Daniel and Kelly’s Extraordinary Universe - How and why do trees get so old?
Episode Date: May 27, 2025Daniel and Kelly talk about the science behind aging trees, and why some trees live so long. See omnystudio.com/listener for privacy information....
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The oldest tree we know of is Methuselah,
a great basin bristlecone pine that is almost 5,000 years old.
Methuselah began putting down its roots during the age of the pyramids in ancient Egypt.
It also lived through the rise and the fall of ancient Greece and ancient Rome as well.
Hamarabi, Nefertiti, Buddha, Pythagoras, Confucius, Socrates, Alexander the Great, Cleopatra,
Genghis Khan, Joan of Arc, Da Vinci, Copernicus, Ivan the Terrible, Shakespeare, Pocahontas,
Newton, Hamilton, Mozart, Napoleon, Lincoln, Darwin, Nightingale, Pasture, Edison,
in Gandhi, Hitler, Parks, Mandela, Martin Luther King, Jr. and Betty White.
Generations of humans have struggled and strove, some making the world better, some making it worse.
But all of them lived out their entire lives in just a sliver of the time,
during which Methuselah has been patiently growing in the White Mountains of California.
There's something both bewildering and awe-inspiring about incredibly old trees.
And today we're going to be talking about what we know about them.
How do we age trees?
And how and why do some trees live so long?
Welcome to Daniel and Kelly's extraordinarily tremendous universe.
Hi, I'm Daniel.
I'm a particle physicist, and I round myself up to 50.
years old. Hello, I'm Kelly Wiener-Smith. I study parasites and space, and I round myself down
to 40. You're even older than I am than I had realized, Daniel.
Oh, wow. What a wonderful thing to hear. It's all about how you round. Although, you know,
I thought we had both agreed that we round up on average, but at only 42, I think I'm going to
go ahead and round down. Yeah. No, I think that's fair. Who really needs more significant
digits than one, right? That's right. That's right.
Do you have a favorite tree?
Do I have a favorite tree?
I love the Redwoods.
You know, out here in California, I got to say that's something spectacular about California
and the mystery, the majesty of being the presence of these super tall and super old beings
and thinking about all the things they've seen and experienced.
I love it.
I just love old trees in general.
Like when you drive down a street in a neighborhood that's like 100 years old and the trees
like cross over the street or have all these wiggles and branches. Whereas like a new suburb with
these like tiny little potty plant trees, it's just a little sad. So old trees are wonderful because
it's something you got to earn. It just takes time. You know, you can't like fast grow a tree to a huge
size. I totally agree. When I lived in California, I had to go see the redwoods. And I realized that
I'd been like looking up at one of those trees with my mouth open. And I was like so glad nothing
had fallen into it. Because it was just like, I must have stood there for, you know, 15 minutes.
looking at the same tree being like, oh, the things that you've seen or, you know, have been
alive through.
It's just incredible.
And then I had the great pleasure of working at Rice University for a while, which I know is
where you did your undergrad.
And they've got that running track around the outside of the university that is surrounded
by live oaks.
And they're the ones that have those like tortuous arms that like go back, they down, they
touch the ground, they come back up again.
Oh, they're so gorgeous.
I actually don't know how old those live oaks are, but there's something about a big tree
that I love.
Yeah, and Rice has so many trees.
I think there's something in the charter that they have to have more trees on campus than students.
So they really preserve the trees on the campus.
I can't believe they've got more trees on campus than students.
If so, they've got to shut that place down, man.
I don't think that's working out.
Well, I'm going to ask you, Kelly, the obvious question.
Given California's redwoods and the majesty of our old trees, what does Virginia have to compare?
I'm giving you an opportunity here.
Oh, my God.
This is easy.
So California is beautiful, but have you been to Shenandoah National Park?
Oh, I have. Land of many uses.
Many uses. What do you mean? Like, you're going to cut my trees down?
No, I just remember camping in the Blue Ridge Mountains one time, and there was a sign when you enter.
It was like, welcome to the Blue Ridge Mountains, land of many uses.
Oh.
I wonder what that means.
Yeah, I don't remember seeing that on the sign.
But, like, you've gone camping in the Blue Ridge. The answer is obvious.
It's just so gorgeous, seeing all of those rolling hills with all the trees.
and the, like, mist coming up over them in the mornings and seeing the sunset.
There's, like, no more beautiful view in all of the United States than what you get.
I'm laying down the gauntlet, man.
I was with you up until that point.
I mean, I like the Blue Ridge Mountains.
For mountains, they're cute.
I mean, they're not that tall or that pointy.
That's why they're so nice to walk.
I like a nice granite-topped mountain, you know, like above the tree line.
That's my Janice, for example.
Oh, yeah. And I just don't think you can compare to the majesty of the coastal redwoods, you know. Nothing stands up to that, in my opinion.
Those are beautiful. I'll give you that. I don't feel like I want to pit one natural beauty against another. But I can't say that in grad school, I tried hiking White Mountain where the bristlecone pines are. So we talked about Methuselah in the opening. And, you know, I was climbing up there and the air was getting thin. And I was like, feeling miserable. And, you know, so no, give me Shenandoah any day where I can breathe.
It's like, I don't want to go to space.
I don't want to go to White Mountain.
Yeah, no, it's beautiful.
Absolutely.
I'll give you that.
And you're right.
We shouldn't pit one against the other.
There's lots of different ways to be beautiful, and we should appreciate all of it.
Amen.
All right.
And so, we had this absolutely incredible question from a listener's son about old trees.
And that's what we're going to be talking about today.
But before we listen to the question, I want to remind you that you can send us your questions,
or you can send us your kids questions at questions at Daniel.
and Kelly.org. We really love hearing from you and we love hearing from your kids. Thank you to everybody who
listens to the pod with your kid. It's a great way to start conversations about science. Yay. All right. So let's
hear the question that we're chatting about today. Hi, Daniel and Kelly. I have a question. Why do
some trees live longer than other trees and why do they live longer than people? This is a great
question because this is a question I've had since I was a kid looking at those redwoods and wondering like
why do they live so long? How do they live so long? What's going on? Yeah, it's a fantastic
question. And it was one where when I listened to it, I thought, oh, this is another one where
I don't really know the answer. And so I was thrilled to have an opportunity to do some research.
And so let's start this conversation by talking about how we even go about aging trees in the
first place. I think a lot of us are familiar with the idea that you can age trees based on their
rings, but it's a little bit more complicated. So you can't just chop down the tree and count the
rings.
It's a handle.
Yes, but then you're a monster.
Well, it reminds me of that far side cartoon where the guy is standing there with his
son and an axe and he's chopped down some big tree and he's going through the history
of the tree, all the things the tree has survived until, of course, that day that he chopped
it down.
Right, but it couldn't survive us.
That's sad.
So tell me then, how do we know how old a tree is without chopping it down and counting its rings?
Well, for a while there, we were used.
using relational ages. So you would say, oh, well, the tree was planted around the time the
Parthenon was built or something like that. And so Pliny was using these relational ages where he would
age trees based on historical stuff that was happening at the same time. But how would you know
what historical stuff is happening at the same time? How would you know that this tree was planted
at the same time as the Parthenon or something? I think records and institutional memory. But you're
right. I mean, you don't know unless somebody happens to know. Local knowledge. And that you can
trust that knowledge. Yeah, I bet they got a lot of ages wrong. That can't work great. I mean,
I'm sure there's a lot of mythology, right? People are like, this tree is thousands of years old and
because people are bad at deep time, you know. Oh my gosh, so bad. And I was reading this book
called Elder Flora and it talks about sort of the history of our relationship with old trees
and how we often get the ages wrong and how trees become important for religious ceremonies and
stuff. So anyway, anyone who's interested in old trees, that's a good book worth checking out. But
towards the end of the 19th century, and I'm surprised this wasn't common earlier, we started
getting a handle on aging trees by counting their rings. So let's talk about the science behind
where these rings come from. Yeah, why do trees have rings and why do they have one ring per
year anyway? Yeah, right. Great question. Why doesn't the inside of a tree all look the same?
Yeah, I mean, I don't have rings. If you cut me open, you couldn't count my age.
Well, we don't really know until we try.
Maybe we should start with a core sample.
Yes, that's right.
I'll get out my increment bore, but we'll get to that.
So here's how trees grow.
All right, say you do the horrible act of cutting down a tree, which, of course,
sometimes you have to do, and we all use paper.
So anyway, no judgment.
So you cut down a tree.
You're looking at the center of a tree.
The center part of the tree is called heartwood.
And if it's a big tree, that center part is actually dead.
What?
Why is it called heartwood if it's dead?
Trees are weird, and that's going to be.
the theme of today's show, I think, is that trees are weird. And so, you know, the listener wanted to
know why humans don't live as long as trees. And I think the answer is trees are weird. And,
you know, I'll do a better job of answering that at the end of the episode. But that's the take-home
point. So the center is dead. And it's dead because it no longer has access to water and
nutrients that are coming up through the xylem, which will get you. So the next level you've got
is the sapwood. And the sapwood is the level where you still get water that's
coming up through the xylem.
So you've got essentially, I think of it as like a series of tubes,
but it's really like specialized cells that go from the roots,
up through the trunk of the tree, and into the canopy.
And so the sapwood is getting access to that water and to the nutrients.
Next to the sapwood is the cambrium.
And the cambrium, maybe the cambrium,
we all know how good I am at pronouncing things,
is going to be very important for the rest of this episode.
So this is the layer where you have,
the growth happening. So on one side, towards the outside of the tree, the cambrium starts producing
bark. And that bark is going to build up over time and that's going to protect the tree.
Towards the inside of the tree, it's producing the sapwood. So it's producing more of that
like woody tissue that you would build a house out of, for example.
Woody tissue otherwise known as wood. Yeah. Well. For us layfolk.
But wouldn't bark be woody tissue kind of also? I don't know. I see. But you wouldn't necessarily
build the house out of bark so I was trying to be a little more specific but yeah well I don't want to
blow my nose on a woody tissue so I guess it has lots of meanings that's right that's right
well before you dig deeper my first question is like are these hard divisions is there like an edge
between the heartwood and the sap wood or is it like a spectrum where like in the middle is something
that's sort of hardy sappy or is it really like a hard bright line there yeah that's a great question
so I'm thinking back at the tree cookies as they're called that I've looked at so this is like you
slice through a tree at two different parts
and it's sort of shaped in a circle
kind of like a cookie. And I feel like
often it looks like there's a pretty
clear delineation between what would be the
heartwood and what would be the sap wood. The heartwood's like
a different color. But it probably
does have like layers
that are gradations in the process
of dying essentially.
Interesting. Versus cells that are still being
fed would be my guess. Right.
And so the Cambrium is the thing that's making more
sapwood on the inside and more
bark on the outside. And it's
that the only part of the tree that's growing? The tree's not like expanding uniformly sort of like
the way the universe expands. It's like only making new rings around the outside. Yeah, it's only
making new rings around the outside. And so say you were to like put a nail into the side of a
tree and you came back 50 years later, that nail would still be at the same height that you had
put it. But it would be essentially getting like absorbed by the tree. Like layers would have grown
around it. And so either that nail wouldn't be visible anymore unless you actually cut into the
tree. And as someone who lives out in the woods in an area where there used to be a lot of
barbed wire fencing, it's amazing how often we'll cut into a tree. And the chainsaw blade will get
messed up because it turned out there was a barbed wire like in the middle of the tree. And the
tree had just grown around it. It was like, nice try, humans. I grow around you.
And so if I had like two models of growth in my head, one where like every person,
part of the tree is expanding. So heartwood is always heartwood just becomes bigger. It sounds like
you're suggesting a different model where like sapwood becomes heartwood. Is that what's happening here?
Yeah. So sapwood and heartwood are both made out of xylem cells, which are the cells where you get
water and the stuff that's dissolved in the water that goes from the ground through the roots and up
towards the top of the tree. Both sapwood and heartwood are dead. Those xylem cells are dead. And as those
xylem cells get more and more compressed, they become heartwood. So the difference between sapwood
and heartwood is that the xylem cells have been compressed so much that water can't move up them
anymore. And that happens as you move towards the center of the tree. So sapwood becomes heartwood
over time. And then that heartwood basically never changes, right? Because it's dead. Now it's just
structural. So in most trees, that heartwood stays structural and it stays there. And so when you
bore through the center of a tree, you can pull out a plug where you, you're, you're
You can see all of the lines throughout the entire life of the tree.
But there are some kinds of trees like the Boabab in Africa where the inside is sort of not the same consistency of wood that most of us think of.
And it tends to sort of decay and rot away.
And so you can't use increment bores for a lot of those trees because the inside is no longer there.
But for most trees, basically the living part of it is like a hollow cylinder.
It's more like a tube than like a filled in cylinder.
and that's expanding and leaving behind its corpses.
Yeah. Isn't that crazy?
That is crazy.
Totally nuts.
It's like the opposite of a snake.
A snake like sheds its skin, but the living part is on the inside.
This is like if the skin was the living part.
Yeah.
Wow.
Trees are weird.
Yes.
Trees are so weird.
Okay.
But so why does that growth leave behind rings instead of just like a homogenous center?
Or why is it linked to the year instead of something else?
right? What's going on every year that makes this mark inside the tree?
Right. So you get rings in areas where there's clear seasonal differences. And that could be
winter, summer, but it could also be wet season and dry season. So not all trees have rings. And in
particular, these rings are either like much fainter or maybe even impossible to see in areas where
conditions are more homogenous or more similar all year long. Like a boring place like California, probably.
But anyways...
If by boring you mean consistently wonderful, then yes.
All right, fine.
Okay, so at the beginning of a season, the wood is a little bit lighter,
and it is more aimed at being able to transport nutrients and water
up and down during the massive growth that starts at the beginning of the spring.
And so that kind of wood is called early wood,
because apparently these folks are just as clever at naming things
as the people who named the rings of Jupiter.
It was it Jupiter or Saturn, where the rings are ABC?
That's definitely Saturn, probably also Jupiter, though I haven't looked that up.
Okay.
And then after the early wood, you get, do you want to go ahead and guess, Daniel?
I'm going to guess latewood.
Yeah, yep, you get latewood.
And light wood, I think, is more about structure.
And so it tends to be tighter and closer together.
I see.
So the kind of new wood that's grown depends on the conditions on the ground.
And that changes through the year.
that changes the kind of wood that it's grown.
Yep.
So every year you get this pattern of like light than dark,
and those are the rings that you see.
And say again, why the late wood is darker than the early wood?
My understanding is that the late wood is meant to be more about structure.
So it doesn't need to be so loose so that water can go up to feed the many leaves
that are growing at the beginning of the season.
When you're at the point where you've got all your leaves or maybe even the leaves are
starting to come down, the new growth is mostly just about structure.
So it's a different kind of cell that looks a little bit different.
Yeah, you make it sound like it's intentional, like the tree got together.
And it's like, hmm, all right, I think we're ready for some structure.
In reality, of course, this is just sort of what has worked, right?
And we're reverse engineering it.
Yeah, it also is responding to the environment.
And so on very wet years or years with really good growth conditions, the distance between rings is much bigger because the cambrium was able to put in more rows of cells.
And so you get a greater distance.
Whereas in years where there's droughts or conditions are bad for some other reasons, the distance between the rings are much smaller.
And do you always get a ring?
Like what about the year without a summer or when there's like a volcanic eruption and we just don't see the sun?
Can you trick trees into thinking a year hasn't passed?
So I don't know the answer to that.
I have aged fish based on their scales.
So I have some knowledge of how the environment impacts aging dynamics.
And there are definitely some years where it's very hard to tell the different.
between the rings or to tell if there is a ring in a particular place or not.
I'm guessing the same thing happens with trees.
I would also guess that when you age a tree and you say it's 4,587 years,
you really mean like 4,587 plus or minus 30 or something like that.
Oh, sure, yeah.
Yeah.
But you can use this tool called an increment borer to go through the center of a tree
and pull out a tiny little pencil-shaped chunk where you can go through
and you can age it by counting the rings,
but you don't need to kill the tree.
It can just handle this little bit of damage.
It's like drawing blood from a human or something.
And if you get enough of these,
you can actually look at climate patterns in a region over time.
And so trees give us a little bit of window into the past.
One tree doesn't really do it because it could be like one year.
It was underneath a bigger tree.
And so it got shaded out so it didn't grow as much.
And then if that tree dies, you know, the next year its growth is bigger.
and so there's some other stuff to pay attention to as well.
But we could look at climactic patterns by using these tree rings.
Yeah, I remember reading that they use old trees for things like understanding the atmospheric carbon content and all sorts of stuff.
It's like an incredible record of what's happened on Earth because it's so sensitive.
It's so lucky that it works this way.
I mean, I can imagine lots of other ways trees could have evolved that they didn't respond in this cyclical way.
I know.
And also for managing fish populations, it's amazing that.
scales tell you how old they are. We really lucked out that nature works in this way.
Nature is a good record keeper, right? There hints all over the world about what happened on this
planet. We just have to be good detectives and like figure out how to read them. And one thing I love
about science is all this work that people have done, you know, this like yeoman work to figure out
like how we can use some part of nature to reveal secrets of the universe, right? You don't just sit around
and, like, let the universe download it into your brain.
You've got to go out there and do the work and figure out, like, oh, we can use this
weird rock and, oh, it turns out trees do this weird thing or fish do this weird thing.
Like, there's so much of experimental science that's people's realizing they could take advantage
of a quirk of nature.
Yeah, and then there's so many things you can do with it.
So, like, one of the favorite things I came across was that archaeologists are using
tree rings to try to date structures.
So if you find, for example, a beam in an old house and you assume that it was
cut down to build the house, then you can look at other tree cores in the area and sort of
match up the fast growth years with the slow growth years. And then you can back date to
figure out when that structure was built, even if you don't have that record anywhere. It's so
amazing. The more you understand about the world, you get all of these surprising linkages that
you can use to learn even more. It's super cool. It's incredible. Okay, but to get back to Carbon
14 dating, it turns out that carbon 14 dating is also a method that we use to date some of the trees
that we come across. So we already talked about the baobab, which sometimes rots in the inside. And so
you can't use an increment bore to like get a little sample of the tree to age it because it doesn't
really have a center. But you can use carbon 14 dating and pull the innermost wood that you can find
to get an estimate for how old the tree is. So these are the various methods that we use to age
trees. So like some of the interior records essentially have been destroyed, but you still have a few.
and so you can say a tree is at least 1,100 years old or at least 75 years old or whatever,
but you don't know what you've missing.
Yep.
That's exactly right.
Yeah.
Fascinating.
Well, it's incredible to me how long these trees live.
And, you know, trees to me are just stunning creatures.
You know, like if we didn't have trees or if I'd never seen a tree and you described
them to me, like, hey, there are these things that build themselves out of air over time,
drinking sunlight and reproduce themselves and provide oxygen, I'd be like, that's some crazy
science fiction nonsense.
but they're real.
It's amazing and they're beautiful
and we can use them to build our homes.
All right, well I want to hear all about
the world record holders
for oldest trees in the world
but first we have to take a quick break.
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Okay, we're back and we're talking about the weird, the amazing, the beautiful, the fantastical, the California and the Virginian, the worldwide tree.
It's everywhere, and it provides us with oxygen and teaches us about the history of our own planet.
So, Kelly, tell us, where are the oldest trees in the world, and are they in California?
Maybe they're in California.
There are a couple other contenders for oldest tree in the world, but at the moment, I think the most widely accepted oldest tree in the world is Methusla, which we talked about in the intro, somewhere between 4,500 and 5,000 years old.
The coordinates are not public because they don't want people to go and, like, carve their names into the side of it, because humans do stuff like that.
Guys.
Do we just hold on for a moment back up, like, wow, 5,000 years old?
What was happening on Earth 5,000 years ago?
So this tree is like older than the great pyramids?
This tree put down its roots during the age of the pyramids.
I think this is the old kingdom.
Wow.
Yeah, incredible.
So it saw the fall of ancient Egypt, the rise and fall of ancient Rome and ancient Greece, like we said in the intro.
So many generations of humans, it's mind-boggling.
I'm not very eloquent.
I can't capture this adequately.
It's just incredible.
It really just gives you a sense for the tiny blip of time that we,
exist on this planet. And of course, even that, right, 5,000 years is a tiny blip of time
from the planet. That's the thing that these old trees do for me is they give me this like
tiniest taste of the deepness of time, the incredible vastness of time in the universe more broadly
and then of course here on Earth. So do you think that these trees are going to see,
you know, the fall of our current civilization? How long do bristlecone pines live?
So I think the bristlecone pines that are 5,000 years old,
are not looking young.
But I do think that there are some clonal organisms that we'll talk about later,
like those stands of quaking aspens that can live for over 10,000 years.
And I hope that we live longer than the quaking aspen stands that are alive today.
We as a species, not me personally.
But I don't know.
We'll have to wait and see.
What do you think?
Are we an imminent decline, Daniel?
Well, that remains to be seen.
I was mostly asking about the lifetime of these trees.
I mean, if you find a population of trees and the oldest ones are about 5,000 years old,
that means either they evolved 5,000 years ago and they're going to live a long, long time,
or that's roughly as long as they can.
Like, have Bristol Cone Pines been living for 5,000-ish years for millions of years?
And this is just sort of like how long they typically live and we're visiting the old folks home for Bristol Cone Pine?
I don't know.
And I don't think that most of them.
people know, what would you have to know in order to answer that question? I guess you would
have to find dead bristlecone pines. You could age when they died and determine that they
had been alive for 5,000 years. I suppose in these dry environments, that kind of petrified wood
could exist, but I don't know if it does exist. Yeah, well, we can tell when the tree dies,
right, because of carbon 14 dating. And you could count its rings. So in principle, it should be
possible to know. You could count its rings if it didn't like. So most of the tree,
trees on my property, eventually they rot away and decay and you can't find them anymore. But if it
petrified and you could find it, I don't know the answer, but my guess would be that they have
been living for a very long time. But if you go out to a long enough time period, you have to
start thinking about things like, well, where were they when the last glacial event happened?
Oh, yeah. And it turns out that bristlecone pines tended to be up in the mountains high enough
and out of the way enough that they weren't bothered by the last glacial event. But it could be that
there are trees out there that would live for a very long time, but they happened to be in
habitats where when the last glacier came through, it knocked them all out because they can't
run away like we can. That's one of the downsides of being a tree. Right. That's amazing. These
guys live so long. You have to think about the changing conditions of the earth when they were
babies or when they were growing up. That's incredible. It is. All right. So Methuselah is maybe a
contender for one of the oldest trees on earth. What else do we find in the old folks home for trees?
Well, so there was a tree called Prometheus that was also a bristlecone pine, but usually the contenders have to be trees that are still alive.
But unfortunately, Prometheus was cut down in its 5,000-year prime.
Oh, no.
Was it by some terrible tourist?
No, it was by, I think, a grad student.
So I know.
Okay, so there was this misconception that old trees were probably the biggest trees.
And that makes sense.
You know, you look at the redwoods and you're like, oh, you might be so old.
But actually there's this trend where the older trees within a species tend to be the smaller ones that started their lives growing more slowly, and maybe even over time didn't get to be as big.
They're just sort of like tiny and stodgy, and I love it.
And so I think this student didn't realize that they were dealing with what might be the oldest tree on the planet.
And so they were trying to get the age, the exact details of the story have been sort of lost to history, but a version of the story is that the student was.
trying to get the age using an increment bore so this thing where you hand crank it into the
tree and that just wasn't working out and so they actually did get permission from the park
service to cut the tree down oh no and then when they cut the tree down it just turned out that
it was 5,000 years old oh my god maybe the oldest tree ever that must have been heartbreaking
yes i think that student did report later that they regretted for the rest of their life that
they cut that tree down.
Imagine surviving for 5,000 years and then some grad student is like, oh, man.
Yeah, the glaciers didn't get you, but the grad student did.
Academia comes for us all eventually.
Oh, man.
Yep, it gets us.
So anyway, tragic story.
So there's also a tree in Chile, the Alercy tree.
And again, sorry, my apologies of I'm mispronouncing it.
but there is a tree in Ulerese Castero National Park
that is 80% likely to be over 5,000 years old.
It's estimated to be 5,484 years old.
And so that tree could win.
Where do you think that 80% uncertainty comes from?
Is that from like the rings being fuzzy
or what we were talking about earlier,
like not every ring is present or visible?
The rings being fuzzy, I think is a problem.
Another problem is that sometimes where,
you go through the tree can influence how many rings you see. And so people tend to do the
boring, like, you know, to get your sample at about like chest height. But I think if you go down
even lower, sometimes you can get some additional rings. It's just complicated. No answer is ever
as clear as you want it to be in science. Well, I appreciate that there's uncertainties.
You know, I've seen talks in biology where you see like data plotted with no uncertainties and like
a line drawn through it. And you're like, what are we doing here, folks?
So I'm always very impressed when I see biology with error bars.
So, kudos to you.
Hey, man, a lot of us understand error bars and confidence intervals and would never publish a paper without them.
I'm so glad to hear it.
All right.
Anyway, we had talked about that tree, the African baobab where the inside sometimes rots out.
But with carbon 14 dating and then attempts at aging the trees, using the rings for the trees where that works, we think that they can live to be as old as 2005.
500 years.
Wow.
There's about 25 species of trees that we know of that we think can live to be
a thousand years old or older.
But it's important to note that not all trees live to be super old.
Like right now, it's spring in Virginia, so it's more beautiful here than anywhere else.
And the dog woods are going to be blooming pretty soon.
And dog woods live to be like 20 or 30 years.
They can live to be as much as like 80 years, I think.
But like a lot of them only live to be 20 or 30 years.
So it's not the case that all trees do outlive humans.
Well, what about the famous redwoods?
These are old trees also, but they're not in like the top 10 oldest trees.
But there must be hundreds of years old, right?
Yeah, so redwoods and giant sequoias are amongst the species of trees that can live to be over a thousand years old.
So they're found amongst those 25-ish species we know of.
But I don't know that there are any redwoods that are contenders for the oldest tree.
Mm-hmm. All right. So then why is there such a huge range? Dogwoods live happily for just a couple of decades. Bricill cone pints scratch out a thorny existence for thousands of years. Redwoods become enormous over about a millennium. Why do these things live such an incredible range?
So this is ecology. Mm-hmm. So what do you think the answer is?
We don't know. Yeah, we don't know. Yeah, both of those work. So the papers that I read, it seems like.
Like, so, you know, there are those 25 species that I mentioned.
Yeah.
In many cases, they are not closely related tree species or they're not super closely related.
And it seems like we have a different answer for a lot of those different species.
So, for example, part of why we think the bristlecone pines have lived so long is that they manage to eke out in existence in an environment that is very dry and is up at the top of a mountain.
And it's just not a nice environment for other competitors or for pests.
And when they escape from these competitors in these pests, they can just focus on slow growth and they can live for a really long time because they don't have to worry about these other competitors.
But then you get the Redwoods in these moist environments with lots of competitors and lots of pests, and they do manage to live for a long time.
And so it seems like you'd need a whole different explanation to figure out why Redwoods are able to live for so long.
It seems to me sort of connected to the question we talked to Katie about, you know, our strategists and case strategists.
Like from a species point of view, it doesn't really matter if you live a long time, another totally valid strategy is to just like have a kid every 30 years and then die off and make room for your kids, right?
Like they're definitely different strategies from an evolutionary point of view that could work to probably get you species down through history, right?
Yeah, exactly.
And additionally, our data set is complicated by things like what we've talked about already, which is, you know, during the last period when the glaciers came through, maybe there were a bunch more species that would have lived for five.
thousand years, but they all got wiped out by the glaciers. Another problem is that humans have
been cutting down trees for a really long time to build our houses and, you know, to build our
skyscrapers, just to build a lot of different stuff. And so we have removed a lot of trees from the
landscape. And so what we have left to age is maybe a subset that is less informative than it would
have been if all of the trees had still been there. Or every once in a while, you get an outbreak or
something like the United States used to have tons of chestnuts. Like everywhere I look now,
there's pines and oaks. If I had lived here before a chestnut like, the most common tree in
my area would have been a chestnut. But now we don't have any of them in the area. And so we have
a biased subset from which to try to answer these questions, why do some trees live longer than
others? But we always have a biased subset, right? We just have the subset that happened to survive
that made it through the death gauntlet of the present conditions.
We never know, like, on average, over 1,000 parallel Earths,
what would have survived?
We just got the ones that happen to get lucky
and happen to survive this time, right?
Isn't that always true of evolutionary history?
Yes.
I'd say it's also sort of always true with physics, too.
Like, you know, you only have the information
that you've already created tools for.
You don't know what you're missing.
And so I think in general,
a big part of being a scientist should involve being humble about what you do and don't know.
No, it's important to always put this in context, right?
And remember that we have a tiny fraction of the information, and that fraction is biased for sure.
So one thing to note that we talked about earlier is that growing slowly seems to be associated with longer life for trees.
And that can either be at the species level or within a species.
So it looks like individuals that tend to grow slowly early in life are also the ones that tend to live longer.
So if they're growing more slowly, they're investing in a denser, higher quality wood.
And maybe they're also investing in stronger roots or some chemicals that can fight off pests.
And so this investment in strength helps them when, for example, a hurricane or tornado comes by.
Maybe they're likely to be still standing when that's done.
Whereas if an individual grows quickly, then the quality of the wood that they produce is less good.
And so something is more likely to take them out if, you know, something like a hurricane or a tornado comes through.
So individuals who grow more slowly tend to be the ones that live longer.
Well, how does this map to long and short lifetimes for other critters?
Like in mammals, what's the longest lived mammal?
Yeah, so this idea does map pretty well to the R&K strategy stuff that we were talking about with Katie when she was on the show.
you end up with some species that grow fast and some species that grow slow.
There's also this idea where if you are not growing as fast as the other mammals and you invest in growing really quickly to try to catch up,
the quality of that fast-grown muscle or fast-grown bones, anything that you grew fast, is probably not as good as if you had grown slowly and invested in doing it right.
So in multiple flora and fauna, we see the signature of fast-grown.
sometimes coming at the expense of the quality of that growth.
I guess I wasn't that interested in mammals, in particular, more like animals, because I know that, you know, there's some sharks that have lived for hundreds of years and turtles live for hundreds of years, whereas, like, I know mice live for just a few years, but they're also tiny.
So, is this, like, size and age correlation work more broadly?
I don't know.
It would be fun to do a whole episode on aging at some point.
I know Greenland sharks can live to be, like, hundreds of years old.
But I don't know why we think Greenland sharks in particular.
live that long. Somebody might know, but I don't know. Somebody's probably gone down and tried to take
a core sample of Greenland shark, and I bet that didn't go very well. No, no, they do not look like
happy sharks. They look old. You look at them and they've got like sadness in their eyes. Not that all
old people are sad. I'm backing up. I'm backing up. Old trees don't look sad. Old trees have a grace
and a beauty that's very hard to match. Oh my gosh, they do. That is true for so many ancient
individuals.
Yeah.
All right, so let's hold some reverence for the old folks among us and take another break
so we can gather our energy and talk about how trees live so long and to answer the
listener's question about why they live longer than people.
Imagine that you're on an airplane and all of a sudden you hear this.
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This season, we're going even deeper into the world.
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Okay, we're back, and we're talking about how California is beautiful and filled with the oldest, the tallest, the tallest, the biggest, and probably the most beautiful trees in the world.
Because there's not a lot of competition because what trees would want to live there if they could live in Virginia?
You're saying if you could survey trees and offer them a spot in Shandoah, they would all pick up and move.
Yeah, I bet.
Who wouldn't?
You might be right.
You might be right.
It is beautiful.
All right.
So tell us these oldest trees.
How is that they go about living so long?
What tricks do they have under their bark that let them survive for thousands upon thousands of years?
So trees are so weird.
And so unlike anything I've come to expect, as a mammal, there are things I expect bodies to do.
And trees just don't follow any of those rules.
Okay, so one, and this is kind of amazing.
So we talked about that Cambriel layer, the layer that is growing the bark while also growing the wood inside of the tree.
The cells in that layer don't show evidence of senescence.
What's senescence?
So senescence is like getting old and sorry everybody, but, you know, the quality of the cell sort of deteriorating over time.
So you're saying in some trees you can see these camereal layers aging, but in the trees that live,
a very long time, they just keep going.
I think that you don't see Cambrian cells aging in like any trees.
Oh.
And this is why trees in general, on average, tend to live a long time.
Oh, fascinating.
We're still trying to figure out why this happens, but the cells just seem to have this
like fountain of youth thing going on.
And so because the cells aren't aging, the things that usually kill trees,
isn't, you know, it just got old and stopped working, but it tends to be things like fire or insects or
erosion or hurricanes. It's, you know, things external to the tree that end up being the cause
of the tree death. It sort of seems like the tree's constantly replicating itself. Like every
years, you basically have a new tree built around the body of the old tree. And so I'm going to
jump out of place in my outline now because, yes, it has this amazing way of replicating itself where
For some trees, if it, like, for example, falls over or if some of the branches touch moist soil, the branches or the part of the tree that fell over can start putting down roots.
And a new sapling comes up from there.
What?
That's crazy.
It's like if I put my elbow in a bowl of oatmeal and, like, turned into a person.
Another Daniel.
You know, it wouldn't be like it produced one of your kids.
It's like producing a clone of you.
So, like, another Daniel emerges from your oatmeal.
I'm glad I didn't give you oatmeal when you were at our place.
Because you can't take more than one of me, that's for sure.
No, that's actually a world full of Daniels would have been great.
Nobody believes you.
All right, so these trees have these weird ways of cloning themselves.
Yeah, so they've got these weird ways of cloning themselves.
And they also have other weird ways of fixing themselves.
Throughout the tree, there are these buds.
And some of the buds will, like, turn into,
branches and stems and leaves and stuff like that. But some of those buds stay dormant. And while the
leaves are growing, a hormonal message is getting sent to those buds that says, stay put. Don't develop,
stay a bud. And so it stays a bud and doesn't do anything. But then if something happens and like
that branch falls off or something and those leaves are no longer sending the message, that bud
snaps into action and starts, you know, building a new stem or something like that. So,
So trees have all of these different parts that are waiting to emerge.
So it would be like if you are fingers, we're sending a message to your wrist,
saying, we've got enough fingers.
Don't worry about it.
But then if you lost your fingers, that message is no longer being sent to your wrist.
And your wrist is like, time to grow more fingers.
And so it's just ready to regenerate what had been lost.
And it's just kind of like standing in wait.
Wow, that's incredible.
That's so different from the way our bodies work.
It feels so alien.
So alien.
Yeah.
Okay, so another thing that's amazing about these trees is, you know, part of them is alive, but a lot of them can be dead.
Hmm.
And so, for example, some trees, and not all trees, but some trees have this system where essentially the, like, pipes that provide water to the, like, top part of the tree, the xylem.
Instead of essentially, like, servicing all of the tree, the pipes service a very particular part of the tree.
What?
Yeah.
And so, like, with bristlecone pines, erosion exposes the roots to, like, dry air and it kills some of the roots.
But as long as some of those roots are still in good shape, they can provide water and nutrients to, like, a branch or a couple different branches.
And so you can end up with, like, I don't know, 80% of the tree being dead, but 20% sliver, still having leaves, still being able to produce seed and still being alive.
And so it's like a very slow process of death, but it still counts as alive because it can still reproduce and it's still producing green leaves.
I never thought about that how one root doesn't service the whole tree.
It's like this root is for that branch and this root is for that branch.
And so if you kill some of the roots, you're killing part of the tree.
You're not just weakening the whole tree.
That's fascinating.
It's like if I had 10 mouths and I need to like feed this one for that leg and this one for the other leg and like, oops.
There wasn't any oatmeal left from my right arm, so that's just going to be hungry today.
And that's weird.
There are tree species where, like, one root has, you know, like multiple, we'll call it pipes that come out of it and it feeds different parts of the tree.
But there are some species of tree where you get this more tight link between a certain set of branches and a certain root.
And in that way, it's able to sort of die in sections and eke out in existence for longer.
It's almost more like a community than an individual, right?
They're just like a bunch of branch root systems that's sort of like growing together.
and some of them die off and some of them continue.
It's like a little community of mini trees.
So I think that comparison works better for our next example.
I feel like what we just talked about would be more like, you know, everything but my hand could die, but my hand is still alive.
And so you'd still call me alive.
That sounds like a horror movie I don't want to see.
Yeah, no, me as well.
But the final example for how trees managed to live so long is cloning.
So you have these trees called quaking.
Aspins in the Rocky Mountains, and they're absolutely gorgeous. They're like, you know, these
long white trees. They turn beautiful colors in the fall. And their roots are able to put out
what's called a ramet. Ramit is a general word for an individual clone when you have like a clonal
organism. But it produces a stem will come out from the root and it will turn into a tree. And then
that tree will produce more roots. And then it will also have a ramet, so a stem that comes out.
It's all the same genotype.
They're all connected by their roots and can take up over 100 acres of land.
And it's all the same genotype.
And so, you know, you can say, okay, well, that doesn't really match how I think of an individual.
And so it's cheating to say that you get to count all of that living stuff.
But they can live for like 10,000 years, we think.
And so, you know, if you're willing to count that as an individual, because it's all the same genotype.
And it has all the same genetic makeup.
I'm sure there's some mutations in there, but, you know, very similar.
Then that can live for up to 10,000 years.
Well, that's interesting.
And really challenges your philosophy of, like, what is an individual?
I mean, if we had human cloning and you turned 85 and we decided to make a new Kelly,
would you consider that Kelly to be the same as you?
And then when you died, would you feel like, no, I'm still alive?
I see your point.
But, like, this tree is able to do that with no help.
Like, it's incredible to me.
And they're also able to produce sea.
So they can produce this way, but they can also produce seeds that can go off and start this whole thing, you know, going somewhere else.
I think it's an interesting philosophical debate about whether all of those trees in 100 acres counts as the same individual or not.
But one way or another, it's an amazing evolutionary strategy to replicate an organism's genes and get them spread throughout the environment.
I guess it does depend on what you consider to be the individual because in my case, to feel like I'm still alive, I would want to take.
keep my memories, my personality, all of my experiences. And if I'm like, bud off a new Daniel
on my elbow, probably wouldn't have all those experiences. And so it wouldn't really be me,
even if it had the same genotype. So there's a whole nature versus nurture aspect. Yeah,
fascinating. Wow. Yeah. So the listener wanted to know,
why do humans not live as long as trees? And I think the answer is that trees have just gone
down such a different evolutionary path than humans have, that they are able to sort of die
incrementally and sort of really stretch the process out. There are a lot of pieces that all need to be
working in order for our bodies to keep going, whereas trees are able to do things like
compartmentalize to eke out in existence for a lot longer. Yeah. I'm sometimes surprised that I'm living
as long as I am when I have all these bits that all have to work all the time. And they all seem
sort of complicated. Like, we are a very elaborate meat machine. It's amazing that we keep going
as long as we do. I absolutely agree. And it's amazing that we don't encounter even more problems
along the way, given how many things have to go perfectly in order for us to continue existing
the way we do. Well, one thing that I think humans will continue to do as we age is to be curious
about the world and to wonder and to build knowledge. And I'm just glad that human knowledge
builds from generation to generation. We can pass this down. You don't have to be 5,000 years
old. I have 5,000 years worth of knowledge because we're able to inherit it from all the folks
that were curious before us. Yes. And it became so clear to me while researching this, just how
important that knowledge is and how it builds on each other and how, you know, Dendrochronology,
which is the aging of trees, helps you with archaeology. And it's just, we're very lucky to have
all of this cultural ability to transmit knowledge. It is incredible. And I love the depth of
nerddom that exists in so many little facets of science. You know, people who have very,
figured out how this works for trees and helps us in other areas.
Like, that requires an individual to be, like, super fascinated by this topic and devote
their life to it.
And wow, I'm just so grateful that there are people out there who are curious and pushing
knowledge forward in every direction simultaneously.
Thank you for being curious and listening to our show.
And we hope to see you at the next episode.
Tune in next time.
Thank you for answering my question.
You answered it really well.
And it's cool how trees can be alive in some places.
and other places at the same time.
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So join host Jacob and Ashley Schick as they bring you to the front lines of One Tribe's mission.
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Welcome to Season 2 of the Good Stuff.
Listen to the Good Stuff podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcast.
Hi, it's Jemma's Begg, host of the Psychology of Your 20s.
This September at the Psychology of Your 20s, we're breaking down the very interesting
ways psychology applies to real life, like why we crave external validation.
I find it so interesting that we are so quick to believe others' judgments of us and not our own judgment of ourselves.
So according to this study, not being liked actually creates similar pain levels as real-life physical pain.
Learn more about the psychology of everyday life and, of course, your 20s.
This September, listen to the psychology of your 20s on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Every case that is a cold case that has DNA.
Right now in a backlog will be identified in our lifetime.
On the new podcast, America's Crime Lab, every case has a story to tell, and the DNA holds the truth.
He never thought he was going to get caught, and I just looked at my computer screen.
I was just like, ah, got you.
This technology's already solving so many cases.
Listen to America's Crime Lab on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Hi, it's Honey German, and I'm back with season two of my podcast.
Grazias, come again.
We got you when it comes to the latest.
music and entertainment, with interviews with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't auditioned in like over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We'll talk about all that's viral and trending, with a little bit of cheesement and a whole lot of laughs.
And, of course, the great vivras you've come to expect.
Listen to the new season of Dacia's Come Again on the IHeartRadio app, Apple Podcast, or wherever you get your podcast.
This is an IHeart podcast.