Minimum Leaf Conductance ( g min ) Is Higher in the Treeline of Pinus uncinata Ram. in the Pyrenees: Michaelis' Hypothesis Revisited

Minimum Leaf Conductance ( g min ) Is Higher in the Treeline of Pinus uncinata Ram. in the Pyrenees: Michaelis' Hypothesis Revisited

The search for a universal explanation of the altitudinal limit determined by the alpine treeline has given rise to different hypotheses. In this study, we revisited Michaelis' hypothesis which proposed that an inadequate "ripening" of the cuticle caused a greater transpiration rate d...

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Published in:Frontiers in plant science Vol. 12; p. 786933
Main Authors: Bueno, Amauri, Alonso-Forn, David, Peguero-Pina, José Javier, de Souza, Aline Xavier, Ferrio, Juan Pedro, Sancho-Knapik, Domingo, Gil-Pelegrín, Eustaquio
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 24-01-2022
Subjects:
cuticular waxes
Michaelis’ hypothesis
minimum leaf conductance
Pinus uncinata
Plant Science
treeline
Michaelis’ hypothesis
Pinus uncinata
treeline
cuticular waxes
minimum leaf conductance
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Summary:The search for a universal explanation of the altitudinal limit determined by the alpine treeline has given rise to different hypotheses. In this study, we revisited Michaelis' hypothesis which proposed that an inadequate "ripening" of the cuticle caused a greater transpiration rate during winter in the treeline. However, few studies with different explanations have investigated the role of passive mechanisms of needles for protecting against water loss during winter in conifers at the treeline. To shed light on this, the cuticular transpiration barrier was studied in the transition from subalpine forests to alpine tundra at the upper limit of the species in the Pyrenees. This upper limit of was selected here as an example of the ecotones formed by conifers in the temperate mountains of the northern hemisphere. Our study showed that minimum leaf conductance in needles from upper limit specimens was higher than those measured in specimens living in the lower levels of the sub-alpine forest and also displayed lower cuticle thickness values, which should reinforce the seminal hypothesis by Michaelis. Our study showed clear evidence that supports the inadequate development of needle cuticles as one of the factors that lead to increased transpirational water losses during winter and, consequently, a higher risk of suffering frost drought.
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This article was submitted to Plant Physiology, a section of the journal Frontiers in Plant Science
These authors have contributed equally to this work
Reviewed by: Anna Lintunen, University of Helsinki, Finland; David Rosenthal, Ohio University, United States; Wenzhi Zhao, Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences (CAS), China
Edited by: Howard Scott Neufeld, Appalachian State University, United States
ISSN:1664-462X
1664-462X
DOI:10.3389/fpls.2021.786933