Font size:
Print
Researchers Uncover Mechanisms Behind Plant Response to Warming
Context:
Researchers at the University of California San Diego have unveiled new insights into how plants adapt to rising temperatures by examining the role of microscopic pores on leaf surfaces.
More on News:
- Microscopic pores called stomata on leaves enable plants to control water loss and intake carbon dioxide for photosynthesis and growth.
- As global temperatures continue to rise, the ability of stomata to widen is increasingly recognised as a crucial mechanism for minimising heat stress in plants.
Background
- Historically, scientists struggled to understand the mechanisms behind stomatal openings in response to rising temperatures due to the complexities of maintaining constant humidity (vapour pressure difference, or VPD) while increasing temperature.
- The researchers developed a method to stabilise VPD values under varying temperatures, allowing them to investigate genetic mechanisms involved in stomatal responses.
Key Findings:
- The study, published in the journal New Phytologist, identified two primary pathways that plants utilise to cope with elevated temperatures:
- Carbon Dioxide Sensors as Central Players: The researchers discovered that carbon dioxide sensors are integral to the plant’s stomatal responses to warming.
- When leaves experience rapid temperature increases, these sensors detect the resultant rise in photosynthesis, which lowers carbon dioxide levels.
- This reduction triggers the stomatal pores to open, allowing for increased carbon dioxide intake, ultimately benefiting the plant’s growth.
- Alternative Heat Response Pathway: Under extreme heat conditions, the study found that photosynthesis can become stressed, leading to a decline in its effectiveness.
- In these scenarios, the stomata bypass the typical carbon dioxide sensor responses and instead engage a secondary heat response pathway.
- This mechanism functions similarly to a backdoor entry, enabling the plant to “sweat” and cool itself down, thereby mitigating heat stress.
Implications for Plant Health and Agriculture:
- By deciphering the mechanisms through which plants regulate stomatal function under varying temperatures, researchers can better predict how different species might respond to future climatic conditions.
- This knowledge can guide agricultural practices, helping to select crop varieties that better withstand heat stress and use water more efficiently.
- As global temperatures rise, enhancing our understanding of plant physiological responses is crucial for developing sustainable agricultural practices and ensuring food security in an increasingly unpredictable climate.