S. Sawada

Mapping QTLs controlling grain yield and its components on chromosome 5A of wheat

Abstract Chromosome 5A of wheat is known to carry a number of genes affecting adaptability and productivity. To localize quantitative trait loci (QTLs) controlling grain yield and its components, an RFLP map was constructed from 118 single-chromosome recombinant lines derived from the F1 between Chinese Spring (Cappelle-Desprez 5A) and Chinese Spring (Triticum spelta 5A). The map was combined with the field-trial data scored over 3 years. A total of five regions in chromosome 5A contributed effects on yield traits. Increases in grain yield, 50-grain weight and spikelet number/ear were determined by complementary QTL alleles from both parents. The effects associated with the vernalization requirement gene Vrn-A1 or a closely linked QTL were significant only in the favorable growing season where the later-flowering vrn-A1 allele from Cappelle-Desprez 5A produced a higher tiller number/plant and spikelet number/ear. The effects of the ear morphology gene q or closely linked QTL(s) were detected for grain yield and ear grain weight. Three other QTLs with minor effects were dispersed along chromosome 5A. These QTLs had large interactions with years due to changes in the magnitude of the significant response. The alleles from T. spelta, however, conferred a higher yield performance.

Detection of loci controlling seed dormancy on group 4 chromosomes of wheat and comparative mapping with rice and barley genomes

Abstract Three quantitative trait loci (QTLs) controlling seed dormancy were detected on group 4 chromosomes of wheat (Triticum aestivum L.) using 119 doubled haploid lines (DHLs) derived from a cross between AC Domain and Haruyutaka. A major QTL, designated QPhs.ocs-4A.1, was identified within the marker interval between Xcdo795 and Xpsr115 in the proximal region of the long arm of chromosome 4A. Two minor QTLs, QPhs.ocs-4B.2 on 4B and QPhs.ocs-4D.2 on 4D, were flanked by common markers, Xbcd1431.1 and Xbcd1431.2 in the terminal region of the long arms, suggesting a homoeologous relationship. These three QTLs explained more than 80% of the total phenotypic variance in seed dormancy of DHLs grown in the field and under glasshouse conditions. The AC Domain alleles at the three QTLs contributed to increasing seed dormancy. Comparative maps across wheat, barley and rice demonstrated the possibility of a homoeologous relationship between QPhs.ocs-4A.1 and the barley gene SD4, while no significant effects of the chromosome regions of wheat and barley orthologous to rice chromosome 3 region carrying a major seed dormancy QTL were detected.

QTL mapping of genes controlling ear emergence time and plant height on chromosome 5A of wheat

Abstract Chromosome 5A of wheat carries major gene loci for agronomic traits including the vernalization requirement (Vrn-A1) and ear morphology (Q). To determine whether the genetic variation for ear emergence time and plant height is attributable to either of these major genes as pleiotropic effects or independent QTL, we combined a RFLP map constructed from 120 recombinant substitution lines derived from a cross between ‘Chinese Spring’ (Cappelle-Desprez 5A) and CS(Triticum spelta 5A) with data collected from field trials over 3 years. For ear emergence time the main effects on flowering time were by Vrn-A1 and QEet.ocs-5A.1, the latter a QTL in the 28.6-cM Xcdo584/Q interval linked to Q by less than 10 cM. The CS(T. spelta 5A) allele at QEet.ocs-5A.1 contributed to an earlier ear emergence time by 2.7–6.0 days, which was approximately equal to the effects of Vrn-A1. For plant height, three QTLs were identified on the long arm and linked in repulsion. The CS(T. spelta 5A) allele at Vrn-A1 or closely linked to Xfba068 contributed to a height reduction of 3.5–6.1 cm, whereas both the Q allele and Qt.ocs-5A.1 allele within the Xcdo1088/Xbcd9 interval from CS(Cappelle-Desprez 5A) produced a shorter plant. When plant height was partitioned into culm length and ear length, the Vrn-A1 allele and CS(Cappelle-Desprez 5A) allele at QCl.ocs-5A.1 within the Xcd1088/Xbcd9 interval were found to contribute to a shorter culm. CS(T. spelta 5A) allele at q was a major determinant of a long ear, together with minor effects at QEl.ocs-5A.1 within the Xcdo1088/Xbcd9 interval.

Identification of genetic loci affecting amylose content and agronomic traits on chromosome 4A of wheat

Abstract Chromosome 4A of wheat carries the Wx-B1 gene encoding the granule-bound starch synthase involved in amylose synthesis in the endosperm. To determine the pleiotropic effects of this locus and effects of independent QTLs on agronomic traits, genetical analysis of chromosome 4A was conducted using 98 single-chromosome recombinant substitution lines derived from a cross of Chinese Spring and Chinese Spring (Kanto107 4A) with a low amylose content due to the null Wx-B1b allele. For amylose content, most of the genetic variation was explained by the allelic difference at the Wx-B1 locus. An additional QTL of minor effect was mapped in the 6.2-cM Xbcd1738/Xcdo1387 interval on the short arm, where the allele from Kanto107 led to an increase in amylose content. Field trials over two seasons revealed a pleiotropic effect of Wx-B1, or else the effect of a closely linked QTL, on ear emergence time. A QTL linked to Wx-B1 was detected for plant height. For plant yield and its components, there was no evidence for significant main effects associated with Wx-B1 or adjacent regions. One plant-yield QTL was identified by RFLP markers on the short arm and this was identical to QTLs controlling spikelet number/ear and grain weight/ear. At these QTLs for agronomic traits, alleles from Kanto107 contributed to an earlier emergence time, a height reduction and an yield increase.

Differential effects of the null alleles at the three Wx loci on the starch-pasting properties of wheat.

Abstract The amylose/amylopectin ratio and the pasting properties of wheat starch are important in producing marketable flour products, especially Japanese noodles. To determine if null mutations at the three Wx loci confer differences in starch-pasting viscosity, we analyzed the variation associated with the null mutations in three separate sets of recombinant substitution lines of chromosomes 7A, 4A and 7D produced from crosses between Chinese Spring and three single-chromosome substitution lines carrying the null Wx alleles. Differential effects of null alleles at the three Wx loci on starch-pasting properties were revealed. With respect to chromosome 4A, the effect of the Wx-B1b allele, giving a higher peak and breakdown viscosity, was unambiguous. In addition, a QTL of minor effect was identified near the centromere on the short arm. The presence or absence of the Wx-A1 protein gave some variation in peak and breakdown viscosity, but the effects of Wx-Alb were much smaller than those of the Wx-Blb allele. Associated effects of the Wx-D1 locus were detected for the breakdown viscosity as the null Wx-D1b allele produced a higher viscosity than the wild-type Wx-D1a. While negative correlations between amylose content and breakdown viscosity were common in the three populations, the null mutations at the Wx loci produced some variation independent of amylose content. The genetic variation detected for breakdown viscosity was more evident than that for peak viscosity in all three recombinant populations.

Molecular cloning of the wheat CK2α gene and detection of its linkage with Vrn-A1 on chromosome 5A

Abstract.The casein kinase CK2 is one of the major multifunctional protein kinases in cells that is expressed ubiquitously and is essential for survival. The α-subunit of CK2 is thought to be involved in light-regulated gene expression and rhythmic expression of genes by circadian rhythm in plants. The rice chromosome-3 region containing the photoperiod-response Hd6 gene, an orthologue of the CK2α genes of Arabidopsis and maize, is in synteny with the wheat chromosome-5A Vrn-A1 region. This evidence proposes two possibilities, first the wheat Vrn-A1 is an orthologue of the rice CK2α, and second the wheat CK2α which has not yet been identified is located independently but tightly linked to Vrn-A1. To clarify whether the wheat CK2α gene is conserved in the Vrn-A1 region and to elucidate the above two possibilities, we attempted to isolate this gene from the wheat cDNA library and to map it on the chromosome-5A region that is syntenous to the rice Hd6 region. The isolated cDNA clone showed an extremely high homology with the Arabidopsis CK2α gene. Using this clone as a probe genomic Southern-blot analyses of the aneuploid lines available in Chinese Spring assigned the wheat homologue of CK2α to the long arm of chromosome 5A. Furthermore, a linkage analysis using an F2 population having recombination in the Vrn-A1 region revealed that the wheat CK2α, designated as tck2a, is tightly linked to Vrn-A1 by 1.1 cM