Register Now

Login

Lost Password

Lost your password? Please enter your email address. You will receive a link and will create a new password via email.

Add post

You must login to add post .

Add question

You must login to ask a question.

Login

Register Now

Welcome to Scholarsark.com! Your registration will grant you access to using more features of this platform. You can ask questions, make contributions or provide answers, view profiles of other users and lots more. Register now!

WHY FUNGI RULE THE WORLD: Mycorrhizal fungi are running the world scientist discovers

For decades humans have underestimated the humble fungi, but not Talbot. As she puts it, “Mycorrhizal fungi are running the world.” Walking through the woods with Jennifer Talbot (CAS’04) means seeing the forest with fresh eyes. But not the way you might think. Those tall, trembling pines stretching into the azure sky? Meh. The autumn sunlight dappling the canopy? Whatever.

The stick stippled with brown and white rot?

“Oh, YEAH!” shouts Talbot, stooping to grab the crumbly branch from the forest floor. She points to a cluster of gelatinous yellow blobs on the bark—a fungus called witches’ butter. “We used to think this was a slime mold, but it isn’t,” she says, pausing to admire the goo. “It’s actually edible, if you want to go there.”

For Talbot, all the action is underfoot. The assistant professor of biology studies a group of organisms called mycorrhizal fungi, which infect the root tips of over 90 percent of plant families on earth—in a good way. The fungi supply nutrients to the plants and get food in return. “The vast majority of plants you see outside could not live where they do without mycorrhizal fungi in the soil,” says Talbot.

Jennifer Talbot
Photo: Jackie Ricciardi

Mycorrhizal fungi also have an outsize role in the decomposition of dead plants and the release of carbon. And since Earth’s soil contains more than three times as much carbon as its atmosphere, what fungi do in the soil could dramatically affect climate change. But nobody knows exactly how, and climate models are woefully fungus-free. Talbot, trained in analytical chemistry and working in biology, is particularly well positioned to fill this knowledge gap, and she’s using genetic sequencing, computer modeling, and ecosystem measurements to uncover fungi’s role. Kathleen Treseder, a professor of ecology and evolutionary biology at the University of California, Irvine, and Talbot’s PhD advisor, says Talbot is “doing stuff that no one else can do.”

FUNGUS: A LOVE STORY

Jennifer Talbot
Talbot with a mushroom of the Mycenagenus. Understanding fungi, says Talbot, will lead to a better understanding of climate change. Photo: Jackie Ricciardi

Fungi are not plants. But, like plants, they have their own kingdom, which encompasses an estimated 6 million species, including molds and yeasts. And while many people associate fungi with mushrooms alone, those familiar stems and caps are merely the fruit body, like an apple on a tree. The “business end” of a mycorrhizal fungus, says Talbot, consists of hyphae, long strings of cells that snake through the soil looking for nutrients, water, and minerals to suck from the dirt and send back to the host plant. In exchange, the host plant gives sugar to the fungus. “It’s a classic type of symbiosis in nature,” says Talbot.

Fungi are a quirky group, both beautiful and bizarre. One of the largest organisms on earth is a fungus called Armillaria ostoyae, sprawling through 2,200 underground acres in Oregon. Another species, Ophiocordyceps unilateralis, commonly known as “zombie fungus,” infects insects’ brains, exploding their heads to release spores. Despite this marvelous diversity, Talbot admits that she was slow to embrace fungi’s charms. “I was really interested in plants. I thought they were driving the show,” she says. “I didn’t know about fungi—they just seemed gross.”


Source: http://www.bu.edu, by Barbara Moran

About Marie

Leave a reply