A Novel STS Marker for Polyphenol Oxidase Activity in Bread Wheat

The enzyme activity of polyphenol oxidase (PPO) in grain has been related to undersirable brown discoloration of bread wheat (Triticum aestivum L.) based end-products, particularly for Asian noodles. Breeding wheat cultivars with low PPO activity is the best approach to reduce the undesirable darkening. Molecular markers could greatly improve selection efficiency in breeding programs. Based on the sequences of PPO genes (GenBank Accession Numbers AY596268, AY596269 and AY596270) conditioning PPO activity during kernel development, 28 pairs of primers were designed using the software ‘DNAMAN’. One of the markers from AY596268, designated as PPO18, can amplify a 685-bp and an 876-bp fragment in the cultivars with high and low PPO activity, respectively. The difference of 191-bp size was detected in the intron region of the PPO gene. The STS marker PPO18 was mapped to chromosome 2AL using a DH population derived from a cross Zhongyou 9507× CA9632, a set of nulli-tetrasomic lines and ditelosomic line 2AS of Chinese Spring. QTL analysis indicated that the PPO gene co-segregated with the STS marker PPO18 and is closely linked to Xgwm312 and Xgwm294 on chromosome 2AL, explaining 28–43% of phenotypic variance for PPO activity across three environments. A total of 233 Chinese wheat cultivars and advanced lines were used to validate the correlation between the polymorphic fragments of PPO18 and grain PPO activity. The results showed that PPO18 is a co-dominant, efficient and reliable molecular marker for PPO activity and can be used in wheat breeding programs targeted for noodle quality improvement.     

A novel molecular marker for the polyphenol oxidase gene located on chromosome 2B in common wheat

Polyphenol oxidase (PPO) is a major cause of time-dependent darkening and discoloration in Asian noodles and other wheat-based products. One of the best ways to reduce this undesirable darkening is to breed new wheat cultivars with low PPO activity using efficient and reliable markers. Based on the sequence of a PPO gene SSPPO-B1 (GenBank accession no. AB254804) located on chromosome 2B of common wheat, 26 pairs of primers were designed to detect polymorphisms between wheat cultivars with low and high PPO activity. F-8, one of these primer pairs, amplified double fragments (band ??a?? of approximately 400?bp and band ??b?? of approximately 600?bp) in the cultivars with low PPO activity, and a single fragment (only band a) in the cultivars with high PPO activity. The differences between the fragments a and b include five indels and several single nucleotide polymorphisms, which occurred in intron II of the PPO gene. F-8 can be used as a sequence-tagged site marker to discriminate between two alleles Ppo-B1a (GQ303713) and Ppo-B1b (AB254804). The screening of 284 accessions of the core collection of Chinese wheat germplasms using the marker F-8 showed that the double fragments were present in 188 accessions, and the single fragments were present in the remaining 96 accessions. Statistical analysis revealed that the cultivars with the double fragments had significantly lower mean PPO activity than those with the single fragments. We also screened the 284 accessions using two additional markers, PPO18 for Ppo-A1 on chromosome 2A and STS01 for Ppo-D1 on chromosome 2D. Results showed that the combination of markers F-8, PPO18, and STS01 could reliably predict PPO activity. These markers can be used in wheat breeding programs for low PPO activity selection to improve the quality of wheat-based products.     

Gene markers for grain polyphenol oxidase activity in common wheat

Polyphenol oxidase (PPO) in grain is regarded as a major factor resulting in time-dependent darkening of wheat end products, particularly for Asian noodles and steamed bread. Breeding wheat cultivars with low PPO activity using efficient and reliable markers is one of the best ways to reduce the undesirable darkening. In the present study, we developed a gene-specific marker (PPO05) for low PPO activity from the sequence AY515506. This marker detected double PCR fragments (<750 and >750 bp) in the cultivars with low PPO activity and a single PCR fragment (<750 bp) in the cultivars with high PPO activity. Screening of this marker on 235 Chinese wheat micro-core collections showed that the double fragments were present in 113 genotypes and the single fragments in the remaining 122 genotypes. Statistic analysis revealed that the cultivars with the double fragments had significantly lower mean PPO activity than those with single fragments. Through sequence analysis and blast search in NCBI, we found that the cultivars with the double fragments contained the PPO-2Ab allele, while the cultivars with the single fragments contained the PPO-2Aa allele. The PPO-2Ab and PPO-2Da alleles were associated with the low grain PPO activity and the PPO-2Aa and PPO-2Db alleles associated with the high PPO activity. The genotypes carrying both PPO-2Ab and PPO-2Da showed the lowest PPO activity, while the genotypes carrying both PPO-2Aa and PPO-2Db showed the highest PPO activity. Comparison of PPO05 and STS01 with the STS markers PPO18 and PPO29 showed that the larger and small fragments of PPO05 were equivalent to the 876- and 685-bp fragments of PPO18, respectively, and that STS01 was the complementary marker of PPO29. Thus, the STS markers PPO05 and STS01 along with PPO18 and PPO29 are the efficient and reliable markers for the evaluation of PPO activity and can be used in wheat breeding programs to improve the quality of noodles and other end products.     

Genetic mapping of new seed-expressed polyphenol oxidase genes in wheat (Triticum aestivum L.)

Polyphenol oxidase (PPO) enzymatic activity is a major cause in time-dependent discoloration in wheat dough products. The PPO-A1 and PPO-D1 genes have been shown to contribute to wheat kernel PPO activity. Recently a novel PPO gene family consisting of the PPO-A2, PPO-B2, and PPO-D2 genes has been identified and shown to be expressed in wheat kernels. In this study, the sequences of these five kernel PPO genes were determined for the spring wheat cultivars Louise and Penawawa. The two cultivars were found to be polymorphic at each of the PPO loci. Three novel alleles were isolated from Louise. The Louise X Penawawa mapping population was used to genetically map all five PPO genes. All map to the long arm of homeologous group 2 chromosomes. PPO-A2 was found to be located 8.9 cM proximal to PPO-A1 on the long arm of chromosome 2A. Similarly, PPO-D1 and PPO-D2 were separated by 10.7 cM on the long arm of chromosome 2D. PPO-B2 mapped to the long arm of chromosome 2B and was the site of a novel QTL for polyphenol oxidase activity. Five other PPO QTL were identified in this study. One QTL corresponds to the previously described PPO-D1 locus, one QTL corresponds to the PPO-D2 locus, whereas the remaining three are located on chromosome 2B.     

Distribution of puroindoline alleles in bread wheat cultivars of the Yellow and Huai valley of China and discovery of a novel puroindoline a allele without PINA protein

Kernel hardness is one of the most important factors determining the milling and processing quality of bread wheat (Triticum aestivum L.). In the present study, 267 wheat cultivars and advanced lines from the Yellow and Huai Valley of China, CIMMYT, Russia and Ukraine were used for identification of SKCS (Single Kernel Characterization System) hardness and puroindoline alleles. Results indicated that Pinb-D1b is the most popular genotype in wheat cultivars from the Yellow and Huai Valley, Russia and Ukraine, whereas PINA null is a predominant genotype in wheat cultivars and advanced lines from CIMMYT. Molecular characterization of PINA-null alleles indicated that one Chinese landrace Chiyacao had the allele Pina-D1l with a single nucleotide C deletion at position 265 in Pina coding region based on sequencing results, and 35 of 39 PINA-null alleles belonged to Pina-D1b according to PCR amplification with the sequence-tagged site (STS) marker Pina-N developed previously. The remaining three cultivars (Jiangdongmen, Heshangtou and Hongquanmang from China) with PINA-null alleles were characterized at the DNA level by a primer walking strategy, and the results showed that all three cultivars with PINA-null alleles possessed a uniform 10,415-bp deletion from −5,117 bp to +5,298 bp (ATG codon references zero), designated as Pina-D1r. Correspondingly, an STS marker Pina-N2 with an expected fragment size of 436-bp spanning the 10,415-bp deletion was developed for detection of the Pina-D1r allele. This study provided a useful molecular marker for straightforward detection of one of the PINA-null alleles and would also be helpful to further understand the molecular and genetic basis of kernel hardness in bread wheat.     

小麦PPO活性基因等位变异的区域分布研究

为了解中国不同生态区小麦种质资源籽粒多酚氧化酶(PPO)活性基因的等位变异的差异与分布,利用小麦PPO活性基因的功能标记PPO16、PPO29与PPO18,检测了来自中国7个不同生态麦区的379份小麦种质资源的等位变异和分布差异。结果表明:(1)在2AL染色体该基因位点有2种等位变异类型:Ppo-A1a(高PPO)和Ppo-A1b(低PPO),其频率分别为51.5%和48.5%。(2)在2DL染色体该基因位点有3种等位变异类型:Ppo-D1a(低PPO)、Ppo-D1b(高PPO)和Ppo-D1ab(中间型),其频率分别为57.8%、32.5%和9.8%。(3)该基因在2AL和2DL染色体上的位点变异有6种不同类型的组合:Ppo-A1a/D1a(中间型)、Ppo-A1a/D1b(高PPO)、Ppo-A1a/Ppo-D1ab(中间型)、Ppo-A1b/D1a(低PPO)、Ppo-A1b/D1b(中间型)和Ppo-A1b/Ppo-D1ab(中间型),其中,与低PPO活性相关的基因型组合Ppo-A1b/D1a的频率为25.6%。(4)小麦PPO活性基因不同变异类型在各生态区的分布存在明显差异,基因型Ppo-A1b在北部冬麦区和西南冬麦区的比例较大,基因型Ppo-D1a在黄淮冬麦区和北部冬麦区的比例较大,基因型组合Ppo-A1b/D1a在北部冬麦区的比例较大。研究认为,结合采用分子标记辅助选择(MAS),有利于小麦籽粒外观品质的遗传改良和新品种选育。     

New DNA markers for high molecular weight glutenin subunits in wheat

End-use quality is one of the priorities of modern wheat (Triticum aestivum L.) breeding. Even though quality is a complex trait, high molecular weight (HMW) glutenins play a major role in determining the bread making quality of wheat. DNA markers developed from the sequences of HMW glutenin genes were reported in several previous studies to facilitate marker-assisted selection (MAS). However, most of the previously available markers are dominant and amplify large DNA fragments, and thus are not ideal for high throughput genotyping using modern equipment. The objective of this study was to develop and validate co-dominant markers suitable for high throughput MAS for HMW glutenin subunits encoded at the Glu-A1 and Glu-D1 loci. Indels were identified by sequence alignment of allelic HMW glutenin genes, and were targeted to develop locus-specific co-dominant markers. Marker UMN19 was developed by targeting an 18-bp deletion in the coding sequence of subunit Ax2* of Glu-A1. A single DNA fragment was amplified by marker UMN19, and was placed onto chromosome 1AL. Sixteen wheat cultivars with known HMW glutenin subunits were used to validate marker UMN19. The cultivars with subunit Ax2* amplified the 362-bp fragment as expected, and a 344-bp fragment was observed for cultivars with subunit Ax1 or the Ax-null allele. Two co-dominant markers, UMN25 and UMN26, were developed for Glu-D1 by targeting the fragment size polymorphic sites between subunits Dx2 and Dx5, and between Dy10 and Dy12, respectively. The 16 wheat cultivars with known HMW glutenin subunit composition were genotyped with markers UMN25 and UMN26, and the genotypes perfectly matched their subunit types. Using an Applied Biosystems 3130xl Genetic Analyzer, four F₂ populations segregating for the Glu-A1 or Glu-D1 locus were successfully genotyped with primers UMN19, UMN25 and UMN26 labeled with fluorescent dyes.     

Inheritance of grain polyphenol oxidase (PPO) activity in multiple wheat (Triticum aestivum L.) genetic backgrounds

Grain polyphenol oxidase (PPO) activity can cause discoloration of wheat (Triticum aestivum L.) food products. Five crosses (PI 117635/Antelope; Fielder/NW03681; Fielder/Antelope; NW07OR1070/Antelope; NW07OR1066/OR2050272H) were selected to study the genetic inheritance of PPO activity. STS markers, PPO18, PPO29 and STS01, were used to identify lines with putative alleles at the Ppo-A1 and Ppo-D1 loci conditioning low or high PPO activity. ANOVA showed significant genotypic effects on PPO activity (P?<?0.0001) in all populations. The generations and generation?×?genotype effects were not significant in any population. A putative third (null) genotype at Ppo-A1 (no PCR fragments for PPO18) was discovered in NW07OR1066 and NW07OR1070 derived populations, and these had the lowest mean PPO activities. Results demonstrated that both Ppo-A1 and Ppo-D1 loci affect the kernel PPO activity, but the Ppo-A1 has the major effect. In three populations, contrary results were observed to those predicted from previous work with Ppo-D1 alleles, suggesting the markers for Ppo-D1 allele might give erroneous results in some genetic backgrounds or lineages. Results suggest that selection for low or null alleles only at Ppo-A1 might allow development of low PPO wheat cultivars.     

Characterization of phytoene synthase 1 gene (<Emphasis Type="Italic">Psy1</Emphasis>) located on common wheat chromosome 7A and development of a functional marker

Phytoene synthase (Psy), a critical enzyme in the carotenoid biosynthetic pathway, demonstrated high association with the yellow pigment (YP) content in wheat grain. Characterization of Psy genes and the development of functional markers for them are of importance for marker-assisted selection in wheat breeding. In this study, the full-length genomic DNA sequence of a Psy gene (Psy-A1) located on chromosome 7A, was characterized by in silico cloning and experimental validation. The cloned Psy-A1 comprises six exons and five introns, 4,175 bp in total, and an ORF of 1,284 bp. A co-dominant marker, YP7A, was developed based on polymorphisms of two haplotypes of Psy-A1, yielding 194 and 231-bp fragments in cultivars with high and low YP content, respectively. The marker YP7A was mapped on chromosome 7AL using an RIL population from cross PH82-2/Neixing 188, and a set of Chinese Spring nullisomic–tetrasomic lines and ditelosomic line 7AS. Psy-A1, co-segregating with the STS marker YP7A, was linked to SSR marker Xwmc809 on chromosome 7AL with a genetic distance of 5.8 cM, and explained 20–28% of the phenotypic variance for YP content across three environments. A total of 217 Chinese wheat cultivars and advanced lines were used to validate the association between the polymorphic band pattern and grain YP content. The results showed that the functional marker YP7A was closely related to grain YP content and, therefore, could be used in wheat breeding programs targeting of YP content for various wheat-based products. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.