Phenotypic variation in root architecture traits and their relationship with eco-geographical and agronomic features in a core collection of tetraploid wheat landraces (Triticum turgidum L.)

Spain has a great landrace diversity of the subspecies of the tetraploid species Triticum turgidum L., namely, durum (or durum wheat), turgidum (or rivet wheat) and dicoccon (or domesticated emmer wheat). These wheats have to confront several foliar diseases such as the leaf rust. In this work, a core collection of 94 landraces of tetraploid wheats were inoculated with three leaf rust isolates. Besides, a larger collection (of 192 accessions) was evaluated in the field. Although the majority of landraces were susceptible, approximately 20% were resistant, especially domesticated emmer wheat landraces. Several variables, such as late heading and red coat seeds were associated to resistant accessions. Regarding ecogeographic variables, a higher rainfall from October to February and more uniform temperature were found in the area of origin of resistant landraces. Based on these results, several resistant landraces were identified that potentially may be used in durum wheat breeding programs. In addition, a predictive model was elaborated to develop smaller subsets for future screening with a higher hit rate for rust resistance.

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Function and evolution of allelic variation of Sr13 conferring resistance to stem rust in tetraploid wheat ( Triticum turgidum L.)

The Plant Journal ◽

10.1111/tpj.15263 ◽

2021 ◽

Author(s):

Baljeet K. Gill ◽

Daryl L. Klindworth ◽

Matthew N. Rouse ◽

Jinglun Zhang ◽

Qijun Zhang ◽

...

Keyword(s):

Stem Rust ◽

Triticum Turgidum ◽

Allelic Variation ◽

Tetraploid Wheat

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The Independent Domestication of Timopheev’s Wheat: Insights from Haplotype Analysis of the Brittle rachis 1 (BTR1-A) Gene

Genes ◽

10.3390/genes12030338 ◽

2021 ◽

Vol 12 (3) ◽

pp. 338

Author(s):

Moran Nave ◽

Mihriban Taş ◽

John Raupp ◽

Vijay K. Tiwari ◽

Hakan Ozkan ◽

...

Keyword(s):

Promoter Region ◽

Haplotype Analysis ◽

Common Ancestor ◽

Triticum Turgidum ◽

Tetraploid Wheat ◽

Wheat Species ◽

Loss Of Function ◽

Brittle Rachis ◽

Gene Level ◽

Large Panel

Triticum turgidum and T. timopheevii are two tetraploid wheat species sharing T. urartu as a common ancestor, and domesticated accessions from both of these allopolyploids exhibit nonbrittle rachis (i.e., nonshattering spikes). We previously described the loss-of-function mutations in the Brittle Rachis 1 genes BTR1-A and BTR1-B in the A and B subgenomes, respectively, that are responsible for this most visible domestication trait in T. turgidum. Resequencing of a large panel of wild and domesticated T. turgidum accessions subsequently led to the identification of the two progenitor haplotypes of the btr1-A and btr1-B domesticated alleles. Here, we extended the haplotype analysis to other T. turgidum subspecies and to the BTR1 homologues in the related T. timopheevii species. Our results showed that all the domesticated wheat subspecies within T. turgidum share common BTR1-A and BTR1-B haplotypes, confirming their common origin. In T. timopheevii, however, we identified a novel loss-of-function btr1-A allele underlying a partially brittle spike phenotype. This novel recessive allele appeared fixed within the pool of domesticated Timopheev’s wheat but was also carried by one wild timopheevii accession exhibiting partial brittleness. The promoter region for BTR1-B could not be amplified in any T. timopheevii accessions with any T. turgidum primer combination, exemplifying the gene-level distance between the two species. Altogether, our results support the concept of independent domestication processes for the two polyploid, wheat-related species.

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Levels of phenotypic variation for developmental traits in landrace genotypes of durum wheat (Triticum turgidum ssp. Turgidum L. conv. durum (Desf.) MK.) from Jordan

Euphytica ◽

10.1007/bf00039728 ◽

1990 ◽

Vol 51 (3) ◽

pp. 265-271 ◽

Cited By ~ 12

Author(s):

A. A. Jaradat

Keyword(s):

Durum Wheat ◽

Phenotypic Variation ◽

Triticum Turgidum ◽

Developmental Traits

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Wheat in the Mediterranean revisited – tetraploid wheat landraces assessed with elite bread wheat Single Nucleotide Polymorphism markers

BMC Genetics ◽

10.1186/1471-2156-15-54 ◽

2014 ◽

Vol 15 (1) ◽

pp. 54 ◽

Cited By ~ 16

Author(s):

Hugo R Oliveira ◽

Jenny Hagenblad ◽

Matti W Leino ◽

Fiona J Leigh ◽

Diane L Lister ◽

...

Keyword(s):

Single Nucleotide Polymorphism ◽

Bread Wheat ◽

Tetraploid Wheat ◽

Nucleotide Polymorphism ◽

Single Nucleotide ◽

Wheat Landraces ◽

The Mediterranean

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Molecular characterization and chromosome-specific TRAP-marker development for Langdon durum D-genome disomic substitution lines

Genome ◽

10.1139/g06-114 ◽

2006 ◽

Vol 49 (12) ◽

pp. 1545-1554 ◽

Cited By ~ 17

Author(s):

J. Li ◽

D.L. Klindworth ◽

F. Shireen ◽

X. Cai ◽

J. Hu ◽

...

Keyword(s):

Triticum Turgidum ◽

Tetraploid Wheat ◽

Substitution Lines ◽

Genome Chromosome ◽

D Genome ◽

Single Chromosome ◽

B Genome ◽

The Individual ◽

Trap Marker

The aneuploid stocks of durum wheat ( Triticum turgidum L. subsp. durum (Desf.) Husnot) and common wheat ( T. aestivum L.) have been developed mainly in ‘Langdon’ (LDN) and ‘Chinese Spring’ (CS) cultivars, respectively. The LDN-CS D-genome chromosome disomic substitution (LDN-DS) lines, where a pair of CS D-genome chromosomes substitute for a corresponding homoeologous A- or B-genome chromosome pair of LDN, have been widely used to determine the chromosomal locations of genes in tetraploid wheat. The LDN-DS lines were originally developed by crossing CS nulli-tetrasomics with LDN, followed by 6 backcrosses with LDN. They have subsequently been improved with 5 additional backcrosses with LDN. The objectives of this study were to characterize a set of the 14 most recent LDN-DS lines and to develop chromosome-specific markers, using the newly developed TRAP (target region amplification polymorphism)-marker technique. A total of 307 polymorphic DNA fragments were amplified from LDN and CS, and 302 of them were assigned to individual chromosomes. Most of the markers (95.5%) were present on a single chromosome as chromosome-specific markers, but 4.5% of the markers mapped to 2 or more chromosomes. The number of markers per chromosome varied, from a low of 10 (chromosomes 1A and 6D) to a high of 24 (chromosome 3A). There was an average of 16.6, 16.6, and 15.9 markers per chromosome assigned to the A-, B-, and D-genome chromosomes, respectively, suggesting that TRAP markers were detected at a nearly equal frequency on the 3 genomes. A comparison of the source of the expressed sequence tags (ESTs), used to derive the fixed primers, with the chromosomal location of markers revealed that 15.5% of the TRAP markers were located on the same chromosomes as the ESTs used to generate the fixed primers. A fixed primer designed from an EST mapped on a chromosome or a homoeologous group amplified at least 1 fragment specific to that chromosome or group, suggesting that the fixed primers might generate markers from target regions. TRAP-marker analysis verified the retention of at least 13 pairs of A- or B-genome chromosomes from LDN and 1 pair of D-genome chromosomes from CS in each of the LDN-DS lines. The chromosome-specific markers developed in this study provide an identity for each of the chromosomes, and they will facilitate molecular and genetic characterization of the individual chromosomes, including genetic mapping and gene identification.

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