Encouraging progress in the mutation breeding has been achieved since a mutation induction has become increasingly important for a cultivar development for complex reproductive or propagating modes, the creation of new genetic resources, especially for crops with a narrow genetic base, and the use of mutants for a genomics study. In Korea, more than 35 cultivars have been released by using the mutation breeding method since the mid-1960s, and the released cultivars were mostly developed (76%) by exposing to radiations (gamma and/or X-ray). Most of the released mutant cultivars (74%) in Korea were food and oil seed crops, especially for improving agronomic traits such as yield, lodging tolerance, maturity, or functional compounds. Currently a high yield potential of cultivated crop cultivars is relatively less popular than before, but the expectation of value-added crops, from the farmer’s side, is in high demand. Accordingly, the mutation breeding program in Korea has assigned more resources to other crop species, including some flowering and ornamental plants. These flowering and ornamental plants are ideal systems for a mutation breeding because their favored traits such as flower color or shape or plant architecture can be visually monitored after a mutagenic treatment. Additionally, these plant species are genetically heterozygous and often propagated vegetatively, which allows for an isolation and selection of mutants within M1 generation. In Korea, a program for the development of potential cultivars of flowering and ornamental crops was launched with financial support from the Biogreen 21 project in RDA. Thisintegrated program which will be conducted by a diverse array of experts will focus on major flowering and ornamental crops in Korea such as rose, chrysanthemum, lily, carnation, orchids, and clover. The potential outcomes from the program will be new highly valued-added cultivars which will provide greater money gains to Korean farmers and lots of valued mutants used for a gene isolation of interest and reverse genetics or functional genomics. Appropriate strategies should be implemented to complete its goals successfully, which includes a)induction of a wide mutant spectrum, b)applications of new irradiation techniques, c)unraveling the complex genetic phenomena controlling mutant traits, and d)development of a mass production and an intensive export system for the developed cultivars.

• Si-Yong Kang(Radiation Plant Breeding and Genetics Lab., Radiation Research Center for Bio-Technology, Korea Atomic Energy Research Institute (KAERI))
• Geung-Joo Lee(Radiation Plant Breeding and Genetics Lab., Radiation Research Center for Bio-Technology, Korea Atomic Energy Research Institute (KAERI))