In Our Time - Slime Moulds
Episode Date: January 30, 2025Melvyn Bragg and guests discuss slime mould, a basic organism that grows on logs, cowpats and compost heaps. Scientists have found difficult to categorise slime mould: in 1868, the biologist Thomas Hu...xley asked: ‘Is this a plant, or is it an animal? Is it both or is it neither?’ and there is a great deal scientists still don’t know about it. But despite not having a brain, slime mould can solve complex problems: it can find the most efficient way round a maze and has been used to map Tokyo’s rail network. Researchers are using it to help find treatments for cancer, Parkinson's and Alzheimer's disease, and computer scientists have designed an algorithm based on slime mould behaviour to learn about dark matter. It’s even been sent to the international space station to help study the effects of weightlessness. WithJonathan Chubb Professor of Quantitative Cell Biology at University College, LondonElinor Thompson Reader in microbiology and plant science at the University of GreenwichAndMerlin Sheldrake Biologist and writerProducer: Eliane Glaser In Our Time is a BBC Studios Audio production
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Hello, if you've ever seen a mysterious white or yellow blob
on your garden compost heap,
or on a fallen tree in the local park,
you'll have come across slime mould.
It's a single-celled organ.
that scientists have struggled to categorize.
In 1868, the biologist Thomas Huxley asked,
is this a plant, or is it an animal?
Is it both, or is it neither?
Despite not having a brain,
slime mold is clever enough to find the shortest way through a maze,
and scientists have used it to design rail networks,
map dark matter in outer space,
and research treatments for cancer and Parkinson's and Alzheimer's disease.
When we're to discuss slime mold are,
Eleanor Thompson, reader in microbiology and plant science at the University of Greenwich,
Jonathan Chubb, Professor of Quantative Cell Biology at University College London,
and Merlin Sheldrake, biologist, writer and research associate at the Briar University in Amsterdam
and Oxford University. Jonathan Chubb, what is slime mold? It's actually quite a vague, fuzzy term
that encompasses a lot of different species. They superficially seem very, very diverse, but there are some
common features. Often a free-living single-cell stage that goes around eating, usually bacteria,
but these organisms also have the ability to make spores, which are environmentally resistant and
dormant and can last for years before they germinate and generate single cells again.
Now there's a tremendous diversity. Some of these things are really a tenth of a millimeter in size.
Others can be a meter across. These are the big things you see on decaying wood.
Some of the forms are incredibly beautiful, things like wolf's milk,
looks like German Christmas biscuits.
There's also the dogs vomit, or better known as scrambled eggs mold,
which looks exactly like that.
It's a very, very successful type of species that is evolved multiple times during evolution,
whereas as far as I'm aware, there's probably only one hominid branch.
Even some bacteria have life cycles that resemble slime molds,
mix of bacteria, which also have a single cell stage,
which can aggregate to form spore-containing structures.
How does slime mold relate to other organisms?
which is plants, animals and fungi.
Putting aside the bacteria,
if we can oversimplify the tree of life into two branches,
which I'm going to get slapped for,
but there's the branch that's a bit more plant-like
and there's a branch that's a bit more animal-like
and fungal-like.
Now, the slime moulds appear on both branches,
so some that are a bit more plant-like
and there are some that are a bit more animal-like.
For example, the acracids are much more plant-like.
They include certain human pathogens like necleria,
whereas the more animal-like ones,
include the amoeba zoa.
That includes a big spectrum of accellular slime molds
and cellular slime molds.
But within these different groups,
you have, for example, animal-like ones like amoeba zoa
looks very, very similar to plant ones like the acracids.
So there's this motif, these features have propped up many times during evolution.
How many species are there?
I guess we probably don't know the extent that there's at least over a thousand,
many of the sort of acerular form.
Yes.
When did people come across from?
Well, to the best of my knowledge, the first one named was Wolfsmilk in the 1600s.
And it was as early as the 1700s, actually, that someone realized this wasn't, initial reaction was this was some kind of fungus.
But it wasn't until another century later that they realized just based on the morphology that it was something a bit different.
It doesn't look like a mushroom.
Yes.
Thank you.
Merlin, Merlin-Shagreb.
Can we develop where this slime models are found and whether we see them and what they look like?
Just give this as a visual map of what?
sitting on looking at or scraping off.
So you'd find them in damp, often shady places,
like on fordden logs or on fordden leaves when walking through a forest.
And in different stages, they look like different things.
And in their single-cell phase, you might think of them as being,
if you had a microscope, as being shaped-shifting blobs,
a little bit like your white blood cells that we have in our bodies.
So shape-shifting single-celled beings.
But then they come together to form networks of slimy,
tentacle-like veins, which could be pinkish, yellowish, orangey.
And these networks are shape-shifting as well,
but they're exploring as a network their environment.
And they're the ones that look a bit like sometimes can look like dogs vomits
or scrambled eggs or tapioca pudding.
But then they come together when they produce reproductive structures.
You'd see those as a very fine stalks, a few millimeters high,
with a spherish kind of structure balanced on top of the stalk
or a sausagey structure balanced on top of the stalk
and they're really remarkable looking.
I mean, there are ones that look like little planets
or like single fish eggs
or like the seed pods of a very unfamiliar plant
or like corals that have erupted from small sacks.
It's remarkable.
There, we're told,
there are around a thousand known species of slime mold
which fall into two main types,
cellular and accellular,
What are these? Let's start with cellular.
Cellular slime molds spend much of their life living as single-celled organisms,
and when times get tough, food gets scarce,
they come together to form multicellular structure.
But the individual cells retain their identity as an individual cell.
So it's a little bit like, imagine when you're playing with bubbles as a child,
those bubbles can sometimes stick together,
but they remain.
You can see the different bubbles in a kind of clump of bubbles.
Now, the accellular ones, when they come together,
because they also come together from a single-celled state
into a kind of merged state.
And when they come together, they form one giant cell.
So it's a bit like those bubbles have joined to form one big bubble
with one outer membrane.
So it's got quite a different way of leaving a single-celled state
and coming into a merged state.
Alan Thompson, let's keep banging on about this.
Well, digging in might be a bit of reasonable.
of this cellular slime mold.
Trying to give the listener an idea what they are.
What's it made up of?
Is it very similar to our own cells, their cells?
Okay, so the cellular slime molds are the ones that we know particularly well
because there's an example of them which we are using a lot in scientific research.
So in the 1930s, an organism called Dictuselium Discodeum was discovered on dung.
and it's an amoeba, it's a eukaryotic cell.
So it's a complex cell type like our own,
which gives us an idea of the preservation of cell features
over evolutionary time,
because this is an anciently evolving branch of organisms
that has cells that look very like our own.
In the scheme of things, in your scheme of things,
does it surprise that their cells are like human cells?
No, because, so I'm really interested in what's maintained over
evolutionary time in cells and so
one sees it all the time so
bacteria in fact do many things
that more complex cells can do
we always think of bacteria as being very simple
but they make up most of life on earth
and then our poxy
eukaryotic branch these complex
cells that end with this tiny
little twig of multicellular
complex life with humans and animals
on it the thing that's special about
the amoebe for us and makes them
nice to use as a model
in the lab is because they're very like
human cells in not having a cell wall
and we'll perhaps talk about the genetics
as we go on.
How does it behave
at different life stages?
Okay, so cellular slime
molds, as Merlin said,
maintain a unicellular
life habit, but they're able
to join together to form a
multicellular organism. So they have this
amazing, fascinating
life cycle where they can
graze their prey microbes
in the environment. So they
go around engulfing bacteria as a food source, but then as they reach very high numbers of cells
and they start to run out of food, they signal to each other with a chemical signal that tells
them that it's time to move on and make spores. So single cells signal and when one cell signals
to another, another cell signals to other, and you get this propagating wave of chemical signals
that then brings together waves of these single cells into a mound.
And then the mound is able to sort of rise up and it topples over.
And then again, the amoebe, they sound so glamorous.
We call this toppled over multicellular organism.
We call it a slug.
So every aspect of this is made to sound really unexciting.
But clearly it is because we have these identical single-celled organisms
which come together to become a multicellular slug.
And then this slug is a true multicellular organism.
which is able to move to a place where it can produce the next generation of spores.
That's the point of the slug.
But in doing that, we've differentiated.
So these independent living cells turn into different types of cell within the slug,
and then they turn into a base, a stalk and a sporehead.
And the amazing thing about that is that only some of the cells are in the spores.
And so sacrifice becomes part of this Dictuselium life cycle.
When did they come into your area of knowledge about what was going on in life?
I was given Dictuselium as a leaving present.
When I left the lab where I did my postdoctoral research,
I was working on a particular set of components of cells
and some very lovely colleagues in the Dictuselium community
gave me some Dictuselium cells to take with me
when I set up my own new lab.
So I've had them for about 10 or 12 years.
How have they behaved in that time?
Yeah, mostly okay.
They are a really lovely organism
because they're just so interesting.
They're a really brilliant teaching tool.
And when we have visitors to the lab
who aren't necessarily scientists,
they're a lovely thing to show them.
What do you show them?
Well, so the unicellular form of dictustilium
is not visible to the naked eye,
but you can see where it is on agar plates
because if you put dictustinium cells
onto what we call a lawn of bacteria,
it will graze those bacteria
and produce very little sweet areas
of grazed out bacteria,
so zones of clearing that you can see on a plate.
So that bridges the microscopic to the macroscopic.
And then the multicellular stages you can actually see with the naked eye.
So you can see the stalk and sporehead.
So even though it's a microbe, visitors to the lab can actually see this thing.
Jonathan, let's talk about the accellular kind.
What's that made of and how does he behave differently from the cellular?
I mean, it has a slightly more complicated life cycle.
It can exist and feed.
There's both this large thing that you see on rotting logs,
but also have small cells which can either be amoeba like the cellular slime molds or flageolate,
which means it's a cell with a tail, think sperm cells.
So I think the most remarkable phase of the life cycle of this organism
is this thing called the plasmodium, which is these things are visible to the naked eye.
Sometimes they can be a meter in diameter.
They're these flat structures that you can see in the soil or on logs.
These are, in some sense is quite unusual because normally when our cells divide,
the cells copy the DNA, they segregate that into two nuclei,
and then the whole cell divides, and each cell has a nucleus.
But with these plasmodial or accellular slime molds,
you get the nuclear division, you get the whole growth,
the cell itself doesn't divide.
You've actually got a single cell,
which can weigh as much as 20 kilos,
which is a very unusual strategy.
We have some cells like that in our bodies.
For example, muscle fibers are often fusions between multiple cells,
but a single fiber is nothing like the scale of the acer slime mold.
So one of the other remarkable features about this,
in a cell that large, moving material around is really rather hard. For example, in our bodies,
we have a circulatory system that can move oxygen and nutrition around. In a single cell, that
becomes a problem. But these slime molds have developed an internal circulation, which we call
cytoplasmic streaming. So if you want to imagine how that works, imagine squeezing a sausage in the
middle. And when you squeeze the sausage in the middle, the contents will move to the other side.
So the cell has these proteins, which basically wrap themselves around the tubes, and they
squeeze, much like if you were squeezing a sausage. And that causes flows of,
fluid along various channels within the cell.
Thank you, Merlin.
How did it make decisions?
We said earlier on they have no brain, and yet they're very intelligent.
Now, can you enlighten us on that?
Well, I think it's helpful to think about some of the behaviors that we're trying to explain.
So one of the very famous slime mold, the plasmodial, or a cellular slime mold behaviors,
is the ability to navigate labyrinths or mazes.
And there are some very well-known examples of this with researchers recreating the
Tokyo Subway Network, but others have done it with the network of Roman roads in Italy or the
American highway system where if you put blobs of food, oats, they love oats.
The rats of the plasmodial slime mold world love oats.
So you can put oats on a big dish, and then the slime mold will find the most efficient
path between the oats.
Having explored the dish, they can also find the shortest path between two points in the
labyrinth.
So the question is, how are they so good at searching space and navigating complex environment?
actually they're so good at this. I have a friend who's an artist and he always got lost in IKEA stores, giant IKEA stores. And he had a stable of slime moulds at home. And he told me once that he'd made a scale model of the floor pan of the IKEA store with all the obstacles and roots that were available to him as a human with a brain. And he unleashed the slime molds in the slime mold-sized IKEA store. And they were able to find the shortest path to the exit faster than he could, even though he had access to shop assistants to help direct him. So he would have.
always say, look, they're cleverer than me. So the question is how then can they navigate?
You know, how can they find shortest paths? How can they do this? And it comes down to what
Jonathan was saying, where these rolling waves of contraction move the cellular contents
along these slimy vein-like protrusions or sort of tentacles, a little bit like tentacles.
And so when one of these arms or veins reaches some food, then it generates
stronger contractions along that arm of the network. And the stronger contractions move more,
cellular fluid along that arm.
And the shorter the path, the more will pass along that arm.
So what this means is that the stronger arms,
the more, if you like, successful arms,
the ones that are touching food,
are strengthened at the expense of the arms that aren't touching food.
And in this way, the slime mold can redistribute its body
orienting to new food sources
and sensitively navigate through landscape.
I'm a bit taking a back by.
I mean, this is the world you dwell in.
This is the world.
It's completely new to me.
It sounds almost like a magical world.
Eleanor again and Jonathan both of you.
What can we gather about these, simole social behaviour in communities?
How do they communicate?
How do they interact?
Starting with you, Eleanor.
Okay, well, if we follow on from the development of the unicellular
to the multicellular organism,
there are two particular features of that that we haven't mentioned so far.
So one is the sacrifice that's involved.
So 20% of a multicellular.
Dictuselium, in the case of this cellular amoeba, will become dead, stork cells.
So there's an element of self-sacrifice.
It's almost a philosophy of science that comes in here.
How do you decide which cells will become the spore and which will become the stalk cells,
so the communication and control of that?
And then the thing that really makes the hairs stand up on my arm still,
and I describe this, is the presence of cheetahs in the community.
So in the population of cells that all look the same as each other,
at the beginning, that aggregate into the multicellular organism.
There are quite a lot of changes that can happen
that will ensure that you become a spore.
So some cells will make jolly well sure that they're in that spore head.
And so we can learn a lot from Dictuselium
about the messages that go between cells
that make those things happen.
How's that decision made, you say,
they decide to move there or there?
Well, this is where knowing things about science
makes the science sound more boring.
So there's self-sacrifice.
So there's another element of this which is kin recognition.
So Dictuselium spores have been found to be more likely to be relatives of each other
so that they can recognise one another.
And these features are surface features.
So there's a green beard is the theory, isn't it?
So the idea that you will choose somebody with a green beard to join your community.
So a Dictuselium cell that recognizes a relative is more likely to aggregate
with something that has that component.
on its cell surface.
Do you want you to carry this on, you?
Not about greenbeards,
but I think these cheetahs that seem to become spores
and not sacrifice themselves,
there's a limit to what the population can take of those.
So they're very good at following the signals
that allow them to become spores,
but if you have too many of them,
the population, you get an overall loss of fitness
that is a break on how far they can actually permeate in a community.
Yes.
What is a cellular slime mold?
What's it useful for?
You look, taking her back.
I'm just trying to be diplomatic.
I'll give a very personal answer,
and I'm possibly in the minority of one.
But for me, I think the idea that its intelligence
is a very human view of the proceedings.
I think for me, it shows, from our perspective,
very, very complicated behaviour using very, very simple rules.
And I think that's what we have to take from this.
What are those rules?
And then think about how that can relate
to more human types of questions, for example.
I mean, you've got this vast network
that's making this decision on which way to go
or which path to strengthen.
Have we talking about slime models or a road or what?
I'm talking about the slime moles mimicking
the establishment of rail networks and things like that.
And in practice, we would never set up a railway network like that.
The way they do it is they send out this big flanks of material,
almost at random.
And that would be like building a railway every few meters
and hoping that one of them would actually find the destination you're aiming for.
But the branch that actually gets to the oat flake
is the one that stabilising all the others are retracted.
So in terms of designing rail networks,
I'm not sure this is really that useful at all.
But in terms of understanding what is effectively a complex behaviour
and understanding the basic rules of that, I think it's extremely useful.
I mean, our brain is also just a network of cells that are communicating
and they're using similar types of basic,
the same types of cell biological processes
to underline the structure of this network.
Just our networks are bigger and more complicated and have more sub-departments.
Yeah, so the way that they find these, or navigate space and find these routes,
is very different from the way that we would do this, because we're centralised organisms.
Now, if we were dropped off in the middle of a desert and we had to go and find water,
we'd have to pick one direction, and we'd try that one direction, we might be successful,
we might not be, and we'd have to keep looking one route at a time.
But slime molds, these acillular slime molds, a bit like fungi, are able to grow out in all directions at once.
which means they can search space quite efficiently.
But when they get to the point of interest,
say it was us in the desert finding water,
but for the slime malls finding an oat flake,
then they can strengthen that line
and retract the parts of their inquiry,
which didn't lead anywhere.
So it's just a different way of navigating space.
And so what that means is that you can,
when researchers have done these experiments
where they've recreated road networks,
or there are some that have used slime malls
to calculate the fastest fire evacuation routes,
from buildings.
What you're doing is they're asking the slime mold
to find the shortest path to the oat flake,
which you've positioned at the exit,
if you're trying to find the fire exit.
So we might design in a slightly different way,
but these are partly demonstration
and partly a way of trying to understand
these different strategies that organisms have
to navigate a changing and varied world.
And what's amazing in these cases, to me,
is that they're able to solve this kind of problem
without a centralised place to do so.
We're used to thinking of our bodies
in terms of centres.
We have heads and we have hearts.
We make capital cities.
We have heads of state.
You know, the centralisation runs all the way through our societal metaphors.
But someone don't.
You know, their coordination sort of takes place a little bit everywhere at once
and a little bit nowhere in particular.
And so I think it's important as an example as a way of life
because it illustrates that one doesn't need a brain to solve problems.
You mean none of us need a brain to solve problems?
So I think one of the things this illustrates is that, you know,
we're used to thinking about brains as being totally key to problem solving
because we have brains and we're proud of our brains and rightfully so.
But there are lots of ways to solve the problems that life presents.
And slime moulds illustrate some of these other ways
and in jolting us into remembering the many ways that there are to solve problems,
I think they've done us a great service,
at least Donovan Science, a great service.
I think there's a lot of examples where even some of the more complicated
emergent behaviours that are shown by the cellular slime moulds are happening
and in our bodies and during development.
The primary example would be how the cells talk to each other
when they're in the single cell state.
So they talk to each other with this chemical called cyclic AMP.
And that chemical, it's like a relay.
So one cell releases cyclic AMP,
and the next cell sees it and goes,
oh, I'll release cyclic AMP,
and then that passes along this chain.
So what happens is a bit like one of those Mexican waves
you get at a football match,
where everyone just sees what their neighbour does
and it goes around the whole stadium.
So you get these waves and waves and waves
propagating across the population.
So that type of emergent behaviour is occurring in several aspects of our own physiology.
So if you have a cut, the cells that are surrounding the edge of the wound will have similar types of wave as they coordinate the closure of the wound.
You see similar patterns.
These waves, certainly on a two-dimensional surface, they form these beautiful spiral patterns.
So you can see these, just making recordings of electrical activity in the brain, you see very similar shapes of activity.
The contractions within our heart show the same types of what we call excitable behavior where you have one cell signaling to the next and so on and so on and so on and so on.
Well, can you develop that a bit?
I would say that if you want to studying a lot of fundamental problems about,
certainly from my perspective, developmental biology
and how you build structures in an organized fashion.
Biology is like to think of some sort of central control element
that directs things or some sort of blueprint.
But the more and more we look at how embryos develop,
there's so much more which is about self-organization
and adaptation to the environment
and almost finding a structure
and then modifying it to suit the environment
and to suit the associated structures.
I want to add to that?
Yeah, I think it's, I mean, it seems to me that one of the central problems of biology that's been around for a very long time is how parts come together to form complex holes.
And how these holes can be nested within even greater holes.
And you think about our bodies, we have cells of certain types which come together into tissues, which come together into organs, which come together into a coordinated feeling, wild, wet you know, and that can explore the world and sit here talking about life.
So these are nested systems of organisation.
such a puzzle on so many levels. How do these cells communicate with each other? How the cells
know what to become, when to stop becoming what they're going to become? How did they then
coordinate with all the other cells? So in the sense that this is a big persistent question in
biology, I think slime molds, especially the cellular slime molds, can really help us to have a
kind of model system where you can see the journey from a cell into a complex morphology,
which can differentiate into different cell types and regulate as an integrated
organism and so much for science is playing around really
and I think they can really contribute to this
enduring question of how the organisms acquire form
and how do organisms develop into complex forms.
John Lund, can we talk about
how useful these slime mules have proved to be for scientists?
I'll talk about the cellular slime molds if that's right.
So I think a lot of people who study slime molds
study them because in the single cell stage
the cells look very much like the cells of our immune system.
cells like neutrophils and macrophages, the job of which is to maraud around the body looking for bacteria and other things to eat and they'll go into a wound and stopping infection getting in.
It's very difficult to study these cells such as neutrophils and macrophages. You can take them out of your blood, but they're often dead within a few hours.
Whereas you can, slime molds just grow on the bench. But actually the overall cells themselves, the way they move, even the chemistry, the bichemistry, explaining why they move is highly related to these immune cells.
And in particular, the two features of immune cells that matter, which is finding your prey,
which is identifying where the bacteria are, and a process we call chemotaxis,
and then killing the bacteria, eating the bacteria, which we call phagocytosis.
So cellular slime molds are experts at this.
Can we talk in a little more detail about how scientists are using these cellular slime molds
to research diseases like cancer, Alzheimer's, Parkinson's, epilepsy,
see, bipolar disorder.
They seem to be everywhere, and they seem to be everywhere effective.
Can you give us a summary of that?
Yes, I can.
So there are probably three parts to this answer,
and the first is probably the most boring part,
but it is what Jonathan has alluded to,
which is that we can grow the cellular slime mould,
the amoeba, dictiostelium,
very easily in the lab.
And we have strains of dictustilium
that we can grow in flasks shaking about
in an incubator, which means we can grow lots of cells,
which means that we can look at the chemistry
of something much more easily than we could have a look at a nerve cell or a component of us.
There's a second part which allows us to really start to study complex things like disease in us,
which is that Dictuselium was sequenced very early in the sequencing era.
And so it became apparent very soon that Dictuselium, through a slight freak of evolution,
actually, has retained an enormous number of genes that correspond to our own.
So the cellular equipment that Dictuselium has...
You have a free to be able to.
Well, yes, so the reason that I see it,
say that is because yeast
are very nice eukaryotic
microbe, they have complex cells like ours
they're fungi and you can grow them very
easily in the lab but they seem to have lost
a lot more of the human-like
genes although up on
the tree of life I think even
a dictustilium biologist would agree
that you would think that fungi will be more similar
to human cells but it just happens that
dictustilium has an unusually large number
of genes that correspond with ours
and therefore if you're
interested in a particular disease
pathogenesis, how a disease progresses.
You can study it in Dictuselium by looking at the gene in the amoeba that goes wrong in human disease.
And then the third part of the answer is that Dictuselium also has many parts of the way it behaves and its life cycle that are analogous to aspects of human disease.
And I can list those if you like or can come.
Okay.
So some things that correspond really nicely with human disease in us are the migration, the motility of cells.
So that's relevant to cancer cells when they metastasize.
So we can study the adhesion of the amoeba dictustadium to a surface
and why it adheres and why it doesn't.
And we can study how cancer cells might move and spread using that system.
The migration of cells is also seen in wound healing.
So we can study the good and the bad of disease.
I mean, there are many aspects of dictustadium that mirror disease.
But the neurodegeneration one that you mentioned,
so Parkinson's and Alzheimer's, it has a couple of things
where it's particularly relevant.
In the case of Alzheimer's,
Dictuselium seems to be very resistant
to the protein aggregation,
the plaque formation that's very characteristic of Alzheimer's disease.
So some research is trying to find out, you know,
what aspects of that you might employ to fight Alzheimer's.
And then in terms of Parkinson's,
which is the second most common neurodegenerative disease of aging,
and many diseases of aging in human,
come down to a problem with the energy generation of the cell.
So the mitochondrial, the compartment of the cell that makes energy.
And diktiostelium has a sort of fun feature,
which is that if it has a defect in its energy generation,
you will often see dictustelium amoeba cells
that can't respond to light very well,
and they don't develop very well in their life cycle.
And when they do develop, they often have little short fat stalks.
And so if you have dictustelium that has these particular appearances,
its characteristics.
It's been found that the genes that go wrong
are often ones that go wrong in human neurodegenerative diseases as well.
So we can explore those cell and genetic pathways
in dictustelium a whole lot more easily
than we can in a human cell.
These strange little objects seem to cover most of the territory, don't they?
Jonathan, a computer scientist using them to,
sending them up into space.
Who's going to take that on?
I can have a go.
The experiment I want to see done in space hasn't been done,
which is to take a huge bucket of dictumstilium spores
or slime mold spores up into space
and just release them and see, do any live ones come back
and can they actually see life somewhere on Earth?
If we can label them somehow,
can we actually get spores to come through the atmosphere?
I think this could be a useful way of colonising future worlds.
It's a bit far out.
But in terms of what's actually been done,
both the cellular and accellular slime molds
are both in up to space.
The cellular slime molds 20 years ago
went up on an acid.
expedition to look at the effects of both gravity on the formation of their three-dimensional
structures, but also the effects of ionizing radiation on the organism.
And actually, they'd found that the cells didn't really care very much.
They did their thing.
More recently, accellular slime molds, Pfizerum, have been on the International Space Station,
again, to look at the behavior of these very large cells in a low-gravity environment.
It was found that they have a more 3D-like structure, whereas if you see them on a log,
they tend to be quite flat.
So there was something learned about that.
I mean, I think the most important thing is that these cells, they like surfaces.
So I'm not sure how informative for the biology of this organism this actually is,
but it was quite interesting.
It was a massive collaboration with a lot of schoolchildren
who made the earth-side measurements of FISA.
How important is a slime mold for very small microbes?
Cellular slime molds can teach us a lot about microbiology.
They're a really good example of the complexity of microbial life.
So I think perhaps there's an idea in general that we're incredibly complicated in super beings.
But when we look at something like Dictuselium, we start to understand just how sophisticated microbial life on earth is.
And if we look at the tree of life whole, not as Jonathan did at the start, but we really, if we include the bacterial groups,
and we see how early off the tree of life, the amoebe that include Dictuselium branch off.
and we see that the fungi and the algae and animals are at the top.
We have this illustration that even something as sophisticated as Dictuselium is a microbe
and it's on a microbial branch.
The world is microbial and Dictuselium also lets us study what's microscopic
because we can see stages of Dictuselium.
So I guess it makes that microbial world visible to us as well.
Jonathan, what do we not yet understand about slime melts?
I think for the last 40 or so years, dominated by technologies of molecular biology, we've amassed a huge amount of data.
And we're drowning in data, really.
I think the challenge really is to try and make sense of all that, to try and integrate all that information.
And my feeling is that, and this is a problem for slime mold research as well, but I feel that slime mold research has a manageable level of complexity,
where we can actually answer big questions without drowning in,
information. So I think the challenges I see, for example, are how do cells really integrate
information? We know we have some good answers for how cells can integrate information from
one signal, but cells are bathed in different signals all the time. They're seeing,
it's like walking down Houston Road during Russia. There's all these sites and sounds that
are completely hitting them. And how does that single cell process all that information?
I think that seems to be the biggest challenge. I mean, more generally, I would say what you have
here is a very, very successful
mode of living. This idea that single
cells can either aggregate or
generate a very large cell which makes spores.
A beautiful example of this
is some of you may have seen the
Terminator movies with Arnold Schwarzenegger.
So in the later
generations of the Terminators, there are
terminators that are made of liquid. So when
their arm gets cut off, it forms this pool of
liquid on the floor which over the next 30
seconds to a minute regenerates
the arm. So it gives the good guys time to
get away. But, you know,
What are the limits to this type of self-organizing emergent behavior?
Could it build more complexity?
Is it a restriction on this complexity?
It's obviously a very successful form of life.
Maybe it doesn't need to.
It's very adaptive.
I mean, that would be the more philosophical question.
What are the limits to this approach?
Can we evolve something that could have more functionality?
Merlein, I'd like to come back to something we touched on earlier.
And I think listeners will be very intrigued to know.
How does Slymo's change our understandings of massive things like memory
in intelligence and individuality.
We said at the beginning, they were without brains,
but they seemed to solve brain problems,
more impressive than human intelligence in some ways.
So can you give us your view on that?
I think there are a few very interesting ways
that they teach us about memory,
and the accellular slime molds in their plasmodial stage,
so these slimy, vein-like networks
have been challenged with all sorts of experiments.
And in one memorable experiment,
these networks were given an opportunity
to cross a salt bridge, a salty channel,
leading to a plate of food of something delicious.
And they didn't like to cross the salty channel.
It's salty, it's uncomfortable.
It's not something they would choose to do.
But over time, they explore,
and over time the ones that explore,
reach the plate of food on the other side of the salty channel.
Now, given the chance to explore this similar sort of obstacle course,
again, the ones that had crossed the salty channel to get to the food,
they were quicker to cross the salty channel.
again. They had somehow learned and had an enduring memory that this was something that they could
expect in their way, some kind of response where they'd remembered that the salty channel was
something that might lead to food. So what's interesting then, it's interesting, first of all,
that they can learn in that way, associative learning, we might think of it as, although there
are potentially other ways to think about it. But then when a slime mould that had learned
was exposed to a slime mold that hadn't been exposed to the obstacle course.
So you might say a naive slime mold.
And they were given the chance to form a connection for around an hour
and then separated.
The naive slime mold was quicker to cross the salty channel to the plate of food.
And what's funny about that is that we usually think of memory as needing a subject.
The subject in our cases, us, in my case, me,
is the owner, if you like, of memories.
the seat of memories.
And it's something to do with my past experience
that I'm recalling when I have a memory.
But in this case,
self, the slime mold,
naive slime mold,
which had not experienced this challenge,
did have the memory.
The memory had somehow been transmitted
from slime mold to slime mold
without the second slime mold,
the naive slime mold,
needing to have that experience.
So I think that raises all sorts of questions
about selfhood,
about the nature of memory,
of how memories might be transmitted
between different organisms,
and certainly,
dislodges some of our assumptions about memory that we might have
if we stood only looking at humans and other animals with brains.
Does it dislodge our ideas of intelligence?
What you're talking about is something that if we weren't using the word slime mold
who said, that's very intelligent and that's very intelligence, and so on.
It sees slime mills that I kind of these sort of pre-slugs
that are getting in the way of me accepting that.
I accept it, of course, I do.
It's imagining how they can do without a...
brain, as you keep saying, what they do, which in some ways sounds as if it's as intelligent
or more intelligent than things we do. I mean, the word intelligence has undergone some
discussion in recent years within biological fields. It used to be a word that were applied to
the sort of behaviours that humans can do, because the cognitive science has placed humans
at the centre of their inquiry naturally, because we try to understand ourselves. But over time,
this is definitions of intelligence have deepened and expanded. And now I subscribe to the view that
intelligence refers not to something, it's not a property that one has or one doesn't have,
that there are behaviours which you might think of as intelligent behaviours, different types
of intelligent behaviour, that one might possess to a greater or lesser degree. And you might
think of those as being able to make decisions between alternative courses of action. You might
think of them as being able to adapt to changes in one's environment. You might think of them as
the ability to solve certain kinds of problem. And when you think about it like that,
almost all organisms have some degree of intelligence
because all organisms have some degree of intelligent behaviour
because they all live in a changing world.
We all live in a changing world.
We all have to solve different kinds of problems.
Now, the kinds of problem that humans have to solve
are quite different from the kinds of problem that a plant has to solve.
So we might miss the ways that plants are sensitively responding to their environment
in problem-solving ways if we only use human categories.
So I'm very interested in how that debate has expanded
and how it leads us into thinking of life from the perspective
of different organisms and stepping outside our own human-centric perspective.
Can I add something to that?
The idea that an organism can know how related it is to its neighbours
is something that we can see happening in these amoebe,
but we can also see it in bacteria.
So if you've got different subspecies of a very common skin bacterium
called staphlocococcusaurius,
that a community of those bacteria will know how...
They're talking about millions here.
Millions of bacteria.
Millions of bacteria.
will know whether their neighbours are related to them or not
and will make decisions according to the relatedness of the bacteria around them.
There's another bacterium called pseudomonas aerogenosa,
which is the one that infects you when you have cystic fibrosis,
but it's a very common environmental organism.
Iron is often a limiting nutrient in the environment,
and pseudomonas erogenosa will cooperate and produce a chemical
that will grab the iron together as a community.
So again, just this idea of intelligence and cooperation,
It's our definition that's problematic
as we learn more and more about life on earth.
We're coming to the end now, but still, Eleanor,
what do you think this investigation
into the effectiveness of slime mills has had on the whole?
How has it changed your view of how the world works?
Well, I have two microbiology degrees,
so I've spent decades thinking in terms of the complexity of life on earth,
but I love to think that our
Well, Merlin's done an amazing job telling the world about fungi
and how complex and interesting and widespread they are
and it would be great if an exploration of the amoebe
which sound perhaps even less exciting
would make people understand that we live in this fantastic microbial world
all life on earth is really microbial
and complexity in life started really early on the evolutionary tree
and we can use it to simplify our understanding of our own bodies in many ways.
So I'm a great proponent for microbiology
and I hope on that level
that our understanding of these systems
helps people appreciate the world that we're living in a bit better.
Jonathan?
From my perspective, I think that I've been working with slime molds now
for nearly 30 years.
Before that, I was very, very welded to this almost religious view
of embryology and developmental biology
that there is a blueprint or a pre-plan
for how an embryo is constructed
and I think I'd probably still be there without that exposure to a completely different way of doing things.
In fact, for about 20 years, most people who worked on slime mould believed in the blueprint model.
I think revolutions in mammalian biology have very much allowed us to relax and believe what we want to believe again,
which is that I think emergence is really, really important.
Finally, last word from you.
I study fungi a lot, which are network-forming organisms that are capable of complex behaviours in this kind of bottom-up way that we've been discussing with slime moths.
and for me, slime molls make it so clear.
They really poster organisms for kind of brainless problem solving, in my mind.
And they illustrate something really fundamental
because so many biogeochemical processes,
so many processes that have really shaped the world over hundreds of millions of years,
have been overseen and conducted by network-forming organisms
that have analogous behaviours.
And so slime malls, for me, are a gateway into a whole other way of being,
a whole way of living, which is not only vitally important today,
but which has shaped the very conditions for our existence.
Well, thank you very much.
Thanks to Merlin Sheldrake, Alan Thompson and Jonathan Chubb.
Next week we take a break and we'll be back on the 16th of January
with the Battle of Balmine 1792.
We saved the French Revolution and cemented the Marseillaise as the National Anthem of France.
Thanks for listening.
And the In Our Time podcast gets some extra time now
with a few minutes of bonus material from Melvin and his guests.
What did you feel you didn't have to have to say that you would like to
said. Jonathan, what about you?
Is it okay if we talk about slime-mould sex?
I think we'll get that the green flag.
So it's probably more arcane than anything in a Julie Hooper novel, and I'll be brief.
Do you need you do, do you?
No, fungi are the worst.
One thing at a time.
Jonathan.
So slime molds get in the mood usually when it's dark, and they're starving, but in
submerged conditions.
So what that encourages them to do is that,
I should start by saying there's actually three mating types
in the slime mold I work on.
So that's one more than us.
But it almost doesn't matter which mating type you are.
But when they decide that they're going to mate,
they all come together and form this giant cell.
And then in that process, you get the nuclear fusion,
which characterize any normal mating process.
And then the fused nuclei segregate into little cells on their own.
And then they proceed to eat all the cells around them.
So this would be like this first matrimonally event being eating the whole village.
So it's completely bizarre.
Anyway, after eating the whole village with all that nutrition,
they then form another type of resistant spore called the macrosis,
which then sits around for a few months until conditions are better.
And what about you, Manin?
Well, I think that slime mods are beautiful gateways into some of the,
so many strange ways to be alive.
And there are so many phenomena, and even in animals,
that are reminiscent of some of the things that slime mods can do,
example with flat worms, you can teach flat worms tricks. They can be taught to learn something.
If you cut off their head, they regrow a whole new head, a whole new brain, and they can still
remember tricks that they've been taught with a new head and a new brain. So the question is,
where is the memory in their body then? Moths and butterflies can learn a new food plant as an adult,
so they'll lay their eggs on a new food plant. And with moths and butterflies, caterpillars can be
exposed for the first time to a new food plant and then they completely liquidate their body
and reform into an adult butterfly or moth with wings and they can somehow remember the new
food plant from this earlier stage of their life despite the fact their body's got undergone a massive
liquidation and reconstruction and reformation and so this is a kind of phenomenon I think opens our
eyes a little bit more to the wild weirdness of life and and perhaps dislodges us a little bit
from some of these more top-down views of development,
like Jonathan was talking about earlier,
with this kind of the single blueprint highway to an outcome approach.
There are lots of ways to get where one needs to get in life.
And so Slymold's open up that world for me,
and I think a really helpful reminders of the many ways there are to be alive.
There's another aspect to the weird and wonderful behavior of Amoebe
that we've discussed today,
that is how many aspects cross over with the fungi
and with the algae.
And these are some of the really difficult groups in evolution
that we've had real problems classifying them.
And today there are still arguments being resolved
as we get gene similarity across these different groups.
But I think that almost the difficulty in understanding amoebe
and understanding fungi and understanding algae
and what they are is a really nice way of illustrating
that all of life on earth originates from one.
cell, you know, one point. So life on Earth has evolved from a cell that had a set of properties.
And even though we have convergent evolution in many characteristics across, we see similarities
in many organisms that's not evolutionary preservation of genes, but this continuum of behavior
that we see in the amoeba and across other groups really shows us that similarity.
I guess probably the last thing I would want to say is that because these modes of existence
have occurred so many different times during evolution, they're obviously doing
something right. So what is that? And can we learn from that? I mean...
Do you think they're on the path towards perfection?
That's a bit of a jump. Sorry.
Well, we can roll with that. There's certain things that they do do very well.
One is there's clearly distributed thinking. It's not I'm the leader that you do this.
When they've exhausted their local environment, they form spores and just chill out for a few years
and wait for conditions to improve. You know, there's a limit to how much they can exploit.
That's interesting when thinking about
fungi in what evidence we have of fungi in the past, you see fungal networks which look very,
very similar to modern fungal networks. So the morphological long history of fungi is one of
consistency. It's as if they hit on this way of life very early and haven't needed to do much
to it. But look at the animal, the fossil vessel of animals, and you see a huge variation in form.
There's a total like cocoa efflorescence of biological possibility in different ways of being,
different numbers of teeth and wings
and all sorts of weird and wonderful ways to be.
And so, yeah, I like the idea that they sort of stumbled on this quite early on
and haven't needed to do that much over all of these hundreds of millions of years.
In our lists of the utility of dictaust helium in the lab,
so the uses of amoeba in biomedical science,
we didn't talk about drug development
and understanding how drugs affect our bodies.
So of there many features of Dictuselium that are useful,
having so many components of cells that are the same as ours
mean that if you have a drug and you treat Dictuselium with a drug,
you can sometimes work out the mechanism of action.
So that's been done in bipolar disorder and epilepsy.
And looking at an epilepsy drug like sodium valproate,
one of our colleagues has tried to screen new drugs
that are less toxic using Dictuselium.
So there's a whole area of not using animals for research here.
So if you've got new drugs that target the same pathway that sodium valproate targets,
there's a high chance that they might be just as toxic as that is
and perhaps produce birth defects in the way that that drug can do.
And then if you find anti-epileptic drugs that don't target that pathway in dictustilium,
you've saved yourself a whole load of very, very early biological research, admittedly.
But it can be a really useful first screen.
for the genetics, the molecular biology, the protein biology,
before you start to move higher up.
Have you anything to say about that, Jonathan?
I mean, I'm fascinated by the fact that this thing has influence on these massive diseases,
which you keep reading about very difficult to cure.
We've gone one step forward in Alzheimer's.
We don't quite know where we are with this, that and the other.
And I just wondered how they went about it.
I can give an example, we have quite a devastating condition called acute respiratory distress syndrome.
Now that's caused by, it's an inflammation of your lungs
and this is caused by immune cells being overactive.
So what happens when you, normally, if you've got healthy lungs,
then it's not usually an issue.
But if you have inflammation, your lungs caused by smoke usually or vomit or something like that,
then the first cells that get there are these immune cells called neutrophils.
Now, they're a bit like, imagine suicide bombers, basically.
They go there and they kill, they start acting.
And if there's any bacteria around, they'll eat those bacteria.
but they're also pretty nonspecific,
so they'll start causing a lot of damage to the tissue.
And of course, when you have more damage to the tissue,
you get even more inflammation,
which means even more immune cells,
so then this whole thing just sort of cascades out of control.
So neutrophils on their own,
for example, if you have a cut and you have this sort of little yellow bit of pus,
that's what they are.
It's not usually a problem,
because what happens is that the next generation of,
or the next round of immune cells,
the lymphocytes come in,
and they're much more specific,
so they can mop up the bacteria
without causing tissue damage.
they also send signals out to the neutrophils saying,
go away, go away.
So the whole wound then becomes a much more controlled environment.
Now, one of those signals, it's called APR,
is something that the slime malls use.
So in the capacity they use it is when they're feeding on a nice plate of bacteria,
when the cell number increases so much and the amount of bacteria drops,
they start releasing this chemical,
and it's basically saying disperse, disperse, disperse.
And it's the same molecule, and this molecule was identified in the slime mold
and is now being used in clinical trials for this.
this horrible respiratory condition.
Well, thank you all very much.
That was a cracker.
Thank you all very much.
You really need to drink after that mind-blowing discussion.
Yes.
So what would you like, Melvin, tea or coffee?
I thought you were going to say a whiskey or a...
Jim and tonic would go down there.
I don't know.
And then what would you like?
So you need the food.
They need to reach this.
I'll have you to take.
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