Genetic Analysis of Anthocyanin Pigmentation of the Anthers and Culm in Common Wheat

Anthocyanin pigmentation of various organs develops during plant ontogeny in response to adverse and damaging abiotic and biotic stressors (environmental factors). Using the monosome method, the genes responsible for anther and culm anthocyanin pigmentation (Pan1 and Pc2, respectively) were localized to 7D chromosome in introgressive lines from crosses between common wheat Triticum aestivum L. and the species Triticum timopheevii Zhuk. Genetic analysis of ten common wheat genotypes using testers carrying genes Pan1, Pc1 and Pc2 showed that these genotypes contained Pan1 and Pc2 genes. Visual examination of plants from 70 and 76 varieties of respectively winter and spring common wheat revealed anthocyanin pigmentation of anthers and culms in 36 varieties. Pan1 and Pc2 genes were presumably introduced into common wheat from Aegilops tauschii (Eig.) Tzvel., a donor of the D genome.     

Molecular mapping,phenotypic expression and geographical distribution of genes determining anthocyanin pigmentation of coleoptiles in wheat ( Triticum aestivumL.)

Three major gene loci determining the anthocyanin pigmentation of coleoptiles were mapped on the short arms of chromosomes 7A, 7B and 7D, respectively. All three genes map about 15 to 20 cM distal from the centromere and, therefore, it may be concluded that they are members of a homoeologous series and should be designated Rc-A1, Rc-B1 and Rc-D1, respectively. Further homoeologous loci exist in Triticum durum, Triticum tauschii, and most probably in Secale cereale and Hordeum vulgare. By analyzing a synthetic×cultivated wheat cross (ITMI mapping population) under different environmental conditions it was shown that the expression of the genes determining anthocyanin pigmentation of the coleoptiles varies. One additional locus was detected on chromosome 4BL. Beside the mapping data, results of a screening for red coleoptile color genes in 468 mainly European wheat varieties are presented. Received: 2 July 2001 / Accepted: 6 August 2001     

Developmental and environmental regulation of anthocyanin pigmentation in wheat tissues transformed with anthocyanin regulatory genes

Summary Cell autonomous anthocyanin pigmentation, produced by the anthocyanin regulatory genes B and C1 controlled by the constitutive CaMV35s promoter (pBC1-7), was used to optimize biolistic gene delivery into embryogenic wheat (Triticum aestivum L. cv ‘Chris’) scutellum cultures. Intensely pigmented callus cells were observed 24 h postbombardment but these cells did not continue to divide and were developmentally terminal. A population of nonexpressing cells generated transgenic sectors which showed light-dependent anthocyanin pigmentation. Anthocyanin pigmentation was suppressed in regenerating shoot cultures but reverted to light-dependent production in the pericarp of developing seeds. Similarly, following microtargeted gene delivery into apical meristems, anthocyanin production was developmentally suppressed in leaf base meristems but prominent anthocyanin sectors developed in mature tissues beyond this region and persisted throughout leaf growth. In three developmental situations, callus proliferation, plant regeneration, and leaf growth, perpetuation of cells with anthocyanin regulator genes under the control of constitutive promoters was dependent on a higher level of regulation to suppress pigmentation at developmentally sensitive stages of meristematic activity. These findings provide additional evidence that the anthocyanin regulatory genes may be responsive to a variety of developmental and environmental stimuli. Present address: Genetics & Plant Breeding Department, G. B. Pant University of Agriculture Technology, Pantnagar, U.P., India, 263145.     

Allelic variation of high molecular weight glutenin subunits of bread wheat in Hebei province of China

In common wheat (Triticum aestivum L.), allelic variations of Glu-1 loci have important influences on grain end-use quality. The allelic variations in high molecular weight glutenin subunits (HMW-GSs) were identified in 151 hexaploid wheat varieties representing a historical trend in the cultivars introduced or released in Hebei province of China from the years 1970s to 2010s. Thirteen distinct alleles were detected for Glu-1. At Glu-A1, Glu-B1 and Glu-D1, we found that the most frequent alleles were the 1 (43.0%), 7+8 (64.9%), 2+12 (74.8%) alleles, respectively, in wheat varieties. Twenty two different HMW-GS compositions were observed in wheat. Twenty-five (16.6%) genotypes possessed the combination of subunits 1, 7+8, 2+12, 25 (16.6%) genotypes had subunit composition of 2*, 7+8, 2+12; 20 (13.2%) genotypes had subunit composition of null, 7+8, 2+12. The frequency of other subunit composition was less than 10%. The Glu-1 quality score greater than or equal to 9 accounted for 20.6% of the wheat varieties. The percentage of superior subunits (1 or 2* subunit at Glu-A1 locus; 7+8, 14+15 or 17+18 at Glu-B1 locus; 5+10 or 5+12 at Glu-D1 locus) was an upward trend over the last 40 years. The more different superior alleles correlated with good bread-making quality should be introduced for their usage in wheat improvement efforts.     

Natural or induced nucleocytoplasmic heterogeneity in Triticum longissimum.

Alien cytoplasms produce a variety of phenotypes in durum wheat (Triticum turgidum) and common wheat (Triticum aestivum) cultivars, which indicate the prevalence of cytoplasmic variability in the subtribe Triticinae. Intraspecific cytoplasmic differences have been demonstrated between the subspecies of Triticum speltoides, Triticum dichasians, and Triticum comosum. In this study, durum wheat lines with cytoplasm from two accessions, B and C, of Triticum longissimum were compared, and meiotic chromosome pairing between the group 4 homoeologues from the same two accessions was examined in common wheat. First, monosomic addition or monosomic substitution lines of common wheat with cytoplasm and one chromosome (designated B) from accession B were crossed with those having cytoplasm and a chromosome designated C-1 or C-2 from accession C. In each substitution line, an alien chromosome substituted for a group 4 homoeologue. Each alien chromosome had a "selfish" (Sf) gene, which remained fixed in the wheat nucleus. The F1s had greatly reduced meiotic pairing between chromosomes B and C-1 and B and C-2, which indicated greatly reduced homology between the group 4 homoeologues from the two accessions. Second, by using Triticum timopheevii as a bridging species, chromosome B in a common wheat line was eliminated and an euploid durum line with cytoplasm from accession B was obtained. This line was fertile. In contrast, a similarly produced durum line with cytoplasm from accession C was male sterile and retained a species cytoplasm specific (scs) nuclear gene from T. timopheevii. In conclusion, nuclear and cytoplasmic heterogeneity pre-existed between accessions B and C and they represent varieties or incipient subspecies in T. longissimum. Alternatively, the Sf genes produced chromosomal heterogeneity and mutated cytoplasmic genes from one or both accessions. Key words : meiotic drive, selfish gene (Sf), gametocidal gene (Gc), Triticum, Aegilops.     

Comparative genetic analysis of the hexaploid wheat Triticum petropavlovskyi Udasz. et Migusch. and Triticum aestivum L

A poorly studied species of hexaploid wheat Triticum petropavlovskyi Udacz. et Migusch. was compared with common wheat Triticum aestivum L. by means of monosomic and genetic analyses of F2 hybrids. Triticum petropavlovskyi was found to carry 13 dominant genes determining its morphological and physiological characters and regular bivalent conjugation of chromosomes. These genes were allelic to the respective genes of common wheat and were located in the same chromosomes. The modes of gene interaction were also the same. There was simple dominance for most genes studied and complementary interaction for the genes of hybrid dwarfism and hybrid necrosis. Triticum petropavlovskyi had the following dominant genes: Hg (downy glume); Rg1 (red glume color); Hl (downy leaf); Hn (downy node); Pa (pubescent auricles); Q (speltlike ears); D1 (grass-clump dwarfism); Ne1 (hybrid necrosis); Ph1 and Ph2 (genes of bivalent conjugation preventing homoeologous chromosomes from pairing); and Vrn1, Vrn2, Vrn3, and Vrn4 (genes of the spring habit). The gene Vrn1, which caused an increase in ear emergence time and a pronounced response to vernalization, was poorly expressed. T. petropavlovskyi was earlier demonstrated to have a species-specific gene P or Eg (elongated glume), which was not allelic to the gene Eg of the tetraploid T. polonicum L. The data obtained indicate that T. petropavlovskyi has originated from T. aestivum via mutations.     

Genetic analysis and molecular mapping of crown rust resistance in common wheat

Key Message

This is the first report on genetic analysis and genome mapping of major dominant genes for near non-host resistance to barley crown rust ( Puccinia coronata var. hordei ) in common wheat.

Abstract

Barley crown rust, caused by Puccinia coronata var. hordei, primarily occurs on barley (Hordeum vulgare L.) in the Great Plain regions of the United States. However, a few genotypes of common wheat (Triticum aestivum L.) were susceptible to this pathogen among 750 wheat accessions evaluated. To investigate the genetics of crown rust resistance in wheat, a susceptible winter wheat accession PI 350005 was used in crosses with two resistant wheat varieties, Chinese Spring and Chris. Analysis of F₁ plants and F₂ populations from these two crosses indicated that crown rust resistance is controlled by one and two dominant genes in Chris and Chinese Spring, respectively. To determine the chromosome location of the resistance gene Cr1 in Chris, a set of 21 monosomic lines derived from Chris was used as female parents to cross with a susceptible spring type selection (SSTS35) derived from the PI 350005/Chris cross. Monosomic analysis indicated that Cr1 is located on chromosome 5D in Chris and one of the crown rust resistance genes is located on chromosome 2D in Chinese Spring. The other gene in Chinese Spring is not on 5D and thus is different from Cr1. Molecular linkage analysis and QTL mapping using a population of 136 doubled haploid lines derived from Chris/PI 350005 further positioned Cr1 between SSR markers Xwmc41-2 and Xgdm63 located on the long arm of chromosome 5D. Our study suggests that near non-host resistance to crown rust in these different common wheat genotypes is simply inherited.     

Molecular analysis of leaf-rust resistant introgression lines obtained by crossing hexaploid wheat Triticum aestivum with tetraploid wheat Triticum timopheevii

Twenty-four Triticum eastivum x T. timopheevii hybrid lines developed on the basis of five varieties of common wheat and resistant to leaf rust were analyzed by the use of microsatellite markers specific for hexaploid common wheat T. aestivum. Investigation of intervarietal polymorphism of the markers showed that the number of alleles per locus ranged from 1 to 4, depending on the marker (2.5 on average). In T. timopheevii, amplification fragments are produced by 80, 55, and 30% of primers specific to the A, B, and D common wheat genomes, respectively. Microsatellite analysis revealed two major areas of introgression of the T. timopheevii genome: chromosomes of homoeological groups 2 and 5. Translocations were detected in the 2A and 2B chromosomes simultaneously in 11 lines of 24. The length of the translocated fragment in the 2B chromosome was virtually identical in all hybrid lines and did not depend on the parental wheat variety. In 15 lines developed on the basis of the Saratovskaya 29, Irtyshanka, and Tselinnaya 20, changes occurred in the telomeric region of the long arm of the 5A chromosome. Analysis with markers specific to the D genome suggested that introgressions of the T. timopheevii genome occurred in chromosomes of the D genome. However, the location of these markers on T. timopheevii chromosomes is unknown. Our data suggest that the genes for leaf-rust resistance transferred from T. timopheevii to T. aestivum are located chromosomes of homoeological group 2.     

Genetic variation in wheat endosperm proteins: an analysis by two-dimensional electrophoresis using intervarietal chromosomal substitution lines

Summary The major endosperm proteins in a range of genotypes of hexaploid wheat have been fractionated by two-dimensional electrophoresis. The genotypes included nine varieties and forty four intervarietal substitution lines in which chromosomes 1A, 1B, 1D, 6A, 6B or 6D from eight of the varieties have been introduced one at a time into a common genetic background. The appearance of different protein subunits was often correlated with a chromosome substitution. This showed that many of the genes for the high molecular weight protein subunits (molecular weight range 55,000 to 140,000 determined by SDS polyacrylamide gel electrophoresis) are specified by chromosomes 1A, 1B and 1D while many of the lower molecular weight subunits (molecular weight range 30,000 to 45,000) are specified by chromosomes 6A, 6B and 6D. The different protein subunits correlated with chromosome substitution could not always be recognised in the varietal source of the substituted chromosome. The different subunits specified by homologous chromosomes in different wheat varieties may differ in isoelectric point and/or molecular weight.     

Molecular analysis of the triticale lines with different Vrn gene systems using microsatellite markers and hybridization in situ

Hexaploid triticale (x Triticosecale Wittmack) lines were examined using molecular markers and the hybridization in situ technique. Triticale lines were generated based on wheat varieties differing by the Vrn gene systems and the earing times. Molecular analysis was performed using Xgwm and Xrms microsatellite markers with the known chromosomal localization in the common wheat Triticum aestivum, and rye Secale cereale genomes. Comparative molecular analysis of triticale lines and their parental forms showed that all lines contained A and B genomes of common wheat and also rye homeologous chromosomes. In the three lines the presence of D genome markers, mapped to the chromosomes 2D and 7D, was demonstrated. This was probably the consequence of the translocations of homeologous chromosomes from wheat genomes, which took part during the process of triticale formation. The data obtained by use of genomic in situ hybridization supported the data of molecular genetic analysis. In none of the lines wheat--rye translocations or recombinations were observed. These findings suggest that the change of the period between the seedling appearance and earing time in triticale lines compared to the initial wheat lines, resulted from the inhibitory effect of rye genome on wheat vernalization genes.     

水分胁迫对不同小麦品种光系统Ⅱ功能基因psbA、psbD及cab表达的影响

两种小麦品种绵农4号(Triticum aestivum L. cv.Miannong No.4)和绵农5号(Triticum aestivum L.cv.Miannong No．5)在渐进水分胁迫下相对含水量、质膜相对透性及光系统ⅡDCIP(2,6-二氯酚靛酚)光化学还原活性变化的差异显示,绵农5号小麦比绵农4号小麦具有较高的水分胁迫耐受力。进而对比了水分胁迫对这两种耐旱性不同的小麦品种的光系统Ⅱ在基因转录及蛋白代谢等方面的影响。结果表明：渐进水分胁迫下．两种小麦的光系统Ⅱ主要基因(psbA、psbD、cab)的转录本水平及其编码蛋白(D1,D2、LHCⅡ)的稳态含量分别下降20％及14％以上,而绵农5号M6基因的转录水平下降程度(39．5％)与绵农4号(61．8%)相比明显缓慢．这可能是其具有较高耐旱性的一个重要原因。     

两种基因型小麦光合作用对NaHSO3响应的差别

两种不同基因型小麦京411(J411,北京地区高产小麦品种)和小偃54(X54,一种远源杂交品种)的光合作用对低浓度NaHS03处理的响应不同。NaHS031mmol／L处理能够提高京411在CO2浓度为350和900μL／L的空气中的净光合速率;而对小偃54,在这两种情况下的净光合速率均无明显影响。以往的研究表明NaHS03促进光合作用的原因类似于PMS(Phenazine methosulfate),都是增加了ATP的合成。此文再次证明并发现经过NaHS031mmol／L处理后,京411叶片作用光关闭后叶绿素荧光瞬时上升的幅度提高,远红光后P700^ (reaction center cholorophyll of PSI)再还原的半时间缩短,表明NaHS03可以促进小麦京411中围绕PSI循环电子传递及其耦联的磷酸化。然而,NaHS03对小偃54的作用光关闭后叶绿素荧光瞬时上升的幅度及远红光后P700^ 再还原的半时间均无明显影响。与小麦京411相比较,小偃54的作用光停止后叶绿素荧光瞬时上升的幅度增大,而且其在远红光后P700^ 再还原的半时间更短,表明小偃54的循环电子传递的能力远高于京411的。两种不同基因型小麦对NaHS03的响应不同很可能是由于二者在循环电子传递能力上有很大的差别。     

应用基因组原位杂交鉴定蓝粒小麦及其诱变后代

应用基因组原位杂交技术（GISH）对普通小麦（Triticum aestivumL.)和长穗偃麦草[Agropyron elongatum(Host)Beauv,2n=10x=70]杂交后选育出的蓝粒小麦蓝-58及其诱变后代的染色体组成进行了鉴定。结果表明,GISH可方便地检测到小麦遗传背景中的长穗偃麦草染色体或易位的片段。如前人报道,蓝-58（2n=42)是一个具有2条长穗偃麦草4E染色体的异代换系（4E/4D）。LW004可能是一个具有两对相互易位染色体的纯合系,其田间表现磷高效特性,LW43-3-4为41条染色体的蓝单体（40W 1’4E）,种子颜色为浅蓝色,通过此法还检测出一些染色体结构发生很大变异的材料如4E的单端体（40W 1‘4E),种子颜色为浅蓝色,通过此法还检测出一些染色结构发生很大变异的材料如4E的单端体（40W 1‘t4E)以及组型为39W 1‘4E 1‘t4E的个体,此项研究结果更为直观地表明控制蓝粒体状的基因的确在来自长穗偃麦草的染色体上。同时说明有效的突变方法与灵活方便的检测手段的有机结合在染色体工程材料的创制和染色体工程育种中起着至关重要的作用。     

Genome-wide association mapping of resistance to eyespot disease (<Emphasis Type="Italic">Pseudocercosporella herpotrichoides</Emphasis>) in European winter wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.) and fine-mapping of <Emphasis Type="Italic">Pch1</Emphasis>

Key message

Genotypes with recombination events in the Triticum ventricosum introgression on chromosome 7D allowed to fine-map resistance gene Pch1, the main source of eyespot resistance in European winter wheat cultivars.

Abstract

Eyespot (also called Strawbreaker) is a common and serious fungal disease of winter wheat caused by the necrotrophic fungi Oculimacula yallundae and Oculimacula acuformis (former name Pseudocercosporella herpotrichoides). A genome-wide association study (GWAS) for eyespot was performed with 732 microsatellite markers (SSR) and 7761 mapped SNP markers derived from the 90 K iSELECT wheat array using a panel of 168 European winter wheat varieties as well as three spring wheat varieties and phenotypic evaluation of eyespot in field tests in three environments. Best linear unbiased estimations (BLUEs) were calculated across all trials and ranged from 1.20 (most resistant) to 5.73 (most susceptible) with an average value of 4.24 and a heritability of H ² = 0.91. A total of 108 SSR and 235 SNP marker–trait associations (MTAs) were identified by considering associations with a ?log₁₀ (P value) ≥3.0. Significant MTAs for eyespot-score BLUEs were found on chromosomes 1D, 2A, 2D, 3D, 5A, 5D, 6A, 7A and 7D for the SSR markers and chromosomes 1B, 2A, 2B, 2D, 3B and 7D for the SNP markers. For 18 varieties (10.5%), a highly resistant phenotype was detected that was linked to the presence of the resistance gene Pch1 on chromosome 7D. The identification of genotypes with recombination events in the introgressed genomic segment from Triticum ventricosum harboring the Pch1 resistance gene on chromosome 7DL allowed the fine-mapping of this gene using additional SNP markers and a potential candidate gene Traes_7DL_973A33763 coding for a CC-NBS-LRR class protein was identified.