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Abstract
Purpose: Inflorescence architecture is an important trait in the seed production of grain legumes. As several genes are responsible for this trait, any mutation, on these genes, may cause change in the inflorescence architecture. This study was conducted to evaluate inflorescence architecture in faba bean exposed to gamma radiation and to characterize the inflorescence architecture mutants phenotypically.
Materials and methods: Faba bean M2 seeds (4898) generated from M1 generation of cultivars Hassawi 2 and ILB4347 were used in this study. M1 seeds were produced by irradiation treatments at two doses of gamma radiations (25 and 50 Gy). Faba bean M2 seeds were planted under field conditions. A total of 4032 mutant plants out of 4898 M2 seeds were evaluated for their inflorescence architecture.
Results: A total of 20 determinate mutants were found and classified into four different types. Determinate type 1 was characterized by the formation of single terminal inflorescence on shoot apical meristem (SAM), type 2 by the formation of multiple inflorescences on SEM and generated upper branches that act as indeterminate type. Type 3 was characterized by the formation of a panicle-like inflorescence. While type 4 was characterized by the formation of primary and secondary panicle-like inflorescence. All of the determinate mutant types had shorter plant height and earlier maturity than control indeterminate type but had lower biological yield and seed yield. Among the determinate mutant types, determinate type 1 was only mutant that had a higher harvest index than the control indeterminate type. This promising mutant can be used to further breeding program to increase biological yield and seed yield.
Conclusions: This study indicated potential of gamma radiation in inducing novel inflorescence architecture in faba bean. The mutants developed are valuable resources to study genes related to inflorescence architecture through forward genetics approach.
Disclosure statement
No potential conflict of interest was reported by the authors.
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Notes on contributors
Nurmansyah
Nurmansyah, Plant breeder utilizing classical and molecular tools for improving crops for tolerance to biotic and abiotic stresses and focusing his research on mutation breeding.
Salem S. Alghamdi
Salem S. Alghamdi, Professor of Plant Breeding. He is involved in conservation and utilization of plant genetic resources for crop improvements. His research mainly focused on development of high-yielding and nutritionally enriched legume crops for stressful environments.
Hussein M. Migdadi
Hussein M. Migdadi, Associate Professor of Molecular Plant Breeding. He is involved in molecular characterization of plant biodiversity, using statistical methods in natural resources management, and evaluation and utilization of plant genetic resources for crop tolerance against abiotic stresses.
Muhammad Farooq
Muhammad Farooq, Associate Professor of Crop Physiology. His research is focused the exploring the mechanisms and causes of the stress effects on plant growth and development. He is also working to develop climate-resilient management strategies for harvesting good crop yields under dry and hot environments.