Poster: Global change
Abs #
25: Elevated CO2 and gene expression: a field study of loblolly pine
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Presenter: |
Moura, Catarina F, c.moura@duke.edu |
Authors | Moura, Catarina F (A) Watkinson, Jonathan (C) Grene, Ruth (C) Jackson, Robert B (A) (B) | | Affiliations: |
(A): Department of Biology - Duke University
(B): Nicholas School of the Environment - Duke University
(C): Department of Plant Pathology, Physiology and Weed Science - Virginia Tech
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Forest ecosystems play an important role in the global carbon cycle and are directly affected by changes in atmospheric CO2 concentration. To better characterize ecological processes associated with the rise of atmospheric CO2 levels, it is essential to explore the underlying physiological and molecular mechanisms present in forest trees. We conducted an experiment comparing patterns of gene expression in loblolly pine trees growing under two different CO2 concentrations, “Ambient” and “Elevated” (Ambient + 200ppm), at the Duke Forest FACE site. RNA was extracted from pine needles sampled throughout the growing season, and hybridized to microarrays containing ~2000 replicated cDNA clones. Genes coding for enzymes involved in carbon metabolism, such as citrate synthase and glucose-6-phosphate isomerase, were upregulated (over expressed) in elevated CO2 conditions. There was no evidence of differential expression on genes coding for Rubisco subunits, but some chloroplast and photosystem associated genes were downregulated under elevated CO2 at the end of the season. The gene coding for ACC synthase, an enyme involved in ethylene synthesis and plant development, was upregulated in elevated CO2 samples during most of the growing season, suggesting increased levels of senescence in those conditions. It is also worth noting that genes in the phenylpropanoid pathway tended to be upregulated under elevated CO2 and oxidative stress response genes showed a strong seasonal variation. This study provides insight into the response of pine trees to a major environmental change and it contributes to a desired understanding of concerted gene regulation and regulatory networks in tree species.
