Instant Genius - Cells - Everything you ever wanted to know about... the biology of life with Sir Paul Nurse
Episode Date: November 23, 2020For this instalment in the Everything you ever wanted to know about... series, we’ve sourced questions from Google, our listeners and the Science Focus team to put to experts and help you understan...d key ideas in science, in short episodes. This week, we're joined by geneticist Sir Paul Nurse, the Director of the Francis Crick Institute in London and one of the recipients of the 2001 Nobel Prize in Physiology or Medicine, which he shared with Leland Hartwell and Timothy Hunt. Paul has recently published a book that helps readers understand biology, called What is Life? (£9.99, David Fickling Books). He shared some of the concepts from the books with us over two quick-fire episodes. Hosted on Acast. See acast.com/privacy for more information. Learn more about your ad choices. Visit podcastchoices.com/adchoices
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Hello and welcome to everything you wanted to know about podcast from the team behind BBC Science Focus magazine.
I'm Amy Barrett, editorial assistant at BBC Science Focus.
For this series, we've sourced questions from Google, our listeners and the science focus team to put to experts and help you understand key ideas in science in short 30 minute episodes.
Today, I'm joined by geneticists of Paul Nurse, the director of the Francis Crick Institute in London and one of the recipients.
of the 2001 Nobel Prize in Physiology or Medicine, which he shared with Leland Hartwell and Timothy Hunt.
Paul has recently published a book that helps readers understand biology called What is Life?
He's going to share some of the concepts from the book with us today.
So, Paul, let's start straight in with the big question. What is biology?
Well, my book, and it does tackle biology, so it is relevant to your question,
is really exploring how do we define life?
What is life?
And really, that's the central subject of biology.
And what I wanted to do here was to try and identify principles
by which one could understand what is different
between something that's living and something that's not living.
And this is something that perhaps biologists don't think quite enough about.
You know, physicists are always having grand ideas.
and they have lots of books and so on about grand ideas.
We biologists tend to be a little bit more mundane in some ways.
We like to describe things, you know, like how many species there are in a habitat
or how many hairs there might be on a beetle's leg or I'm a molecular biologist, so I sequence genes.
And so this is a lot of details, and that's what we tend to sort of gravitate towards.
But actually, there are some really grand ideas in biology, which I describe, at least some of them,
and they can lead to principles to understanding how life works.
So it's a rather short book and it's aimed at just the ordinary lay reader
to try and deal with those topics.
So for someone who perhaps hasn't encountered biology for a long time,
what key aspects do they need to know about to feel like they've got a grip on what life is?
Well, what I do in the book is describe five of what I call the great idea.
of biology. And they are the cell, which is the basic unit of life. We're all made of cells.
And in fact, there's some living things which are only one cell. So that's a very important idea.
A second one is the gene, which is the basis of heredity. That is why when we had different generations,
we look a bit like our mother and father and a plant looks like the plants that got together to make that plant.
and that is heredity, and the basis of that is genes.
So I talk about genes as the basis of heredity.
Then probably the greatest idea in biology,
which is that evolution by natural selection,
Charles Darwin's great idea,
because that leads to the living things having purpose.
It's a very clever idea.
They have purpose.
You know, they grow, they maintain themselves,
they reproduce themselves.
And based on, in fact, the cell and the gene,
you can, through natural selection,
living organisms can acquire that purpose.
And how do they do it?
Well, that's the two next ideas.
They do it because they are chemical machines,
fantastically sophisticated chemical machines,
which is the basis of their growth
and how they can copy themselves and so on.
And it's all connected together
because they are also informational machines.
So all the different bits of the chemistry
talk to other bits of the chemistry.
And that leads to them behaving as a whole.
That is a whole organism.
They have the five ideas,
and then I generate principles from that
to try and say what I think life is.
So it seems like the cell is very fundamental
in our understanding of,
of what life is. Can you tell me what are cells?
Well, cells are the basic unit of life, in two meanings of the word unit of life.
They're the basic structural unit, by which I mean every living thing that we know on this
planet is built of cells. And we have about, I think, three trillion cells.
If I've got that number wrong, all you have to remember is it's a lot of them.
and it's a basic structural unit.
But it's also more than that,
it's also the basic functional unit.
Now, what do I mean by that?
What I mean is that it functions as life.
It has the properties of life.
There's some living things.
I'm a researcher, and I work on yeast,
which is only made of a single cell.
And so all the characteristics of life
are seen there in that single single,
cell. Others, like our cells, for example, are made up, as I've said, of a large number of
cells. But one thing, if you're not interested, Amy, in cells with what I've said,
always remember that you were once a single cell. When you were, at the very conception,
when the sperm from your father entered the egg of your mother, you were a single cell.
And so there's very good reasons for you to be interested and everybody else to be interested in cells.
And how big or how small can cells be?
Well, they can be very small.
If we take bacteria, for example, which are one of the smallest forms of life,
they are only one or two micrometers long.
A micrometer is a millionth of a meter.
So that's absolutely tiny.
If we take my yeast cell that I study, it's 10 micrometers, so it's still very, very tiny.
But some cells can be really quite big.
If you take a hen's egg and when you look at the yolk in there, that is a single cell, which then will undergo.
Really?
Absolutely.
And it will undergo repeated divisions and eventually make a little chicken.
But that's a single cell and that's very large.
or if we take one of your nerve cells that can spread from, that can extend from your spine right down your leg, that could be half a meter or even a meter long.
So cells vary in size over a thousandfold or more.
So they are amazingly diverse.
And you've mentioned that cells can divide.
How do they do that?
Well, that's critical because if you have a cell, it can maintain itself.
and it can grow.
But the critical thing for life is that after it's grown for a while,
it can divide into two and produce two new cells.
And those two new cells behave in just like the original single cell.
And that's because they contain all the genes that they inherited from the mother cell.
So you have a mother cell, two daughter cells,
and there's lots of – they contain the similar,
of genes that you have there.
And so it is actually central to life that you can reproduce,
because if you can't reproduce, you don't go anywhere, really.
I mean, and so it's absolutely core for life.
How does it occur?
Well, it occurs through a process that actually I study.
It's called the cell cycle.
And what it means is it's the cycle by which cells reproduce them.
cells. And critical for that is back to genes again are two processes. One process where you copy
all the genes. So instead of having one copy, you have two. And then towards the end of the cell cycle,
those two copies are separated into the newly divided cells. And every cell cycle, every reproductive
cycle has to have those two processes working. And I've spent almost my entire life trying to understand
what controls those processes and why they occur in such a regular way.
So how doesn't cell know when it's time to divide?
You know, that's a really good question.
And 40 years on, I'm still not quite sure of the answer, to be quite honest.
And I'm just hoping I'll have a few more years left so that I can actually crack it.
I know roughly what it is important.
For most cells, and it's actually, you can state the problem rather simply, cells grow to a certain size, double the size of the original cell often.
And then they divide.
So somehow the cell knows how big it is.
It measures how big it is.
This is sort of acting as a whole.
I mentioned that a bit earlier.
It's acting as a whole.
It knows how big it is, and it says to itself, if it could speak,
now it's time to divide, and it goes through the process of division and all the genes that have
been copied earlier segregate, separate into the two newly divided cells. So the question you ask
mostly reduces to how do cells know how big they are. And that's something I'm really
interested in, I have to say, and I don't know quite the answer. I've got some ideas. But what that
information, when you get that information, how big you are, you then have to activate the chemistry
that leads to the reproductive process. And that works through a key molecule. I'm not going to talk
too much about molecules because it gets a bit complicated, but it's a key molecule. And I do want to
mention this one called cyclin-dependent kinase. It's an enzyme. And that enzyme triggers all the
events that are needed for the cell to reproduce itself. And my lab discovered it, together with one or
two other labs. So we discovered it quite a few years ago. I discovered it in yeast and then showed that
exactly the same process and the same enzyme works in human beings and everything in between
yeast and human beings. So that was my eureka moment. I got very excited about that. And the way we
showed that was a rather, it's an experiment that everybody said just couldn't possibly work.
I took a yeast cell, which is defective in the gene that makes this enzyme.
It's a gene we call CDC2, but you don't have to remember that.
CDC2.
And what we did is we sprinkled human genes on the yeast cells.
I mean, it wasn't quite like that, but that's sort of essentially what happens,
sprinkled them on the cells.
And the theory was this. If humans had DNA that encoded the same gene, or same type of gene, I should say, then if a yeast cell took it up, it could rescue a defective yeast gene, if you see what I mean.
So I used a yeast strain that is defective in this gene, and it couldn't divide at high temperature. It divides well at low temperature, but not at high temperature.
and simply what we did, and when I mean we, it was Melanie Lee,
who was a collaborator of mine in the lab, who did most of the experiments,
and what she did, sprinkled the genes onto this defective strain that couldn't divide,
and looked for a human gene that would make it divide.
And we found it.
I mean, nobody believed that could possibly work,
because you imagine yeast and humans diverged in evolutionary terms
1.5 billion years ago.
That's 1,500 million years ago.
And it's amazing.
What it means is that we could take,
despite that immense amount of time,
it still works.
It still works.
And that's why we could conclude
that everything we see,
living thing that we can see,
like fungi or plants or animals,
turn out to have the same control
that was discovered by that experiment.
That's amazing.
And so that enzyme itself must have been quite fundamental
in the early stages of life on Earth.
Well, it is fundamental for most of life that we can see.
It is different in very simple forms of life, bacteria, for example.
They don't have that enzyme.
So it was somehow, I'll say invented.
It wasn't invented, but it came about.
sometime between 1.5 billion years ago and 2 billion years ago.
But life on this planet's been going for about 3.5 billion years.
So for the first couple of billion years, it didn't work in bacteria like this.
But once it was invented 1.5, 2 billion years ago,
it inhabited all the living things we can see except bacteria.
That's amazing.
And you've mentioned the word gene quite a bit.
Can you just tell me what is a gene?
Yes, I should have done that. So the gene is my second idea in the book, actually. And the genes are the basis of heredity. They are the key for inheritance. So I can't see what colour eyes you have, but they will be controlled by genes. I have blue eyes and there will be a certain combination of genes that give blue eyes. So many of the characteristics that we have,
than every living thing has, are determined by genes, interacting with the environment as well.
I mean, affected by what you eat and how you live and all those sorts of things.
But genes are absolutely crucial.
Now, what are they made of?
Well, this was a very important discovery.
They're made of a chemical.
The chemical's DNA.
That's an acronym for deoxyribonucleic acid, but let's just call it DNA.
because it's much easier to say. And this was discovered in the 1940s, 1944, 45. It's discovered in a research
institute I used to work in. I used to be president of it in New York, but not in 1945,
it must be said, much much later. And that was shown by the researcher working there, a collection
of researchers there, that DNA was the basis of genes. How did they do that? A little bit,
they used a sort of similar thinking to how I just described finding the CDC2 gene. What they did
is they took a bacteria that was harmless, it didn't cause disease. And they took a similar
bacteria which did cause the disease, and they extracted different chemicals from,
the one that did cause disease, and again sort of sprinkled it on to the cells, a little bit
like we did 50 years later. And they found that if they sprinkled DNA onto the cells that
weren't virulent that didn't cause disease, then they could transform them into cells that did
cause the disease. So they came to the conclusion that DNA must be the basis of heredity. And that
That was in the mid-1940s.
And then the second experiment, which most people are more familiar with,
is the one that was done in England, actually.
And that was based on the structure of DNA.
And that's based on experiments done by Rosalind Franklin
and Morris Wilkins in London,
who looked at the structure of DNA.
and it was interpreted in Cambridge by Jim Watson and Francis Crick.
And that led to the very famous double helix structure, which is the basis of DNA.
And what a double helic structure means is this.
It's like a ladder, which is twisted.
So it's a twisted ladder.
And the sides of the ladder are connected by the rungs of the ladder.
And the sides are made up of four chemical.
bases, and they have names, I'm going to just give the letters, so we don't have to remember them,
A, G, C, and T.
And what's clever about these chemicals is that if you have A on one side of the ladder,
that can only connect to a T on the other side of the letter through the rungs.
So you have A connected to T and you have G connected to C.
And what this means is that if you now break the rungs and pull those ladders apart,
you'll have AGCT, for example, down one side,
and A will connect with T and so on on the other side,
so you can make a precise copy of the original DNA molecule.
Isn't that a clever idea?
So the combination of knowing it was DNA was important,
and then getting the structure really revealed
the basis of heredity in the gene. So that's why it's such an important idea.
And so the DNA of every living thing only has those AG, C, and T?
Absolutely right. Every living thing. And that includes bacteria, even though they are more
primitive, so it's even older. And it's likely that that was emerged very soon after
after life appeared on the planet.
And we are talking three and a half billion years ago when life first, it can be.
Well, what we say is we can see what looked like fossils, fossil bacteria, which are three
and a half billion years old.
Wow.
Containing DNA.
Yeah.
Well, we don't know if they contain DNA.
So we do guess at that.
But since every living thing on the planet we do know of contains DNA, we're making the
assumption that one did as well.
And so genes that we have, do we all have the same number of genes?
We, that is all human beings, have very similar numbers.
And it's 22,000 that we have.
The genome, human genome was sequenced nearly 20 years ago now, actually.
It's still not absolutely complete.
But we know a lot more about it than we did 20 years ago.
and there's 22,000.
Now, my lab organized the sequencing back to my yeast,
the yeast I worked on a bit before the human genome was sequenced,
so it's a bit older.
It's much easier to do yeast than humans.
So we got it completely done over 20 years ago,
and we showed it only has 5,000 genes.
So we have 22,000, yeast has.
5,000. But some organisms have many more genes than we do. Some plants have 50,000 genes.
There's probably even more. So having a large number of genes doesn't mean you're intelligent.
It just means you have the ability maybe to be intelligent. And so different living things have
a wide range of different numbers of genes. That's it for us today. In the next episode,
Paul and I will pick up where we left off to continue talking genes and DNA.
He will reveal how these are key to understanding the evolution of life on Earth
and even explore some of the possibilities for life outside our planet.
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For more easy to understand explanations of key scientific concepts,
visit sciencefocus.com or pick up the latest issue of BBC Science Focus magazine.
Thank you for listening to the Science Focus podcast from the BBC Science Focus magazine team.
with the UK's best-selling science and technology monthly, available in print and in several digital formats
throughout the world. Find out more at sciencefocus.com or look out for us in your app store.
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