Scientists have discovered a key molecular cog in a plant’s biological clock. In response to temperature, it controls the speed of circadian, or daily, rhythms.
Transcription factors, known as genetic switches, drive gene expression in plants based on external stresses such as light, rain, soil quality, or even animals grazing on them.
A team of researchers has isolated one genetic switch, called FBH1, that reacts to temperature, tweaking the rhythm here and there as needed while keeping it on a consistent track.
“Temperature helps keep the hands of the biological clock in the right place,” says Steve A. Kay, dean of the USC Dornsife College of Letters, Arts and Sciences and the corresponding author of the study. “Now we know more about how that works.”
Kay worked with lead author Dawn Nagel, a postdoctoral researcher, and coauthor Jose Pruneda-Paz, an assistant professor at the University of California, San Diego, on the study, which is published in the Proceedings of the National Academy of Sciences.
Understanding the mechanics of how the interactions between the biological clock and the transcriptional network work could allow scientists to breed plants that are better able to deal with stressful environments—crucial in a world where farmers attempt to feed an increasing population amid urban development of arable land and a rising global temperature.
“Global climate change suggests that it’s going to get warmer and since plants cannot run away from the heat, they’re going to have to adapt to a changing environment,” Nagel says.
“This study suggests one mechanism for us to understand how this interaction works.”
How plants deal with stress
Both plants and animals have transcription factors, but plants have on average six times as many, likely because they lack the ability to get up and walk away from any of their stressors.
“Plants have to be exquisitely tuned to their environment,” Kay says. “They have evolved mechanisms to deal with things that we take for granted. Even light can be a stressor, if you are rooted to one location.”
Among other things, Kay’s research explores how these transcription factors affect plants’ circadian rhythms, which set the pace and schedule for how plants grow.
Kay and his team conducted their research on Arabidopsis, a flowering member of the mustard family that is used as a model organism by scientists because of its high-seed production, short life cycle, and the fact that now all of its genome has been sequenced.
The Ruth L. Kirschstein National Research Service Award and the National Institutes of Health, National Institute of General Medical supported the work.