- [Voiceover] Organisms
that reproduce sexually
have got to get their
genes together somehow.
To do this, they package
their genetic material
into specialized cells called sex cells.
This is the sperm cell.
It's the sex cell of the male.
The sole purpose of the sperm,
the entire reason for its existence,
is to transfer the male's genetic material
into the female sex cell or the egg.
So the sperm cell is packed with features
that allow it to fulfill its job.
It's basically a little torpedo.
You can see, just like a torpedo,
it has a pointed head which allows it
to travel in the forward direction.
At the back end it has the tail,
and the tail is just a flagellum,
and as the flagellum spins it
acts like a little propeller.
And then it has a middle section.
Now within that middle section,
wrapped around the base
of the flagellar tail,
are all of these little
organelles called mitochondria.
You can see I'm drawing these mitochondria
wrapped around the flagellar base here.
And mitochondria are organelles
that are responsible for
giving energy to a cell.
And the sperm cell has
a whole bunch packed
right into the base of the flagellum here.
Probably 75 to 100, and they're
quite large mitochondria.
In fact, these mitochondria
are often fused together
to create big organelles.
And the reason is because
in order to propel
the sperm torpedo towards the egg,
it needs a lot of energy.
And that all comes from
these mitochondria.
Now the payload of the
torpedo is here in the head,
and that's the genetic material,
our DNA within the nucleus.
I'll draw it kind of all coiled back here.
And here's the nuclear envelope here.
And just like any regular torpedo,
the sperm torpedo has a
warhead right in the front.
And that warhead is a
little collection of enzymes
called the acrosome.
And the acrosome is gonna be important
later on for fertilization.
But that's pretty much it.
There's a tail at the back
to provide propulsion,
some mitochondria in the middle section
to give energy to the tail,
a head which contains
the nuclear material,
and the acrosome.
This is a pretty bare bones cell.
It's designed to move fast
and to get to the egg.
There are no bells and whistles here.
Now that's in contrast to the egg cell.
Now the first thing you'll notice
is that the egg cell is round,
unlike the torpedo
shape of the sperm cell.
This is not a cell that's
made for active mobility.
The second thing is that
the egg cell is huge
compared to the sperm cell.
It's so big, in fact,
that it's almost visible.
In fact, sometimes it is
visible to the human eye.
Now compared to the sperm
cell, which I'll draw in here,
the egg cell is about
10,000 times more massive.
And similar to the sperm cell,
the egg cell has its
share of genetic material
ready to combine during fertilization.
You can see it here within the nucleus.
And so you may have noticed this
thick outer coating on the egg cell here,
that's a very important structure
called the zona pellucida.
And the zona pellucida is a
thick layer of glycoproteins
that sit on the outside of the egg.
And glycoproteins are basically a protein,
I'll draw a protein here in green,
with a whole bunch of
branching sugar chains
that are coming off of them.
And so what this looks like
is basically a little tree
or a long branching
thing that's growing out
of the edge of the egg cell.
And there's a whole bunch of them,
and they form this very thick
kind of protective layer
that the sperm has to get through.
And the edge of the egg cell
is the actual plasma membrane.
And once the sperm can deliver
its genetic material beyond that,
fertilization has occurred.
Now there's a whole
bunch of other structures
within the egg cytoplasm as well.
And remember this thing is huge.
And I'm gonna draw in a few here in green.
Now what I'm drawing in are
actually more mitochondria.
Now remember the egg cell had
75 to 100 big mitochondria
right at the base of the flagellum
to provide energy to drive locomotion.
Well, the egg cell has mitochondria too.
It's got a lot of other
different organelles as well.
But the egg cell is so large, it's got
somewhere between 100 and 200
thousand mitochondria present.
So keep those mitochondria
in mind, we'll talk
about them a little bit
later in the next section.
So now that you've met the
two major players here,
the sperm and the egg,
or the male and female
sex cells respectively, we can talk
about what happens when they meet.
And that process is called fertilization.
So we'll go ahead and
label our egg down here.
And we'll put a quick
label on this as well.
This is the zona pellucida
that we talked about earlier.
So we'll draw the sperm here
coming in to meet the egg.
We'll draw its tail.
We'll draw its middle section here.
And we'll draw its torpedo-like head here.
Get rid of all this zona pellucida
glycoprotein in the middle here.
Now here are the mitochondria
in the middle section here,
and we have the genetic material payload
of our sperm torpedo here in the back,
and our acrosome here in the front.
Now the first thing that
happens during fertilization
is that the sperm comes into contact
with the zona pellucida.
And the zona pellucida actually binds
to the outside of the sperm,
and that's called sperm binding.
And it's step number one.
Now what happens when the sperm gets bound
to the zona pellucida is
that that sets up a reaction
called the acrosomal reaction.
So step number two is called
the acrosome reaction.
And that little warhead
tip of the sperm torpedo
gets released, and so we have
all of the acrosomal enzymes
that were sitting in the head
that just kind of leak out
into that zona pellucida.
And as those enzymes leak
out, they actually start
to digest away the zona pellucida.
Here you can see I'm kind of eating away
here at those glycoprotein,
and that allows the sperm
head to dive in deeper
towards our plasma membrane.
Now as the sperm gets closer
to the plasma membrane
of the egg, and it comes
in contact right here,
it starts up a process of binding.
The two touch and they come together.
And as they start together,
it causes another reaction,
and that third reaction is
called cortical reaction.
And what I haven't drawn here
is another structure in the egg,
and those structures are right
underneath the plasma membrane,
and they just sit there waiting.
And they wait and their entire job
is to wait for a sperm to bind.
And as soon as a single sperm binds,
they get ejected out into
that zone pellucida as well.
Just like the acrosomal enzymes,
these enzymes that are contained
within the cortical granules also start
eating away at the zona pellucida.
These enzymes eat away, and
they dissolve and chew up
these glycoproteins, but
specifically they chew up
the glycoprotein that
allows sperm to bind.
So at this point we have a
single sperm that's bound,
set off the cortical reaction,
and these cortical granules are released
that chew up all the other places
that more sperm can bind.
So as our other sperm
torpedoes are coming in,
they're just bouncing off.
They hit the glycoproteins,
but the one that they need
to bind to isn't there because
it's all been chewed up
and degraded by these cortical granules.
So that's actually called
a block to polyspermy.
Now that's a very important concept.
Polyspermy is a term that
just means multiple sperm.
And what we don't want is
for more than one sperm
to inject its nuclear material,
its DNA into this egg.
What you'd end up with is an egg
with a single contribution from mom
and then one or two or
three or 100 contributions
or genetic material from dad.
And that would never
work, you'd end up with
all sorts of problems as
the egg started to divide.
Occasionally, that does happen,
and it can result in a zygote that fails.
But for the most part, as
these cortical granules
dissolve away all the
sperm binding glycoproteins
of the zona pellucida, other
sperm just can't get in
and they bounce off as they arrive.
So now we have a sperm that's made its way
all the way to the plasma
membrane of our egg cell.
It's started to bind
to the plasma membrane,
the acrosome is gone,
I'll erase that here.
It's done its job.
The cortical granules have been released,
and they're preventing
other sperm from getting in.
And we start to actually
fuse our plasma membranes
of our sperm cell and our egg cell.
And that allows for this
entire structure to come in.
All of the genetic
material here within the,
all of the genetic
material within the nucleus
of the sperm cell can start to come out
and get released here into the egg.
And once we have fusion
of genetic material,
that is fertilization.
So just to recap, we'll go back to look
at our close-up of our sperm.
We can see that it's a
very mobile structure
evolved basically to get genetic material
from the male to the female egg cell.
It's got a tail that propulses it,
it's got mitochondria that feed it energy,
it's got a head with a
payload of nuclear material
and an acrosome warhead on the tip.
The egg cell is a giant
cell by comparison.
It's got a specialized
layer of glycoproteins
on the outside that have a
bunch of specialized features
and then a bunch of cytoplasm,
including mitochondria.
And then the process of
egg meeting sperm itself
is called fertilization.
Sperm binds to the zona
pellucida, the glycoproteins,
you have an acrosomal reaction,
and then a cortical reaction prevents
more than one sperm getting in.
And then material, the genetic material
of the sperm is transferred.
Now you'll notice here that I drew
the genetic material from
the nucleus coming in.
Now some of you may be wondering,
"Well don't mitochondria have
genetic material as well?"
Well, that's true. Mitochondria
do have mitochondrial DNA.
And potentially, some
of these mitochondria
can get sucked in during that
genetic transfer process as well.
But remember, our egg cell had
100 to 200 thousand mitochondrial copies,
and our sperm cell only had 75 to 100.
Now there's a little bit of debate,
but in the end the male contributes
essentially no mitochondria to the zygote
that's formed after
the egg and sperm fuse.
Now, it could be that
some of those mitochondria
actually do make their way
in and then are degraded.
We're not really sure.
But given just the numbers,
statistically with one
to two hundred thousand
versus only 75 to 100, nearly
all of the genetic material
from the mitochondria is gonna
be from the mother anyway.