Received July 2, 2006
Accepted September 20, 2006
Developmental and Embryo Axis Regulation of Gibberellin Biosynthesis during Germination and Young Seedling Growth of Pea (Pisum sativum L.)
Belay T. Ayele , Jocelyn A. Ozga *, Leonid V. Kurepin , and Dennis M. Reinecke
Plant Physiology and Molecular Biology Research Group, Department of Agricultural, Food and Nutritional Science, University of Alberta, 4-10 Agriculture/Forestry Centre, Edmonton, Alberta, Canada T6G 2P5
Department of Biological Sciences, University of Calgary, Biological Sciences Bld, University Dr. 2500 NW, Calgary, Alberta, Canada T2N 1N4
* Corresponding author; email: jocelyn.ozga{at}ualberta.ca.
The expression patterns of five genes (PsGA20ox1, PsGA20ox2, PsGA3ox1, PsGA2ox1 and PsGA2ox2) encoding five regulatory GA biosynthesis enzymes (two GA 20-oxidases, a GA 3
-hydroxylase and two GA 2-hydroxylases) were examined to gain insight into how these genes coordinate GA biosynthesis during germination and early post-germination stages of the large-seeded dicotyledonous plant, pea (Pisum sativum L.). At the time the developing embryo fills the seed coat, high mRNA levels of PsGA20ox2 (primarily responsible for conversion of C20-GAs to GA20), PsGA2ox1 (primarily responsible for conversion of GA20 to GA29) and PsGA2ox2 (primarily responsible for conversion of GA1 to GA8) were detected in the seeds, along with high GA20 and GA29 levels, the enzymatic products of these genes. Embryo maturation was accompanied by a large reduction in PsGA20ox2 and PsGA2ox1 mRNA and lower GA20 and GA29 levels. However, PsGA2ox2 transcripts remained high. Following seed imbibition, GA20 levels in the cotyledons decreased while PsGA3ox1 mRNA and GA1 levels increased, implying that GA20 was being used for de novo synthesis of GA1. The presence of the embryo axis was required for stimulation of cotyledonary GA1 synthesis at the mRNA and enzyme activity levels. As the embryo axis doubled in size, PsGA20ox1 and PsGA3ox1 transcripts increased, both GA1 and GA8 were detectable, PsGA2ox2 transcripts decreased, and PsGA2ox1 transcripts remained low. Cotyledonary-, root- and shoot-specific expression of these GA biosynthesis genes and the resultant endogenous GA profiles support a key role for de novo GA biosynthesis in each organ during germination and early seedling growth of pea.
