Identification and analysis of gibberellin 2-oxidase (GA2ox) members in Cunninghamia lanceolate and the negative regulatory character of ClGA2ox12 in tree stature and xylem lignin deposits

Abstract

Cunninghamia lanceolata (Lamb.) Hook (C. lanceolate) is a fast-growing evergreen coniferous tree species with high wood yield and fantabulous timber quality. To date, numerous studies have revealed that gibberellins (GAs) regulate the formation of plant wood (secondary xylem). Moreover, GA 2-oxidases (GA2oxs) are known as the major enzymes that deactivate GAs. However, a small or no number of the GA2oxs involved in xylem development and lignin biosynthesis mediated by the GA pathway in woody plants have been identified previously. In this study, 5 GA2oxs members were identified in C. lanceolate, including 4 ClGA2ox12s and one ClGA2ox8-like. Exogenous gibberellin not only promoted lignin deposition in the stem of C. lanceolate but also up-regulated the expression of the lignin biosynthesis gene ClCAD1 by 2–3 folds and one of ClGA2ox12s (designated ClGA2ox12) by 4 folds, suggesting that ClGA2ox12 may be involved in the modulation of lignin deposition by the gibberellin signaling pathway in C. lanceolate. Furthermore, transgenic Populus tomentosa overexpressing ClGA2ox12 exhibited growth retardation and a typical dwarfing phenotype, with a reduction of approximately 40 % in the number of xylem cell layers and a decrease of approximately 16.7 %-26.9 % in lignin content relative to wild-type plants. At the same time, the expression level of lignin biosynthetic genes and lignin content were down-regulated in transgenic plants. Together, these results suggested that ClGA2ox12 functioned as a GA 2oxs catabolic enzyme that plays pivotal roles in plant growth processes, xylem development, and lignin biosynthesis, which gives insights into producing dwarf and low-lignin varieties of C. lanceolate.