Saved in:
Bibliographic Details
Main Authors: Nattiwong Pankasem, Po‐Kai Hsu, Bryn N. K. Lopez, Peter J. Franks, Julian I. Schroeder
Format: Artículo Open Access
Published: Wiley 2024
Subjects:
Online Access:https://nph.onlinelibrary.wiley.com/doi/10.1111/nph.20121
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1867002606018101248
author Nattiwong Pankasem
Po‐Kai Hsu
Bryn N. K. Lopez
Peter J. Franks
Julian I. Schroeder
author_facet Nattiwong Pankasem
Po‐Kai Hsu
Bryn N. K. Lopez
Peter J. Franks
Julian I. Schroeder
Nattiwong Pankasem
Po‐Kai Hsu
Bryn N. K. Lopez
Peter J. Franks
Julian I. Schroeder
collection Wiley Open Access
contents Warming triggers stomatal opening by enhancement of photosynthesis and ensuing guard cell CO2 sensing, whereas higher temperatures induce a photosynthesis‐uncoupled response Nattiwong Pankasem Po‐Kai Hsu Bryn N. K. Lopez Peter J. Franks Julian I. Schroeder New Phytologist Summary Plants integrate environmental stimuli to optimize photosynthesis vs water loss by controlling stomatal apertures. However, stomatal responses to temperature elevation and the underlying molecular genetic mechanisms remain less studied. We developed an approach for clamping leaf‐to‐air vapor pressure difference (VPDleaf) to fixed values, and recorded robust reversible warming‐induced stomatal opening in intact plants. We analyzed stomatal temperature responses of mutants impaired in guard cell signaling pathways for blue light, abscisic acid (ABA), CO2, and the temperature‐sensitive proteins, Phytochrome B (phyB) and EARLY‐FLOWERING‐3 (ELF3). We confirmed that phot1‐5/phot2‐1 leaves lacking blue‐light photoreceptors showed partially reduced warming‐induced stomatal opening. Furthermore, ABA‐biosynthesis, phyB, and ELF3 were not essential for the stomatal warming response. Strikingly, Arabidopsis (dicot) and Brachypodium distachyon (monocot) mutants lacking guard cell CO2 sensors and signaling mechanisms, including ht1, mpk12/mpk4‐gc, and cbc1/cbc2 abolished the stomatal warming response, suggesting a conserved mechanism across diverse plant lineages. Moreover, warming rapidly stimulated photosynthesis, resulting in a reduction in intercellular (CO2). Interestingly, further enhancing heat stress caused stomatal opening uncoupled from photosynthesis. We provide genetic and physiological evidence that the stomatal warming response is triggered by increased CO2 assimilation and stomatal CO2 sensing. Additionally, increasing heat stress functions via a distinct photosynthesis‐uncoupled stomatal opening pathway. 10.1111/nph.20121 http://creativecommons.org/licenses/by-nc-nd/4.0/
doi_str_mv 10.1111/nph.20121
format Artículo Open Access
id wiley_oa_10_1111_nph_20121
institution Wiley Open Access
license_str_mv http://creativecommons.org/licenses/by-nc-nd/4.0/
publishDate 2024
publisher Wiley
record_format wiley_oa
spellingShingle Warming triggers stomatal opening by enhancement of photosynthesis and ensuing guard cell CO2 sensing, whereas higher temperatures induce a photosynthesis‐uncoupled response
Nattiwong Pankasem
Po‐Kai Hsu
Bryn N. K. Lopez
Peter J. Franks
Julian I. Schroeder
New Phytologist
Warming triggers stomatal opening by enhancement of photosynthesis and ensuing guard cell CO2 sensing, whereas higher temperatures induce a photosynthesis‐uncoupled response Nattiwong Pankasem Po‐Kai Hsu Bryn N. K. Lopez Peter J. Franks Julian I. Schroeder New Phytologist Summary Plants integrate environmental stimuli to optimize photosynthesis vs water loss by controlling stomatal apertures. However, stomatal responses to temperature elevation and the underlying molecular genetic mechanisms remain less studied. We developed an approach for clamping leaf‐to‐air vapor pressure difference (VPDleaf) to fixed values, and recorded robust reversible warming‐induced stomatal opening in intact plants. We analyzed stomatal temperature responses of mutants impaired in guard cell signaling pathways for blue light, abscisic acid (ABA), CO2, and the temperature‐sensitive proteins, Phytochrome B (phyB) and EARLY‐FLOWERING‐3 (ELF3). We confirmed that phot1‐5/phot2‐1 leaves lacking blue‐light photoreceptors showed partially reduced warming‐induced stomatal opening. Furthermore, ABA‐biosynthesis, phyB, and ELF3 were not essential for the stomatal warming response. Strikingly, Arabidopsis (dicot) and Brachypodium distachyon (monocot) mutants lacking guard cell CO2 sensors and signaling mechanisms, including ht1, mpk12/mpk4‐gc, and cbc1/cbc2 abolished the stomatal warming response, suggesting a conserved mechanism across diverse plant lineages. Moreover, warming rapidly stimulated photosynthesis, resulting in a reduction in intercellular (CO2). Interestingly, further enhancing heat stress caused stomatal opening uncoupled from photosynthesis. We provide genetic and physiological evidence that the stomatal warming response is triggered by increased CO2 assimilation and stomatal CO2 sensing. Additionally, increasing heat stress functions via a distinct photosynthesis‐uncoupled stomatal opening pathway. 10.1111/nph.20121 http://creativecommons.org/licenses/by-nc-nd/4.0/
title Warming triggers stomatal opening by enhancement of photosynthesis and ensuing guard cell CO2 sensing, whereas higher temperatures induce a photosynthesis‐uncoupled response
topic New Phytologist
url https://nph.onlinelibrary.wiley.com/doi/10.1111/nph.20121