Your search keyword '"Wohor, Osman Z."' showing total 3 results

1. Genome-Wide Association Studies on Resistance to Pea Weevil: Identification of Novel Sources of Resistance and Associated Markers.

Author

Osuna-Caballero, Salvador, Cobos, María J., Ruiz, Carmen M., Wohor, Osman Z., Rispail, Nicolas, and Rubiales, Diego

Subjects

GENOME-wide association studies, CURCULIONIDAE, TRANSCRIPTION factors, MYB gene, PEAS, INSECT pests

Abstract

Little resistance to the pea weevil insect pest (Bruchus pisorum) is available in pea (Pisum sativum) cultivars, highlighting the need to search for sources of resistance in Pisum germplasm and to decipher the genetic basis of resistance. To address this need, we screened the response to pea weevil in a Pisum germplasm collection (324 accession, previously genotyped) under field conditions over four environments. Significant variation for weevil seed infestation (SI) was identified, with resistance being frequent in P. fulvum, followed by P. sativum ssp. elatius, P. abyssinicum, and P. sativum ssp. humile. SI tended to be higher in accessions with lighter seed color. SI was also affected by environmental factors, being favored by high humidity during flowering and hampered by warm winter temperatures and high evapotranspiration during and after flowering. Merging the phenotypic and genotypic data allowed genome-wide association studies (GWAS) yielding 73 markers significantly associated with SI. Through the GWAS models, 23 candidate genes were found associated with weevil resistance, highlighting the interest of five genes located on chromosome 6. These included gene 127136761 encoding squalene epoxidase; gene 127091639 encoding a transcription factor MYB SRM1; gene 127097033 encoding a 60S ribosomal protein L14; gene 127092211, encoding a BolA-like family protein, which, interestingly, was located within QTL BpLD.I, earlier described as conferring resistance to weevil in pea; and gene 127096593 encoding a methyltransferase. These associated genes offer valuable potential for developing pea varieties resistant to Bruchus spp. and efficient utilization of genomic resources through marker-assisted selection (MAS). [ABSTRACT FROM AUTHOR]

Published

2024

2. Pea Breeding for Resistance to Rhizospheric Pathogens

Author

Wohor, Osman Z., primary, Rispail, Nicolas, additional, Ojiewo, Chris O., additional, and Rubiales, Diego, additional

Published

2022

3. Pea Breeding for Resistance to Rhizospheric Pathogens

Author

Agencia Estatal de Investigación (España), Ministerio de Ciencia e Innovación (España), International Crops Research Institute for the Semi-Arid Tropics, Wohor, Osman Z., Rispail, Nicolas, Ojiewo, Chris O., Rubiales, Diego, Agencia Estatal de Investigación (España), Ministerio de Ciencia e Innovación (España), International Crops Research Institute for the Semi-Arid Tropics, Wohor, Osman Z., Rispail, Nicolas, Ojiewo, Chris O., and Rubiales, Diego

Abstract

Pea (Pisum sativum L.) is a grain legume widely cultivated in temperate climates. It is important in the race for food security owing to its multipurpose low-input requirement and environmental promoting traits. Pea is key in nitrogen fixation, biodiversity preservation, and nutritional functions as food and feed. Unfortunately, like most crops, pea production is constrained by several pests and diseases, of which rhizosphere disease dwellers are the most critical due to their long-term persistence in the soil and difficulty to manage. Understanding the rhizosphere environment can improve host plant root microbial association to increase yield stability and facilitate improved crop performance through breeding. Thus, the use of various germplasm and genomic resources combined with scientific collaborative efforts has contributed to improving pea resistance/cultivation against rhizospheric diseases. This improvement has been achieved through robust phenotyping, genotyping, agronomic practices, and resistance breeding. Nonetheless, resistance to rhizospheric diseases is still limited, while biological and chemical-based control strategies are unrealistic and unfavourable to the environment, respectively. Hence, there is a need to consistently scout for host plant resistance to resolve these bottlenecks. Herein, in view of these challenges, we reflect on pea breeding for resistance to diseases caused by rhizospheric pathogens, including fusarium wilt, root rots, nematode complex, and parasitic broomrape. Here, we will attempt to appraise and harmonise historical and contemporary knowledge that contributes to pea resistance breeding for soilborne disease management and discuss the way forward.

Published

2022