6. ケビン・アーハーンの生化学-タンパク質精製I (6. Kevin Ahern's Biochemistry - Protein Purification I)

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Professor Kevin Ahern: Happy Friday!
[students cheering]
It never fails to elicit a few whoos!
By the end of the term it's going to be like, "uhh."
Now it's still the, "Whoo!"
Big weekend plans?
Studying Biochemistry, this is good.
The heck with Biochemistry, right?
Alright so we're pretty much on target with where we need to be
and I'm very happy with that,
and I'm very happy with the interactions I've had
with many of you so far so it's been very positive for me.
I very much enjoy that.
We're turning our attention now,
as I said last time, to thinking about
using our knowledge of protein structure as a way of
working with proteins.
Biochemists are pretty nerdy people.
And as I probably say further in the term
and probably next term as well,
"Biochemists are also lazy people."
So we like to find easy ways to do things,
and that's one of the things that we work on pretty hard.
You'll hear some of those
later as I talk about some of the techniques.
So we are turning our attention for a couple of lectures
to techniques that we use in Biochemistry
specifically to isolate large,
and in some cases small molecules.
It's mostly relevant for the proteins we've been talking about
but we'll talk about some other things as well.
The number one tool you see biochemists use in a laboratory,
you can't walk into a biochemistry laboratory
without finding a centrifuge.
So a centrifuge is something that is ubiquitous
and it's a tool that allows us to do a sort of gross
separation on the basis of size.
Gross meaning rough, not gross meaning bad.
Having that separation technique is very useful.
So for example, when we're working with proteins,
or molecules, metabolites, or any of these things,
they're coming from out of cells.
And if we want to isolate them from the cells
we have to do something about
separating the various components of the cells,
because separation is a means for isolating,
or what I call purifying, a molecule.
So if we want to purify a molecule
we really need to get that molecule
separate from everything else.
So what we will see in this process
is that there are numerous steps that have to happen
in order for us to be able to do that.
You'll see there are some shortcuts that work fairly well,
other times those shortcuts don't work well,
so there is no one way of isolating molecules.
There's no one way of isolating molecules.
Some molecules take a lot of steps,
some molecules don't take so many steps
and I'm hoping to equate you with some of the steps
in this process.
As I said, centrifugation is a way that we start
because we first of all have to get the material
that is part of the cell.
So the material that we're working with
might be in the cytoplasm of the cell,
the material we work with might be in the nucleus,
it might be in the mitochondrion.
Of course if we are talking about eukaryotic cells.
If we're talking about bacterial cells,
then it's basically in the cytoplasm
or it's in the membranes.
Of course it might be in the membranes
of eukaryotic cells as well,
so we have to have ways of isolating these various components
and centrifugation turns out to be a really, really good way
because these are very large complexes
and the way that we separate them is by what's called
differential centrifugation.
So differential meaning we use different rates of spinning
the centrifuge and those different rates of spinning
will cause different things
to go to the bottom of the tube.
So you can see here a depiction of some of those steps,
we've taken some a bunch of these cells
and the first step of isolating anything
is busting open the cells.
There are numerous ways of busting open the cells.
We can sonicate them, we can in some cases we can use enzymes.
In some cases we might want to use high pressure.
This particular method hears involves mechanical agitation.
It doesn't really matter.
First thing we do is bust open the cells.
We bust open the cells we've got the contents of everything
that's in that cell in that tube we're starting with.
You can see that here.
If we spin that at a low rate,
we will precipitate certain big things.
If we spin at a higher rate,
we'll participate smaller things.
So usually we'll spin it a slow rate at first
to get rid of the cellular debris,
the nuclei things like that,
and then we'll pour off the supernatant,
and take that supernatant, which is the liquid part
and spin it at a higher rate.
So when we do that we will spin out things
like mitochondria, etcetera.
Depending on where our protein or molecules of interest
are in the cell we can isolate
those components relatively efficiently.
Let's assume we have done that,
and now we've got this soup of whatever it is
that contains the molecules we're interested in working with.
One of the very common techniques that we work with,
and particularly it works very well with proteins for example,
and one that you probably did in basic biology or in chemistry
when you did things, was to use a technique called dialysis.
Dialysis is a way of separating small things
from big things and the basis by which it works
is it involves taking your soup,
your soup is the thing that you've taken out of the centrifuge
that contains the material that you're interested in,
and putting it into what's called a dialysis bag.
So we've done that here.
The yellow you see on the screen is the soup that we have.
The dialysis bag has a very useful property
that it is porous to the small molecules
that are contained in the soup
but it's not permeable to the larger ones.
So, for example I might have a soup here that is full of salt,
Salt sodium chloride, potassium chloride,
or something like that small molecules
and I want to get that protein and other things I have in here
separate from those small molecules.
The dialysis is very simple,
the small molecules as I said are permeable,
they'll come out, and the larger molecules are not permeable
and they will remain on the inside.
And in doing this I'm thus able to remove most of the salt
away from the proteins or the other things
that I'm interested in here.
So dialysis turns out to be a very simple
yet useful way of separating big from small.
There are other ways of separating big from small
That don't involve dialysis tubing
and they may involve separation of bigger molecules,
for example, that wouldn't fit through a dialysis tubing.
This technique, called gel filtration,
which is also called molecular exclusion.
Gel filtration equals molecular exclusion.
Involves a very cool trick.
Well as you'll see in these various techniques
that I'm going to show you,
the materials that are doing the separation
are typically used in what are called columns.
The material that does the separation
is actually shown over here on the right,
it's sort of an enlargement of what's in there,
and I'll tell you a little bit more about that.
So let's imagine-first of all let's talk about
what the material is, alright?
So let's say I've got a mixture of proteins
and I've got some proteins in there
that have a molecular weight of about 5,000
which wouldn't fit through a dialysis tube
and I've got other proteins that have a molecular weight of let's say 80,000
which also wouldn't fit through a dialysis tube.
So I can't use dialysis to separate those.
I've got to find some other way
to separate those proteins from each other.
Molecular exclusion or gel filtration
and by the way the word chromatography comes up,
when I say gel filtration chromatography,
all chromatography means is separation.
So gel filtration separation, molecular exclusion separation.
That's what those refer to.
These columns that I have here contain the material
that allows the separation to occur.
So as I said I want to tell you
a little bit about what these materials are.
As you can see on the enlargement
these are little round things.
This is a pretty big enlargement.
It turns out that these materials,
as we use them in the laboratory, are little tiny beads.
Little tiny beads maybe a millimeter or less in diameter.
They're pretty small.
But they have a really cool property.
The cool property that they have
is that they have holes in them,
and the holes are connected to tunnels within them.
And the tunnels go in one place and come out the other place.
So things can travel through these beads.
This technique relies on something very important
and the important thing that it relies on
is the fact that holes and the tunnels all have a fixed size.
They all have a fixed size.
That fixed size is called the exclusion limit.
Exclusion limit.
Why do I tell you that?
And why is that important?
Well, if they all have the same size,
the exclusion is that they're only going to allow
molecules of a certain size to fit into them
and travel through them.
So I gave you an example of 'I've got some proteins
'that have a size of 5,000 in molecular weight
'and some that have a size of 80,000 in molecular weight.'
If I used a set of beads that had an exclusion limit
of let's say 30,000 molecular weight,
what it would mean is that anything that has
a molecular weight of less that 30,000 will fit in there,
and anything that has a molecular weight
of greater than 30,000 will not fit in there.
Everybody got that?
So the exclusion limit determines
which things will fit in there.
Now, what does this mean,
well it turns out to be very simple.
Because if we think about the small guys going in here-
traveling through the column.
What we start with is a mixture of proteins,
we put them on the top of the column,
and then we take buffer and we let buffer flow
so that it's flowing through the column,
it's flowing through the beads,
and we're just simply monitoring
the rate with which the proteins pass through there.
And because one group of proteins is traveling through
the beads and the other group of proteins
is not traveling through the beads,
it means that the ones that are traveling through the beads
are in fact taking a longer distance through the column.
So therefore things that are less than the exclusion limit
will come out last.
Things that are greater than the exclusion limit
will come out first,
because they don't enter the beads at all.
Question?
The beads are in a fixed position, that's correct.
The beads are in a fixed position.
So buffer is flowing through them,
it's flowing through the column,
but for the most part we look at this thing right up here
we can see that the yellow guys which are so big
they don't fit in there are zooming through.
The green ones which are close to the size of the beads
may fit in some cases, not fit in other cases
and they go in the middle.
And then the little guys up here,
that are less than the size of the exclusion limit,
they travel through all kinds of beads.
They take a much longer path going through.
Gel filtration chromatography
allows us to separate proteins on the basis of size.
We'll see other ways of separating proteins
on the basis of size as well.
Yes, question?
Yes her question is will there be more than one protein
in the sample, and that's a very important thing to recognize.
Yes, because if I only had one protein in the sample,
I would already have it purified.
So I've got to have a mixture of proteins
and usually I won't even have two or three like depicted here,
I might have a few hundred.
So this isn't a way of getting a protein pure
but it's one of the steps of getting a protein pure.
Well, not completely, his question was,
I can only separate them into two groups.
I've sort of drawn this so that we can imagine
they are coming off actually in three groups.
So that's basically what you'll see.
You'll see a group that comes through fairly fast,
a group that comes through less fast,
and a group that comes through the slowest.
So roughly three groups.
Is it fairly clear to tell when you're transitioning
from one group to another?
Only if you have colors like these.
[laughing]
So what you do is you will collect a few drops in a tube
then switch to another tube,
switch to another tube, another tube,
and then you'll use other analytical techniques
to tell you what was in that tube.
Good question, good question.
Very good question.
Does the structure of the protein change
as it goes through the beads?
Hopefully not, hopefully not.
But remember that the structure of a protein is very critical,
so your question is very relevant.
If the protein structure changes
as its going through the beads
we might end up with protein that's pure,
or relatively pure but not active.
So that's a consideration sometimes.
And that's why the choice of the buffer
that we use is very, very carefully done.
So that's gel filtration, gel exclusion chromatography.
I want to tell you about another technique that we use
that actually relates to something we've been talking
about in class so far.
This is called ion exchange chromatography.
And you can understand it pretty simply.
But I'll describe it to you.
Ion exchange chromatography also uses little tiny beads.
Just like gel filtration chromatograph except,
the beads that we use here, they do not have any holes in them,
so no holes.
Instead the beads have molecules attached
to the surface of them that have a charge.
So they have molecules on the surface that have a charge.
Now wherever we have a charge we have to have a counter-ion.
You can see this set of beads all has a charge of negative.
When we started out with this bead it wasn't negative.
It had a sodium ion or a potassium ion
that was a counter ion to it
so that it's overall charge was zero, right?
We always have to have a counter ion.
We don't just have these charges
just by themselves when we pour something into a tube.
So we had a counter ion.
We had a sodium or we had a potassium
that was positively charged.
When I apply my mixture of proteins to this.
I'm going to some proteins in there that
some are going to have a positive charge,
some are going to have a negative charge,
and some are going to have a zero charge, right?
Well if I have a positively charged protein,
that positively charged protein can exchange
with the counter ion,
that is it can replace a sodium or a potassium
and then that positively charged protein
is going to stick to the bead.
So the exchange is the critical thing.
If we know what the counter ion is
we know the type of chromatography that we're doing.
So if the counter ion is a positively charged molecule
we are doing cation exchange chromatography.
This shows cation exchange chromatography.
Now you might sit here and think
'well is it possible to have beads with a positive charge
'and then have a negative counter ion
'like chloride or something like that?'
The answer is yes.
And if we had that then we would be doing
anion exchange chromatography.
I think you can pretty well figure out what is going to happen
and it is going to be the difference between these two.
If I'm doing cation exchange chromatography
the molecules that are going to travel the slowest
through here are going to be the positively charged ones.
The ones that are going to travel the fastest through here
are going to be the negatively charged ones.
And the ones that are in the middle are going to be
somewhere in the middle of those charges.
Why doesn't the protein interact
with the charge that it's displacing?
Well, it can to some extent but remember
that it is positively charged and there wouldn't be a reason
for it to interact with a positively charged potassium.
If I were to ask you this question on the exam,
you just made me think of a good exam question for the exam.
So I'll tell you, I'm going to tell you what the question is.
I'm not going to put it on the exam necessarily
but it would be a good exam question,
maybe a future year, right?
So the question is where would you expect
to see the counter ions?
Attached to these guys.
Attached to these guys coming off.
Because they're going to be positively charged,
they're going to find the negatively charged proteins
that are in there and they are going to come off with them.
Make sense?
You want me to ask that question on the exam?
No, I just told you the answer.
[laughing]
Yes, say that again.
Her question was,
"how come the proteins don't interact with the counter ions?"
I said well these proteins aren't going to interact
with the counter ions because they are positively charged
and the counter ions themselves are positively charged.
Where would we expect to see the counter ions?
Attached to the negative proteins
that are coming out down here.
These won't have counter ions,
they are going to stick to the beads,
these guys down here are going to stick to the counter ions.
Maybe I can think of a harder way to ask that question
so we'll have it on the exam.
Okay, yes?
Is there any way to use both kinds
of chromatography in sequence?
In fact it turns out that people do use both
and they'll actually mix these beads together
and they make something known as,
and you have this before, a water filter.
Water filters are really good at pulling out
an awful lot of positively and negatively charged things
and letting everything else pass through.
So yes, very good question.
Okay, so that's what is going on with these guys.
I think you can hopefully understand that fairly well.
Okay, this just shows you the chemical structures
of some of these things,
you don't really need to know them,
I'm just showing them for your own information.
There's the structure of a resin
that would be used for cation chromatography.
This would be used for anion chromatography.
Remember it's named for the counter ion.
So the counter ion is positively charged,
the counter ion here is negatively charged.
Now I'll tell you about a technique,
another kind of chromatography that is very powerful
and it is also very easy to understand.
And whenever you can do this kind of chromatography,
you can usually reduce the number of steps
in your purification process by a long ways.
It's called affinity chromatography.
This technique also uses beads,
but instead of having charges as the basis
or having size as the basis,
these guys rely on the fact that many proteins
bind to other molecules.
So, for example, we're going to talk about proteins
later on in this term that bind to and use ATP.
They bind to and use ATP.
Well let's imagine for a moment we take those beads
That we've been talking about these times
and instead of attaching something else to them
we attach ATP to them.
So we've got a bead that's full of ATPs.
And let's imagine that I take my mixture of proteins
that I get from the cells
and I pour them on top of the column and I let them come out.
What's going to come out first?
Well the things that are going to come out first
are those proteins that don't bind to ATP.
The things that are going to stick to the column,
at least at first, are going to be the proteins
that bind to ATP because they are going
to bind to the ATP on there.
All of a sudden I've just purified
all of the ATP binding proteins in that mixture.
That's really useful.
Now, there might be a bunch of proteins that bind ATP
so I might not have it pure,
but let us say I know of something
that only my protein binds to.
It only binds to Kevin A. Hernium
and we attach Kevin A Hernium to this column,
what's going to happen?
I'm going to purify that one protein
that binds to Kevin A. Hernium.
By the way I don't want to interact with that protein.
You see how powerful a technique this can be?
One step, I got my stuff.
Well some of you are probably sitting here thinking well,
'How do you get it off the column?
'You get it purified when you put it on there.
'How are you going to get it off?'
This is a very important point.
Very important point.
These bindings that we are talking about
are not covalent bindings.
When we talk about something that's not covalently bound,
they are relatively easy to get removed.
Let's imagine here that I have this ATP column,
how would I get my material off?
Well the easiest way to do it would be to add ATP.
The protein because it's not covalently bound
isn't stuck there a hundred percent of the time.
It comes off, it comes on, it comes off, it comes on, right?
If it comes off and now it encounters a free ATP,
instead of coming back to the column,
it's just going to start shooting through.
So I can always wash my proteins off of my column.
By adding the thing that it binds to.
How would I get something off of an anion exchange column?
How would I do that?
What's that?
So an anion exchange column,
what's going to stick to an anion exchange column?
Positive charge is going to stick to-
no actually negative ions are going to bind aren't they?
We name it for the displaced ion.
Which means it's going to be positively charged, right?
So if I add a bunch of positive charges to this
what's going to happen?
I asked you a trick question.
I can't just add positive charges,
I can't just add negative charges,
I have to add both because I can't add just ions, right?
So I'm going to add salt.
It's going to add positive and negative,
my protein going to come shooting off.
So you see something about how powerful these columns are now
for purifying things, yes.
Her question is,
that's actually a very good question,
her question is, could I use the supports
that are stuck on the column,
kind of like I did with the ATP?
And the answer is you could.
Generally, you wouldn't do that because,
A, they'd would be expensive
and, B, they might contaminate your protein
in a way you didn't want to have them on there.
But it's a very good question.
Salt would be much less expensive
and we can always get rid of salt by dialysis.
Make sense?
Okay.
Good, good question.
All right, so we now know about affinity chromatography.
Let's talk about a more advanced technique called HPLC.
How many of you have ever run HPLC?
Probably several of you have, yeah, a few.
So HPLC is a technique for separating molecules
on the basis of their polarity.
Not their charge, but their polarity.
HPLC stands for High Performance Liquid Chromatography.
Some people mistakenly call it
High Pressure Liquid Chromatography and that's wrong.
It does operate at high pressure
and we will see why in a minute.
But it's High Performance Liquid Chromatography.
How does it work?
Well, it turns out that with HPLC it also works in columns,
but instead of having beads about the size of a millimeter,
we have little little itty bitty tinny winny tiny beads
hard to see individually with the eye.
And these get packed into columns
that are typically stainless steel columns
and the reason it is stainless steel
is that they're packed together very very very tight.
That means if we want to get liquid moving through them
we have to put the liquid at very high pressure,
which is why some people call it High Pressure.
In order to move the liquid through the column.
There are two main types of HPLC that I will talk about.
Actually, one that I'm going to talk about,
there are two that exist.
They're called reverse phase and normal phase.
Reverse phase is by far the most common one used
and that's what I'm going to talk about here.
Reverse phase chromatography
uses these little beads,
little tiny beads that are in there
and uses beads that have attached to them,
very non-polar molecules.
We can think of long carbon chains
sticking off of those beads.
Non-polar molecules are on the surface of those beads.
Remember I said this is a technique
that separates on the basis of polarity.
Water is very polar.
Water is not charged,
but it's polar because it has hydrogen bonds,
whereas something like Hexane is not very polar,
no Hydrogen bonds.
If I take my materials
and usually these are smaller molecules that we're using,
we're not always using proteins,
we're using smaller molecules like maybe amino acids.
If I take my mixture of compounds
and I apply it to this column, and I force them through
with this liquid that's going through there,
what I will see is that the molecules that will come off first
are those that are the most polar.
And the molecules that stay on the longest
are those that are the least polar
because they'll interact with those non-polar components.
People use HPLC because it's a very, very reproducible
type of technology.
So here's a mixture of five compounds
that were separated by HPLC,
and we can see in five minutes
the first compound is coming off
and over here at about eleven minutes or twelve minutes,
the fifth compound is coming off.
If I take this mixture of five things
and I run fifteen different runs through the column,
they will all look essentially identical to this
and, more importantly, they will all come off
at exactly the same time that we see them on here.
And the reason that happens is because
there are so many beads in there and they're so tightly packed
that those interactions happen consistently
as they're travelling through the column.
We thought about that gel exclusion chromatography,
we think okay, well, it can go this way,
it can go this way,
there were all different kinds of ways it could go.
In the case of the HPLC, it doesn't have as many variables
in turns of paths that it can take.
So HPLC has the advantage that it's very, very reproducible.
So, I'll repeat that now,
the first things that come off in an HPLC column
are those that are the most polar.
Something coming off at five minutes, number one,
is the most polar molecule that is in that mixture.
Things that are coming off at eleven minutes over here,
number five would be the least polar
and these guys in the middle
will be somewhere in between in terms of polarity.
Yes?
This can be used
to separate a wide variety of small molecules,
including carbohydrates, including lipids and so forth.
Okay, well I'll say it
but we haven't talked about carbohydrates
or lipids and so forth.
Carbohydrates are molecules that tend to be much more polar
than lipids, for example.
So if we were separating here,
number one would have a higher likelihood
of being carbohydrates
than number five would have a higher likelihood
of being lipids than number one.
And we can actually,
the advantage of HPLC is that we can actually separate
usually not, say, carbohydrates from lipids
but we can separate individual lipids
from each other very easily.
In my master's thesis, I worked on vitamin A.
And this technique is so powerful that we could
separate different forms of vitamin A very readily
that were identical chemically,
but they had different -cis and -trans bonds
and those very subtle differences in structure
caused them to have differences in polarity.
This reproducibility of HPLC was really, really powerful
technique for this kind of separation.
That help?
Thank you for the question.
Let's turn our attention to,
I want to talk about Agarose Gel Electrophoresis first
before I talk about Polyacrylamide Gel.
How many people have run an agarose gel?
Okay, good, boy that's good to see so many hands going up.
Agarose gel electrophoresis is one I don't have
a good figure for, but I can tell you about it.
Agarose gels are, I'll show you what a
agarose gel might look like.
Polyacrylamide gels schematically look exactly the same
although agarose gels sometimes can be done horizontally,
as a slab instead of vertically,
although you can also do vertical agarose gels.
What is agarose?
Well, agarose is a polysaccharide
that has many sugar units attached to each other.
So we can imagine it's a polymer,
it's something we actually get from seaweed.
It's a polymer of these guys
and that means we have a long chain of sugars.
Now if it were just a long chain of sugars,
it wouldn't really have the properties that it does,
but these long chains of sugars
are interconnected to each other.
So I have a chain connected to a chain connected to a chain.
Those chains actually make, those crosses
between individual strands, make holes,
they make holes,
and those holes provide a way for things to move through them.
We thought of the holes that we had in the beads,
we're now thinking of holes at a molecular level
that are between strands of polysaccharides.
So these holes act something like a sieve.
Now the holes, I should tell you, are quite large,
they're quite large
and the reason they're quite large
is because the things that are moving through them
are also quite large.
We use agarose gels to separate molecules of nucleic acid,
DNA or RNA and in case you don't know this
this largest molecules in the cell,
by a long ways, are DNA and RNA,
DNA being the larger of the two.
If you take all the DNA in your cell, in one cell of your body
and you stretch it end to end, seven feet of DNA.
That's how long each DNA molecule is inside of your cells.
You have enough DNA in your entire body
if you stretched it all end to end,
you can go to the sun and back.
180,000,000 miles of DNA.
And now you know why you're tired on Monday morning.
Right, I've got to wake all that DNA up.
So, we're talking about big stuff.
Now typically we're not separating things
that are quite that large,
we're separating DNA fragments that are smaller than that
but nonetheless, DNA fragments are pretty large,
so we have to have holes that they can pass through.
If we block them from passing through
then we're not going to ever get them off
our gel that we're running.
All right, so I make a gel, I make this gel that's got this-
and now this gel material which we call it a gel
because it's kind of like Jello,
it has sort of a liquidy consistency.
We set it up so that we have buffer, and we have buffer
and we put our DNA molecules that we want to separate
right there in what's called a well.
Then we close this all up and we apply
an electrical current to it,
and when we apply an electrical current to it,
we make it so that the negative is at the top
and the positive is at the bottom.
I'll tell you why in a second.
What's going to happen is electricity is going to flow,
and it's going to move from top to bottom, making a circuit.
The reason we put minus at the top
is DNA is full of phosphates,
there's a phosphate between every nucleotide
and phosphate is negatively charged.
DNA is a polymer of negative charge.
DNA forms nice rod-like, regular structures
and the longer the DNA molecule is that we have,
the more positive charges we have.
The length is proportional to the positive charge.
The length is proportional to the positive charge.
That becomes important.
The reason it's important is
something that has more charges will have more force,
but the force it will have divided by its size is equal.
Larger molecules have more force,
that is more negative charges,
but the number of charges they have per length is the same.
If I have something that has
a DNA molecule with three nucleotides
it has two negative charges, two phosphates between them.
If I have something that has six, it has five.
If I have something that has ten, it has nine.
It gets longer, I add more negative charges.
The length is proportional to the number of negative charges.
And what does mean?
Well it means that if I apply a negative charge
at the top of this guy,
that the force that's acting on each molecule
divided by its size is the same.
The force divided by the size of each molecule is the same.
Okay, I see people nodding their heads, good.
I see other people looking a little more quizzical.
Since the size is proportional
to the number of negative charges
and the force that's acting on those negative charges
the force divided by the size the molecule, is the same.
Whether it's a large molecule or a small molecule.
So if the force is all the same,
what's the basis of separation?
This becomes the easy part.
If the forces are all the same the thing that moves
the molecules is how fast they can travel
through those pores.
Small guys can travel faster,
large guys have a harder time getting through,
they travel slower.
Small versus large.
So in agarose electrophoresis,
the smallest molecules are the fastest moving,
the larger molecules are the slowest moving.
This technique is really powerful
because I can separate something that has,
oh let's say, 500 nucleotides from something
that has 600 nucleotides reasonably good,
I can do that separation.
And agarose gel electrophoresis allows me to do that.
Well if you understand agarose gel electrophoresis,
you're going to understand
polyacrylamide gel electrophoresis as well.
There are only a couple of considerations for that.
Polyacrylamide gel electrophoresis uses a polymer
of a monomer called acrylamide.
It makes the gel that you actually see right here,
and, like I said, agarose gels look very similar.
The primary difference for our purposes is that
polyacrylamide also makes a mesh
and leaves holes for things to travel.
The difference is the holes are much smaller.
The holes are much smaller than they are
in agarose gel electrophoresis.
Why do we make them with smaller holes?
Primarily because we use polyacrylamide gel to separate proteins,
and proteins are much smaller than DNAs.
Proteins are much smaller than DNAs.
If we don't make the pore size small enough,
we're not going to have a difference between
large and small making its way through.
Well there's another consideration for those of you
who hopefully are thinking about this,
and the other consideration that we have
is that proteins don't have a uniform negative charge, right?
Some of them are going to be positively charged.
Some of them are going to be negatively charged.
Some of them are going to be uncharged.
And if I put them into this mixture
just like I talked about before,
and I put minus at the top and I put plus at the bottom,
and I put my proteins right here, when I turn on the current,
the positively charged proteins
are going to jump right up here and stay on the top,
and the negative ones are going to move,
and the zeros are going to sit there and go,
'I don't know what to do.
'We're not going to separate things, guys, that's not good.'
Moreover we don't have the same phenomena
that we did before where we had the size
that was proportional to the number of negative charges.
That was the key to agaroses.
For DNA, the size was proportional to the number of charges.
So in doing separations
of proteins on polyacrylamide gel electrophoresis-
By the way, polyacrylamide gel electrophoresis
people call PAGE, P-A-G-E.
Any abbreviation I use in this class you can use also.
P-A-G-E.
If I want to separate proteins
by polyacrylamide gel electrophoresis,
I have to use a very cool trick.
I'm going to describe that trick to you.
I have to make the proteins have the same property as DNA had.
DNA's property was
the longer it was the more negative charges it had.
Remember, DNA's a rod, it's elongated.
Most proteins, I said, are what form?
Globular, they're not elongated, right?
So how am I going to make this elongated,
and how am I going to make this have a negative charge
that makes it more negative the longer it is?
This is the cool trick.
You add a substance called sodium dodecyl sulfate,
and no you don't need to know that.
You do need to know its acronym, S-D-S.
SDS is a detergent.
It is a detergent that,
when it is mixed with proteins, does two things.
One, it denatures the protein.
I told you last time why soaps and detergents denature proteins.
How is it doing that?
Disrupting hydrogen bonds, no.
Hydrophobic bonds, it's disrupting the hydrophobic bonds,
and when it does that it converts it from being globular
to stretching out.
We've made a rod.
Now the second part is a little harder to understand
but it turns out to be true,
and that is the SDS is abundant
and so it coats this rod with SDS.
It coats it and it coats it so well
that longer proteins get more SDS
and shorter proteins get less SDS.
So the amount of SDS that a protein has
is a function of its length.
And guess what?
SDS is negatively charged.
So now I've converted globular proteins
into something that's much more like DNA.
It's rod-shaped and the amount of negative charge it has
is proportional to the length of that rod.
Pretty cool.
So what I've just described to you is what's called SDS-PAGE.
SDS applied to these proteins
and then probably polyacrylamide gel electrophoresis.
Yeah, question?
Is the SDS readily removable
from the proteins at the end of the process?
Very good question, yes and no.
Do you suppose the proteins
at the end of this process would be active?
Probably not.
So this technique is usually used as an analytical technique.
Remember I said we had those little tubes
that came down from the gel exclusion,
and I said we use other analytical techniques
to see what was in them.
We would take a little bit from each of those tubes
and we would put it on each well,
and we would say which thing is coming out here,
which thing is coming out here,
which thing is coming out here?
So this would tell me very readily
which protein is coming out where
because I would see different sizes on that column.
Yeah, question?
SDS denatures the protein,
that's the key to how it works, yes.
Well, you wouldn't use SDS to purify it.
I mean, you wouldn't use the SDS-PAGE to purify it.
You would use SDS-PAGE to analyze it,
but it's not going to be a purification, okay,?
Good question though.
Yes?
I'm sorry, say it again?
What about it?
[inaudible] concentration
of the detergent?
To be honest with you,
I don't know the answer to that question,
but, suffice it to say, you would want to have an excess of SDS
in the solution so that you have plenty to coat the proteins.
So maybe that answers your question.
Yes?
Say it again?
For every two amino acids
you need one SDS.
So that coating is happening on a regular repeating basis.
That's correct.
Yes?
Okay her question is,
basically if you have two proteins of similar length,
how good is this process at separating those?
The answer is, pretty darn good.
You can separate things with a fairly small
distinction in molecular weight.
Yes?
Agarose is a more liquid thing,
but you can do it either way.
What do you guys say we finish with a song?
We've been talking about Henderson-Hasselbach.
Let us do some Henderson-Hasselbach
to the tune of "My Country 'Tis of Thee."
[singing]
Henderson Hasselbach
you put my brain in shock.
Oh woe is me.
The pKa's can make me lie in bed awake.
They give me really bad headaches.
Oh hear my plea.
Salt-acid Ratios
help keep the pH froze
by buffering.
They show tenacity,
complete audacity,
if used within capacity to maintain things.
I know when H's fly
a buffer will defy
them actively.
Those protons cannot waltz
when they get bound to salts.
With this the change of pH halts.
All praise to thee.
Thus now that I've addressed
this topic for the test
I've got know-how.
The pH I can say
equals the pKA
in sum with log of S or A.
I know it now!
[END]