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Article

Wx Gene in Hordeum chilense: Chromosomal Location and Characterisation of the Allelic Variation in the Two Main Ecotypes of the Species

Departamento de Genética, Escuela Técnica Superior de Ingeniería Agronómica y de Montes, Edificio Gregor Mendel, Campus de Rabanales, Universidad de Córdoba, CeiA3, ES-14071 Córdoba, Spain
*
Author to whom correspondence should be addressed.
Submission received: 17 April 2019 / Revised: 15 May 2019 / Accepted: 17 May 2019 / Published: 22 May 2019
(This article belongs to the Special Issue Chromosome Manipulation for Plant Breeding Purposes)

Abstract

:
Starch, as the main grain component, has great importance in wheat quality, with the ratio between the two formed polymers, amylose and amylopectin, determining the starch properties. Granule-bound starch synthase I (GBSSI), or waxy protein, encoded by the Wx gene is the sole enzyme responsible for amylose synthesis. The current study evaluated the variability in Wx genes in two representative lines of Hordeum chilense Roem. et Schult., a wild barley species that was used in the development of tritordeum (×Tritordeum Ascherson et Graebner). Two novel alleles, Wx-Hch1a and Wx-Hch1b, were detected in this material. Molecular characterizations of these alleles revealed that the gene is more similar to the Wx gene of barley than that of wheat, which was confirmed by phylogenetic studies. However, the enzymatic function should be similar in all species, and, consequently, the variation present in H. chilense could be utilized in wheat breeding by using tritordeum as a bridge species.

1. Introduction

Starch is the main component of wheat grain, constituting up to 75% of its dry weight. This polysaccharide contains two different glucose polymers: amylose (22%–35% of the total) and amylopectin (68%–75% of the total) [1]. Changes in the ratio between these polymers have a clear influence on starch gelatinization, pasting and gelation properties [2], affecting the end-use quality levels of different wheat products, such as bread, pasta, and noodles [3,4,5], as well their shelf-lives [6] and nutritional values [7].
Starch synthesis involves several starch synthases, starch branching enzymes, and starch debranching enzymes [8]. The most studied of these proteins has been the granule-bound starch synthase I (GBSSI) or waxy proteins (ADP glucose starch glycosyl transferase, EC 2.4.1.21), which are solely responsible for amylose synthesis [9]. In wheat, these proteins are synthesized by genes located in the short arm of the seven-group homeologous chromosome, with the exception of the Wx-B1 gene that, owing to a translocation event, is located in the 4AL chromosome [10]. In wheat relatives, this gene is located in similar positions, and its molecular configuration of 12 exons and 11 introns is highly conserved in all of these species [11]. In other Poaceae species, such as barley (Hordeum vulgare L.), this gene has shown the identical structure and location [12].
The variability of waxy proteins has been studied in common and durum wheat, as well as in some wild and cultivated relatives [13]. However, the variability in modern wheat cultivars is not very wide, according to data in the Wheat Gene Catalogue [14]. In the search for new waxy variants, species from the primary and secondary wheat pools could contain good candidates. These species have been successfully used to transfer useful traits to wheat. In some cases, these transfer events have generated amphiploids that have also been used as bridge species [15]. In other cases, these amphiploids have been derived to produce human-made crops, such as tritordeum (×Tritordeum Ascherson et Graebner), that have shown promising characteristics [16].
Tritordeum was synthesized using mainly durum wheat and Hordeum chilense Roem. et Schult. (2n = 2× = 14, HchHch), a wild barley species native to Chile and Argentina, included in the section Anisolepis Nevski [17]. In this species, variation in genes related to quality has been widely evaluated over the last decade [18,19,20,21] and has been used to expand the genetic base of tritordeum. Furthermore, this species exhibits advantageous agronomic and quality characteristics [22,23,24], which, together with its ability to be crossed with other members of the Triticeae tribe [25], make it useful in cereal breeding.
In its natural distribution area, H. chilense shows some ecotypes, based on morphological and ecophysiological traits [26,27]. The two main groups are related to the first two H. chilense lines used to develop tritordeum, H1 and H7. Tritordeum developed using these lines showed differences in fertility, grain size, and life cycle, depending on the female parent (H1 or H7) used [25]. An analysis of the genes related to the flour quality from both lines also showed that these ecotypes could have different effects on the tritordeum quality. These differences have been evaluated for the seed storage proteins [18,28], hordoindolines [29], and pigment enzymes [30,31].
The main goals of this study were to analyze allelic variation and molecularly characterize of the Wx genes in the H1 and H7 lines of H. chilense, and to determine the gene’s chromosomal location.

2. Materials and Methods

2.1. Plant Materials

Seeds of two H. chilense lines (H1 and H7) that were self-pollinated for two generations were used in this study. The ditelosomic addition lines (CS + 7HchS and CS + 7HchL), together with both parental lines (common wheat cv. “Chinese Spring” and line H1) were used to locate the Wx gene in H. chilense. These materials were grown in greenhouse conditions.

2.2. DNA Extraction and PCR Amplification

For DNA extractions, ~100 mg of young leaf tissue was excised and immediately frozen in liquid nitrogen. DNA was isolated using the cetyltrimethyl ammonium bromide (CTAB) method as described by Stacey and Isaac [32].
The primers BDFL (5′-CTGGCCTGCTACCTCAAGAGCAACT-3′) and BRD (5′-CTGACGTCCATGCCGTTGACGA-3′) designed by Nakamura et al. [33] were used to detect the presence of the Wx-Hch1 gene in the ditelosomic addition lines. The amplification was performed in a 20 μL final reaction volume, containing 50 ng of genomic DNA, 1.25 mM MgCl2, 0.2 mM dNTPs, 4 μL 10× PCR buffer, 0.2 μM of each primer and 0.75 U GoTaq® G2 Flexi DNA polymerase (Promega). The PCR conditions included an initial denaturation step of 3 min at 94 °C followed by 35 cycles as follows: 30 s at 94 °C, 30 s at 65 °C then 2 min at 72 °C. After the 35 cycles, a final extension of 5 min at 72 °C was included.
Amplification products were fractionated in vertical PAGE gels with 8% polyacrylamide concentration (w/v, C: 1.28%) and the bands were stained with GelRed™ nucleic acid staining (Biotium) and visualized under UV light.

2.3. Cloning of PCR Products and Sequencing Analysis

Owing to the length and structure of the Wx gene, ~2800 bp with 11 introns and 12 exons, three fragments were amplified using primers designed by Guzmán and Alvarez [34]. The first fragment includes the first to third exons (Wx1Fw: 5′-TTGCTGCAGGTAGCCACACC-3′ and Wx1Rv: 5′-CCGCGCTTGTAGCAGTGGAA-3′), the second extends from the third to the sixth exon (Wx2Fw: 5′-ATGGTCATCTCCCCGCGCTA-3′ and Wx2Rv: 5′-GTTGACGGCGAGGAACTTGT-3′), and the last fragment covers the region spanning the 6th to the 11th exon (Wx3Fw: 5′-GGCATCGTCAACGGCATGGA-3′ and Wx3Rv: 5′-TTCTCTCTTCAGGGAGCGGC-3′).
All amplifications were performed in 50 μL final volumes, containing 100 ng of DNA genomic, 1.25 mM MgCl2, 0.2 mM dNTPs, 10 μL 10× PCR buffer and 0.75 U GoTaq® G2 Flexi DNA polymerase (Promega). The primer concentrations were 0.4, 0.3 and 0.2 μM per primer for the first, second and third fragments, respectively. The PCR conditions included an initial denaturation step of 3 min at 94 °C and then 35 cycles as follows: for Wx1Fw/Wx1Rv, 40 s at 94 °C, 30 s at 64 °C and 1 min at 72 °C, for Wx2Fw/Wx2Rv, 30 s at 94 °C, 30 s at 66 °C and 90 s at 72 °C, and for Wx3Fw/Wx3Rv, 40 s at 94 °C, 30 s at 62 °C and 90s at 72 °C. After the 35 cycles, all reactions included a final extension of 5 min at 72 °C.
The PCR products were purified by separation in 1% agarose gel, excised and then independently ligated into the pSpark®-TA Done vector (Canvax). They were then transformed into Escherichia coli ‘CVX5α’ competent cells (Canvax). Inserts were sequenced by Sanger method from at least three different clones. The novel sequences are available from the GenBank database [Wx-Hch1a: MK045501 for the H1 line, and Wx-Hch1b: MK045502 for the H7 line].

2.4. Data Analysis

The sequences were analyzed and compared with sequences of CS (Wx-A1: AB019622, Wx-B1: AB019623, and Wx-D1: AB019624), two-rowed barley cv. Vogelsanger Gold (Wx-H1: X07931) and six-rowed barley cv. Morex (Wx-H1: AF474373) available in the databases using Geneious Pro version 5.0.4 software (Biomatters Ltd., Auckland, New Zealand). The synonymous substitution rate (Ks) and non-synonymous substitution rate (Ka), as well as the Ka/Ks ratios, were computed using DNAsp ver. 5.0 [35]. Divergence times were calculated by the mean divergence time, 2.7 million years ago (MYA) between the A and D genomes estimated by Dvorak and Akhunov [36]. Predicted proteins, as well as secondary structure predictions, were also obtained with this software, using the EMBOSS tool Garnier [37]. Amino acid substitutions between the predicted proteins obtained from the new alleles and reference proteins were analyzed using the PROVEAN (Protein Variation Effect Analyzer) software tool to predict whether these amino acid substitutions or InDels have an impact on their biological function [38,39].
A phylogenetic tree was constructed with the software MEGA6 [40] using the complete coding regions of the two sequences obtained, together with the following sequences of the Wx genes: common wheat CS (Wx-A1: AB019622, Wx-B1: AB019623, and Wx-D1: AB019624), two-rowed barley “Vogelsanger Gold” (Wx-H1: X07931) and six-rowed barley ‘Morex’ (Wx-H1: AF474373). A neighbor-joining cluster of all of the analyzed sequences was generated using the Poisson correction method for amino acid sequences [41] with one bootstrap consensus from 1,000 replicates [42].

3. Results

To determine the location of the Wx gene, different combinations of primers were used. However, for some of them, owing to similar fragment sizes, establishing the unambiguous presence of the Wx gene from H. chilense was difficult. The BDFL/BRD primers, designed by Nakamura et al. [33], provided the most reliable results (Figure 1).
Because data obtained from other Triticeae species indicated that the Wx genes were mainly located on the short arm of the chromosome 7 [10], the CS + 7HchS and CS + 7HchL lines were used to determine the arm location of this gene in H. chilense. Figure 1 shows the presence of one additional band in the CS + 7HchL line (Lane 3) that is a similar size to a band in the H. chilense (H1) line (Lane 4), which is absent in both the common wheat CS (Lane 1) and the CS + 7HchS line (Lane 2). Thus, the Wx-Hch1 gene is located on 7HchL (H1), suggesting an inversion in this H. chilense chromosome.
The Wx-Hch1 gene was analyzed in two lines of H. chilense that represent two different biotypes of this species present in Chile. Due to the length of this gene (~2700 bp), the genomic sequence was obtained amplifying three fragments, which covered the complete coding sequence. The first fragment of ~620 bp, covered part of the second exon (the first one in the coding sequence, see Figure 1) until the end of the fourth exon, while the second fragment (~960 bp) spanned the fourth to the seventh exons. Finally, the third fragment (~1160 bp) was the region between the end of fragment 2 and the 12th exon, including the TGA codon. The alignment and comparison are shown in Figure S1. The initiation codon, ATG, and the termination codon, TGA, for translation, as well as the splice junctions of each intron of Wx-Hch1, were in homologous positions to those in other Wx genes. Both alleles detected in H. chilense (Wx-Hch1a and Wx-Hch1b) were smaller in size than the Wx genes used for comparison (Table 1).
The comparison between the seven nucleotide sequences showed that the greatest homology level was detected between the Wx-Hch1 genes and the Wx-H1 variants from barley (90.8%). However, the comparison of the Wx genes from common wheat cv. Chinese Spring showed lower values of 83.6% for Wx-D1, 84.7% for Wx-B1 and 87.7% for Wx-A1. Nevertheless, the predicted proteins of these same sequences showed homology greater than 94% for all comparisons, and greater than 97.7% among barley species. This is in concordance with most of the sequence differences being found in introns. In all cases, the exons were the same size, with the exception of exon 2, which contained one or two additional codons in wheat but was similar in both H. chilense and H. vulgare (Table 1).

3.1. Amino acid Predicted Sequence Analysis

While coding sequences of the Wx genes varied, most variation resulted in silent mutations that did not impact protein sequence or structure. Additionally, these proteins were synthesized as precursors or pre-proteins, including one transit-peptide of 70 amino acids and one mature domain. Nevertheless, potentially impactful sequence variation was detected in a conserved region of the mature domain related to waxy protein activity. These changes can lead to marked differences in the predicted sequences of the respective proteins (Figure S2).
The Hordeum sequences, including both H. chilense biotypes, showed the insertion of one amino acid residue within the signal peptide between positions 53 and 54. Furthermore, these sequences had deletions of Gly73 or Ala73 residues detected in the wheat proteins. Both InDels were the consequences of the aforementioned elimination of one or two codons in exon 2. Three non-conservative amino acid changes were detected in both H. chilense variants. For two of these changes, Pro24 → Arg and Ser416 → Pro, the H7 line showed the same amino acids as the other evaluated sequences. The Ser416 → Pro change could have deleterious effects according to the PROVEAN analysis, with a score of −2.869. The 419 position was different in both H. chilense sequences and was also different than the other sequences, with the exception of Wx-A1, which was similar to that of Wx-Hch1a (Table 2).
The amino acid sequences from H. chilense were more similar to the waxy proteins from barley than those derived from any wheat genome. Only 15 changes were detected between H. chilense and barley variants, while up to 54 changes were observed when this comparison was carried out with wheat waxy proteins, and ten changes were common to both barley and wheat species (Figure S2).
Up to 15 amino acids variants were detected within the transit peptide. The sequence changes generated some variations in the secondary structure of the transit peptide. The most dramatic was the Val5 → Ala change (detected in barley waxy proteins but not in H. chilense ones) that resulted in an elongated first helix and the disappearance of a β strand in the secondary structure (Figure 2). With the exception of the aforementioned change in position 24 (Pro in Wx-Hch1a and Arg in the others), all changes were common to both H. chilense variants. The barley variants showed three of these conservative changes (Val5 → Ala, Ile18 → Val and Met68 → Val), although the waxy protein of cv. Vogelsanger Gold (Wx-H1a variant) included one additional non-conservative change at position 70 (Arg70 → Ser). Four of these differences, all classified as conservative, were common to Wx-B1 and Wx-D1 (Pro25 → Ala, Leu30 → Val, Asn34 → Ser, and Ser62 → Thr), although each variant showed two additional changes (Ala39 → Pro and Ile45 → Thr for Wx-B1, and Ile45 → Val and Lys52 → Thr for Wx-D1). Nevertheless, Wx-A1 was the most varied, with five unique changes (three conservative: Ile18 → Val, Ala58 → Pro and Gly61 → Phe, and two non-conservative: Gly17 → Ser and Ser62 → Asp) and one change in common with Wx-D1 (Ile45 → Val) (Figure 2).
Numerous changes were also observed in the mature proteins both in barley and wheat (Table 2). Five of these changes were common to both species (Asn123 → Lys, Thr142 → Arg, Pro 232 → Leu, Ser416 → Pro and Asp590 → Glu), whereas two changes were exclusively detected in barley (Arg438 → Lys and Ala496 → Val) and nine were exclusively detected in wheat (Val115 → Ile, Phe145 → Tyr, Ile158 → Val, Trp162 → Cys, Ala373 → Gly, Ile427 → Val, Leu471 → Val, Ala535 → Val and Gln551 → His). The other changes were detected in one or two wheat sequences (Table 2). Two of these changes could have effects on enzyme function (Figure 3). In addition to the abovementioned change, Ser416 → Pro, which was unique to Wx-Hch1a, another change with deleterious effects predicted by the PROVEAN analysis was Pro232 → Leu, with a score of −4.061. The other changes observed were considered neutral.
Up to five of the eight motifs described by Leterrier et al. [44] are involved in the ADP glucose-binding and catalytic sites within the mature protein. Three changes were observed inside these conserved motifs (Figure 3). However, only the change Ile427 → Val was considered relevant because, although this change was also detected in barley waxy protein, the wheat waxy proteins all showed Val as the residue in this position. The change Thr356 appeared in barley and the Wx-D1 protein, while Val 496 was exclusively found in the barley protein. The PROVEAN analysis suggested that these changes be considered neutral because their influence on the enzyme function was very limited.

3.2. Phylogenetic Analysis

The complete amino acid sequences of the two novel variants from H. chilense obtained in this study, together with other waxy protein sequences present in the NCBI database, were used to construct a phenogram based on the Poisson correction method for amino acid sequences (Figure 4). Three main clusters were observed, representing the correlations between the H. chilense sequences and the common barley sequences used.
These data were corroborated when the genomic nucleotide sequences of these variants were analyzed. Furthermore, the Ks and Ka substitution rates among Wx genes were calculated using the coding sequences of the complete genes. The comparison value between the genes from H. chilense and H. vulgare was high (Ks = 0.127), which suggested that the divergence time between species was ~2.3 MYA based on the mean divergence rate (0.0533 Ks per MY) obtained for this gene in a previous study [45].

4. Discussion

Knowledge regarding the influence of the amylose/amylopectin ratio on starch properties has encouraged the search for allelic variants that could increase/decrease either starch component. The most studied, in this context, has been the ADP glucose starch glycosyl transferase (GBSSI or the waxy proteins) solely responsible for amylose synthesis. This starch synthase has been studied in several cereal species, mainly those in which the starch properties are important for their use in the agri-food industry or in bio-ethanol production [46].
Recently, biotechnological techniques have allowed the development of new species using phylogenetically related species. These new species could also be used as a bridge to transfer new variations to common wheat. Thus, H. chilense, as a species involved in the synthesis of tritordeum, could be useful [25]. The incorporation of the Hch genome in durum wheat has clear effects on the quality characteristics of the tritordeum. For example, the presence of the glutenins or hordeins of this wild species modifies the strength of the gluten in tritordeum flour [22], and their hordoindolines change the texture of the grain from the ultra-hard of the parent durum wheat to soft in the derived tritordeum [29].
Here, we have studied one of the main keys in cereal flour quality, starch, by molecularly characterising the Wx gene in the two main lines of H. chilense used in the development of the tritordeums [25]. The H. chilense waxy proteins presented structures very similar to those of waxy proteins in other species of Triticeae, such as wheat and barley. The sizes of the predicted proteins were similar, although numerous amino acid changes were detected. However, these changes were mostly silent and not related to the active site of this enzyme, and probably, without influence on its function. In fact, some of these changes have been observed in other Wx genes [13]. The highly conserved structure of this gene makes it a good candidate for phylogenetic analysis [11,45,47,48,49,50,51]. In this study, the use of Ka established the separation between the Hordeum genomes at ~3 MYA.
In barley, Kramer and Blander [52] located the Wx gene on the short arm of chromosome 1 (7H). In common wheat, the waxy loci are located on chromosome 7AS (Wx-A1), chromosome 4AL, which was translocated from the original 7BS, (Wx-B1) and chromosome 7DS (Wx-D1) [10]. Here, the Wx-Hch1 gene from H. chilense was located on 7HchL, opposite the arm location found in the other Triticeae species [13]. Mattera et al. [53] indicated a similar change in the location of the Phytoene syntase (Psy-1) gene in H. chilense. Psy-1 was mapped in the distal region of 7HchS, while this gene was located on the opposite arm of chromosome 7 in other Poaceae species [14]. On the basis of these changes, Mattera et al. [53] suggested that an inversion occurred between the distal parts of 7HchS and 7HchL, which has been confirmed by Avila et al. [54]. The location of the Wx-Hch1 gene on 7HchL in the present study supports this hypothesis on a structural change involving the distal regions of H. chilense chromosome 7Hch.

5. Conclusions

Variability in the Wx gene sequences was detected in two H. chilense lines representative of the two main ecotypes of species. This gene is located on the long arm of the 7Hch chromosome, opposite to the other Triticeae species, which suggests the presence of an inversion between the distal parts of 7HchS and 7HchL. Molecular characterization of these alleles showed that this gene is more similar to the Wx gene of barley than those of wheat. However, the enzymatic function would be similar in all species and, consequently, the variation present in H. chilense could be utilized in wheat breeding through the use of tritordeum as a bridge species.

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/2073-4395/9/5/261/s1, Figure S1. Alignment of nucleotide sequences of the Wx alleles evaluated in this study, Figure S2. Alignment of predicted protein sequences of the waxy proteins evaluated in this study.

Author Contributions

J.B.A. conceived and designed the study; J.B.A., L.C., and R.R. performed the experiments; J.B.A. and A.C. analyzed the data and wrote the paper. All authors have read and approved the final manuscript.

Funding

This research was supported by grants AGL2014-52445-R and RTI2018-093367-B-I00 from the Spanish State Research Agency (Ministry of Science, Innovation and Universities), co-financed by the European Regional Development Fund (FEDER) from the European Union.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. James, M.G.; Denyer, K.; Myers, A.M. Starch synthesis in the cereal endosperm. Curr. Opin. Plant Biol. 2003, 6, 215–222. [Google Scholar] [CrossRef]
  2. Zeng, M.; Morris, C.F.; Batey, I.L.; Wrigley, C.W. Sources of variation for starch gelatinization, pasting, and gelation properties in wheat. Cereal Chem. 1997, 74, 63–71. [Google Scholar] [CrossRef]
  3. Martin, J.M.; Sherman, J.D.; Lanning, S.P.; Talbert, L.E.; Giroux, M.J. Effect of variation in amylose content and puroindoline composition on bread quality in a hard spring wheat population. Cereal Chem. 2008, 85, 266–269. [Google Scholar] [CrossRef]
  4. Miura, H.; Tanii, S. Endosperm starch properties in several wheat cultivars preferred for Japanese noodles. Euphytica 1994, 72, 171–175. [Google Scholar] [CrossRef]
  5. Park, C.S.; Baik, B.-K. Characteristics of French bread baked from wheat flours of reduced starch amylose content. Cereal Chem. 2007, 84, 437–442. [Google Scholar] [CrossRef]
  6. Hayakawa, K.; Tanaka, K.; Nakamura, T.; Endo, S.; Hoshino, T. End use quality of waxy wheat flour in various grain-based foods. Cereal Chem. 2004, 81, 666–672. [Google Scholar] [CrossRef]
  7. Regina, A.; Bird, A.; Topping, D.; Bowden, S.; Freeman, J.; Barsby, T.; Kosar-Hashemi, B.; Li, Z.; Rahman, S.; Morell, M. High-amylose wheat generated by RNA interference improves indices of large-bowel health in rats. Proc. Natl. Acad. Sci. USA 2006, 103, 3546–3551. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  8. Baldwin, P.M. Starch Granule-Associated Proteins and Polypeptides: A Review. Starch-Stärke 2001, 53, 475–503. [Google Scholar] [CrossRef]
  9. Echt, C.S.; Schwartz, D. Evidence for the inclusion of controlling elements within the structural gene at the Waxy locus in maize. Genetics 1981, 99, 275–284. [Google Scholar]
  10. Yamamori, M.; Nakamura, T.; Endo, T.R.; Nagamine, T. Waxy protein deficiency and chromosomal location of coding genes in common wheat. Theor. Appl. Genet. 1994, 89, 179–184. [Google Scholar] [CrossRef]
  11. Mason-Gamer, R.J.; Weil, C.F.; Kellogg, E.A. Granule-bound starch synthase: Structure, function, and phylogenetic utility. Mol. Biol. Evol. 1998, 15, 1658–1673. [Google Scholar] [CrossRef] [PubMed]
  12. Rohde, W.; Becker, D.; Salamini, F. Structural analysis of the waxy locus from Hordeum vulgare. Nucleic Acids Res. 1988, 16, 7185–7186. [Google Scholar] [CrossRef]
  13. Guzmán, C.; Alvarez, J.B. Wheat waxy proteins: Polymorphism, molecular characterization and effects on starch properties. Theor. Appl. Genet. 2016, 129, 1–16. [Google Scholar] [CrossRef] [PubMed]
  14. McIntosh, R.A.; Yamazaki, Y.; Dubcovsky, J.; Rogers, W.J.; Morris, G.; Appels, R.; Xia, X.C. Catalogue of gene symbols for wheat. 2013. Available online: http://www.shigen.nig.ac.jp/wheat/komugi/genes/macgene/2013/GeneSymbol.pdf. (accessed on 23 August 2018).
  15. Alvarez, J.B.; Guzmán, C. Interspecific and intergeneric hybridization as a source of variation for wheat grain quality improvement. Theor. Appl. Genet. 2018, 131, 225–251. [Google Scholar] [CrossRef] [PubMed]
  16. Martín, A.; Alvarez, J.B.; Martín, L.M.; Barro, F.; Ballesteros, J. The development of tritordeum: A novel cereal for food processing. J. Cereal Sci. 1999, 30, 85–95. [Google Scholar] [CrossRef]
  17. Von Bothmer, R.; Jacobsen, N.; Baden, C.; Jorgensen, R.; Linde-Laursen, I. An Ecogeografical Study of the Genus Hordeum, 2nd ed.; International Plant Genetic Resources Institute: Rome, Italy, 1995. [Google Scholar]
  18. Alvarez, J.B.; Martín, A.; Martín, L.M. Variation in the high-molecular-weight glutenin subunits coded at the Glu-Hch1 locus in Hordeum chilense. Theor. Appl. Genet. 2001, 102, 134–137. [Google Scholar] [CrossRef]
  19. Alvarez, J.B.; Broccoli, A.; Martín, L.M. Variability and genetic diversity for gliadins in natural populations of Hordeum chilense Roem. et Schult. Genet. Resour. Crop Evol. 2006, 53, 1419–1425. [Google Scholar] [CrossRef]
  20. Atienza, S.G.; Giménez, M.J.; Martín, A.; Martín, L.M. Variability in monomeric prolamins in Hordeum chilense. Theor. Appl. Genet. 2000, 101, 970–976. [Google Scholar] [CrossRef]
  21. Atienza, S.G.; Alvarez, J.B.; Villegas, A.M.; Gimenez, M.J.; Ramirez, M.C.; Martín, A.; Martín, L.M. Variation for the low-molecular-weight glutenin subunits in a collection of Hordeum chilense. Euphytica 2002, 128, 269–277. [Google Scholar] [CrossRef]
  22. Alvarez, J.B.; Campos, L.A.C.; Martín, A.; Martín, L.M. Influence of HMW and LMW glutenin subunits on gluten strength in hexaploid tritordeum. Plant Breed. 1999, 118, 456–458. [Google Scholar] [CrossRef]
  23. Martinek, P.; Svobodová, I.; Věchet, L. Selection of the wheat genotypes and related species with resistance to Mycosphaerella graminicola. Agriculture 2013, 59, 65–73. [Google Scholar] [CrossRef]
  24. Rodríguez-Suárez, C.; Mellado-Ortega, E.; Hornero-Méndez, D.; Atienza, S. Increase in transcript accumulation of Psy1 and e-Lcy genes in grain development is associated with differences in seed carotenoid content between durum wheat and tritordeum. Plant Mol. Biol. 2014, 84, 659–673. [Google Scholar] [CrossRef] [PubMed]
  25. Martín, A.; Martín, L.M.; Cabrera, A.; Ramírez, M.C.; Giménez, M.J.; Rubiales, D.; Hernández, P.; Ballesteros, J. The potential of Hordeum chilense in breeding Triticeae species. In Triticeae III; Jaradat, A.A., Humphreys, M., Eds.; Science Publishers Inc.: Enfield, UK, 1998; pp. 377–386. [Google Scholar]
  26. Tobes, N.; Ballesteros, J.; Martínez, C.; Lovazzano, G.; Contreras, D.; Cosio, F.; Gastó, J.; Martín, L.M. Collection mission of H. chilense Roem. et Schult. in Chile and Argentina. Genet. Resour. Crop Evol. 1995, 42, 211–216. [Google Scholar] [CrossRef]
  27. Giménez, M.J.; Cosío, F.; Martínez, C.; Silva, F.; Zuleta, A.; Martín, L.M. Collecting Hordeum chilense Roem. et Schult. germplasm in desert and steppe dominions of Chile. Plant Genet. Resour. Newsl. 1997, 109, 17–19. [Google Scholar]
  28. Pistón, F.; Shewry, P.; Barro, F. D hordeins of Hordeum chilense: A novel source of variation for improvement of wheat. Theor. Appl. Genet. 2007, 115, 77–86. [Google Scholar] [CrossRef]
  29. Guzmán, C.; Alvarez, J.B. Molecular characterization of two novel alleles of Hordoindoline genes in Hordeum chilense Roem. et Schult. Genet. Resour. Crop Evol. 2014, 61, 307–312. [Google Scholar] [CrossRef]
  30. Alvarez, J.B.; Martín, L.M.; Martín, A. Chromosomal localization of genes for carotenoid pigments using addition lines of Hordeum chilense in wheat. Plant Breed. 1998, 117, 287–289. [Google Scholar] [CrossRef]
  31. Rodríguez-Suárez, C.; Atienza, S.G.; Pistón, F. Allelic variation, alternative splicing and expression analysis of Psy1 gene in Hordeum chilense Roem. et Schult. PLoS ONE 2011, 6, e19885. [Google Scholar] [CrossRef] [PubMed]
  32. Stacey, J.; Isaac, P.G. Isolation of DNA from Plants. In Protocols for Nucleic Acid Analysis by Nonradioactive Probes; Isaac, P.G., Ed.; Humana Press: Totowa, NJ, USA, 1994; pp. 9–15. [Google Scholar]
  33. Nakamura, T.; Vrinten, P.; Saito, M.; Konda, M. Rapid classification of partial waxy wheats using PCR-based markers. Genome 2002, 45, 1150–1156. [Google Scholar] [CrossRef]
  34. Guzman, C.; Alvarez, J.B. Molecular characterization of a novel waxy allele (Wx-Au1a) from Triticum urartu Thum. ex Gandil. Genet. Resour. Crop Evol. 2012, 59, 971–979. [Google Scholar] [CrossRef]
  35. Librado, P.; Rozas, J. DnaSP v5: A software for comprehensive analysis of DNA polymorphism data. Bioinformatics 2009, 25, 1451–1452. [Google Scholar] [CrossRef] [PubMed]
  36. Dvorak, J.; Akhunov, E.D. Tempos of Gene Locus Deletions and Duplications and Their Relationship to Recombination Rate During Diploid and Polyploid Evolution in the Aegilops-Triticum Alliance. Genetics 2005, 171, 323–332. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  37. Rice, P.; Longden, I.; Bleasby, A. EMBOSS: The European molecular biology open software suite. Trends Genet. 2000, 16, 276–277. [Google Scholar] [CrossRef]
  38. Choi, Y.; Chan, A.P. PROVEAN web server: A tool to predict the functional effect of amino acid substitutions and indels. Bioinformatics 2015, 31, 2745–2747. [Google Scholar] [CrossRef] [PubMed]
  39. Choi, Y.; Sims, G.E.; Murphy, S.; Miller, J.R.; Chan, A.P. Predicting the Functional Effect of Amino Acid Substitutions and Indels. PLoS ONE 2012, 7, e46688. [Google Scholar] [CrossRef]
  40. Tamura, K.; Stecher, G.; Peterson, D.; Filipski, A.; Kumar, S. MEGA6: Molecular Evolutionary genetics analysis version 6.0. Mol. Biol. Evol. 2013, 30, 2725–2729. [Google Scholar] [CrossRef] [PubMed]
  41. Zuckerkandl, E.; Pauling, L. Evolutionary Divergence and Convergence in Proteins. In Evolving Genes and Proteins; Bryson, V., Vogel, H.J., Eds.; Academic Press: New York, NY, USA, 1965; pp. 97–166. [Google Scholar]
  42. Felsenstein, J. Confidence limits on phylogenies: An approach using the bootstrap. Evolution 1985, 39, 783–791. [Google Scholar] [CrossRef]
  43. Murai, J.; Taira, T.; Ohta, D. Isolation and characterization of the three Waxy genes encoding the granule-bound starch synthase in hexaploid wheat. Gene 1999, 234, 71–79. [Google Scholar] [CrossRef]
  44. Leterrier, M.; Holappa, L.; Broglie, K.; Beckles, D. Cloning, characterisation and comparative analysis of a starch synthase IV gene in wheat: Functional and evolutionary implications. BMC Plant Biol. 2008, 8, 98. [Google Scholar] [CrossRef]
  45. Guzmán, C.; Caballero, L.; Martín, L.M.; Alvarez, J.B. Waxy genes from spelt wheat: New alleles for modern wheat breeding and new phylogenetic inferences about the origin of this species. Ann. Bot. 2012, 110, 1161–1171. [Google Scholar] [CrossRef]
  46. Cornejo-Ramírez, Y.I.; Martínez-Cruz, O.; Del Toro-Sánchez, C.L.; Wong-Corral, F.J.; Borboa-Flores, J.; Cinco-Moroyoqui, F.J. The structural characteristics of starches and their functional properties. CyTA-J. Food 2018, 16, 1003–1017. [Google Scholar]
  47. Yan, L.; Bhave, M.; Fairclough, R.; Konik, C.; Rahman, S.; Appels, R. The genes encoding granule-bound starch synthases at the waxy loci of the A, B, and D progenitors of common wheat. Genome 2000, 43, 264–272. [Google Scholar] [CrossRef] [PubMed]
  48. Mason-Gamer, R.J. Origin of North American Elymus (Poaceae: Triticeae) allotetraploids based on Granule-bound starch synthase gene sequences. Syst. Bot. 2001, 26, 757–768. [Google Scholar]
  49. Ingram, A.L.; Doyle, J.J. The origin and evolution of Eragrostis tef (Poaceae) and related polyploids: Evidence from nuclear waxy and plastid rps16. Am. J. Bot. 2003, 90, 116–122. [Google Scholar] [CrossRef] [PubMed]
  50. Fortune, P.M.; Schierenbeck, K.A.; Ainouche, A.K.; Jacquemin, J.; Wendel, J.F.; Ainouche, M.L. Evolutionary dynamics of Waxy and the origin of hexaploid Spartina species (Poaceae). Mol. Phylogenet. Evol. 2007, 43, 1040–1055. [Google Scholar] [CrossRef] [PubMed]
  51. Ortega, R.; Alvarez, J.B.; Guzmán, C. Characterization of the Wx gene in diploid Aegilops species and its potential use in wheat breeding. Genet. Resour. Crop Evol. 2014, 61, 369–382. [Google Scholar] [CrossRef]
  52. Kramer, H.H.; Blander, B.A.S. Orienting linkage maps on the chromosomes of barley. Crop Sci. 1961, 1, 339–342. [Google Scholar] [CrossRef]
  53. Mattera, M.G.; Ávila, C.M.; Atienza, S.G.; Cabrera, A. Cytological and molecular characterization of wheat-Hordeum chilense chromosome 7Hch introgression lines. Euphytica 2015, 203, 165–176. [Google Scholar] [CrossRef]
  54. Avila, C.M.; Mattera, M.G.; Rodríguez-Suárez, C.; Palomino, C.; Ramírez, M.C.; Martín, A.; Kilian, A.; Hornero-Méndez, D.; Atienza, S.G. Diversification of seed carotenoid content and profile in wild barley (Hordeum chilense Roem. et Schultz.) and Hordeum vulgare L.-H. chilense synteny as revealed by DArTSeq markers. Euphytica 2019, 215, 45. [Google Scholar] [CrossRef]
Figure 1. (a) Diagrammatic representation of Wx gene showing the three fragments used for sequencing, and (b) PCR analysis for the chromosomal location of H. chilense Wx gene using primers BDFL/BRD from Nakamura et al. [33] in common wheat, ditelosomic addition lines, and H. chilense. Lanes are as follows: 1, cv. Chinese Spring (CS), 2, CS + 7HchS line, 3, CS + 7HchL line, and 4, H1 line.
Figure 1. (a) Diagrammatic representation of Wx gene showing the three fragments used for sequencing, and (b) PCR analysis for the chromosomal location of H. chilense Wx gene using primers BDFL/BRD from Nakamura et al. [33] in common wheat, ditelosomic addition lines, and H. chilense. Lanes are as follows: 1, cv. Chinese Spring (CS), 2, CS + 7HchS line, 3, CS + 7HchL line, and 4, H1 line.
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Figure 2. Comparison of the secondary structure motifs predicted by Garnier for the transit peptide region among all sequences evaluated.
Figure 2. Comparison of the secondary structure motifs predicted by Garnier for the transit peptide region among all sequences evaluated.
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Figure 3. Consensus sequence of the predicted proteins from H. chilense showing the motifs described by Leterrier et al. [44] conserved in waxy proteins. Squares indicate substitution sites (blue for wheat, red for barley and black for both ones), and arrows point relevant changes found in the novel alleles.
Figure 3. Consensus sequence of the predicted proteins from H. chilense showing the motifs described by Leterrier et al. [44] conserved in waxy proteins. Squares indicate substitution sites (blue for wheat, red for barley and black for both ones), and arrows point relevant changes found in the novel alleles.
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Figure 4. Neighbor-joining tree based on the Poisson correction method for amino acid sequences analyzed. Number above nodes indicates bootstrap estimates from 1000 replications.
Figure 4. Neighbor-joining tree based on the Poisson correction method for amino acid sequences analyzed. Number above nodes indicates bootstrap estimates from 1000 replications.
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Table 1. Size of the different exons and introns of the coding sequence in the Wx sequences evaluated.
Table 1. Size of the different exons and introns of the coding sequence in the Wx sequences evaluated.
Wx-A1a1Wx-B1a1Wx-D1a1Wx-H1a2/Wx-H1b3Wx-Hch1a/Wx-Hch1b
Exon 2321324321318318
Exon 38181818181
Exon 49999999999
Exon 5154154154154154
Exon 6101101101101101
Exon 7354354354354354
Exon 8180180180180180
Exon 9192192192192192
Exon 108787878787
Exon 11129129129129129
Exon 12117117117117117
Intron 28299908985
Intron 38488958480
Intron 4109113104126109
Intron 5125133152136113
Intron 6996914110689
Intron 79192859289
Intron 89586829494
Intron 99084848282
Intron 109897989797
Intron 11931151167685/86
Total27812794286227942735/2736
1 cv. Chinese Spring (NCBI ID: Wx-A1, AB019622, Wx-B1, AB019623, Wx-D1, AB019624) [43]. 2 cv. Vogelsanger Gold (NCBI ID: X07931) [12]. 3 cv. Morex (NCBI ID: AF474373).
Table 2. Amino acid comparison of predicted mature protein among waxy protein variants evaluated.
Table 2. Amino acid comparison of predicted mature protein among waxy protein variants evaluated.
Position 1Wx-Hch1a/bWx-H1a2Wx-A1a2Wx-B1a2Wx-D1a2
103Pro Ala
115Val IleIleIle
123AsnLysLysLysLys
131ValIleIle
137Ala Val Val
139Glu Arg Lys
142ThrArgArgArgArg
145Phe TyrTyrTyr
158Ile ValValVal
162Trp CysCysCys
189Gln Leu
201Ala Val Val
206AspAsn Asn
208Asn Asp
212Tyr His
232ProLeuLeuLeuLeu
244Asn Ser
249Thr Ala
356Thr IleAla
362Ala Thr
363Val Ala
367Ile ValVal
373Ala GlyGlyGly
416Ser/ProProProProPro
419Val/MetLeu LeuLeu
427Ile ValValVal
438ArgLys
443ValMet Ile
449Gly ThrSerSer
452Arg Trp
471Leu ValValVal
496AlaVal
508Val Met
535Ala ValValVal
551Gln HisHisHis
587Ile ValVal
588Val IleIle
590AspGluGluGluGlu
597Met Leu
1 This position should be increased for Wx-A1 and -D1 (+1), and for Wx-B1 (+2). 2 NCBI ID: barley [X07931] and common wheat cv. “Chinese Spring” [Wx-A1: AB019622, Wx-B1: AB019623, Wx-D1: AB019624].

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Alvarez, J.B.; Castellano, L.; Recio, R.; Cabrera, A. Wx Gene in Hordeum chilense: Chromosomal Location and Characterisation of the Allelic Variation in the Two Main Ecotypes of the Species. Agronomy 2019, 9, 261. https://0-doi-org.brum.beds.ac.uk/10.3390/agronomy9050261

AMA Style

Alvarez JB, Castellano L, Recio R, Cabrera A. Wx Gene in Hordeum chilense: Chromosomal Location and Characterisation of the Allelic Variation in the Two Main Ecotypes of the Species. Agronomy. 2019; 9(5):261. https://0-doi-org.brum.beds.ac.uk/10.3390/agronomy9050261

Chicago/Turabian Style

Alvarez, Juan B., Laura Castellano, Rocío Recio, and Adoración Cabrera. 2019. "Wx Gene in Hordeum chilense: Chromosomal Location and Characterisation of the Allelic Variation in the Two Main Ecotypes of the Species" Agronomy 9, no. 5: 261. https://0-doi-org.brum.beds.ac.uk/10.3390/agronomy9050261

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