Kristin Simons scite author profile

The Q gene is largely responsible for the widespread cultivation of wheat because it confers the freethreshing character. It also pleiotropically influences many other domestication-related traits such as glume shape and tenacity, rachis fragility, spike length, plant height, and spike emergence time. We isolated the Q gene and verified its identity by analysis of knockout mutants and transformation. The Q gene has a high degree of similarity to members of the AP2 family of transcription factors. The Q allele is more abundantly transcribed than q, and the two alleles differ for a single amino acid. An isoleucine at position 329 in the Q protein leads to an abundance of homodimer formation in yeast cells, whereas a valine in the q protein appears to limit homodimer formation. Ectopic expression analysis allowed us to observe both silencing and overexpression effects of Q. Rachis fragility, glume shape, and glume tenacity mimicked the q phenotype in transgenic plants exhibiting post-transcriptional silencing of the transgene and the endogenous Q gene. Variation in spike compactness and plant height were associated with the level of transgene transcription due to the dosage effects of Q. The q allele is the more primitive, and the mutation that gave rise to Q occurred only once leading to the world's cultivated wheats. W HEAT, rice, and maize are the three major cereal crops that provide most of the calories consumed by humans. Bread (common) wheat (Triticum aestivum L., 2n ¼ 6x ¼ 42, AABBDD genomes) arose 8000-10,000 years ago (for review see Nesbitt and Samuel 1996;Feldman 2001) from the spontaneous hybridization of the tetraploid wheat T. turgidum L. (2n ¼ 4x ¼ 28, AABB genomes) with the diploid goatgrass Aegilops tauschii Coss. (2n ¼ 2x ¼ 14, DD genomes) (Kihara 1944;McFadden and Sears 1946). Domestication of wheat resulted from mutations that gave rise to traits such as soft glumes, a nonfragile rachis, and the free-threshing character.The Q gene governs the free-threshing character and square spike phenotype. In addition, Q pleiotropically affects a repertoire of other characters important for domestication such as rachis fragility (Leighty and

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A unique wheat disease resistance-like gene governs effector-triggered susceptibility to necrotrophic pathogens

Faris

Zhang²,

Lu³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

473

405

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Plant disease resistance is often conferred by genes with nucleotide binding site (NBS) and leucine-rich repeat (LRR) or serine/threonine protein kinase (S/TPK) domains. Much less is known about mechanisms of susceptibility, particularly to necrotrophic fungal pathogens. The pathogens that cause the diseases tan spot and Stagonospora nodorum blotch on wheat produce effectors (host-selective toxins) that induce susceptibility in wheat lines harboring corresponding toxin sensitivity genes. The effector ToxA is produced by both pathogens, and sensitivity to ToxA is governed by the Tsn1 gene on wheat chromosome arm 5BL. Here, we report the cloning of Tsn1 , which was found to have disease resistance gene-like features, including S/TPK and NBS-LRR domains. Mutagenesis revealed that all three domains are required for ToxA sensitivity, and hence disease susceptibility. Tsn1 is unique to ToxA-sensitive genotypes, and insensitive genotypes are null. Sequencing and phylogenetic analysis indicated that Tsn1 arose in the B-genome diploid progenitor of polyploid wheat through a gene-fusion event that gave rise to its unique structure. Although Tsn1 is necessary to mediate ToxA recognition, yeast two-hybrid experiments suggested that the Tsn1 protein does not interact directly with ToxA. Tsn1 transcription is tightly regulated by the circadian clock and light, providing further evidence that Tsn1 -ToxA interactions are associated with photosynthesis pathways. This work suggests that these necrotrophic pathogens may thrive by subverting the resistance mechanisms acquired by plants to combat other pathogens.

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High-resolution crossover mapping reveals similarities and differences of male and female recombination in maize

et al. 2018

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Meiotic crossovers (COs) are not uniformly distributed across the genome. Factors affecting this phenomenon are not well understood. Although many species exhibit large differences in CO numbers between sexes, sex-specific aspects of CO landscape are particularly poorly elucidated. Here, we conduct high-resolution CO mapping in maize. Our results show that CO numbers as well as their overall distribution are similar in male and female meioses. There are, nevertheless, dissimilarities at local scale. Male and female COs differ in their locations relative to transcription start sites in gene promoters and chromatin marks, including nucleosome occupancy and tri-methylation of lysine 4 of histone H3 (H3K4me3). Our data suggest that sex-specific factors not only affect male–female CO number disparities but also cause fine differences in CO positions. Differences between male and female CO landscapes indicate that recombination has distinct implications for population structure and gene evolution in male and in female meioses.

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Kristin Simons

Molecular Characterization of the Major Wheat Domestication Gene Q

A unique wheat disease resistance-like gene governs effector-triggered susceptibility to necrotrophic pathogens

High-resolution crossover mapping reveals similarities and differences of male and female recombination in maize

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