Abstract
Picea pungens (Engelm.), known for its blue-green needles, has become a likable ornamental species in northeast China since 2000. Nonetheless, a lack of propagation methods that can maintain genetic fidelity and develop seedlings at a large scale prevents the further expansion of the species. Somatic embryogenesis (SE), paired with cryopreservation technologies, may provide a valid alternative. Picea pungens SE is not new, but its practical application has been limited due to low efficiencies in SE initiation and maturation as well as a lack of effective cryopreservation technology. In this study, experiments were carried out to overcome the limitations by modifying culture media. For initiation, the efficiency was enhanced by adjusting concentrations of 2.4-dichlorophenoxy acetic acid (2,4-D), 6-benzyl amino–purine (6-BA) or sucrose supplemented to the induction medium. The concentrations of 4.0 mg/L 2,4-D, 2 mg/L 6-BA, and 5 to 10 g/L sucrose were found optimal in maximizing initiation efficiency. For maturation, the efficiency, expressed as the number of mature somatic embryos per gram of fresh mass cultured (E/gFM), varied greatly with the choices of the basal medium and concentration of abscisic acid (ABA) of the maturation medium. Based on our results, the judicial choices were using the DCR medium as the basal medium and 10 mg/L ABA. The maturation efficiency could also be improved by adjusting the maturation medium’s osmotic pressure by manipulating the concentrations of carbohydrate and Gelrite and culture density. While the maturation medium, using sucrose as carbohydrate source or supplemented with a low (<8 g/L) Gelrite concentration, facilitated maturation, optimal selections were truly genotype-dependent. Our results also suggest that, while the optimal culture density varied with genotype, in general it is needless to culture more than 100 mg embryogenesis tissues per dish (size: 10 × 1.5 cm). Based on this study, the optimum pretreatment for embryogenesis tissue cryopreservation was culturing the tissues on the proliferation medium with 0.4 mol/L sorbitol for 24 h, followed by treatment with 5% Dimethyl sulfoxide. This study significantly improved the initiation (achieved a frequency of 0.56) and embryo maturation efficiencies (achieved 1030 E/gFM) and established an effective preculturing protocol for cryopreservation (recovered 1354 E/gFM) for the species. The protocols developed here, paired with the available ones for other SE steps in the literature, form a well-refined SE technology intended for commercial application to Picea pungens.
Funder
Major Science and Technology Project “Research on Collection and Preservation Technologies of Germplasm Resources in the Trees of Changbai Mountain” of Jilin Provincial Forestry
Central Finance of China
Reference45 articles.
1. Somatic embryogenesis in mature zygotic embryos of Picea pungens;Tao;Sci. Rep.,2021
2. Implementation of conifer somatic embryogenesis in clonal forestry: Technical requirements and deployment considerations;Park;Ann. For. Sci.,2002
3. Somatic embryogenesis and plant regeneration from zygotic embryo culture in blue spruce (Picea pungens Engelmann);Afele;Plant Cell Rep.,1992
4. Somatic embryogenesis of Picea pungens Engelmann;Sun;J. Beijing For. Univ.,2010
5. Somatic embryogenesis of selected spruce species (Picea abies, Picea omorika, Picea pungens ‘Glauca’ and Picea breweriana);Bojarczuk;Acta Soc. Bot. Pol. Pol.,2008
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