5 Ways Plants Defend Themselves
Sorry, Vegans: Brussels Sprouts Like to Live, Too
Before we cede the entire moral penthouse to “committed vegetarians” and “strong ethical vegans,” we might consider that plants no more aspire to being stir-fried in a wok than a cow aspires to being put in a chulent for Shabbos. Plants are lively and seek to keep it that way. The more that scientists learn about the complexity of plants — their keen sensitivity to the environment, the speed with which they react to changes in the environment, and the extraordinary number of tricks that plants will rally to fight off attackers and solicit help from afar — the more impressed researchers become, and the less easily we can dismiss plants as so much fiberfill backdrop, passive sunlight collectors on which deer, antelope and vegans can conveniently graze. It’s time for a green revolution, a reseeding of our stubborn animal minds.
When plant biologists speak of their subjects, they use active verbs and vivid images. Plants “forage” for resources like light and soil nutrients and “anticipate” rough spots and opportunities. By analyzing the ratio of red light and far red light falling on their leaves, for example, they can sense the presence of other chlorophyllated competitors nearby and try to grow the other way. Their roots ride the underground “rhizosphere” and engage in cross-cultural and microbial trade.
“Plants are not static or silly,” said Monika Hilker of the Institute of Biology at the Free University of Berlin. “They respond to tactile cues, they recognize different wavelengths of light, they listen to chemical signals, they can even talk” through chemical signals. Touch, sight, hearing, speech. “These are sensory modalities and abilities we normally think of as only being in animals,” Dr. Hilker said.
Plants can’t run away from a threat but they can stand their ground. “They are very good at avoiding getting eaten,” said Linda Walling of the University of California, Riverside. “It’s an unusual situation where insects can overcome those defenses.” At the smallest nip to its leaves, specialized cells on the plant’s surface release chemicals to irritate the predator or sticky goo to entrap it. Genes in the plant’s DNA are activated to wage systemwide chemical warfare, the plant’s version of an immune response. We need terpenes, alkaloids, phenolics — let’s move.
“I’m amazed at how fast some of these things happen,” said Consuelo M. De Moraes ofPennsylvania State University. Dr. De Moraes and her colleagues did labeling experiments to clock a plant’s systemic response time and found that, in less than 20 minutes from the moment the caterpillar had begun feeding on its leaves, the plant had plucked carbon from the air and forged defensive compounds from scratch.
Just because we humans can’t hear them doesn’t mean plants don’t howl. Some of the compounds that plants generate in response to insect mastication — their feedback, you might say — are volatile chemicals that serve as cries for help. Such airborne alarm calls have been shown to attract both large predatory insects like dragon flies, which delight in caterpillar meat, and tiny parasitic insects, which can infect a caterpillar and destroy it from within.
Enemies of the plant’s enemies are not the only ones to tune into the emergency broadcast. “Some of these cues, some of these volatiles that are released when a focal plant is damaged,” said Richard Karban of the University of California, Davis, “cause other plants of the same species, or even of another species, to likewise become more resistant to herbivores.”
Yes, it’s best to nip trouble in the bud.
Dr. Hilker and her colleagues, as well as other research teams, have found that certain plants can sense when insect eggs have been deposited on their leaves and will act immediately to rid themselves of the incubating menace. They may sprout carpets of tumorlike neoplasms to knock the eggs off, or secrete ovicides to kill them, or sound the S O S. Reporting in The Proceedings of the National Academy of Sciences, Dr. Hilker and her coworkers determined that when a female cabbage butterfly lays her eggs on a brussels sprout plant and attaches her treasures to the leaves with tiny dabs of glue, the vigilant vegetable detects the presence of a simple additive in the glue, benzyl cyanide. Cued by the additive, the plant swiftly alters the chemistry of its leaf surface to beckon female parasitic wasps. Spying the anchored bounty, the female wasps in turn inject their eggs inside, the gestating wasps feed on the gestating butterflies, and the plant’s problem is solved.
Here’s the lurid Edgar Allan Poetry of it: that benzyl cyanide tip-off had been donated to the female butterfly by the male during mating. “It’s an anti-aphrodisiac pheromone, so that the female wouldn’t mate anymore,” Dr. Hilker said. “The male is trying to ensure his paternity, but he ends up endangering his own offspring.”
Plants eavesdrop on one another benignly and malignly. As they described in Science and other journals, Dr. De Moraes and her colleagues have discovered that seedlings of the dodder plant, a parasitic weed related to morning glory, can detect volatile chemicals released by potential host plants like the tomato. The young dodder then grows inexorably toward the host, until it can encircle the victim’s stem and begin sucking the life phloem right out of it. The parasite can even distinguish between the scents of healthier and weaker tomato plants and then head for the hale one.
“Even if you have quite a bit of knowledge about plants,” Dr. De Moraes said, “it’s still surprising to see how sophisticated they can be.”
The first line of defense occurs when plant cells detect the presence of some sort of foreign invader (by detecting general characteristics such as the flagella of bacteria or the chitin found in fungi cell walls) and alert surrounding cells by releasing certain molecules that tell other cells to amp up their defenses. For example, alerted plant cells may secrete molecules that are harmful to invadors or build up their cell walls for extra protection.
The second line of defense exists to protect plants from sneakier invadors. Some pathogens have figured out how to disable the plant’s first line of defense. When plant cells recognize that they are being attacked, they fight back. Just as pathogens have evolved to disable plant defenses, plants have evolved to be able to recognize these disabling attacks and counter them.
There are different signs that help indicate which kind of defense is activated in a plant and in response to what kind of pathogen. By studying these signs and what is going on in the genome of plants, researchers can try to figure out which parts of the plant genome and which proteins are involved in which kinds of defense.
For example, one of the signs of a plant activating thesecond line of defense is something called the hypersensitive response (HR). Basically, plant cells right around an infection site will kill themselves to stop a pathogen from spreading throughout the plant. This prevents pathogens from getting access to things that they need (like water and nutrients) and usually stops the infection! You have probably noticed this phenomenon on leaves in your backyard! Plants are faced by attackers constantly and it is only through strategies like this one that they are able to thrive through challenges.
The roles of the various proteins (A, B, and C) are performed by many proteins in a real plant cell. A HUGE number of proteins are involved and there are many ways that both plant and pathogen can respond to fight back against each other.
As you may have noticed, the plant immune system is very complicated! Only a small amount of information is currently known. There are so many different proteins and pathways involved that there are endless research possibilities on the subject. Research is so exciting because there is so much in the world to study and understand!
This is another startling example of Hashem’s incredible design in an area that we did not expect and may have taken for granted.