Quantitation of Gibberellins A1 A3 A4 A9 and a Putative A9-Conjugate in Grafts of Sitka Spruce (Picea sitchensis) during the Period of Shoot Elongation

摘要

The levels of endogenous gibberellin A1 (GA1), GA3, GA4, GA9, and a cellulase hydrolyzable GA9 conjugate in needles and shoot stems of mature grafts of Sitka spruce (Picea sitchensis [Bong.] Carr.) grown under environmental conditions that were either inductive, hot, and dry, or noninductive, cool, and wet, for flowering, were estimated by combined gas chromatography-mass spectrometry selected ion monitoring using deuterated [²H2]GA1, GA3, GA4, and GA9 as internal standards. The samples were taken when the shoots had elongated about 30, 70, and 95% of the final shoot length and 17 days after elongation had terminated. The concentration of putative GA9-conjugate, estimated by GCSIM of GA9 after cellulase hydrolysis of the highly water soluble fraction, was 33 nanograms per gram fresh weight in the needles of both heat and drought- and cool and wet-treated plants sampled just after bud burst. The concentration gradually decreased to a final value of 13 nanograms per gram fresh weight in the heat and drought-treated grafts and 6 nanograms per gram fresh weight in the cool and wet-treated grafts. The stems contained no detectable putative GA9 conjugate. Free GA9 was highest in heat and drought-treated material. For plants subjected to this treatment, GA9 increased from 22 to 32 nanograms per gram fresh weight in needles and from 1 to 22 nanograms per gram fresh weight in stems during the rapid stem elongation phase. By day 17, after cessation of shoot elongation, GA₉ had decreased to 12 nanograms per gram fresh weight in needles and 9 nanograms per gram fresh weight in the shoot stems. The cool and wet-treated material also showed an increase in GA₉ concentration during shoot elongation. However, the concentration was not as high and was also delayed compared with heat and drought-treated material. By day 17, after cessation of shoot elongation, GA₉ concentration was 9 nanograms per gram fresh weight in needles and 5 nanograms per gram fresh weight in stems for cool and wet treatment plants. The concentration of GA₄ was very low in tissue from both treatments. Fluctuation in concentration of the more polar gibberellins, GA₁ and GA₃, showed the same pattern as fluctuations in the content of GA₉. However, the heat and drought-treated material had lower amounts of GA₁ and GA₃ during the later phases of shoot elongation, than the cool and wet-treated material. These results imply differential metabolism between clones treated with conditions inductive and noninductive for flowering. Higher concentrations of putative GA₉ conjugate and free GA₉ in the hot and dry treatment indicate a higher capacity of synthesizing, for flowering, the physiologically important GA₄ in the heat and drought-treated material. This synthesis does not, however, result in a buildup of the GA₄ pool, probably because of a high turnover rate of GA₄. The cool and wet-treated material had higher amounts of GA₁ and GA₃, indicating that the differentiation was preferentially directed toward vegetative growth.