Abstract
The irradiation of dry seeds is the most widely-used irradiation method for improving seed-propagated crops; however, the irradiation of other tissues also has useful effects. The irradiation of plant reproductive organs, rather than seeds, for mutation breeding has advantages, such as producing non-chimeric progeny. However, the mutation frequency and spectrum produced using this method have not been analyzed on a genome-wide level. We performed a genotype-by-sequencing analysis to determine the frequencies of single-base substitutions and small (1–2 bp) insertions and deletions in hot pepper (Capsicum annuum L.) plants derived from crosses using gamma-irradiated female or male gametophytes. The progeny of irradiated gametophytes showed similar or higher DNA mutation frequencies, which were dependent on the irradiation dose and irradiated tissue, and less biased single base substitutions than progeny of irradiated seeds. These characteristics were expected to be beneficial for development of mutation population with a high frequency of small DNA mutations and performing reverse-genetics-based mutation screening. We also examined the possible use of this irradiation method in manipulating the meiotic recombination frequency; however, no statistically significant increase was detected. Our results provide useful information for further research and breeding using irradiated gametophytes.
Highlights
Irradiation has long been used in various ways for crop improvement
Increasing the meiotic recombination frequency in gametogenesis using irradiation was attempted based on the assumption that DNA damage, including double-strand breaks caused by irradiation, affects the recombination frequency [5]
We investigated, using a GBS analysis, the frequencies of mutations, and meiotic recombination events in gametes generated from the irradiated reproductive organs of hot pepper (Capsicum annuum L.), to examine the applicability of irradiating these tissues for crop improvement
Summary
In which mutagenesis by irradiation is used to develop a mutation population, followed by the selection of lines with useful agronomic characteristics, has been most widely used in this area since Stadler [1,2] reported the first induced crop mutation resulting from X-irradiation. Increasing the meiotic recombination frequency in gametogenesis using irradiation was attempted based on the assumption that DNA damage, including double-strand breaks caused by irradiation, affects the recombination frequency [5]. Irradiation conditions, including types of radiation and plant tissues, are factors that affect the spectra and frequencies of DNA mutations, which are important determinants of the range of mutant phenotypes and the size of the mutation population required to obtain a certain proportion of mutant individuals [6]
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