Your search keyword '"Wallington, Emma J."' showing total 10 results

1. CRISPR/Cas9 Gene Editing of Gluten in Wheat to Reduce Gluten Content and Exposure—Reviewing Methods to Screen for Coeliac Safety

Author

Jouanin, A.A., Gilissen, L.J.W.J., Schaart, J.G., Leigh, Fiona J., Cockram, James, Wallington, Emma J., Boyd, Lesley A., van den Broeck, H.C., van der Meer, I.M., America, A.H.P., Visser, R.G.F., Smulders, M.J.M., Jouanin, A.A., Gilissen, L.J.W.J., Schaart, J.G., Leigh, Fiona J., Cockram, James, Wallington, Emma J., Boyd, Lesley A., van den Broeck, H.C., van der Meer, I.M., America, A.H.P., Visser, R.G.F., and Smulders, M.J.M.

Published

2020

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Author

Jouanin, Aurélie, Schaart, Jan G., Boyd, Lesley A., Cockram, James, Leigh, Fiona J., Bates, Ruth, Wallington, Emma J., Visser, Richard G.F., Smulders, Marinus J.M., Jouanin, Aurélie, Schaart, Jan G., Boyd, Lesley A., Cockram, James, Leigh, Fiona J., Bates, Ruth, Wallington, Emma J., Visser, Richard G.F., and Smulders, Marinus J.M.

Published

2019

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Author

Jouanin, Aurélie, Schaart, Jan G., Boyd, Lesley A., Cockram, James, Leigh, Fiona J., Bates, Ruth, Wallington, Emma J., Visser, Richard G.F., Smulders, Marinus J.M., Jouanin, Aurélie, Schaart, Jan G., Boyd, Lesley A., Cockram, James, Leigh, Fiona J., Bates, Ruth, Wallington, Emma J., Visser, Richard G.F., and Smulders, Marinus J.M.

Published

2019

4. A rice Serine/Threonine receptor-like kinase regulates arbuscular mycorrhizal symbiosis at the peri-arbuscular membrane

Author

Roth, Ronelle; https://orcid.org/0000-0001-5566-8954, Chiapello, Marco; https://orcid.org/0000-0001-7768-3047, Montero, Héctor; https://orcid.org/0000-0001-8590-6394, Gehrig, Peter, Grossmann, Jonas, O'Holleran, Kevin, Hartken, Denise, Walters, Fergus, Yang, Shu-Yi, Hillmer, Stefan, Schumacher, Karin, Bowden, Sarah; https://orcid.org/0000-0001-5105-076X, Craze, Melanie, Wallington, Emma J; https://orcid.org/0000-0003-3715-7901, Miyao, Akio; https://orcid.org/0000-0002-2822-2866, Sawers, Ruairidh, Martinoia, Enrico, Paszkowski, Uta; https://orcid.org/0000-0002-7279-7632, Roth, Ronelle; https://orcid.org/0000-0001-5566-8954, Chiapello, Marco; https://orcid.org/0000-0001-7768-3047, Montero, Héctor; https://orcid.org/0000-0001-8590-6394, Gehrig, Peter, Grossmann, Jonas, O'Holleran, Kevin, Hartken, Denise, Walters, Fergus, Yang, Shu-Yi, Hillmer, Stefan, Schumacher, Karin, Bowden, Sarah; https://orcid.org/0000-0001-5105-076X, Craze, Melanie, Wallington, Emma J; https://orcid.org/0000-0003-3715-7901, Miyao, Akio; https://orcid.org/0000-0002-2822-2866, Sawers, Ruairidh, Martinoia, Enrico, and Paszkowski, Uta; https://orcid.org/0000-0002-7279-7632

Abstract

In terrestrial ecosystems most plant species live in mutualistic symbioses with nutrient-delivering arbuscular mycorrhizal (AM) fungi. Establishment of AM symbioses includes transient, intracellular formation of fungal feeding structures, the arbuscules. A plant-derived peri-arbuscular membrane (PAM) surrounds the arbuscules, mediating reciprocal nutrient exchange. Signaling at the PAM must be well coordinated to achieve this dynamic cellular intimacy. Here, we identify the PAM-specific Arbuscular Receptor-like Kinase 1 (ARK1) from maize and rice to condition sustained AM symbiosis. Mutation of rice ARK1 causes a significant reduction in vesicles, the fungal storage structures, and a concomitant reduction in overall root colonization by the AM fungus Rhizophagus irregularis. Arbuscules, although less frequent in the ark1 mutant, are morphologically normal. Co-cultivation with wild-type plants restores vesicle and spore formation, suggesting ARK1 function is required for the completion of the fungal life-cycle, thereby defining a functional stage, post arbuscule development.

Published

2018

5. Food processing and breeding strategies for coeliac-safe and healthy wheat products

Author

Jouanin, Aurélie, Gilissen, Luud J.W.J., Boyd, Lesley A., Cockram, James, Leigh, Fiona J., Wallington, Emma J., van den Broeck, Hetty C., van der Meer, Ingrid M., Schaart, Jan G., Visser, Richard G.F., Smulders, Rene, Jouanin, Aurélie, Gilissen, Luud J.W.J., Boyd, Lesley A., Cockram, James, Leigh, Fiona J., Wallington, Emma J., van den Broeck, Hetty C., van der Meer, Ingrid M., Schaart, Jan G., Visser, Richard G.F., and Smulders, Rene

Abstract

A strict gluten-free diet is currently the only treatment for the 1-2% of the world population who suffer from coeliac disease (CD). However, due to the presence of wheat and wheat derivatives in many food products, avoiding gluten consumption is difficult. Gluten-free products, made without wheat, barley or rye, typically require the inclusion of numerous additives, resulting in products that are often less healthy than gluten-based equivalents. Here, we present and discuss two broad approaches to decrease wheat gluten immunogenicity for CD patients. The first approach is based on food processing strategies, which aim to remove gliadins or all gluten from edible products. We find that several of the candidate food processing techniques to produce low gluten-immunogenic products from wheat already exist. The second approach focuses on wheat breeding strategies to remove immunogenic epitopes from the gluten proteins, while maintaining their food-processing properties. A combination of breeding strategies, including mutation breeding and possibly genome editing, will be necessary to produce coeliac-safe wheat. Individuals suffering from CD and people genetically susceptible who may develop CD after prolonged gluten consumption would benefit from reduced CD-immunogenic wheat. Although the production of healthy and less CD-toxic wheat varieties and food products will be challenging, increasing global demand may require these issues to be addressed in the near future by food processing and cereal breeding companies.

Published

2018

6. A PSTOL-like gene, TaPSTOL, controls a number of agronomically important traits in wheat

Author

Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, Wallington, Emma J., Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, and Wallington, Emma J.

Abstract

Background Phosphorus (P) is an essential macronutrient for plant growth, and is required in large quantities by elite varieties of crops to maintain yields. Approximately 70% of global cultivated land suffers from P deficiency, and it has recently been estimated that worldwide P resources will be exhausted by the end of this century, increasing the demand for crops more efficient in their P usage. A greater understanding of how plants are able to maintain yield with lower P inputs is, therefore, highly desirable to both breeders and farmers. Here, we clone the wheat (Triticum aestivum L.) homologue of the rice PSTOL gene (OsPSTOL), and characterize its role in phosphate nutrition plus other agronomically important traits. Results TaPSTOL is a single copy gene located on the short arm of chromosome 5A, encoding a putative kinase protein, and shares a high level of sequence similarity to OsPSTOL. We re-sequenced TaPSTOL from 24 different wheat accessions and (3) three T. durum varieties. No sequence differences were detected in 26 of the accessions, whereas two indels were identified in the promoter region of one of the durum wheats. We characterised the expression of TaPSTOL under different P concentrations and demonstrated that the promoter was induced in root tips and hairs under P limiting conditions. Overexpression and RNAi silencing of TaPSTOL in transgenic wheat lines showed that there was a significant effect upon root biomass, flowering time independent of P treatment, tiller number and seed yield, correlating with the expression of TaPSTOL. However this did not increase PUE as elevated P concentration in the grain did not correspond to increased yields. Conclusions Manipulation of TaPSTOL expression in wheat shows it is responsible for many of the previously described phenotypic advantages as OsPSTOL except yield. Furthermore, we show TaPSTOL contributes to additional agronomically important traits including flowering time and grain size. Analysis of TaPSTO

7. A PSTOL-like gene, TaPSTOL, controls a number of agronomically important traits in wheat

Author

Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, Wallington, Emma J., Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, and Wallington, Emma J.

Abstract

Background Phosphorus (P) is an essential macronutrient for plant growth, and is required in large quantities by elite varieties of crops to maintain yields. Approximately 70% of global cultivated land suffers from P deficiency, and it has recently been estimated that worldwide P resources will be exhausted by the end of this century, increasing the demand for crops more efficient in their P usage. A greater understanding of how plants are able to maintain yield with lower P inputs is, therefore, highly desirable to both breeders and farmers. Here, we clone the wheat (Triticum aestivum L.) homologue of the rice PSTOL gene (OsPSTOL), and characterize its role in phosphate nutrition plus other agronomically important traits. Results TaPSTOL is a single copy gene located on the short arm of chromosome 5A, encoding a putative kinase protein, and shares a high level of sequence similarity to OsPSTOL. We re-sequenced TaPSTOL from 24 different wheat accessions and (3) three T. durum varieties. No sequence differences were detected in 26 of the accessions, whereas two indels were identified in the promoter region of one of the durum wheats. We characterised the expression of TaPSTOL under different P concentrations and demonstrated that the promoter was induced in root tips and hairs under P limiting conditions. Overexpression and RNAi silencing of TaPSTOL in transgenic wheat lines showed that there was a significant effect upon root biomass, flowering time independent of P treatment, tiller number and seed yield, correlating with the expression of TaPSTOL. However this did not increase PUE as elevated P concentration in the grain did not correspond to increased yields. Conclusions Manipulation of TaPSTOL expression in wheat shows it is responsible for many of the previously described phenotypic advantages as OsPSTOL except yield. Furthermore, we show TaPSTOL contributes to additional agronomically important traits including flowering time and grain size. Analysis of TaPSTO

8. A PSTOL-like gene, TaPSTOL, controls a number of agronomically important traits in wheat

Author

Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, Wallington, Emma J., Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, and Wallington, Emma J.

Abstract

Background Phosphorus (P) is an essential macronutrient for plant growth, and is required in large quantities by elite varieties of crops to maintain yields. Approximately 70% of global cultivated land suffers from P deficiency, and it has recently been estimated that worldwide P resources will be exhausted by the end of this century, increasing the demand for crops more efficient in their P usage. A greater understanding of how plants are able to maintain yield with lower P inputs is, therefore, highly desirable to both breeders and farmers. Here, we clone the wheat (Triticum aestivum L.) homologue of the rice PSTOL gene (OsPSTOL), and characterize its role in phosphate nutrition plus other agronomically important traits. Results TaPSTOL is a single copy gene located on the short arm of chromosome 5A, encoding a putative kinase protein, and shares a high level of sequence similarity to OsPSTOL. We re-sequenced TaPSTOL from 24 different wheat accessions and (3) three T. durum varieties. No sequence differences were detected in 26 of the accessions, whereas two indels were identified in the promoter region of one of the durum wheats. We characterised the expression of TaPSTOL under different P concentrations and demonstrated that the promoter was induced in root tips and hairs under P limiting conditions. Overexpression and RNAi silencing of TaPSTOL in transgenic wheat lines showed that there was a significant effect upon root biomass, flowering time independent of P treatment, tiller number and seed yield, correlating with the expression of TaPSTOL. However this did not increase PUE as elevated P concentration in the grain did not correspond to increased yields. Conclusions Manipulation of TaPSTOL expression in wheat shows it is responsible for many of the previously described phenotypic advantages as OsPSTOL except yield. Furthermore, we show TaPSTOL contributes to additional agronomically important traits including flowering time and grain size. Analysis of TaPSTO

9. A PSTOL-like gene, TaPSTOL, controls a number of agronomically important traits in wheat

Author

Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, Wallington, Emma J., Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, and Wallington, Emma J.

Abstract

Background Phosphorus (P) is an essential macronutrient for plant growth, and is required in large quantities by elite varieties of crops to maintain yields. Approximately 70% of global cultivated land suffers from P deficiency, and it has recently been estimated that worldwide P resources will be exhausted by the end of this century, increasing the demand for crops more efficient in their P usage. A greater understanding of how plants are able to maintain yield with lower P inputs is, therefore, highly desirable to both breeders and farmers. Here, we clone the wheat (Triticum aestivum L.) homologue of the rice PSTOL gene (OsPSTOL), and characterize its role in phosphate nutrition plus other agronomically important traits. Results TaPSTOL is a single copy gene located on the short arm of chromosome 5A, encoding a putative kinase protein, and shares a high level of sequence similarity to OsPSTOL. We re-sequenced TaPSTOL from 24 different wheat accessions and (3) three T. durum varieties. No sequence differences were detected in 26 of the accessions, whereas two indels were identified in the promoter region of one of the durum wheats. We characterised the expression of TaPSTOL under different P concentrations and demonstrated that the promoter was induced in root tips and hairs under P limiting conditions. Overexpression and RNAi silencing of TaPSTOL in transgenic wheat lines showed that there was a significant effect upon root biomass, flowering time independent of P treatment, tiller number and seed yield, correlating with the expression of TaPSTOL. However this did not increase PUE as elevated P concentration in the grain did not correspond to increased yields. Conclusions Manipulation of TaPSTOL expression in wheat shows it is responsible for many of the previously described phenotypic advantages as OsPSTOL except yield. Furthermore, we show TaPSTOL contributes to additional agronomically important traits including flowering time and grain size. Analysis of TaPSTO

10. A PSTOL-like gene, TaPSTOL, controls a number of agronomically important traits in wheat

Author

Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, Wallington, Emma J., Milner, Matthew J., Howells, Rhian M., Craze, Melanie, Bowden, Sarah, Graham, Neil, and Wallington, Emma J.

Abstract

Background Phosphorus (P) is an essential macronutrient for plant growth, and is required in large quantities by elite varieties of crops to maintain yields. Approximately 70% of global cultivated land suffers from P deficiency, and it has recently been estimated that worldwide P resources will be exhausted by the end of this century, increasing the demand for crops more efficient in their P usage. A greater understanding of how plants are able to maintain yield with lower P inputs is, therefore, highly desirable to both breeders and farmers. Here, we clone the wheat (Triticum aestivum L.) homologue of the rice PSTOL gene (OsPSTOL), and characterize its role in phosphate nutrition plus other agronomically important traits. Results TaPSTOL is a single copy gene located on the short arm of chromosome 5A, encoding a putative kinase protein, and shares a high level of sequence similarity to OsPSTOL. We re-sequenced TaPSTOL from 24 different wheat accessions and (3) three T. durum varieties. No sequence differences were detected in 26 of the accessions, whereas two indels were identified in the promoter region of one of the durum wheats. We characterised the expression of TaPSTOL under different P concentrations and demonstrated that the promoter was induced in root tips and hairs under P limiting conditions. Overexpression and RNAi silencing of TaPSTOL in transgenic wheat lines showed that there was a significant effect upon root biomass, flowering time independent of P treatment, tiller number and seed yield, correlating with the expression of TaPSTOL. However this did not increase PUE as elevated P concentration in the grain did not correspond to increased yields. Conclusions Manipulation of TaPSTOL expression in wheat shows it is responsible for many of the previously described phenotypic advantages as OsPSTOL except yield. Furthermore, we show TaPSTOL contributes to additional agronomically important traits including flowering time and grain size. Analysis of TaPSTO