Deviation between δ13C and Leaf Intercellular CO2inSalix interiorCuttings Developing under Low Light

Abstract

Leaf δ¹³C values of perennial species are sometimes less negative than model‐predicted δ¹³C values derived from instantaneous measures of p_i/p_a. It has been hypothesized that the less negative δ¹³C values could be caused by ¹³C‐enriched stored carbon imported during the early stages of leaf growth. The δ¹³C values of newly emerging leaves could thus represent δ¹³C values of stem‐stored carbohydrates and may also provide integral measures of p_i/p_a at the end of the past growing season. We tested these hypotheses by sprouting cuttings of Salix interior under wet and dry soil‐moisture conditions in a controlled environmental chamber. Plants were defoliated after 56 d, and watering treatments were then reversed for half of the plants in each treatment. The δ¹³C values of newly emerging leaves did not correlate with p_i/p_a ratios of newly emerging leaves or of mature leaves prior to defoliation, thereby indicative that δ¹³C values of newly emerging leaves are not a simple reflection of prior p_i/p_a. Also, the δ¹³C values of newly emerging leaves were more enriched in ¹³C relative to the δ¹³C values of stem carbohydrates in the treatments where water regimes were reversed. Newly emerging leaves after defoliation had higher δ¹³C values despite the lower instantaneous water‐use efficiency and similar values of p_i/p_a to older photosynthetic leaves. Large differences between observed and model‐predicted p_i/p_a values also occurred in older, more mature leaves, and this may be because large proportions of their total mass were derived from carbon import.