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in American Sign Language and English. Tim and Jake may be deaf roommates, but they have very different views on what it means to be deaf in a hearing world. When it comes to taking out the trash, they spiral into a comic and insightful examination of their personal garbage.
βLiving together is one thing, understanding each other?β
That can get messy. A trash, March 7th through the 28th, tickets at pack NYC.org. Hi, I'm Ira Plateau, and you're listening to Science Friday. Today on the podcast, to paraphrase side-hime, we go into the woods.
First up, date on efforts to restore the American Chestnut.
These trees once towered over the landscape, dominating forests in parts of the eastern U.S., they provided food for people and animals, and they were a hugely valuable source of lumber, but in the late 1800s, a fungal blight in the U.S., virtually wiped out the American Chestnut plants across the country. Streets once lined with beautiful trees, went bare.
And due to the blight, the species now exist mainly as a shrubby plant, not as a towering tree.
βNew genetic work could help speed up breeding efforts to add fungal resistance to createβ
a harder year Chestnut population. Joining me now is Jared Westbrook, he's director of science for the American Chestnut Foundation. Welcome to Science Friday. Hello, Ira.
Nice to have you. We've talked about Chestnut Restoration efforts. How long has it been going on? Where does the project now stand? So Chestnut Restoration in the U.S. has been going on since the 1920s, and people have
tried a lot of different things.
First, the trees got the blight originally from imported Chinese and Japanese chestnuts
that were brought over, and they had the blight pathogen on these trees, and the Japanese and the Chinese chestnuts actually are interfertal when you cross them and breed them with American chestnuts. So the early efforts were in hybridization between the Asian species and the American species. We, with the American Chestnut Foundation, breeding program, we've been doing this for 40
years, and we have been doing this program called Back Crossing, where we take the Chinese and the American hybrids, and we cross them back to a lot of different surviving wild trees. People tell us, "Oh, there's a flowering tree near the side of the road," and we then give them pollen from some of our hybrid trees that we've selected for having improved blight resistance, and then they have bred those hybrids with diverse American chestnut trees all
across the range. So we now have hundreds of orchards up and down the east coast of the U.S., and some of the things that we've done recently is just look at all those trees. They've been growing and they've been living with the blight for the last 15 years, and we've sequenced their genomes, we've looked at how resistant they are, and so now what
we're doing is breeding those best trees together, and we can speed up this process of doing the breeding and selection by way of doing DNA testing on their kids, and being able to sort out which of the kids have improved resistance relative to the parents. So then we can kind of ratchet up the resistance levels over multiple generations of breeding.
βNow are you doing that breeding by hand, pollinating or how is that happening?β
Yes, so we have 16 stage chapters, and these are our folks that have been doing this breeding for decades, and they care for each individual orchard, and mow the grass and keep the trees alive, and so we then exchange pollen, so we tell them, okay, this tree is likely to have resistance, and they send us the pollen, and then we coordinate shipping that pollen to the location where we want to do the breeding, so it's a very decentralized effort.
So you're never going to have a pure bread American chestnut again.
There are actually some rare surviving American chestnuts, and we have bread, some of those trees together, when we look at their kids, actually some of their kids also have partially enhanced resistance, so we are continuing to do breeding with those trees. There's a relatively few number of those trees, like when we actually looked at all of these surviving American chestnuts, and we look at their kids, like only seven trees, I would say,
out of like hundreds that we assessed have, you know, appreciable improvement in resistance, so the hybrids help us capture more of the diversity, because the American chestnuts that we breed with don't have to have the resistance. Well, let's talk about that, because I'd like to know how a Chinese chestnut differs. Yeah, so the Chinese chestnuts, they've been bred in China, like orchard production of chestnuts,
So they tend to have a shorter stature, the American chestnut grows more like...
the Chinese chestnut tends to grow more like an orchard tree, and what we're trying to do is combine the tall grows of the American chestnut with the blight resistance of the Chinese chestnut. If you know the genetics involved, could you just engineer the trade into the American chestnut
βand say, we'll get a giant tree and have the resistance?β
Yeah, so like one of the mistakes that we've made over time with this project is we assumed simplicity, like with our back cross program, we assumed two to three genes contribute to resistance, and what we learned when we were doing the DNA sequencing of our hybrids is that actually hundreds of different parts of the genome contributes to that resistance. So it's a complex trait, and when you do, I mean for complex traits, like the standard, the global standard for improving
those traits, like let's say milk yield and cows, growth and trees, you want to use recurrence
selection, which is basically select the best parents, select better kids, keep going over multiple
generations. With genetic engineering, it can be kind of challenging because we, you know, we put in a gene from wheat that seem to have some improvements in resistance when you looked at the seedlings, and we anoculated the little baby chestnuts, but then when we put them out in the field, and we looked at the resistance over time, it didn't hold up very well, and the genetically modified trees tended to grow slower. So it's a complex system and using this breeding strategy of
multiple generations of breeding for improved blight resistance and growth is for sure going to work. Now, so you're going back to the future. Going back to the future, and one of the things I just want to mention is that we can make this go a lot faster. You know, trees are very slow, doing multiple generations of breeding and trees is a multi-decade long process, and with genomic tools, basically what that enables us to do is we can do this crossing between
these best trees, and then do some gene-typing on their kids and be able to, like, mainly plant the 10% best together from our DNA test, or without even having to do the inoculation on the trees, you plant those trees together, they start to breed with each other, and then we can have a lot of seed-firm forest restoration. So then how long do you think it's going
to take for this restoration? So, you know, there were four billion estimated four billion trees.
βSo planting four billion trees is a huge task, but I think like in the next decade, with doingβ
this faster selection, we can have the next generation of trees. It takes about like seven years for the chestnuts in an orchard to start producing flowers and nuts. So in the next seven years, from the crosses that we're making now, we should start to have seed available for some of this forest restoration trials. And I think that with the improved breeding techniques that we're using, we should be able to double the level of resistance that we have now to the next generation.
So tell me then what success looks like to you. Success looks like trees that have mostly American chestnut genetics that are blight resistant, that grow tall, that are competitive, that capture the diversity that remains in the wild population. We want to put like maybe a few hundred to a thousand together in sites like in the forest where there's been a clear cut or there's been a fire in a disturbance area. We plant these trees together
and maybe we plant a few hundred to a thousand and 20 percent of those trees may be carry enough resistance to where they will survive long-term and start to fruit on their own.
And if we get a critical mass in all of these smaller planting locations distributed across the
east coast, what we want is the tree to start to reproduce on its own in the forest. So we don't have to have perfection for that. We need to have some subset of the population like 10 or 20 percent of the trees that we plant have resistance and they grow to the canopy, then that enables the population to continue to kind of self perpetuate on its own in the forest. You know our listeners are going to be listening and saying, gee, I wonder if there's
βsomething I can do to help. Is there something an individual can do to help you?β
Yeah, so I mean, we have already a large network of people that have been planting and maintaining these orchards and going forward, we need sites for doing some of our field testing. So we want to be able to plant like 200 trees at a site and over time we will give them the chestnut light fungus, we'll notulate them and we'll evaluate their resistance and make selections and continue the breeding. So that's one way to help. Of course, we're a nonprofit organization and so just
becoming a member of the American Chestnut Foundation can help sustain the effort. We need to continue this effort over decades. Here you're saying money, money or land. Well, if you have
Land, how much land?
need to give you? And how do I give it to you? Well, some of these plantings are like anywhere from like a half acre up to multiple acres. The key is to maintain the orchard over time. So, you know, we partner with all these people and they like put up deer fences or, you know, mow around the trees. So it is a commitment to do that and then we we go in and we enoculate. So just understand that this this is research and breeding. So we are going to give them the disease and then we're going
to make selections from there. This is multi-generational, what's it like? Yeah, I mean, I'm the third,
I'm in the third generation of scientists working on this. So, and we need to continue to bring
βyounger people into this effort. Well, Jared, this sounds really interesting. I think you're goingβ
to get some response. Thank you for being with us today. Thank you. I appreciate it. Dr. Jared Westbrook is director of Science for the American Chestnut Foundation in Asheville, North Carolina. After the break, what if you could build a forest in the center of your town? Stay with us. From viral moments to cultural revolutions, celebrity deep dives to social commentary, basement open mics to comedy legends, spilling the tea. Amazon music's got something for everyone
with millions of podcast episodes, just download the Amazon music app and start listening. Continuing our forest excursion, maybe your town doesn't seem well-suited
βfor miles of woods or maybe the forests around you were cut down years ago. Well, how about thisβ
option? A mini forest. Hanna Lewis is the author of the book Mini Forest Revolution using the Miyawaki method to rapidly rewild the world. Welcome to Science Friday. Thank you. Thank you
for having me here. What is a mini forest? A mini forest is basically a human attempt to
regrow a native forest that's as natural and ecologically functional as possible. It's a native forest that is perfectly suited to the soil and the climate and the topographical conditions where you're planting it and to do that in the small spaces around where we live and work. So this is different from people just planting some trees. What is the Miyawaki method
βall about? The Miyawaki method was developed by Japanese botanists and professor named Akira Miyawaki,β
his work spanned the second half of the 20th century and into the 21st century, it involves identifying the native climax community for a given spot and planting the whole community. So not just the canopy trees but also the understory species as well and planting them densely. The general rule is to plant about three plants per square meter or per square yard. The plants are often pretty small when you put them in just a few feet tall just a couple of years old and so they're not making
a lot of their own shade or litter yet so the soil is exposed and so the other part of the method
is just applying a dense layer of mulch to protect that soil in the first couple of years while
it's still exposed to sunlight. So can anybody do this or do you need special skills or equipment or knowledge? The method was designed to really welcome community members of all ages from all different backgrounds to come together and plant together. The plants are small enough that it's like putting a tomato transplant in the ground almost because the trees are still small. So it's very it's very welcoming for people to plant together. The planning process does take a lot of thought and consideration
and consultation with local forestry experts, local ecologists, people that understand the ecosystem and can help figure out what that native climax community is. And also, you know, the ground preparation sometimes a landscaping company or a professional is it's helpful for somebody with those skills and understanding to help with the land prep too. So you need somebody to come down and help you prep the land. You just don't pick out a vacant lot and start doing this.
I mean, a vacant lot is a perfect place to start if the folks in charge of that vacant lot are open to it. But there's definitely some planning and collaboration and partnership that goes into
It, you know, ahead of time before the planting.
Are you looking for rapidly growing trees? So really what you're looking for is the native
βclimax community. They're the species that grow in at the end of a sort of a natural period of ecologicalβ
succession, where what we all notice when we see a vacant lot is that it quickly gets taken over by small, fast growing, short-lived plants and that are taking advantage of lots of sun and sunlight and space. But then over time you get bigger plants, slower growing plants, and the site changes. So eventually you get what do you species? You'll get some fast growing pioneer trees like maybe
pine or birch. But then you have a shadier, moisture site with, you know, the roots have loosened
up the soil there and the conditions are different than when it was a vacant lot. And so eventually shade tolerance species then germinate there. And when they take over the canopy, they shade out everything else. Everything else that needed sun to grow there can no longer grow there. And so it becomes sort of a self-perpetuating community. And so yeah, so you're not actually picking the fast growing species. You're picking the shade tolerance ones that will format community that sort of
self-perpetuating climax community for a forest. So then do you need a minimum size for your forest
if it's creating all the shade and whatever for it to be successful? Yeah, sort of a goldly locks kind of size is like the size of a tennis court which is easy to picture for it to work as well as possible. Yeah, you want to have a certain depth like people talk about at least four meters or four yards deep. And what that does is that helps to create a microclimate where sunlight, the wind, the external temperatures cannot penetrate as well as they could if it was narrower.
And so you get that cooler moisture microclimate that forest species appreciate.
βNow, how long does all of this take to get to a successful self-sustaining stage?β
It takes about two to three years for it to become self-sustaining. And the way that happens is your planting species that are going to do well there because their natives, their co-evolved with each other, they're adapted to the local conditions. They grow well and since they're planted close together as they grow they branch out and they start to touch each other and form a canopy. And so then they're shading outweeds and they're creating that microclimate that holds
humidity inside. So you're no longer need to water or weed after two or three years. Wow, this is fascinating. And thank you for taking time to be with us today. Yes, thank you. Thank you so much. Bring us coming up. Hannah Lewis, author of the book, "Mini Forest Revolution," using the Miyawaki method to rapidly rewild the world. She works for nonprofit renewing the
βcountryside in Minnesota. And if you want to learn more about the idea of "Mini Forest,"β
there's an article on this topic on our website at sciencefreightay.com/miniforest. This episode was produced by Charles Berquist and you know what would help this podcast grow tall and strong? Send this episode to your most forestry friends and rate and review it wherever you get your podcasts. See you soon. I'm Eriofleto. [BLANK_AUDIO]
