Science Friday - From Microbes To Mammoths: How Life Transformed The Planet
Episode Date: July 3, 2024When you think about Earth, you might think of a giant rock, floating around in space, making laps around the sun. A rock that just happens to have critters, plants, and people crawling around its sur...face. A new book by Ferris Jabr called Becoming Earth: How Our Planet Came to Life argues otherwise: Life doesn’t just exist on Earth, but life is Earth, and the Earth itself is alive. That idea might sound radical, and it is. There’s a shift happening in how we understand the planet, and what it’ll take to save it, and ourselves, from the future humans are creating. Becoming Earth takes readers on adventures across the world to learn how life has transformed the Earth, from changing the color of the sky to reshaping the continents. Guest host Anna Rothschild talks with author Ferris Jabr, a science writer based in Portland, Oregon. Transcripts for each segment will be available after the show airs on sciencefriday.com. Subscribe to this podcast. Plus, to stay updated on all things science, sign up for Science Friday's newsletters.
Transcript
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Have you ever considered that the Earth itself is alive?
A cell is not an organism, but a cell is alive.
Everybody agrees about that.
So why can't we extend that to things that are larger than organisms?
It's Wednesday, July 3rd, and you're listening to Science Friday.
I'm SciFri producer Rasha Irredi.
A new book called Becoming Earth, How Our Planet Came to Life, by science writer Ferris Jaber,
argues that life doesn't just exist on Earth's surface,
that we and all these critters and plants and microbes
aren't just hitching a ride around the galaxy on the space rock we call Earth.
Instead, life itself is Earth.
The book takes readers on adventures all across the world
to learn how life transformed the planet
and how we fit into the picture.
Here's guest host, Anna Rothschild.
So, Ferris, what do you mean when you say that Earth is alive?
So the fundamental concept of a living world or a living planet is really ancient.
You know, we find this in mythologies and religions going way back in time.
But within the history of Western science, this concept of a living planet has been rather
controversial for a long time.
And it was really popularized by the Gaia hypothesis introduced in the 1960s and 70s.
In the course of writing this book, I've come to see life not as something that simply
exists on the surface of the planet, but rather as a physical extension of the planet.
And I think that what we call life and the larger planetary environment together form a single,
highly interconnected living system. So I've come to see all the organisms on the planet,
plus the planet itself, as the largest known living system, the largest living entity that we know of.
How did you arrive at this idea that Earth came to life? For me, it began. It begins,
began at least 10 years ago when I learned this incredible fact about our planet's largest forest,
the Amazon rainforest, which is that the Amazon does not simply receive the rain, for which
it's named. It actually generates about half of the rain that falls on its canopy each year.
And the way this happens is truly astonishing because the Amazon is pulling huge volumes of water
from the soil, releasing that water to the atmosphere, and at the same time, it is throwing
up all of these tiny biological particles like pollen grains and microbes and fungal spores
and even bits and pieces of leaves and insect shells. And it's the combination of all of that
water in the atmosphere released by the forest and all these tiny living particles on which the
water can condense that dramatically accelerates the water cycle and the formation of clouds.
That's a huge part of what makes it so rainy in a rainforest. And this, you know, learning
that the Amazon did this, that the Amazon basically made its own weather.
and sustained itself to an extent by making its own reign, started to dramatically change the way
I thought about the relationship between life and Earth. I'd always been told that life is subject
to its environment, not the other way around, and that's sort of been the predominant thinking
in Western science for a long time, you know, the environment shapes life. And even when the field
of ecology began to recognize that, you know, sometimes life changes its environment as well,
it was typically focused on pretty small scale changes, like a beaver constructing a dam or some worms churning a patch of soil, not really taking seriously the idea that life could change something the size of a continent or an ocean or the planet.
But when I learned about the Amazon, which spans an entire continent and changes weather throughout South America and even influences weather on other continents, I started to really question that conventional wisdom.
And I started to look for other examples of life dramatically transforming its environment.
And I quickly found that the Amazon is just one example of this phenomenon, that in fact,
microbes, plants, fungi, and animals have radically altered the planet throughout the past
at least three and a half billion years.
And they are responsible for many of the defining features of the planet.
So when you start to see life that tightly interconnected with the planet's fundamental
geology and structure and chemistry, it raises the question of whether the entire Earth system itself
is alive in some meaningful sense. Right. I mean, you're not the first person to sort of raise this
question. You mentioned the Gaia hypothesis from the 1970s before. Can you explain what that is?
Sure. So British chemist and engineer and inventor James Lovelock proposed the Gaia hypothesis
in the 1960s, and then he published his first full-length book on it in 1979.
His initial insight came when he was actually working for NASA at JPL,
and they had asked him to help them find ways of detecting life on other planets.
And he realized you may not even need to go to another planet to do that,
that wherever life emerged, it would inevitably transform its home planet.
It would change the chemical ecosystem.
equilibrium of that planet and push it into a new state. For example, Earth would not have an
oxygen-rich environment, were it not for life continually putting oxygen into the environment in the
first place? And he eventually came to what he called the Guy hypothesis, which proposes that
together life and Earth are this single self-regulating living system and that Earth in many
ways resembled its smaller constituent life forms. It had rhythms and a kind of metabolism and a
physiology that looked a lot like what actual organisms were doing. And so he wanted to formally
draw these comparisons. You know, initially, Lovelock said that life was kind of working together
to deliberately make the planet as habitable as possible. And that was one of the things that kind of
got him in trouble in the beginning and that he later retracted because he was giving
life a bit too much agency, you know, too much purpose. Over time, he and an American biologist
named Lynn Margulis, you know, refined and developed the Gaia hypothesis together. Over time,
they came to see it more as an emergent phenomenon that this system they called Gaia,
this living entity, emerged from these planetary scale interactions between organisms and the
ecosystems they were embedded in and the ways that they changed each other through geological time.
Let's dive into an example just to sort of make this relationship really clear. If you had to pick one, this might be like picking between your children or something. What's the most profound way that you think life has transformed the planet? I always come back to the long oxygenation of the planet as perhaps the single most profound change. So this began roughly two and a half billion years ago when these ocean microbes called cyanobacteria evolved oxygenic.
photosynthesis for the first time. So they were doing the kind of photosynthesis we are most familiar
with now, where they are taking in sunlight and water, and they are putting out oxygen as a
byproduct. And in doing so, they started to suffuse the ocean and the atmosphere with oxygen,
whereas before, it essentially contained no free oxygen whatsoever. And so slowly over time,
cyanobacteria, and then later algae, and then much later land plants, they collectively transformed
the atmosphere and the entire chemistry of the planet. Because once you shift the atmosphere to an
oxygen-rich state, you've changed the chemistry of everything else that happens on Earth. So originally,
if we go back more than three billion years, Earth probably had this hazy, orange sky that was
full of methane and carbon dioxide and was kind of smoggy. When life started to oxygenate the
atmosphere, it shifted the color of the sky to the blue part of the spectrum by changing. By
changing the chemical composition of the air. So life is really why we have a blue sky in the first
place. And then having a high oxygen environment and land plants, something that could burn,
that made fire possible for the first time, maybe somewhere between 500 to 400 million years ago,
whereas before, fire was literally not possible, because if you don't have oxygen and
combustible matter, you cannot have wildfire. And then we have something like 6,000 unique
mineral species on Earth, which is vastly more than any other planetary body we've ever
discovered, including, you know, the moon and Mercury and Mars and all of our sibling planets.
And most of those can only exist in a high oxygen environment.
So the mineral diversity of Earth that defines our planet is also largely because of life.
So you're basically saying that bacteria farts changed the world.
Absolutely.
And I think we have to give microbes and their exhalations and various byproducts a lot of credit
because, you know, they are the earliest, the most ancient, the smallest, the most fundamental form of life on this planet.
And they really created, you know, many of the most profound changes over billions of years before any multicellular creatures even existed.
Right, right. I want to get into some more examples because you really talk about some kind of mind-blowing ways that life has profoundly altered Earth history.
So one of the things you write about in your book is your trip to Siberia.
to a place called Pleistocene Park, which is kind of giving Jurassic Park vibes a little bit.
So what's going on in Pleistocene Park?
Pleistocene Park is a truly fascinating and daring experiment in the Far Arctic in Siberia,
run by the Zimov's, Sergei and Nikita Zimov, a father and son scientific team and their families.
And they have this theory that large megafauna in the Pleistocene,
seen, you know, things like mammoths and mason, these large grazing animals co-evolved with
the grasslands that existed at the time. And so the grazers and the grasses maintained and sustained
each other. You know, these large animals would trample the trees and shrubs that would otherwise
compete with grass. And the grass would provide these grazers with this kind of rapidly
regenerating vegetation that they could continually graze on. But it went further than that.
in their estimation because together the grasses and the grazers, according to their theory,
were helping to keep the permafrost frozen. So for example, the grazers, just by being so
large and by walking through these grasslands, we're stripping away these insulating layers of snow,
which allowed these frigid temperatures to penetrate deeper and keep that permafrost frozen.
And grasses, just by virtue of being lighter, paler and color than trees, reflect more light and
heat back to space. So they're also keeping the land cooler. And so their idea is to bring back
large grazing animals to Siberia to kind of recreate some version of these ancient Pleistocene
grasslands and thereby counteract the thawing of permafrost to some extent.
I mean, that was one of the most counterintuitive things in your book to me. The fact that
actually by removing snow, by using their big feet to remove snow from the ground,
it could keep the earth cooler by kind of freezing that ground beneath.
I don't know why.
It never occurred to me that by removing snow, you could have a cooling effect.
But it makes sense.
Yeah, I know.
I know exactly what you mean because sometimes we get these heavy snowfalls, you know,
here in Portland, Oregon.
And my first thought is to worry about our poor plants.
But actually, they're probably being insulated.
You know, if the snow is actually covering them in the right way,
that's actually an insulating layer.
And it's when you remove that layer.
exposed to just the chill air itself, that they can actually get more damage, you know, frost
damage and ice damage. Right. In another of your many field trips in this book, which I have to say,
I'm so jealous, you got to go to such incredible places to report the story. You travel deep
underground and you look into microbes that actually breathe rock. I'm sorry, tell us about that.
What does that even mean? Yeah, that is truly bizarre. So I descendant.
close to a mile beneath the surface of the planet in this former gold mine in South Dakota
that's been converted into sort of a scientific laboratory and a place for exploration.
Most of the scientists there are actually physicists conducting these experiments that have to be
shielded from cosmic rays.
But I went with a team of biologists, specifically geomicrobologists.
They hunt for these really weird and fascinating microbes that live in the deep crust of our planet,
miles beneath the surface. And they are very different from most of the surface microbes that we know.
They seem to be able to live for a really long time, potentially millions of years. They often have very slow
metabolisms. And some of them breathe rock or metal instead of oxygen. You know, breathing or I guess
what's more scientifically known as respiration, it's all about moving electrons around in order to be able to do
certain kinds of cellular work. And we use oxygen as kind of our final dumping ground for these
electrons. You know, it's an amazing electron acceptor. It's so readily reacts with other elements.
But what if you live somewhere where there isn't a lot of oxygen or there's no oxygen available?
Well, you have to turn to other elements, other chemicals that are also capable of accepting electrons.
So rock and metal are alternatives, and they'll work in a pinch. They're not as efficient or as, you
great as oxygen, but they can work. So there are microbes that have learned to do this. Some of them
will chew rock and metal and bring it into their cells, and others will actually create these
external electrical conduits with the rock or metal that surrounds them, and they can
like pass electrons off to their rockier metallic surroundings that way. Okay, so because these little
microbes don't have oxygen, they move electrons around using other elements. I mean, just bananas. So,
Farras, what effect do these tiny organisms have on Earth's crust?
So in addition to inhabiting this, you know, the deep crust and living in these pores that are filled with water,
they are continually engaged in this alchemy of Earth. You know, they're converting minerals from one state to another.
They're taking minerals into their cells and changing them and putting out new byproducts.
Some micros will collect flakes of metal around them that attract more and more.
more metal flakes that eventually turn into an ore of gold or silver or some other precious metal.
And it is thought, it's not definitive, but there is this theory that maybe some of these
microbes were really important for the formation of the continents.
So the continental crust is made of granite, which as far as we know is only abundant on
our planet.
We've never found it in a significant amount anywhere else that we've looked in the cosmos.
And granite is less dense than basalt, so it will float on top of the basalt. And that's really where the continents came from in the first place, is that it was this less dense layer of granite that floated over the oceanic basalt and therefore rose above sea level over time. And microbes, by inhabiting and dissolving the ancient crust, likely made that crust more hydrated, basically. They brought these wet clay byproducts into the crust. They basically lubricate.
it and accelerated this process of subduction that was fundamental for the creation, the formation
of those initial layers of granite and continental crust. So microbes may have, to some extent,
kind of laid the groundwork for all of their terrestrial life. And some models, some scientific
models and computer models suggest if it wasn't for life, we may have had an earth that's
just, you know, pockmarked by islands here and there or had very small continents, but really
not the massive landmasses that we have now.
That is so fascinating. I mean, microbes basically like creating the continents in some way. It's just, it's not something that you would imagine. But it makes sense when you, when you read about it in the book, it's so incredible. It really flips things around because we're so used to thinking of life, you know, inhabiting what is already there, not creating what it needs to, you know, to live or creating something that, you know, future generations of life could use. But what we're learning more and more is that's exactly what life.
does, is that life doesn't just, you know, use what it finds. It makes new things that haven't
existed before. It profoundly transforms the planet. And then subsequent generations, you know,
subsequent waves of evolving life take advantage of what life before them made. After the break,
more on how life reshaped the Earth and our role in it. I'm talking with science writer Ferris
Jaber about his new book, Becoming Earth. All about how life transforms.
to the planet. Ferris, what's something you learned that kind of broke your brain while you were writing
this book? When I learned about the connection between plankton and giant pieces of the Earth's bones
and rocks and structure, that really blew my mind. So if you take a small piece of the White Cliffs of
Dover in the UK, you know, a small piece of the chalk or limestone that makes up these massive cliffs
and you look at it under a really powerful microscope, you will see these little tiny bone-like structures, these little pegs that are packed together just like the stones in a stone archway.
And that's because what you're looking at are the degraded remains of the exoskeletons of ancient single-celled plankton that lived in the ocean around 65 million years ago.
And they encased themselves in these intricate, lacy skeletons of limestone.
and when they died, they sank to the seafloor,
and their skeletons collected in these deep seafloor sediments
and eventually petrified.
They turned to stone over time.
And then through changing sea levels,
sometimes these petrified sediments are exposed,
and that is exactly what the White Cliffs of Dover is.
It's a massive collection of tiny single-celled fossils.
And in fact, it turns out that most limestone formations on the planet
are made of the remains of,
ancient plankton and other ocean creatures that build chalky shells or skeletons for themselves,
which means that all of the structures we have built with limestone and chalk, like the Washington
Monument or the Colosseum or the pyramids of Giza, are themselves made of plankton and these
ancient ocean creatures. So that was truly mind-blowing for me. And I think that speaks so well to
the reciprocity of life and earth, of geology and biology, how life is literally becoming rock.
then becoming life again. These incredible dusts blow over from the Sahara to the Amazon,
and they fertilize the Amazon rainforests with a lot of the nutrients that the forest needs.
That dust is also essentially ancient plankton. It's coming from these ancient lakes in Africa,
these ancient lake beds where all of these ancient fossilized plankton skeletons are accumulated,
and then they're blowing across the ocean onto another continent and fertilizing a thriving
forest that has endured for millions of years.
Just incredible. You know, Ferris, let's get existential for a moment. This book really makes you question what it means to be alive. Do scientists have a standard definition of life?
They don't. And that is one of the things that fascinates me the most about life is that, you know, clearly this has been an obsession for science for millennia. And yet to this day, we do not have a precise consensus definition of life. If you open a textbook, you will see long lists of criteria of qualities that supposedly distinguish the animate from the inanimate, but not a precise definition and certainly not some, you know, fundamental beautiful equation that explains the phenomenon we call life.
And so scientists are continually debating and reconsidering how best to define life. It very much remains an open question.
Right. You know, when the Gaia hypothesis first came out in the 70s, it was kind of panned as an idea by many scientists.
I'm wondering, is this book part of a kind of greater wave of rethinking the Gaia hypothesis and rethinking sort of what Earth itself is?
I think so. I think we are seeing the start of a movement right now that is really going to bring this idea of the co-evolution of Earth and life and of thinking of Earth as a living planet to the forefront. And I think that's in part because of how relevant this is to what our planet is going through right now. But I know of a lot of writers and scientists who are thinking about these ideas, you know, these interrelated ideas of Earth and life changing each other and what it means for a
system as large as the Amazon or indeed the entire planet to be alive. And as you were saying,
you know, a lot of scientists in particular in the life sciences harshly criticized and ridiculed
Gaia when it first emerged. And I think that was in large part because there was this conflation
between saying Earth was alive and saying Earth was an organism. Lynn Margulist, in particular,
should get a lot of credit for clarifying over time that to say Earth is alive does not mean you
we're saying Earth is an organism. I've come to see life as something that happens at multiple
scales. Like a cell is not an organism, but a cell is alive. Everybody agrees about that.
So why can't we extend that to things that are larger than organisms? That's where the debate
really begins is like below the level of the cell with things like viruses and then above the
level of the organism with things like ecosystems and planets. But I see all of these things now
as systems. You know, there are networks of interrelated components that are partly animate and
partly inanimate. And I think what we call life can emerge at any of those levels or scales.
And I think that is, you know, that's part of the realization we are coming to is that we need to
broaden our concept of what life is, of what constitutes a living system. Right. I mean, even the
human body is a system, if you really think about it. Like, we contain many parts that are inorganic.
We contain iron and other minerals and we require those to live. And we also,
require other microbes to live. Our microbiome, without our microbiome, we simply could not be alive. So even
within ourselves, we are complex. We contain organic and inorganic parts. Yeah, could not have said it
better myself. And I think there's this beautiful analogy, you know, between, say, the human body,
a tree and planet Earth, where each of those is a complex system that is made of both the
animate and inanimate. And actually, by mass or volume,
Each of those is mostly inanimate. The human body by weight is mostly water. We have, you know, skeletons that are largely rock or mineral, if you want to think of them that way. A tree is mostly dead wood, dead tissue that's sort of laced and ringed with living cells. Earth is mostly rock and water and air, but it has this incredible flowering skin of life. And in each case, that minority of, you know, living tissue, of living things sustains this larger living system or living entity. So Earth is not unusual in that sense.
Like we and Earth are very much analogous in that way.
Did writing this book change your idea of what needs to happen to keep our future from, well, being engulfed in literal flames?
Yeah. I mean, first of all, it changed the way that I see myself in relation to the planet, you know, pretty fundamentally.
Because I honestly do not think of myself as just another creature, as only just another creature on the skin of this planet.
anymore. I now see myself as literally continuous with the matter of the planet as literally an extension, a
physical extension of the planet. And I've come to see all life that way. You know, I think that's something
we sometimes feel or intuit about organisms like plants that are literally rooted, you know, to the
earth and literally grow out of it. But I think that's true for all of us, because life necessarily
emerged from the matter of Earth. It was only the matter of the planet that was available to become life,
to become animated. And then I think, you know, thinking of the Earth as a true living entity,
not, you know, accepting that as a scientific reality, not just some sort of woo-woo mystical thought
or, you know, a nice turn of phrase, but like a literal scientific reality is also profoundly
distinct from thinking of ourselves as merely inhabiting the planet or simply being passengers
on this so-called spaceship Earth. If we are, you know, literally Earth, if we are
literally extensions of Earth, then the urgency of what we have to do right now and the moral
obligation of what we have to do right now is heightened all the more. And I think in parallel,
you know, the kind of science we've been talking about, Earth's system science, is such a
clarifying guide for how to best respond to the current climate crisis. Because it really, it forces
you to reckon with what we are doing in the most truest, most material way that we can't just think of it
as pumping our cars full of gas and releasing bad pollution to the atmosphere and we're
bad humans for doing that. No, like, what are we actually doing? Like, we're going into the
bowels of the planet, unearthing ancient life, burning it, releasing all of that carbon to the
atmosphere and completely throwing the planet's long-evolved rhythms out of balance. You know, for me,
that's a much clearer, more profound and more compelling way to think about what is happening
to our planet right now.
Ferris, thank you so much for joining me today. This was such a pleasure. Likewise, this was so much fun. Thank you for having me.
Ferris Jaber is a science writer and author of Becoming Earth. Read an excerpt from the book at ScienceFriiday.com slash Earth.
That wraps up this week's show. Lots of folks help make it happen, including Jordan Smudjik.
Charles Bergquist. George Harper. John Dancosky.
On tomorrow's episode, some sciencey grilling advice for your summer cookout. Join us. Join us.
I'm sci-frag producer Rasha Auretti.
