ASHS 2024 Conference

The genus Miscanthus is considered an ideal choice for both ornamental and biofuel purposes, owing to its appealing aesthetics and significant potential for high-energy biomass production. Traditional breeding efforts in Miscanthus have predominantly focused on enhancing nutrient efficiency and tolerance to both biotic and abiotic stresses. However, these endeavors are often time-consuming. The emergence of plant genome editing technologies has opened up a new and efficient avenue for Miscanthus breeding. These innovative techniques hold promise for accelerating the breeding process, allowing for more rapid and targeted improvements in desired traits. The development of an efficient plant regeneration system is crucial for the application of modern genome editing technologies in Miscanthus breeding and for achieving large-scale biomass production. Among the Miscanthus species, Miscanthus sinensis poses a particular challenge in tissue culture regeneration. In this report, we present an effective system for callus induction and regeneration in Miscanthus sinensis. Callus was induced from the stems of in vitro-cultured Miscanthus sinensis 'Gracillimus' using a modified MS media supplemented with varying levels of 2,4-D. Regeneration-competent callus was achieved through continuous selection on the callus maintenance/selection medium over a period of 6 months. Remarkably, 100% of the callus successfully regenerated new shoots on a modified MS medium containing Benzylaminopurine (6-BA) and α-Naphthaleneacetic acid (NAA). This marks the first efficient 'Gracillimus' regeneration system using in vitro culture as the starting material. The established system demonstrates a high potential for the micropropagation of Miscanthus sinensis 'Gracillimus' with a propagation rate of 3.5. Currently, efforts are underway for genome editing of Miscanthus sinensis utilizing this established system.