified; 17 were related to conditions after timely sowing and 23 to heat stress after late sowing. The various parameters of chlorophyll fluorescence were associated with 23 QTLs, which were located on chromosomes 1A, 2A, 3A, and 2D and explained 3.67 to 18.04 % of phenotypic variation, whereas chlorophyll content was associated with 17 QTLs on chromosomes 2A, 2B, 2D, 5B, and 7A explaining 3.49 to 31.36 % of phenotypic variation. Most of the identified QTLs were clustered on chromosome 2D followed by 2A and 1A. The QTL Qchc.iiwbr-2A for chlorophyll content linked with marker gwm372 was stable over conditions and explained 3.81 to 18.05 % of phenotypic variation. In addition, 7 epistatic QTL pairs were also detected which explained 1.67 to 11.0 % of phenotypic variance. These identified genomic regions can be used in marker assisted breeding after validation for heat tolerance in wheat.     

Short periods of high temperature during meiosis prevent normal meiotic progression and reduce grain number in hexaploid wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Key message

Exposure of wheat to high temperatures during male meiosis prevents normal meiotic progression and reduces grain number. We define a temperature-sensitive period and link heat tolerance to chromosome 5D.

Abstract

This study assesses the effects of heat on meiotic progression and grain number in hexaploid wheat (Triticum aestivum L. var. Chinese Spring), defines a heat-sensitive stage and evaluates the role of chromosome 5D in heat tolerance. Plants were exposed to high temperatures (30 or 35 °C) in a controlled environment room for 20-h periods during meiosis and the premeiotic interphase just prior to meiosis. Examination of pollen mother cells (PMCs) from immature anthers immediately before and after heat treatment enabled precise identification of the developmental phases being exposed to heat. A temperature-sensitive period was defined, lasting from premeiotic interphase to late leptotene, during which heat can prevent PMCs from progressing through meiosis. PMCs exposed to 35 °C were less likely to progress than those exposed to 30 °C. Grain number per spike was reduced at 30 °C, and reduced even further at 35 °C. Chinese Spring nullisomic 5D-tetrasomic 5B (N5DT5B) plants, which lack chromosome 5D, were more susceptible to heat during premeiosis–leptotene than Chinese Spring plants with the normal (euploid) chromosome complement. The proportion of plants with PMCs progressing through meiosis after heat treatment was lower for N5DT5B plants than for euploids, but the difference was not significant. However, following exposure to 30 °C, in euploid plants grain number was reduced (though not significantly), whereas in N5DT5B plants the reduction was highly significant. After exposure to 35 °C, the reduction in grain number was highly significant for both genotypes. Implications of these findings for the breeding of thermotolerant wheat are discussed.

     

Conditional and unconditional QTL mapping of drought-tolerance-related traits of wheat seedling using two related RIL populations

For discovering the quantitative trait loci (QTLs) contributing to early seedling growth and drought tolerance during germination, conditional and unconditional analyses of 12 traits of wheat seedlings: coleoptile length, seedling height, longest root length, root number, seedling fresh weight, stem and leaves fresh weight, root fresh weight, seedling dry weight, stem and leaves dry weight, root dry weight, root to shoot fresh weight ratio, root-to-shoot dry weight ratio, were conducted under two water conditions using two F_8:9 recombinant inbred line (RIL) populations. The results of unconditional analysis are as follows: 88 QTLs accounting for 3.33–77.01% of the phenotypic variations were detected on chromosomes 1A, 1B, 1D, 2A, 2B, 2D, 3A, 3B, 4A, 4B, 4D, 5A, 5B, 5D, 6A, 6B, 6D, 7A, 7B and 7D. Among these QTLs, 19 were main-effect QTLs with a contribution rate greater than 10%. The results of the conditional QTL analysis of 12 traits under osmotic stress on normal water conditions were as follows: altogether 22 QTLs concerned with drought tolerance were detected on chromosomes 1B, 2A, 2B, 3B, 4A, 5D, 6A, 6D, 7B, and 7D. Of these QTLs, six were main-effect QTLs. These 22 QTLs were all special loci directly concerned with drought tolerance and most of them could not be detected by unconditional analysis. The finding of these QTLs has an important significance for fine-mapping technique, map-based cloning, and molecular marker-assisted selection of early seedling traits, such as growth and drought tolerance.     

普通小麦基因组中耐低磷胁迫特性的染色体控制

以普通小麦中国春的一套缺四体为材料,对其耐低磷胁迫特性进行鉴定和遗传分析。结果表明：（１）第１,４,７部分同源群与低磷胁迫特性关系最密切,且第１,７部分同源群内各染色体间在该性状的遗传互补性良好。第４部分同源群则不同,４Ａ可以有效补偿４Ｂ与４Ｄ的缺失,反之则不能。（２）第２,３,５６部分同源群与低磷胁迫特性关系不密切,且这些同源群内某一染以体的缺失大多不能被其他染色体有效地补偿,尤其是第３与第６部     

Interacting quantitative trait loci control loss of peripheral tolerance and susceptibility to autoimmune ovarian dysgenesis after day 3 thymectomy in mice

Day 3 thymectomy (D3Tx) results in a loss of peripheral tolerance mediated by CD4(+)CD25(+) T cells and the development of autoimmune ovarian dysgenesis (AOD) in A/J and (C57BL/6J x A/J)F(1) (B6AF(1)) hybrids but not in C57BL/6J mice. Quantitative trait loci (QTL) linkage analysis using a B6AF(1) x C57BL/6J backcross population verified Aod1 and Aod2 that were previously mapped as qualitative traits. Additionally, three new QTL intervals, Aod3, Aod4, and Aod5, on chromosomes 1, 2, and 7, respectively, influencing specific subphenotypes of AOD were identified. QTL linkage analysis using the A x B and B x A recombinant inbred lines verified Aod3 and confirmed linkage to H2. Aod5 colocalized with Mater, an ovarian-specific autoantigen recognized by anti-ovarian autoantibodies in the sera of D3Tx mice. Sequence analysis of Mater identified allelic, strain-specific splice variants between A/J and C57BL/6J mice making it an attractive candidate gene for Aod5. Interaction analysis revealed significant epistatic effects between Aod1-5 and Gasa2, a locus associated with susceptibility to D3Tx-induced autoimmune gastritis, as well as with H2. These results indicate that the QTL controlling D3Tx-induced autoimmune phenomenon are both organ specific and more generalized in their effects with respect to the genesis and activity of the immunoregulatory mechanisms maintaining peripheral tolerance.     

Transfer and mapping of the heat tolerance component traits of <Emphasis Type="Italic">Aegilops speltoides</Emphasis> in tetraploid wheat <Emphasis Type="Italic">Triticum durum</Emphasis>

Aegilops speltoides is an important genetic resource for wheat improvement and has high levels of heat tolerance. A heat-tolerant accession of Ae. speltoides pau3809 was crossed with Triticum durum cv. PDW274, and BC₂F_4-6 backcross introgression lines (BILs) were developed, phenotyped for important physiological traits, genotyped using SSR markers and used for mapping the QTL governing heat tolerance component traits. A set of 90 BILs was selected from preliminary evaluation of a broader set of 262 BILs under heat stress. Phenotyping was conducted for physiological traits such as cell membrane thermostability, chlorophyll content, acquired thermotolerance, canopy temperature and stay green. Much variation for these traits was observed in random as well as selected sets of BILs, and comparison of the BILs with the recurrent parent showed improvement for these traits under normal as well as heat stress conditions, indicating that introgressions from Ae. speltoides might have led to the improvement in the heat tolerance potential of the BILs. Introgression profiling of the 90 BILs using SSR markers identified Ae. speltoides introgression on all the 14 chromosomes with introgressions observed on A as well as B genome chromosomes. QTL mapping identified loci for various heat tolerance component traits on chromosomes 2B, 3A, 3B, 5A, 5B and 7A at significant LOD scores and with phenotypic contributions varying from 11.1 to 28.7 % for different traits. The heat-tolerant BILs and QTL reported in the present study form a potential resource that can be used for wheat germplasm enhancement for heat stress tolerance.     

QTL mapping of terminal heat tolerance in hexaploid wheat (T. aestivum L.)

High temperature (>30 °C) at the time of grain filling is one of the major causes of yield reduction in wheat in many parts of the world, especially in tropical countries. To identify quantitative trait loci (QTL) for heat tolerance under terminal heat stress, a set of 148 recombinant inbred lines was developed by crossing a heat-tolerant hexaploid wheat (Triticum aestivum L.) cultivar (NW1014) and a heat-susceptible (HUW468) cultivar. The F(5), F(6), and F(7) generations were evaluated in two different sowing dates under field conditions for 2 years. Using the trait values from controlled and stressed trials, four different traits (1) heat susceptibility index (HSI) of thousand grain weight (HSITGW); (2) HSI of grain fill duration (HSIGFD); (3) HSI of grain yield (HSIYLD); and (4) canopy temperature depression (CTD) were used to determine heat tolerance. Days to maturity was also investigated. A linkage map comprising 160 simple sequence repeat markers was prepared covering the whole genome of wheat. Using composite interval mapping, significant genomic regions on 2B, 7B and 7D were found to be associated with heat tolerance. Of these, two (2B and 7B) were co-localized QTL and explained more than 15 % phenotypic variation for HSITGW, HSIGFD and CTD. In pooled analysis over three trials, QTL explained phenotypic variation ranging from 9.78 to 20.34 %. No QTL × trial interaction was detected for the identified QTL. The three major QTL obtained can be used in marker-assisted selection for heat stress in wheat.