Respiratory acclimation in Arabidopsis thaliana leaves at low temperature

Respiratory acclimation in Arabidopsis thaliana leaves at low temperature. Talts, P., Parnik, T., Gardestrom, P., & Keerberg, O. Journal of Plant Physiology, 161(5):573–579, May, 2004. Place: Munich Publisher: Elsevier Gmbh WOS:000221613300009
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Acclimation of 25 degreesC-grown Arabidopsis thaliana at 5 degreesC resulted in a marked increase of leaf respiration in darkness (R-d) measured at 5 degreesC. R-d was particularly high in leaves developed at 5 degreesC. Leaf respiration (non-photorespiratory intracellular decarboxylation) in the light (R-l) also increased during cold acclimation, but less so than did R-d. The ratio R-d/P-t (P-t - true photosynthesis) was higher in more acclimated or cold-developed leaves, while the ratio R-l/P-t remained unchanged. In cold-acclimated leaves, R-l did not correlate with 3-phosphoglycerate and pyruvate nor with hexose phosphate pools in the cytosol. R-l in A. thaliana leaves was probably not limited by the substrate during cold acclimation. Under the conditions tested, R-d was more sensitive to low temperature stress than R-l.

@article{talts_respiratory_2004,
	title = {Respiratory acclimation in {Arabidopsis} thaliana leaves at low temperature},
	volume = {161},
	issn = {0176-1617},
	doi = {10/ddt8s8},
	abstract = {Acclimation of 25 degreesC-grown Arabidopsis thaliana at 5 degreesC resulted in a marked increase of leaf respiration in darkness (R-d) measured at 5 degreesC. R-d was particularly high in leaves developed at 5 degreesC. Leaf respiration (non-photorespiratory intracellular decarboxylation) in the light (R-l) also increased during cold acclimation, but less so than did R-d. The ratio R-d/P-t (P-t - true photosynthesis) was higher in more acclimated or cold-developed leaves, while the ratio R-l/P-t remained unchanged. In cold-acclimated leaves, R-l did not correlate with 3-phosphoglycerate and pyruvate nor with hexose phosphate pools in the cytosol. R-l in A. thaliana leaves was probably not limited by the substrate during cold acclimation. Under the conditions tested, R-d was more sensitive to low temperature stress than R-l.},
	language = {English},
	number = {5},
	journal = {Journal of Plant Physiology},
	author = {Talts, P. and Parnik, T. and Gardestrom, P. and Keerberg, O.},
	month = may,
	year = {2004},
	note = {Place: Munich
Publisher: Elsevier Gmbh
WOS:000221613300009},
	keywords = {Arabidopsis thaliana, acclimation, capacity, chloroplasts, cytosolic metabolites, decarboxylation, leaf respiration, light, low   temperature, metabolism, mitochondria, photosynthesis, snow gum, winter rye},
	pages = {573--579},
}

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