By Allison MacLachlanPosted July 13, 2011
A tiny plant called
Arabidopsis thaliana just helped scientists unearth new clues about the daily cycles of many organisms, including humans. This is the latest in a long line of research, much of it supported by the National Institutes of Health, that uses plants to solve puzzles in human health.
While other model organisms may seem to have more in common with us, greens like
Arabidopsis provide an important view into genetics, cell division and especially light sensing, which drives 24-hour behavioral cycles called circadian rhythms.
Some human cells, including cancer cells, divide with a 24-hour rhythm. One of the main human circadian rhythm genes, cryptochrome, has been associated with diabetes and depression. Both of these discoveries grew from work with plants.
"We don’t have stems and we don’t flower, but our body parts, like those of plants, are controlled by circadian clocks,” says NIH geneticist Laurie Tompkins. “Clocks operate more or less the same way in all organisms, but some aspects of clock function are easier to study in plants.”
The new work, released this week in the early online publication of
Nature, investigated why
Arabidopsisdoes its major stem-growing in the dark—a pattern common to most plants. Biologist Steve Kay and colleagues at the University of California, San Diego, report that a specific trio of proteins regulates the rhythm in
The group of proteins, called the evening complex, interacts in the early evening to silence two genes that usually promote plant growth. When the evening complex’s activity trails off a few hours before dawn, proteins release the brakes on growth and plants enter their nightly phase of rapid stem elongation.
When Kay’s team mutated the three genes that code for the evening complex, they noticed that this made the
Arabidopsis biological clock run out of sync—stems grew unusually long and flowered early.
Scientists aren’t yet certain why night is the best time for stems to grow, but Kay speculates it has to do with using resources efficiently. Plants pick up carbon and nitrogen during the day, then store these essential nutrients as starch and proteins. “In the later night, they can release these resources in a coordinated fashion to provide the building blocks for stem growth,” says Kay.
“Our understanding of human health and the role of clocks in health and disease can greatly benefit from studying how clocks work in plants,” he adds.
Kay’s work could also shed light on how clock genes regulate cell division in human embryos.
Scientists like Kay are interested in answering basic biological questions, but others who work with plants have their eyes on future disease therapies.
Plant-based molecules, for instance, are being used to target reservoirs of HIV that hide out in their hosts. At the University of California, Berkeley, chemist Jay Keasling is looking for simple ways to get microbes to produce greater quantities of these plant-based molecules at lower cost.
How plants like
Arabidopsis suppress harmful genes may also help improve HIV therapies. A team of biologists led by Craig Pikaard at Washington University in St. Louis is investigating RNA polymerases, chemicals important in determining which genes get switched on, to learn how plants silence harmful virus-derived genes. Similar silencing pathways could be harnessed for HIV therapies.
More generally, scientists are looking toward plants as a medicinal source. Chemist Sarah O’Connor at MIT is genetically engineering periwinkle plants, the natural source of the anticancer drug vinblastine, to produce variations of the drug with halogens attached. Halogens make some medicines last longer in the body, meaning that probing periwinkle’s capabilities could make cancer treatments more effective.
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