Introducing Beneficial Alleles from Plant Genetic Resources into the Wheat Germplasm

Sharma, S. B.; Schulthess, Albert W.; Bassi, Filippo M.; Бадаева, Е. Д.; Neumann, Kerstin; Graner, Andreas; Özkan, Hakan; Werner, P.; Knüpffer, H.; Kilian, Benjamin

doi:10.3390/biology10100982

Cited by 53 publications

(46 citation statements)

References 246 publications

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“…Moreover, the initial process of domestication might have taken approximately 2–3,000 years ( Kislev, 1984 ; Tanno and Willcox, 2006 ) as seen from the archeological records where fragile, partly fragile, and nonfragile spikes can be found in the same farming sites, providing high chances to hybridize. Consistent with these biological and archeological data, the variation in the domesticated-emmer genome includes ∼73% of that of wild emmer ( Zhou et al, 2020 ; Keilwagen et al, 2022 ; Sharma et al, 2021 ). Genotyping of T. aestivum landraces has shown that a significant part of the variation in wild or domesticated tetraploid wheat has also found its way into the A and B subgenomes of the bread wheat genome suggesting that there was only a limited genetic barrier between tetraploid and hexaploid wheat ( Dvorak et al, 2006 ).…”

Section: Evolution Under Allopolyploidysupporting

confidence: 70%

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Evolution and origin of bread wheat

Levy

Feldman

2022

The Plant Cell

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Bread wheat (Triticum aestivum, genome BBAADD) is a young hexaploid species formed only 8500-9000 years ago through hybridization between a domesticated free-threshing tetraploid progenitor, genome BBAA, and Aegilops tauschii, the diploid donor of the D subgenome. Very soon after its formation, it spread globally from its cradle in the fertile crescent into new habitats and climates, to become a staple food of humanity. This extraordinary global expansion was probably enabled by allopolyploidy that accelerated genetic novelty through the acquisition of new traits, new intergenomic interactions, and buffering of mutations, and by the attractiveness of bread wheat’s large, tasty, and nutritious grain with high baking quality. New genome sequences suggest that the elusive donor of the B subgenome is a distinct (unknown or extinct) species rather than a mosaic genome. We discuss the origin of the diploid and tetraploid progenitors of bread wheat and the conflicting genetic and archaeological evidence on where it was formed and which species was its free-threshing tetraploid progenitor. Wheat experienced many environmental changes throughout its evolution, therefore, while it might adapt to current climatic changes, efforts are needed to better use and conserve the vast gene pool of wheat biodiversity on which our food security depends.

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Section: Evolution Under Allopolyploidysupporting

confidence: 70%

“…aestivum , which is of global importance, the other subspecies being only locally cultivated, and we refer to it as bread wheat. In this review, we follow Mac Key’s classification, yet additional classifications were proposed as summarized by Sharma et al (2021) .…”

Section: Introductionmentioning

confidence: 99%

Evolution and origin of bread wheat

Levy

Feldman

2022

The Plant Cell

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“…Publicly available data were downloaded from 65 https://doi.org/10.5447/IPK/2019/18 . Additional genomic data was downloaded from EMBL ENA with the following IDs: ERR2936519 and ERR2936122 (GBS data of cv.…”

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confidence: 99%

“…Sometimes the published information is incorrect or misleading. In this study, we consider the taxon names used by Sharma et al 65 . However, we cannot change existing database entries.…”

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Detecting major introgressions in wheat and their putative origins using coverage analysis

Keilwagen

Lehnert

Berner

et al. 2022

Sci Rep

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Introgressions from crop wild relatives (CWRs) have been used to introduce beneficial traits into cultivated plants. Introgressions have traditionally been detected using cytological methods. Recently, single nucleotide polymorphism (SNP)-based methods have been proposed to detect introgressions in crosses for which both parents are known. However, for unknown material, no method was available to detect introgressions and predict the putative donor species. Here, we present a method to detect introgressions and the putative donor species. We demonstrate the utility of this method using 10 publicly available wheat genome sequences and identify nine major introgressions. We show that the method can distinguish different introgressions at the same locus. We trace introgressions to early wheat cultivars and show that natural introgressions were utilised in early breeding history and still influence elite lines today. Finally, we provide evidence that these introgressions harbour resistance genes.

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Identification of adapted breeding lines to improve barley hybrids for Spain

Fernández‐Calleja

Boutin²,

Dyrszka³

et al. 2022

Crop Science

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This study explores the potential of Spanish germplasm for the development of hybrids adapted to southern Europe, a new region for hybrid barley (Hordeum vulgare). A set of 140 locally adapted, advanced breeding lines, developed in a Spanish public breeding program, were evaluated for their potential to widen the germplasm available for hybrid barley development. A subset of 24 lines was introduced into three-way hybrid combinations and tested in a field trial network of four locations and 2 yr. The hybrid performance of the rest of the lines was estimated based on genomic prediction models. No three-way hybrid exceeded the best check. We succeeded in identifying lines with high general combining ability, which could produce promising two-way hybrids. Some were among those tested in the field, whereas others resulted from genomic predictions, validating the strategy followed of mining locally adapted breeding lines. Rachis brittleness detected in field trials revealed a low but detrimental effect of the presence of alternative brittle mutations in the hybrid combination. The success of hybrid breeding in southern Europe requires further investigation of the underlying heterotic patterns, and appropriate management

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Introducing Beneficial Alleles from Plant Genetic Resources into the Wheat Germplasm

Cited by 53 publications

References 246 publications

Evolution and origin of bread wheat

Evolution and origin of bread wheat

Detecting major introgressions in wheat and their putative origins using coverage analysis

Identification of adapted breeding lines to improve barley hybrids for Spain

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