Photosynthetic Down Regulation of Young Hybrid Larch Trees in Nitrogen Poor and Rich Soil
Watanabe, M., Watanabe, Y., Kitaoka, S., Utsugi, H., Kita, K. and Koike, T. 2011. Growth and photosynthetic traits of hybrid larch F1 (Larix gmelinii var. japonica x L. kaempferi) under elevated CO2 concentration with low nutrient availability. Tree Physiology 31: 965-975.
In a study that sheds further light on this complex topic, Watanabe et al. (2011) grew three-year-old seedlings of hybrid larch F1 (Larix gmelinii var. japonica x Larix kaempferi) for 139 days under two different concentrations of atmospheric CO2 (360 and 720 ppm) together with two levels of soil nitrogen (N) supply -- low and high (0 and 30 kg/ha, respectively) -- in 7-liter pots placed within phytotrons located in Sapporo, Japan. This they did under natural daylight conditions (~90% of full sunlight) and at day/night temperatures of 25/16°C; and on the 118th day of the experiment, between 0900 and 1500 hours, they made numerous net photosynthesis rate measurements, while at the end of the 139-day period they harvested the trees and determined their increase in dry-weight biomass.
The six scientists report that there was no significant difference between the net photosynthetic rates of the trees grown at the two different CO2 concentrations in either the low or high soil N treatments at the 118th day of the study, indicative of an essentially complete down-regulation of this important plant process. Nevertheless, they state that the biomass gained by the trees over the full 139-day experiment was significantly enhanced in the CO2-enriched air: by fully 44% in the low soil N treatment and 35% in the high soil N treatment.
As for how these large growth stimulations could have occurred, Watanabe et al. surmise that net photosynthesis rates under elevated CO2 would have been higher than those under ambient CO2 "during the early period of the experiment (short-term response to elevated CO2), in turn causing the seedlings under elevated CO2 to use more carbohydrates to produce needles." And they thus conclude that the greater number of needles in the CO2-enriched trees led to "an increase in the assimilation of the whole-plant scale even after down-regulation of photosynthesis," which would obviously have led to a greater production of biomass in the CO2-enriched trees.
The implications of these observations are rather straightforward. In the words of the Japanese researchers, "these results suggest that elevated CO2 may increase the growth of hybrid larch F1 even under low nutrient availability," such that "the growth of hybrid larch F1 may be stimulated under future elevated CO2," irrespective of soil nutrient conditions.