Your search keyword '"Glume"' showing total 3 results

1. Differential effects of elevated CO2 on awn and glume metabolism in durum wheat (Triticum durum).

Author

Tcherkez, Guillaume, Ben Mariem, Sinda, Jauregui, Iván, Larraya, Luis, García-Mina, Jose M., Zamarreño, Angel M., Fangmeier, Andreas, and Aranjuelo, Iker

Subjects

*AMINO acid metabolism, *DURUM wheat, *SECONDARY metabolism, *METABOLISM, *MOLE fraction, *WHEAT

Abstract

While the effect of CO2 enrichment on wheat (Triticum spp.) photosynthesis, nitrogen content or yield has been well-studied, the impact of elevated CO2 on metabolic pathways in organs other than leaves is poorly documented. In particular, glumes and awns, which may refix CO2 respired by developing grains and be naturally exposed to higher-than-ambient CO2 mole fraction, could show specific responses to elevated CO2. Here, we took advantage of a free-air CO2 enrichment experiment and performed multilevel analyses, including metabolomics, ionomics, proteomics, major hormones and isotopes in Triticum durum. While in leaves, elevated CO2 tended to accelerate amino acid metabolism with many significantly affected metabolites, the effect on glumes and awns metabolites was modest. There was a lower content in compounds of the polyamine pathway (along with uracile and allantoin) under elevated CO2, suggesting a change in secondary N metabolism. Also, cytokinin metabolism appeared to be significantly affected under elevated CO2. Despite this, elevated CO2 did not affect the final composition of awn and glume organic matter, with the same content in carbon, nitrogen and other elements. We conclude that elevated CO2 mostly impacts on leaf metabolism but has little effect in awns and glumes, including their composition at maturity. The specific impact of elevated CO2 on metabolic pathways in wheat (Triticum spp.) organs other than leaves is poorly documented. We addressed this aspect by taking advantage of a free-air CO2 enrichment experiment in durum wheat (Triticum durum). We found changes in polyamine and cytokinin metabolism under elevated CO2 in glumes and awns but no modifications in final composition at maturity. Elevated CO2 mostly impacts on leaf metabolism but has little effect on glumes and awns. [ABSTRACT FROM AUTHOR]

Published

2024

2. Identification and map-based cloning of long glume mutant gene lgm1 in barley.

Author

Zhang, Zhenlan, Zhao, Pengtao, Wang, Xiaoyun, Wang, Haiyan, Zhai, Zhouping, Zhao, Xiaoguang, Xing, Liping, Qi, Zengjun, and Shang, Yi

Subjects

*MOLECULAR cloning, *ZINC-finger proteins, *BARLEY, *ALLELES in plants

Abstract

The spikes of gramineous plants are composed of specialized units called spikelets. Two bracts at the spikelet bases are known as glumes. The spikelet glumes in barley are degenerated into threadlike structures. Here, we report a long glume mutant, lgm1, similar in appearance to a lemma with a long awn at the apex. Map-based cloning showed that the mutant lgm1 allele has an approximate 1.27 Mb deletion of in chromosome 2H. The deleted segment contains five putative high-confidence genes, among which HORVU.MOREX.r3.2HG0170820 encodes a C2H2 zinc finger protein, an ortholog of rice NSG1/LRG1 and an important candidate for the Lgm1 allele. Line GA01 with a long glume and short awn was obtained in progenies of crosses involving the lgm1 mutant. Interestingly, lsg1, a mutant with long glumes on lateral spikelets, was obtained in the progenies of the lgm1 mutant. The long glume variant increased the weight of kernels in the lateral spikelets and increased kernel uniformity across the entire spike, greatly improving the potential of six-rowed barley for malting. [ABSTRACT FROM AUTHOR]

Published

2024

3. Differential effects of elevated CO2 on awn and glume metabolism in durum wheat (Triticum durum)

Author

Tcherkez, Guillaume [0000-0002-3339-956X], Aranjuelo, Iker [0000-0002-8231-5043], Tcherkez, Guillaume, Ben Mariem, Sinda, Jauregui, Iván, Larraya, Luis, García-Mina, José María, Zamarreño, Ángel M., Fangmeier, Andreas, Aranjuelo, Iker, Tcherkez, Guillaume [0000-0002-3339-956X], Aranjuelo, Iker [0000-0002-8231-5043], Tcherkez, Guillaume, Ben Mariem, Sinda, Jauregui, Iván, Larraya, Luis, García-Mina, José María, Zamarreño, Ángel M., Fangmeier, Andreas, and Aranjuelo, Iker

Abstract

While the effect of CO2 enrichment on wheat (Triticum spp.) photosynthesis, nitrogen content or yield has been well-studied, the impact of elevated CO2 on metabolic pathways in organs other than leaves is poorly documented. In particular, glumes and awns, which may refix CO2 respired by developing grains and be naturally exposed to higher-than-ambient CO2 mole fraction, could show specific responses to elevated CO2. Here, we took advantage of a free-air CO2 enrichment experiment and performed multilevel analyses, including metabolomics, ionomics, proteomics, major hormones and isotopes in Triticum durum. While in leaves, elevated CO2 tended to accelerate amino acid metabolism with many significantly affected metabolites, the effect on glumes and awns metabolites was modest. There was a lower content in compounds of the polyamine pathway (along with uracile and allantoin) under elevated CO2, suggesting a change in secondary N metabolism. Also, cytokinin metabolism appeared to be significantly affected under elevated CO2. Despite this, elevated CO2 did not affect the final composition of awn and glume organic matter, with the same content in carbon, nitrogen and other elements. We conclude that elevated CO2 mostly impacts on lea

Published

2024