Tatsuya M. Ikeda

A barley Hordoindoline mutation resulted in an increase in grain hardness

Barley seed proteins, Hordoindolines, are homologues of wheat Puroindolines, which are associated with grain hardness. Barley Hordoindoline genes are known to comprise Hina and Hinb, and Hinb consists of two Hinb genes, Hinb-1 and Hinb-2. Two types of allele were found for Hina, Hinb-1 and Hinb-2 genes, respectively, among Japanese two- and six-rowed barley lines. One of the alleles of Hinb-2 (Hinb-2b) had a frame-shift mutation resulting in an in-frame stop codon. For two-rowed barley lines, grain hardness was significantly higher among lines with the Hinb-2b than those with the wild type Hinb-2 gene (Hinb-2a). Protein spots corresponding to HINa, HINb-1, and HINb-2 were identified by 2D-gel electrophoresis among barley lines with Hinb-2a. Among the lines with Hinb-2b, HINa and HINb-1 were expressed at similar levels as those in the wild type, but HINb-2 was not detected. A DNA (cleaved amplified polymorphic sequence) marker was developed to distinguish between the Hinb-2a and Hinb-2b gene sequences. Analysis of grain hardness among F2 lines derived from a cross between a line with Hinb-2a (Shikoku hadaka 115) and a line with the Hinb-2b (Shikoku hadaka 84) showed significantly higher grain hardness in the mutant lines. From these results, the Hinb-2b frame-shift (null) mutation might play a critical role in barley grain hardness. The DNA marker will be useful in barley breeding to select lines having harder grain texture.

Distribution of Hordoindoline genes in the genus Hordeum

Hordoindoline (Hin) genes, which are known to comprise Hina, Hinb-1, and Hinb-2, are associated with grain hardness in barley. However, the interspecific variation in the Hin genes in the genus Hordeum has not been studied in detail. We examined the variation in Hin genes and used it to infer the phylogenetic relationships between the genes found in two H. vulgare subspecies (cultivated barley and H. vulgare subsp. spontaneum) and 10 wild relatives (H. bogdanii, H. brachyantherum, H. bulbosum, H. chilense, H. comosum, H. marinum, H. murinum, H. patagonicum, H. pusillum, and H. roshevitzii). The Hina and Hinb genes of these species were amplified by PCR. We found two Hinb genes in three wild species (H. bogdanii, H. brachyantherum, and H. roshevitzii) and preliminarily named them Hinb-A and Hinb-B. Cluster analysis showed that the 17 Hinb genes present in Hordeum formed two distinct clusters (named A and B). Seven Hinb genes were included in Cluster-A, and 10 Hinb genes were included in Cluster-B. All Hinb-A genes were included in Cluster-A, while all of the Hinb-B genes were included in Cluster-B. In contrast, the Hinb-1 and Hinb-2 genes in H. vulgare were included in Cluster-B. These results suggest that the Hinb genes duplicated during the early stages of diversification in the genus Hordeum. On the other hand, the Hinb-1 and Hinb-2 genes in H. vulgare seem to have been generated by a duplication of the Hinb gene after the split of the lineages leading to H. vulgare and H. bulbosum.

Chromosome 5H of Hordeum species involved in reduction in grain hardness in wheat genetic background

Grain hardness is an important factor affecting end-use quality in wheat. Mutations of the puroindoline genes, which are located on chromosome 5DS, control a majority of grain texture variations. Hordoindoline genes, which are the puroindoline gene homologs in barley, are located on chromosome 5HS and are also responsible for grain texture variation. In this study, we used three types of wheat–barley species (Hordeum vulgare, H. vulgare ssp. spontaneum, and H. chilense) chromosome addition lines and studied the effect of chromosome 5H of these species on wheat grain characteristics. The 5H chromosome addition lines showed significantly lower grain hardness and higher grain weight than the corresponding wheat parents. The effect of enhancing grain softness was largest in the wheat–H. chilense line regardless of having an increase in grain weight similar to those in the wheat–H. vulgare and wheat–H. spontaneum lines. Our results indicated that chromosome 5H of the Hordeum species plays a role in enhancing grain softness and increasing grain weight in the wheat genetic background, and the extent of effect on grain hardness depends on the type of Hordeum species. Protein analysis of hordoindolines indicated that profiles of 2D-electrophoresis of hordoindolines were different among Hordeum species and hordoindolines in the addition lines appeared to be most abundant in wheat–H. chilense line. The differences in enhancing grain softness among the Hordeum species might be attributed to the quantity of hordoindolines expressed in the 5H chromosome addition lines. These results suggested that the barley hordoindolines located on chromosome 5HS play a role in reducing grain hardness in the wheat genetic background.

Comparison of Quality-Related Alleles Among Australian and North American Wheat Classes Exported to Japan

ABSTRACT Grain hardness, amylose content, and glutenin subunit composition are critical determinants for end-use properties of wheat. To improve the end-use properties of domestic wheats, we studied these traits between the Australian and North American wheat classes exported to Japan in 2009 and 2011 by analyzing the corresponding alleles. Most hard classes had Pina-D1b or Pinb-D1b. A partial waxy allele (Wx-B1b) was found in all Australian Standard White (ASW) seeds in 2009 and two-thirds of ASW seeds in 2011. All or most American hard wheat seeds had Glu-D1d. Most U.S. Western White (WW) seeds had a null allele (Glu-A1c) or alleles that lacked one of the two Glu-B1 subunits. Most hard red winter (HRW) seeds had Glu-B3b or Glu-B3g. Quality characteristics of these classes seemed to be consistent with these results. In addition, we also found new Glu-1 and Glu-3 alleles in HRW and WW. These results suggested that although there are variations in its allelic composition from year to year, each class has u...

Identification and distribution of Puroindoline b-2 variant gene homologs in Hordeum

The barley hordoindoline genes (Hina and Hinb) are homologous to the wheat puroindoline genes (Pina and Pinb). These genes are involved in grain hardness, which is an important quality for barley processing. We identified novel variants of Hina and Hinb in 10 wild Hordeum species (H. bogdanii, H. brachyantherum, H. bulbosum, H. chilense, H. comosum, H. marinum, H. murinum, H. patagonicum, H. pusillum, and H. roshevitzii) covering all Hordeum genomes and preliminarily named them Hinc. These nucleotide sequences were highly similar to those of Puroindoline b-2 variant genes (Pinb-2v) and were located on chromosome 7I in H. chilense. The Hinc genes in H. bogdanii, H. bulbosum, H. patagonicum, and H. roshevitzii were pseudogenes possessing in-frame stop codons. We also found a partial Hinc sequence in H. murinum. This gene was not found in cultivated barley and H. vulgare subsp. spontaneum. The phylogenetic tree of Gsp-1, Hin, and Pin genes demonstrates that Hinc and Pinb-2v genes formed one cluster. Therefore, we considered that Hinc and Pinb-2v genes shared a common ancestral gene and were homologous to each other. We also studied the evolutional process of Gsp-1, Hin, and Pin genes. Our results suggested that Gsp-1 might be the most closely related to a putative ancestral gene on Ha locus.