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PROFESSOR: I wanted to say a
few things about the end of,

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00:00:29,650 --> 00:00:32,180
what was meant to be
the end of class six.

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It was chapter
seven in the book.

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It was meant to be an
overview of the forebrain.

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00:00:46,760 --> 00:00:51,820
And at the end
here I was talking

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about the-- we got
through the limbic system,

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00:00:56,950 --> 00:01:00,420
and then I wanted to say a
little bit about the neocortex.

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00:01:00,420 --> 00:01:07,385
So this picture here, this
gives a little outline

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00:01:07,385 --> 00:01:09,475
meant to show the
addition of neocortex.

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00:01:12,020 --> 00:01:14,610
Here is a slide
where I'm showing

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that the limbic system
is, one way to define

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it is by connections
to the hypothalamus.

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But now when we get
to the neocortex,

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the first topic that we
always think of neocortex

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is as so important in learning.

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00:01:29,440 --> 00:01:33,780
And I want to point out that
it was in the early olfactory

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system, long before
there was any neocortex,

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00:01:37,900 --> 00:01:43,260
there evolved these
two types of learning,

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00:01:43,260 --> 00:01:47,380
that have remained the two
major types of learning, that

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00:01:47,380 --> 00:01:56,030
do involve neocortex in mammals,
including the human beings.

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00:01:56,030 --> 00:01:57,829
Two different kinds of learning.

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00:01:57,829 --> 00:01:59,370
So what are these
two different kinds

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00:01:59,370 --> 00:02:02,420
of learning I'm talking about?

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00:02:02,420 --> 00:02:04,910
You can think of them in
terms of the structures that

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00:02:04,910 --> 00:02:07,610
are involved, or
you can give a name.

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00:02:07,610 --> 00:02:10,121
The types of learning.

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00:02:10,121 --> 00:02:13,440
You know what I'm talking
about, any of you?

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00:02:16,120 --> 00:02:19,630
Remember I talked about the
early evolution of olfaction,

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and how the connections were
with this ventral-most part

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00:02:23,710 --> 00:02:26,060
of the striatum,
the corpus striatum.

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00:02:26,060 --> 00:02:29,055
And I said that the important
thing about those connections

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00:02:29,055 --> 00:02:32,220
was that they were
plastic, they could change.

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00:02:32,220 --> 00:02:41,145
That's how animals learn
to like certain smells

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and not like others.

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00:02:42,310 --> 00:02:46,880
They identify objects that way.

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00:02:46,880 --> 00:02:49,440
But they did another thing, too.

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00:02:49,440 --> 00:02:53,602
Different regions they
went to smelled different.

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00:02:53,602 --> 00:02:56,550
So without any vision,
there were two kinds

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00:02:56,550 --> 00:02:59,000
of learning that were possible.

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00:02:59,000 --> 00:03:02,980
Places that were good or bad for
them, according to the feedback

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00:03:02,980 --> 00:03:04,500
they get, and the
objects in those

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00:03:04,500 --> 00:03:08,800
places that could be good
or bad to eat, for example.

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00:03:08,800 --> 00:03:10,780
They also, of course,
could smell predators.

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00:03:10,780 --> 00:03:12,490
And that's still
true in many mammals.

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00:03:16,650 --> 00:03:18,860
So this is the way
I summarized it.

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Learned object preferences
with identification of objects

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00:03:24,770 --> 00:03:27,150
according to whether
they're good or bad.

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00:03:27,150 --> 00:03:29,410
And place learning,
identification memory

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of good places and bad places.

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00:03:32,760 --> 00:03:36,120
The first one is
striatal dependent.

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00:03:36,120 --> 00:03:39,280
And that remains true
even though the habits

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formed aren't dependent
so much on olfaction.

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00:03:44,800 --> 00:03:49,650
In primates they're mostly
dependent on other senses,

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but olfaction is
still important.

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The other is place learning.

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And that has become critical
for what humans usually

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think of when they think
of memory, long-term memory

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formation.

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And that will be a theme
that will recur in the class.

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And what is the part of
the brain involved here?

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We always think of hippocampus.

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But in many animals, long
before you could really

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identify something that
looked like a seahorse

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or a hippocampus, it
was part of the pallium.

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It was the medial pallium.

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00:04:31,260 --> 00:04:35,490
In a picture like this,
it's this part here.

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00:04:35,490 --> 00:04:37,056
It's meant to be medial.

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It's a little hard to
show medial and lateral

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in a picture like this.

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But it's part of the
limbic system, connected

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to the hypothalamus.

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And we're going to discuss
later why that came to be true.

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How that evolved.

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There are good reasons why we
became so dependent on parts

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of the limbic system
for our memories.

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So now, with neocortex
expansion there

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were new sensory pathways
that became prominent.

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00:05:13,220 --> 00:05:15,380
They were more
rapidly conducting

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than the spinal
reticular pathways

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00:05:17,450 --> 00:05:21,680
and the spinal thalamic
pathways in sending information

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to the forebrain.

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00:05:24,880 --> 00:05:27,280
Now we're talking mainly
about pathways to neocortex.

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And here I'm just showing
the addition of cortex.

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And then here I've
altered this diagram

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00:05:38,040 --> 00:05:41,840
here to show neocortex up here.

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There's the medial pallium.

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00:05:43,909 --> 00:05:45,450
So I made it look
like a hippocampus.

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00:05:48,200 --> 00:05:49,950
So that's part of the
limbic system, which

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00:05:49,950 --> 00:05:55,050
is all of this in the diagram.

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00:05:55,050 --> 00:05:59,790
And this is really also
limbic, but it's olfactory.

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The olfactory parts
of the limbic system.

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They're limbic because
they're closely connected

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00:06:04,380 --> 00:06:06,200
with hypothalamus.

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In fact, many animals
actually have direct olfactory

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connections to the hypothalamus.

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So now the two pathways.

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I don't know why,
but students always

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find it difficult
to memorize this.

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We talked about
spinal reticular,

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00:06:23,590 --> 00:06:25,815
we talked about spinal thalamic.

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00:06:25,815 --> 00:06:30,610
Now here is another system
that has a number of branches,

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but many more of its axons go
all the way to the thalamus.

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00:06:35,750 --> 00:06:37,900
So it's a pathway
to the neocortex

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00:06:37,900 --> 00:06:39,750
by way of the thalamus.

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00:06:39,750 --> 00:06:43,280
And I've shown here that
the first part of it

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is the dorsal columns.

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They are actually axons of
primary sensory neurons.

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00:06:49,660 --> 00:06:51,620
So here they start,
out on the skin.

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00:06:51,620 --> 00:06:57,390
Specialized end organs
like Pacinian corpuscles,

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00:06:57,390 --> 00:07:02,220
sensitive to touch and things
like that, in the skin.

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00:07:02,220 --> 00:07:03,570
There's its axon.

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00:07:03,570 --> 00:07:04,390
It does branch.

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00:07:04,390 --> 00:07:06,450
It connects in the
spinal cord, too.

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00:07:06,450 --> 00:07:09,380
But it ascends all the way to
the top of the spinal cord.

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00:07:09,380 --> 00:07:12,900
And some anatomy texts say
caudal end of the hindbrain.

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It's a little bit arbitrary
where you mark that division.

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00:07:15,890 --> 00:07:17,300
I follow [INAUDIBLE].

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00:07:17,300 --> 00:07:19,230
He puts it at the very
top of the spinal cord.

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00:07:19,230 --> 00:07:21,450
That's the dorsal column nuclei.

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00:07:26,270 --> 00:07:28,640
We'll be talking
about that very soon.

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00:07:28,640 --> 00:07:33,760
We'll see the dorsal
column nuclei,

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00:07:33,760 --> 00:07:37,890
representing all different parts
of the body except the face.

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00:07:37,890 --> 00:07:40,535
But in fact, the face is
represented there too,

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00:07:40,535 --> 00:07:42,770
and I will show you how.

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But that is the first
synapse in the pathway.

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So it conducts rapidly.

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They tend to be all
myelinated, fairly large axons.

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So this pathway now, from
the dorsal column nuclei,

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00:07:57,960 --> 00:08:03,640
decussates right here
and ascends in a pathway

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00:08:03,640 --> 00:08:06,250
through the hindbrain
and midbrain that we call

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00:08:06,250 --> 00:08:09,920
the medial lemniscus,
the medial ribbon.

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00:08:09,920 --> 00:08:14,200
So that goes directly
to the thalamus.

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00:08:14,200 --> 00:08:20,940
There are a few branches that
go into reticular formation,

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00:08:20,940 --> 00:08:23,830
but the main pathway goes
right to the thalamus.

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00:08:23,830 --> 00:08:28,000
And those thalamic cells connect
to somatosensory neocortex.

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00:08:28,000 --> 00:08:33,700
That's how our somatosensory
cortex gets its major input.

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00:08:33,700 --> 00:08:36,549
It does get input through
the spinal thalamic pathway,

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00:08:36,549 --> 00:08:40,419
and even a little bit from
the spinal reticular also.

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00:08:40,419 --> 00:08:44,430
But at least for fine
touch, very discriminative

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00:08:44,430 --> 00:08:47,610
touch, especially
the touch that we

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use when we're moving our
fingers over something, very

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dependent on this pathway.

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So here is the top view.

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It shows the same thing.

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The primary sensory neuron
and its axon terminating.

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00:09:01,370 --> 00:09:04,670
If this is in the
lumbar enlargement,

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00:09:04,670 --> 00:09:06,790
so lets say it's
coming from the foot,

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00:09:06,790 --> 00:09:12,410
it would go to the medial
dorsal column nucleus.

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00:09:12,410 --> 00:09:14,220
There's two nuclei there.

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00:09:14,220 --> 00:09:17,160
The medial one represents
the lower body,

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and the upper one represents
the arms and chest.

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00:09:21,380 --> 00:09:23,700
And there's the axon
that decussates.

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The axon of the medial lemniscus
starts from the dorsal column

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00:09:26,785 --> 00:09:31,130
nuclei, crosses over,
goes to the thalamus.

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00:09:31,130 --> 00:09:33,490
So it's a crossed pathway.

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00:09:33,490 --> 00:09:39,270
So that all evolved after
the crossing evolved.

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Which was admittedly very
early, very early chordates.

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But if we look at the
most ancient ones,

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we look at hagfish, we
look at sea lamprey,

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they don't have any
pathway resembling this.

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In fact, most mammals
don't have much

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of a pathway that's
like this one.

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It's the mammals this
becomes prominent,

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00:10:03,010 --> 00:10:06,160
and other advanced
vertebrates like birds.

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00:10:08,930 --> 00:10:13,030
And now, along with that,
you get descending pathways

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00:10:13,030 --> 00:10:16,280
coming down from those
somatosensory regions.

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And one of the
somatosensory regions

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became more specialized for
controlling fine movement.

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00:10:22,240 --> 00:10:25,200
That was the motor cortex.

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So I'm showing it
here on the side view.

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00:10:28,430 --> 00:10:31,630
And I'm depicting two
neurons for a good reason.

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Because I want to point out
that the somatosensory, what we

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call somatosensory
cortex, and motor cortex,

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both have pathways
to the spinal cord.

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Here's the one you're
probably most familiar with.

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It comes from motor cortex.

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Note that there are branches to
the striatum, to the thalamus,

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00:10:53,790 --> 00:10:57,020
to the midbrain,
to the hindbrain,

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00:10:57,020 --> 00:10:59,050
especially to the pons.

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00:10:59,050 --> 00:11:01,205
But it goes all the way
down to the spinal cord,

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00:11:01,205 --> 00:11:03,720
where most of the
axons and interneurons

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00:11:03,720 --> 00:11:06,350
are in the ventral horn.

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00:11:06,350 --> 00:11:08,640
A few of them, as I
showed here, go directly

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00:11:08,640 --> 00:11:09,820
to the motor neurons.

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00:11:09,820 --> 00:11:13,550
Now the somatosensory
cortex has similarly

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00:11:13,550 --> 00:11:16,640
descending pathways all
the way to the spinal cord.

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00:11:16,640 --> 00:11:20,520
But these terminate
in the dorsal horn,

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00:11:20,520 --> 00:11:23,110
the part of the spinal cord
that gets the sensory input

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00:11:23,110 --> 00:11:24,266
from the dorsal roots.

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00:11:24,266 --> 00:11:27,450
We'll show the adult.

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00:11:27,450 --> 00:11:32,700
We'll be talking a little
more about that very soon.

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00:11:32,700 --> 00:11:34,860
Here shows that
that, of course, has

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00:11:34,860 --> 00:11:37,560
to be a decussating
pathway, too.

201
00:11:37,560 --> 00:11:41,945
Because we know that the
opposite side of the body is

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00:11:41,945 --> 00:11:42,445
represented.

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00:11:45,570 --> 00:11:47,800
If this is the left
side, it's represented

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00:11:47,800 --> 00:11:49,690
on the right side of the brain.

205
00:11:49,690 --> 00:11:53,230
So that pathway way decussates
too at about the same place

206
00:11:53,230 --> 00:11:55,590
the medial lemniscus decussates.

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00:11:55,590 --> 00:12:00,450
At the caudal, that's a very
dramatic place in the brain,

208
00:12:00,450 --> 00:12:02,970
between hindbrain
and spinal cord,

209
00:12:02,970 --> 00:12:04,840
because of the major
decussations that

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00:12:04,840 --> 00:12:08,660
occur there just above
the dorsal column nuclei.

211
00:12:11,690 --> 00:12:16,000
I mentioned birds have this too.

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00:12:16,000 --> 00:12:21,030
You have a structure in
birds, particularly prominent

213
00:12:21,030 --> 00:12:28,200
in the more advanced birds
like owls and other raptors,

214
00:12:28,200 --> 00:12:30,250
but many birds have this.

215
00:12:30,250 --> 00:12:34,280
The word wulst in
German means a bulge.

216
00:12:34,280 --> 00:12:38,660
And it does form a bulge in the
hemispheres of these animals.

217
00:12:38,660 --> 00:12:42,750
And they have a motor wulst
just like our motor cortex.

218
00:12:42,750 --> 00:12:45,860
It projects directly
to the spinal cord.

219
00:12:45,860 --> 00:12:48,730
They do have somatosensory
wulsts and visual wulsts

220
00:12:48,730 --> 00:12:50,730
as well.

221
00:12:50,730 --> 00:12:53,090
They also have a very
large subcortical region

222
00:12:53,090 --> 00:12:55,600
that has connections
also like neocortex,

223
00:12:55,600 --> 00:12:59,857
just like the wulst does, but it
doesn't require cortex at all.

224
00:12:59,857 --> 00:13:00,940
It's actually subcortical.

225
00:13:04,110 --> 00:13:08,130
It's called the nested
pallium, or the nidopallium.

226
00:13:08,130 --> 00:13:11,962
We'll mention that a few times.

227
00:13:11,962 --> 00:13:18,140
Just so you know something
about other companions,

228
00:13:18,140 --> 00:13:19,160
advanced vertebrates.

229
00:13:22,920 --> 00:13:26,010
Now let's just
mention very briefly

230
00:13:26,010 --> 00:13:28,100
what characterizes
the sensory and motor

231
00:13:28,100 --> 00:13:31,980
functions of the neocortex and
what other types of functions

232
00:13:31,980 --> 00:13:34,090
depend on neocortex.

233
00:13:34,090 --> 00:13:39,510
Think of neocortex as
adding to sensory processes.

234
00:13:39,510 --> 00:13:46,680
Acuity, both sensory and
motor, fine movement control,

235
00:13:46,680 --> 00:13:49,650
find discrimination of objects.

236
00:13:49,650 --> 00:13:53,430
But it also made it
better at objects

237
00:13:53,430 --> 00:13:56,460
could be separated from
the background more easily.

238
00:13:56,460 --> 00:14:00,630
So it's not just a mishmash of
stimuli they're responding to,

239
00:14:00,630 --> 00:14:02,630
but they respond to
specific objects.

240
00:14:02,630 --> 00:14:05,070
So that means they have to
form images of those objects.

241
00:14:05,070 --> 00:14:06,830
And that's something
neocortex does.

242
00:14:09,700 --> 00:14:13,260
And I think the most unique
thing about neocortex--

243
00:14:13,260 --> 00:14:17,590
just that fine control,
the acuity, sensory-motor,

244
00:14:17,590 --> 00:14:21,790
that's just sort of a
quantitative improvement

245
00:14:21,790 --> 00:14:24,630
over what lower structures did.

246
00:14:24,630 --> 00:14:28,100
But this is something
really unique.

247
00:14:28,100 --> 00:14:32,640
It adds the ability to
anticipate and plan.

248
00:14:32,640 --> 00:14:37,350
Anticipate stimuli, we do
that with image formation.

249
00:14:37,350 --> 00:14:41,140
Imaging depends on the posture
of parts of the neocortex.

250
00:14:41,140 --> 00:14:42,840
And also we plan movements.

251
00:14:42,840 --> 00:14:46,240
We don't just react.

252
00:14:46,240 --> 00:14:48,680
That uses an internal
model, a kind

253
00:14:48,680 --> 00:14:49,990
of simulation of the world.

254
00:14:49,990 --> 00:14:52,780
It depends on those
images as well.

255
00:14:52,780 --> 00:14:56,870
So those are really
the unique parts.

256
00:14:56,870 --> 00:14:59,150
I put review slides at
the end of this chapter

257
00:14:59,150 --> 00:15:00,360
that you should look at.

258
00:15:03,030 --> 00:15:08,880
I want to get on here
with the main topic

259
00:15:08,880 --> 00:15:12,040
of the day, formation
of the neural tube

260
00:15:12,040 --> 00:15:15,690
in the embryo-- how
central nervous system

261
00:15:15,690 --> 00:15:17,630
development begins.

262
00:15:17,630 --> 00:15:20,100
And we'll focus on
the spinal level.

263
00:15:20,100 --> 00:15:23,600
That is where the neural
tube first fully forms.

264
00:15:23,600 --> 00:15:26,800
But the entire central nervous
system begins as a tube.

265
00:15:31,360 --> 00:15:33,240
Remember, it all evolves,
actually, together.

266
00:15:37,460 --> 00:15:39,460
So we're going to do
the embryology today.

267
00:15:39,460 --> 00:15:42,529
And next time we'll be able to
get to the adult spinal cord,

268
00:15:42,529 --> 00:15:44,320
and then also the
autonomic nervous system.

269
00:15:46,920 --> 00:15:49,830
These are the stages
of development

270
00:15:49,830 --> 00:15:51,600
of a nervous system.

271
00:15:51,600 --> 00:15:56,730
After the egg is fertilized
you get the formation

272
00:15:56,730 --> 00:15:58,720
of a morula, a clump of cells.

273
00:15:58,720 --> 00:16:02,800
That becomes a blastula, which
is a hollow ball of cells.

274
00:16:02,800 --> 00:16:04,870
Now it's got fluid
in the middle.

275
00:16:04,870 --> 00:16:09,160
Then a major step,
gastrulation, where

276
00:16:09,160 --> 00:16:15,255
the organism, instead of just
this hollow ball of cells

277
00:16:15,255 --> 00:16:18,945
with fluid in the middle,
becomes shaped like a doughnut.

278
00:16:18,945 --> 00:16:23,110
The formation of the alimentary
canal-- mouth at one end,

279
00:16:23,110 --> 00:16:24,220
anus at the other.

280
00:16:24,220 --> 00:16:25,520
That forms very early.

281
00:16:25,520 --> 00:16:26,710
We'll see pictures of that.

282
00:16:26,710 --> 00:16:29,130
And then finally
neurulation, the formation

283
00:16:29,130 --> 00:16:33,970
of the nervous system, the major
thing we want to talk about.

284
00:16:33,970 --> 00:16:36,950
Now, Lewis Wolpert, in his
very interesting little book,

285
00:16:36,950 --> 00:16:39,700
Triumph of the Embryo,
when he revised it,

286
00:16:39,700 --> 00:16:42,460
other authors joined
him and it became

287
00:16:42,460 --> 00:16:45,830
a more standard embryology book.

288
00:16:45,830 --> 00:16:47,730
This is also very interesting.

289
00:16:47,730 --> 00:16:50,230
All of the things that I
found in Triumph of the Embryo

290
00:16:50,230 --> 00:16:53,450
are still there, but
he really simplified it

291
00:16:53,450 --> 00:16:56,380
and talked about the
major principles.

292
00:16:56,380 --> 00:16:57,960
And one of the
things he laid out

293
00:16:57,960 --> 00:17:03,090
was the cellular events, what
are the cellular events that

294
00:17:03,090 --> 00:17:06,050
characterize development
of the nervous system?

295
00:17:08,710 --> 00:17:09,329
What are they?

296
00:17:12,400 --> 00:17:14,000
Well, contraction.

297
00:17:14,000 --> 00:17:16,380
Parts of the cell
could contract.

298
00:17:16,380 --> 00:17:18,020
What does that involve?

299
00:17:18,020 --> 00:17:20,260
In involves
contractile proteins,

300
00:17:20,260 --> 00:17:22,869
just like we have in muscle.

301
00:17:22,869 --> 00:17:27,030
Cells have that also, to
some degree, in development.

302
00:17:30,540 --> 00:17:32,440
Contraction.

303
00:17:32,440 --> 00:17:38,130
Well, cells have to, in order
to form organized tissue, cells

304
00:17:38,130 --> 00:17:42,200
have to be able to stick to
things, stick to each other

305
00:17:42,200 --> 00:17:46,150
to form these little processes
that can adhere to something.

306
00:17:46,150 --> 00:17:47,580
So they show adhesion.

307
00:17:47,580 --> 00:17:51,680
And the adhesive
properties through cell

308
00:17:51,680 --> 00:17:53,860
adhesion molecules in
the membrane, which

309
00:17:53,860 --> 00:17:58,150
can change during the
course of development.

310
00:17:58,150 --> 00:18:00,480
That's a big part of
development, selective adhesion

311
00:18:00,480 --> 00:18:03,970
and changes in adhesion.

312
00:18:03,970 --> 00:18:06,010
And then cells can move.

313
00:18:06,010 --> 00:18:07,940
How do they move?

314
00:18:07,940 --> 00:18:10,710
So we'll be talking about that.

315
00:18:10,710 --> 00:18:13,730
And finally, of course, growth.

316
00:18:13,730 --> 00:18:16,300
And by growth, often
an embryologist

317
00:18:16,300 --> 00:18:19,700
is talking about
growth by proliferation

318
00:18:19,700 --> 00:18:22,750
of cells, mitosis.

319
00:18:22,750 --> 00:18:25,700
It also means growth and
increased size of cells.

320
00:18:25,700 --> 00:18:28,616
But the main factor is
increased numbers of cells.

321
00:18:33,860 --> 00:18:37,770
So here's the pictures
that Wolpert uses.

322
00:18:37,770 --> 00:18:43,840
From a single fertilized
egg here, to the morula.

323
00:18:43,840 --> 00:18:46,600
It looks like a raspberry.

324
00:18:46,600 --> 00:18:51,000
And here it becomes the blastula
with fluid in the middle.

325
00:18:51,000 --> 00:18:55,030
And then note some cells
have moved to the interior.

326
00:18:55,030 --> 00:19:00,680
And there's more
contraction at one side,

327
00:19:00,680 --> 00:19:02,940
the outside of the cell,
than on the inside.

328
00:19:02,940 --> 00:19:06,630
And that leads to invagination
that you see beginning here.

329
00:19:06,630 --> 00:19:09,820
And then look what happens.

330
00:19:09,820 --> 00:19:12,650
These little
processes extend out.

331
00:19:12,650 --> 00:19:15,160
Those little
filaments are called

332
00:19:15,160 --> 00:19:19,720
filopodia, filamentous feet.

333
00:19:19,720 --> 00:19:21,830
They extend out,
and they actually

334
00:19:21,830 --> 00:19:24,540
reach the other side,
where they adhere.

335
00:19:24,540 --> 00:19:27,430
So now you have adhesion.

336
00:19:27,430 --> 00:19:29,340
You have both of these
processes we just

337
00:19:29,340 --> 00:19:34,860
talked about are happening,
contraction and adhesion.

338
00:19:34,860 --> 00:19:38,380
Movement-- notice
the movement that's

339
00:19:38,380 --> 00:19:41,890
being caused by the contraction,
contractile proteins

340
00:19:41,890 --> 00:19:43,816
in those filopodia.

341
00:19:43,816 --> 00:19:48,920
So it pulls this side of
the embryo right across.

342
00:19:48,920 --> 00:19:51,210
And that causes
changes that cause

343
00:19:51,210 --> 00:19:56,100
an opening to form
between here and here.

344
00:19:56,100 --> 00:19:59,650
The cells continue to
move to the inside.

345
00:19:59,650 --> 00:20:03,480
But that process from
here to hear, or actually

346
00:20:03,480 --> 00:20:06,729
all along the bottom,
is called gastrulation.

347
00:20:06,729 --> 00:20:08,145
This is just seen
in the sections.

348
00:20:11,040 --> 00:20:13,620
This shows us one
of the cells, how

349
00:20:13,620 --> 00:20:17,540
complicated they can be with
their various extensions

350
00:20:17,540 --> 00:20:19,070
and movement.

351
00:20:19,070 --> 00:20:25,960
Because if this was all there
was, we'd have one layer.

352
00:20:25,960 --> 00:20:27,890
That outer layer
is the ectoderm.

353
00:20:27,890 --> 00:20:30,930
But cells move inward.

354
00:20:30,930 --> 00:20:32,210
They move to the interior.

355
00:20:32,210 --> 00:20:35,300
And that becomes the
mesoderm and the endoderm.

356
00:20:35,300 --> 00:20:37,715
Mesoderm forming
muscle and skeleton,

357
00:20:37,715 --> 00:20:40,516
and the endoderm forming
the internal organs.

358
00:20:44,320 --> 00:20:52,070
So then none of this gives
you a central nervous system.

359
00:20:52,070 --> 00:20:56,300
How do we get a central
nervous system out of that?

360
00:20:56,300 --> 00:20:59,410
So we need to talk
about neurulation,

361
00:20:59,410 --> 00:21:01,820
the formation of
the neural tube.

362
00:21:01,820 --> 00:21:05,620
And then proliferation of the
cells, migration of cells,

363
00:21:05,620 --> 00:21:07,160
and differentiation of cells.

364
00:21:07,160 --> 00:21:10,920
By differentiation
we mean the cell

365
00:21:10,920 --> 00:21:14,170
changes so the cells look
different from each other.

366
00:21:14,170 --> 00:21:15,700
They differentiate
from each other.

367
00:21:15,700 --> 00:21:20,680
They form dendrites, they form
axons, if they're neurons.

368
00:21:20,680 --> 00:21:23,014
If they're glial cells
they also form processes,

369
00:21:23,014 --> 00:21:24,680
depending on what
kind of glia they are.

370
00:21:27,940 --> 00:21:29,720
So these are the
questions I'm asking.

371
00:21:29,720 --> 00:21:32,630
First of all, what
is the notochord?

372
00:21:32,630 --> 00:21:35,140
We've heard that
term used before.

373
00:21:35,140 --> 00:21:38,270
You should remember what it is.

374
00:21:38,270 --> 00:21:39,680
Some of you might.

375
00:21:39,680 --> 00:21:42,290
What is the notochord?

376
00:21:42,290 --> 00:21:45,010
It's not in all animals.

377
00:21:45,010 --> 00:21:49,390
It's just in all animals
that we call chordates.

378
00:21:49,390 --> 00:21:50,822
So what is it?

379
00:21:50,822 --> 00:21:53,360
The notochord.

380
00:21:53,360 --> 00:21:55,790
Yes?

381
00:21:55,790 --> 00:22:00,790
AUDIENCE: The cartilaginous
tube that becomes the

382
00:22:00,790 --> 00:22:01,750
PROFESSOR: Yes.

383
00:22:01,750 --> 00:22:04,110
Tube may not be
the most accurate.

384
00:22:04,110 --> 00:22:06,770
It's cartilaginous for sure.

385
00:22:06,770 --> 00:22:08,200
What is it?

386
00:22:08,200 --> 00:22:09,825
AUDIENCE: It's beneath
the neural tube.

387
00:22:13,100 --> 00:22:14,670
PROFESSOR: But wait.

388
00:22:14,670 --> 00:22:18,390
It precedes the neural tube.

389
00:22:18,390 --> 00:22:21,700
But where in the organism?

390
00:22:21,700 --> 00:22:25,974
At least, what does it
become in the organism?

391
00:22:25,974 --> 00:22:28,147
AUDIENCE: In the back.

392
00:22:28,147 --> 00:22:28,980
PROFESSOR: The back.

393
00:22:28,980 --> 00:22:29,940
Exactly.

394
00:22:29,940 --> 00:22:32,760
It's always along the back.

395
00:22:32,760 --> 00:22:34,590
At least what's going
to become the back.

396
00:22:34,590 --> 00:22:37,230
Maybe that's how
it becomes a back.

397
00:22:37,230 --> 00:22:39,750
The notochord is at
the surface, one side,

398
00:22:39,750 --> 00:22:41,986
that becomes the back.

399
00:22:41,986 --> 00:22:43,694
AUDIENCE: Does notochord
become backbone?

400
00:22:47,630 --> 00:22:50,380
PROFESSOR: It doesn't
become the backbone,

401
00:22:50,380 --> 00:22:55,350
but the skeletal
elements form around it.

402
00:22:55,350 --> 00:22:57,320
There are induction processes.

403
00:22:57,320 --> 00:23:01,870
Molecules coming from the
notochord exert really powerful

404
00:23:01,870 --> 00:23:03,200
changes.

405
00:23:03,200 --> 00:23:06,100
First of all in the formation
of the nervous system, but then

406
00:23:06,100 --> 00:23:07,825
the formation of the
skeleton as well.

407
00:23:12,520 --> 00:23:20,000
Who discovered this phenomenon
of induction of the CNS?

408
00:23:20,000 --> 00:23:23,270
Now, we know now that
the inductive process,

409
00:23:23,270 --> 00:23:25,460
the notochord
induces the formation

410
00:23:25,460 --> 00:23:27,000
of the nervous system.

411
00:23:27,000 --> 00:23:29,430
But how was it discovered?

412
00:23:29,430 --> 00:23:32,840
Who discovered that there's
some kind of induction that's

413
00:23:32,840 --> 00:23:34,250
happening?

414
00:23:34,250 --> 00:23:37,482
Because if you
move things around,

415
00:23:37,482 --> 00:23:39,440
you can get nervous system
forming differently,

416
00:23:39,440 --> 00:23:40,398
or in different places.

417
00:23:42,900 --> 00:23:44,630
Remember the names?

418
00:23:44,630 --> 00:23:46,850
There were actually two
people, but only one of them

419
00:23:46,850 --> 00:23:49,220
got the Nobel Prize for it.

420
00:23:51,750 --> 00:23:55,170
His name was Hans Spemann.

421
00:23:55,170 --> 00:23:56,590
Spemann got the prize.

422
00:23:56,590 --> 00:23:58,870
But the discovery
was made in his lab

423
00:23:58,870 --> 00:24:03,360
by his student, a young
woman named Hilde Mangold.

424
00:24:07,700 --> 00:24:10,670
Why didn't she get
the Nobel Prize?

425
00:24:10,670 --> 00:24:13,890
Unfortunately, they don't
give Nobel Prizes to someone

426
00:24:13,890 --> 00:24:16,090
who has died.

427
00:24:16,090 --> 00:24:22,340
She died in a kitchen accident
when she was only 26 years old.

428
00:24:22,340 --> 00:24:25,135
But she should be
remembered just as Spemann

429
00:24:25,135 --> 00:24:27,230
is for the discovery
of induction

430
00:24:27,230 --> 00:24:28,652
of the nervous system.

431
00:24:33,280 --> 00:24:36,650
And then we want to know
what neural crest cells are.

432
00:24:36,650 --> 00:24:40,026
You've got to know something
about the neural tube formation

433
00:24:40,026 --> 00:24:43,220
to be able to answer that.

434
00:24:43,220 --> 00:24:46,010
I should have a
piece of paper here.

435
00:24:46,010 --> 00:24:48,130
I didn't bring my
piece of paper.

436
00:24:48,130 --> 00:24:50,610
You just take a piece of paper
and push at the two ends.

437
00:24:50,610 --> 00:24:52,350
What happens?

438
00:24:52,350 --> 00:24:53,980
It will indent, right?

439
00:24:53,980 --> 00:24:56,100
And you can get it to
indent in one place.

440
00:24:56,100 --> 00:25:00,410
That's what happens to
the nervous system here.

441
00:25:00,410 --> 00:25:01,440
Here's a sheet of paper.

442
00:25:01,440 --> 00:25:05,790
It's one cell thick ectoderm.

443
00:25:05,790 --> 00:25:09,200
And that is the notochord.

444
00:25:09,200 --> 00:25:11,869
This is just part of the
ectoderm, the part that

445
00:25:11,869 --> 00:25:13,410
will become the back
of the organism.

446
00:25:16,170 --> 00:25:18,030
There's the notochord.

447
00:25:18,030 --> 00:25:20,870
Then there's an influence
from the notochord.

448
00:25:20,870 --> 00:25:25,460
Note here I show cells getting
thicker in this region.

449
00:25:25,460 --> 00:25:29,360
That's what we call
a neural plate.

450
00:25:29,360 --> 00:25:31,380
The cells are already
determined now.

451
00:25:31,380 --> 00:25:33,880
Which ones are going to
become nervous system

452
00:25:33,880 --> 00:25:38,100
and which will remain other
parts of the ectoderm,

453
00:25:38,100 --> 00:25:38,860
like the skin.

454
00:25:42,870 --> 00:25:47,750
And then, because of
differences in contraction,

455
00:25:47,750 --> 00:25:50,527
despite during
gastrulation earlier,

456
00:25:50,527 --> 00:25:51,610
you get an endogenization.

457
00:25:54,820 --> 00:25:56,880
So it doesn't really
happen because somebody

458
00:25:56,880 --> 00:26:00,310
pushed the sides like
a piece of paper.

459
00:26:00,310 --> 00:26:02,660
But the dynamics
are very similar.

460
00:26:02,660 --> 00:26:08,170
So it starts to form a groove
along the back of the organism.

461
00:26:08,170 --> 00:26:10,500
So think of it in
three dimensions.

462
00:26:10,500 --> 00:26:12,640
That's why I like you to
think of a piece of paper.

463
00:26:12,640 --> 00:26:16,260
If we push in, it's
gonna form a groove

464
00:26:16,260 --> 00:26:19,560
all along the back
of the organism.

465
00:26:19,560 --> 00:26:21,260
There's the notochord.

466
00:26:21,260 --> 00:26:24,965
The molecules emanating
from that notochord

467
00:26:24,965 --> 00:26:32,610
are what's causing these changes
in the ectoderm above it.

468
00:26:32,610 --> 00:26:37,350
And note I show two little
bulges on the sides.

469
00:26:37,350 --> 00:26:39,590
That is called the neural crest.

470
00:26:39,590 --> 00:26:41,100
And it's very different.

471
00:26:41,100 --> 00:26:44,010
Because as these two
edges come together

472
00:26:44,010 --> 00:26:47,810
so you end up with
a tube, these cells

473
00:26:47,810 --> 00:26:49,060
don't become part of the tube.

474
00:26:49,060 --> 00:26:50,900
They stay on the outside.

475
00:26:50,900 --> 00:26:52,960
It's those neural
crest cells that

476
00:26:52,960 --> 00:26:56,050
form the peripheral
nervous system.

477
00:26:56,050 --> 00:26:59,540
All the cells of the
peripheral nervous system

478
00:26:59,540 --> 00:27:03,960
come from the neural
crest at this level

479
00:27:03,960 --> 00:27:05,930
of the nervous system.

480
00:27:05,930 --> 00:27:07,620
Now, there are cells
that don't come

481
00:27:07,620 --> 00:27:10,190
from neural crest
in the head region.

482
00:27:10,190 --> 00:27:12,670
There they come from
both neural crest

483
00:27:12,670 --> 00:27:14,570
and from what we call placodes.

484
00:27:14,570 --> 00:27:16,590
It's thickening of
the ectoderm that

485
00:27:16,590 --> 00:27:20,270
happens due to other
inductive influences.

486
00:27:20,270 --> 00:27:22,650
Not the notochord now.

487
00:27:22,650 --> 00:27:25,390
It can also come from
peripheral nervous system.

488
00:27:25,390 --> 00:27:28,790
But here in the
spinal cord, it all

489
00:27:28,790 --> 00:27:32,030
comes from the neural crest.

490
00:27:32,030 --> 00:27:34,970
And then there's a few
names you should learn.

491
00:27:34,970 --> 00:27:39,460
When this tube forms,
note I show here the tube

492
00:27:39,460 --> 00:27:41,190
is already getting
a little thicker.

493
00:27:41,190 --> 00:27:43,500
There are cells
proliferating there.

494
00:27:43,500 --> 00:27:47,390
They proliferate in
the sides of the tube,

495
00:27:47,390 --> 00:27:51,280
not at the very top
and the very bottom.

496
00:27:51,280 --> 00:27:53,270
The very top is
called the roof plate.

497
00:27:53,270 --> 00:27:56,120
It remains one cell thick.

498
00:27:56,120 --> 00:27:57,662
And the bottom is
the floor plate.

499
00:27:57,662 --> 00:28:01,910
It also remains one cell
thick, right to the adult.

500
00:28:01,910 --> 00:28:04,350
But the walls get
thicker and thicker.

501
00:28:04,350 --> 00:28:10,020
And in development the ventral
part closest to the notochord

502
00:28:10,020 --> 00:28:14,440
tends to proliferate
a little bit faster.

503
00:28:14,440 --> 00:28:16,980
That's where the motor
neurons will form.

504
00:28:16,980 --> 00:28:21,320
So we call the upper
part here the alar plate.

505
00:28:21,320 --> 00:28:24,840
And the lower part
the basal plate.

506
00:28:24,840 --> 00:28:28,160
And little groove
separating the two

507
00:28:28,160 --> 00:28:31,390
is called the sulcus
limitans, the limiting sulcus.

508
00:28:31,390 --> 00:28:33,960
And we'll see pictures
of that as we go on.

509
00:28:43,770 --> 00:28:47,030
Let me show you
some pictures of it.

510
00:28:47,030 --> 00:28:51,740
We mentioned this already,
the discovery of induction.

511
00:28:51,740 --> 00:28:53,950
Where does that closure begin?

512
00:28:53,950 --> 00:28:55,190
Remember, it's a groove.

513
00:28:55,190 --> 00:28:58,670
It's a neural groove all along
the back of the organism.

514
00:28:58,670 --> 00:29:07,050
And then it forms a tube,
as you see in this picture.

515
00:29:07,050 --> 00:29:09,905
Well, where does
this first begin?

516
00:29:16,665 --> 00:29:20,640
So I show you this picture.

517
00:29:20,640 --> 00:29:22,460
It begins sort of in the middle.

518
00:29:22,460 --> 00:29:24,840
This is the head,
this is rostral.

519
00:29:24,840 --> 00:29:27,780
This is the caudal end here.

520
00:29:27,780 --> 00:29:30,420
That's where the neural
tube is first closing.

521
00:29:30,420 --> 00:29:32,420
So if we go further
back or further forward,

522
00:29:32,420 --> 00:29:33,600
it would look like this.

523
00:29:33,600 --> 00:29:36,630
It would be a
neural groove still.

524
00:29:36,630 --> 00:29:38,390
So it starts to close.

525
00:29:38,390 --> 00:29:42,060
That region corresponds
to the cervical region

526
00:29:42,060 --> 00:29:45,950
of the spinal cord, the upper
part, or the most rostral part

527
00:29:45,950 --> 00:29:47,820
of the spinal cord.

528
00:29:47,820 --> 00:29:51,350
That's where development
is a little more advanced.

529
00:29:51,350 --> 00:29:53,240
That's where the neural
tube first closes.

530
00:29:58,450 --> 00:30:02,110
So the last region to close,
as you can guess, it sort of

531
00:30:02,110 --> 00:30:06,690
zips up this way and zips up
caudally, the very tail region

532
00:30:06,690 --> 00:30:07,580
here.

533
00:30:07,580 --> 00:30:09,280
The last part to close.

534
00:30:09,280 --> 00:30:16,385
And similarly, the most rostral
part of the CNS, the last part

535
00:30:16,385 --> 00:30:17,270
to close.

536
00:30:17,270 --> 00:30:21,110
So if some abnormality occurs
during early development,

537
00:30:21,110 --> 00:30:26,360
and it does happen, you can get
a failure to completely close.

538
00:30:26,360 --> 00:30:29,270
When it doesn't
close caudally here,

539
00:30:29,270 --> 00:30:31,440
you get a condition
known as spina bifida.

540
00:30:34,210 --> 00:30:36,870
That can be
corrected surgically.

541
00:30:36,870 --> 00:30:41,040
But when it fails
to close rostrally,

542
00:30:41,040 --> 00:30:47,960
there's a failure of the
forebrain to develop.

543
00:30:47,960 --> 00:30:50,090
You call it anencephaly.

544
00:30:50,090 --> 00:30:54,350
Basically it means
without a brain.

545
00:30:54,350 --> 00:30:55,790
They do have some brain.

546
00:30:55,790 --> 00:30:58,020
They have the brainstem.

547
00:30:58,020 --> 00:31:02,650
And babies that are born that
way don't live very long.

548
00:31:02,650 --> 00:31:07,490
It's impossible to repair that.

549
00:31:07,490 --> 00:31:10,540
They've been
studied a little bit

550
00:31:10,540 --> 00:31:14,830
in their brief,
very brief lives.

551
00:31:14,830 --> 00:31:16,810
Let's take a look
at that happening.

552
00:31:31,580 --> 00:31:34,590
These are interesting
animations that you can actually

553
00:31:34,590 --> 00:31:36,400
find on the web.

554
00:31:36,400 --> 00:31:39,920
If you look at the cross section
up here-- don't take notes now,

555
00:31:39,920 --> 00:31:40,830
look up here.

556
00:31:40,830 --> 00:31:43,530
Look up here.

557
00:31:43,530 --> 00:31:46,220
Look at the screen or you're
missing the main show.

558
00:31:51,020 --> 00:31:55,120
You see the neural tube in
the 3D picture there closing.

559
00:31:55,120 --> 00:31:57,620
You see what's
happening up there.

560
00:31:57,620 --> 00:31:59,990
The black dots are
the neural crest cells

561
00:31:59,990 --> 00:32:02,460
that are staying on the outside.

562
00:32:02,460 --> 00:32:04,350
They don't get incorporated.

563
00:32:04,350 --> 00:32:08,790
The tube closes without them.

564
00:32:08,790 --> 00:32:15,440
The red is the mesoderm,
mostly muscle tissue there.

565
00:32:15,440 --> 00:32:19,840
And the vertebrae are forming
around the neural tube.

566
00:32:22,570 --> 00:32:28,470
So that's where you find
the peripheral ganglia

567
00:32:28,470 --> 00:32:30,010
of the sympathetic
nervous system.

568
00:32:30,010 --> 00:32:33,090
And there's the
dorsal root ganglia.

569
00:32:33,090 --> 00:32:34,760
What are these out here?

570
00:32:34,760 --> 00:32:36,410
They're the neural crest cells.

571
00:32:36,410 --> 00:32:39,030
I didn't mention those before.

572
00:32:39,030 --> 00:32:42,620
They're migrating
into the skin, mostly

573
00:32:42,620 --> 00:32:46,183
melanocytes, the pigmented
cells in the skin.

574
00:32:53,000 --> 00:32:54,690
Rather than look
at that again, I

575
00:32:54,690 --> 00:32:58,980
want to show you an actual
photograph of neurulation

576
00:32:58,980 --> 00:33:01,030
in the clawed frog, the Xenopus.

577
00:33:03,740 --> 00:33:07,430
It happens very fast, so we'll
look at it several times.

578
00:33:07,430 --> 00:33:14,220
If you just focus
on one of these,

579
00:33:14,220 --> 00:33:18,660
you see the whole thing because
they've speeded it up so much.

580
00:33:18,660 --> 00:33:21,760
With the formation you don't
really see the neural plate,

581
00:33:21,760 --> 00:33:26,962
but you see the neural groove
forming and you see it close.

582
00:33:26,962 --> 00:33:30,720
It zips up rostrally
and caudally.

583
00:33:30,720 --> 00:33:33,500
And then the embryo
turns a little bit

584
00:33:33,500 --> 00:33:36,560
so it looks a little bit more
like the end of this one.

585
00:33:42,530 --> 00:33:44,705
You can find those, if
you do some searching.

586
00:33:44,705 --> 00:33:47,270
You can find them online.

587
00:33:47,270 --> 00:33:51,850
This is just a picture of
that early stage, taken

588
00:33:51,850 --> 00:33:53,340
with the electron
microscope when

589
00:33:53,340 --> 00:33:55,930
they used a method
called freeze-fracture.

590
00:33:55,930 --> 00:33:57,440
They freeze it solid.

591
00:33:57,440 --> 00:34:03,080
And then if they could get
it to break along this line,

592
00:34:03,080 --> 00:34:08,159
you can see individual
cells in both the CNS

593
00:34:08,159 --> 00:34:12,570
there in the neural tube, and
the mesoderm and the ectoderm.

594
00:34:12,570 --> 00:34:16,350
And then you see the
endoderm down here.

595
00:34:16,350 --> 00:34:18,580
And this just shows
what it's like in humans

596
00:34:18,580 --> 00:34:24,655
at particular stages, 22 and
24 days after conception.

597
00:34:27,389 --> 00:34:31,204
I picked this because it's right
after the neural tube starts

598
00:34:31,204 --> 00:34:32,370
to close.

599
00:34:32,370 --> 00:34:35,666
In the hamster, that
I've used a lot,

600
00:34:35,666 --> 00:34:40,630
it closes on the eighth
day after conception.

601
00:34:40,630 --> 00:34:44,040
So it can happen in some
species very, very fast.

602
00:34:44,040 --> 00:34:47,359
Of course, they're
much smaller too.

603
00:34:47,359 --> 00:34:49,820
It tends to be slower
in the larger animals.

604
00:34:54,739 --> 00:34:57,700
So what is this
term, sonic hedgehog?

605
00:34:57,700 --> 00:35:01,290
We're not going back to
comparative neurology here.

606
00:35:01,290 --> 00:35:03,433
It's the name for what?

607
00:35:03,433 --> 00:35:04,308
AUDIENCE: [INAUDIBLE]

608
00:35:10,160 --> 00:35:16,120
PROFESSOR: It's a particular
molecule, sonic hedgehog.

609
00:35:16,120 --> 00:35:19,510
It's just the name for
a protein, a molecule.

610
00:35:22,090 --> 00:35:23,880
It actually has
a number of roles

611
00:35:23,880 --> 00:35:25,760
in the formation of
the nervous system.

612
00:35:25,760 --> 00:35:28,480
Where's it come
from in this process

613
00:35:28,480 --> 00:35:32,590
we're starting right now?

614
00:35:32,590 --> 00:35:35,620
I told you before, where
the induction comes from.

615
00:35:40,370 --> 00:35:41,710
The notochord.

616
00:35:41,710 --> 00:35:47,210
Sonic hedgehog is
generated by the notochord.

617
00:35:47,210 --> 00:35:49,860
It induces the formation
of the nervous system,

618
00:35:49,860 --> 00:35:51,880
and does other things too.

619
00:35:51,880 --> 00:35:57,500
And if we look at
this picture, they're

620
00:35:57,500 --> 00:36:04,300
coming-- these would be
where the molecules are.

621
00:36:04,300 --> 00:36:07,110
Of course, they're
probably going all around.

622
00:36:07,110 --> 00:36:12,920
I'm showing the ones that are
in a concentrated way affecting

623
00:36:12,920 --> 00:36:14,650
these cells above it.

624
00:36:14,650 --> 00:36:17,210
But still coming there.

625
00:36:17,210 --> 00:36:21,525
And it's affecting this
lower part of the cord.

626
00:36:21,525 --> 00:36:24,780
It serves as a
ventralizing influence.

627
00:36:24,780 --> 00:36:29,810
It makes that ventral part
of the neural tube-- see,

628
00:36:29,810 --> 00:36:31,700
they're still here.

629
00:36:31,700 --> 00:36:35,690
It makes the cells here form
differently than the cells

630
00:36:35,690 --> 00:36:37,520
up here.

631
00:36:37,520 --> 00:36:40,460
Without sonic hedgehog and
its ventralizing influence,

632
00:36:40,460 --> 00:36:43,180
you wouldn't get to form
early differentiation of motor

633
00:36:43,180 --> 00:36:45,380
neurons.

634
00:36:45,380 --> 00:36:49,070
What about the dorsal part?

635
00:36:49,070 --> 00:36:53,660
There are inductive
influences on this part,

636
00:36:53,660 --> 00:36:56,960
the part that came
from way out here.

637
00:36:56,960 --> 00:37:00,930
It forms the dorsal
part of the cord.

638
00:37:00,930 --> 00:37:06,330
Those inductive influences
came from the ectoderm.

639
00:37:06,330 --> 00:37:08,590
And I mention it here.

640
00:37:08,590 --> 00:37:11,300
The dorsalizing
factors are secreted

641
00:37:11,300 --> 00:37:15,266
by the ectoderm adjacent
to the neural tube.

642
00:37:15,266 --> 00:37:20,220
The main ones are
this BMP-4 and 7.

643
00:37:20,220 --> 00:37:23,630
BMP actually means bone
morphogenetic protein,

644
00:37:23,630 --> 00:37:27,665
because it has a role in
bone formation as well.

645
00:37:27,665 --> 00:37:29,866
And now we're talking
about its influence

646
00:37:29,866 --> 00:37:31,370
on the nervous system.

647
00:37:31,370 --> 00:37:35,050
So it induces changes in
the dorsal part of the cord.

648
00:37:37,980 --> 00:37:41,000
It causes those cells
to develop differently

649
00:37:41,000 --> 00:37:43,940
than the ones ventrally.

650
00:37:43,940 --> 00:37:45,620
That leaves a lot of
things unexplained.

651
00:37:45,620 --> 00:37:48,216
But at least it was
a start in looking

652
00:37:48,216 --> 00:37:51,360
at how the nervous
system develops.

653
00:37:51,360 --> 00:37:53,610
Now I want to talk
about cell division.

654
00:37:53,610 --> 00:37:56,760
What are the two main
types of cell division

655
00:37:56,760 --> 00:37:58,440
that I described
in this chapter?

656
00:38:01,860 --> 00:38:03,800
There are differences
in cell division

657
00:38:03,800 --> 00:38:08,480
that make a huge difference in
h how the nervous system forms.

658
00:38:08,480 --> 00:38:11,290
Symmetric and asymmetric.

659
00:38:11,290 --> 00:38:14,567
And for that, you need to
look at a picture like this.

660
00:38:14,567 --> 00:38:15,525
This is the cell cycle.

661
00:38:19,550 --> 00:38:22,170
The cell here moves
away from the ventricle.

662
00:38:22,170 --> 00:38:23,870
But when I say
the cell, I really

663
00:38:23,870 --> 00:38:25,820
mean the nucleus of the cell.

664
00:38:25,820 --> 00:38:31,270
Because it's attached
to the pia out here,

665
00:38:31,270 --> 00:38:34,210
to the ventricle here.

666
00:38:34,210 --> 00:38:36,780
But it moves away
from the ventricle

667
00:38:36,780 --> 00:38:39,310
in order to synthesize its DNA.

668
00:38:39,310 --> 00:38:44,450
It moves towards the ventricle
in order to undergo mitosis.

669
00:38:44,450 --> 00:38:48,905
And it can undergo mitosis
with a symmetric split

670
00:38:48,905 --> 00:38:52,330
or an asymmetric split.

671
00:38:52,330 --> 00:38:54,970
When it splits
symmetrically, it tends

672
00:38:54,970 --> 00:39:00,830
to split along a line
that's at right angles

673
00:39:00,830 --> 00:39:03,920
to ventricular surface.

674
00:39:03,920 --> 00:39:07,870
And when it does that, the
distribution of proteins

675
00:39:07,870 --> 00:39:12,960
in the cell-- there's two
proteins in particular--

676
00:39:12,960 --> 00:39:17,200
tends to be pretty even
in the two daughter cells.

677
00:39:17,200 --> 00:39:21,930
So the two daughter cells
will behave pretty similar.

678
00:39:21,930 --> 00:39:26,930
Basically, they remain stem
cells, they keep dividing.

679
00:39:26,930 --> 00:39:30,610
But when it splits
asymmetrically,

680
00:39:30,610 --> 00:39:34,690
you end up with a very uneven
distribution of those proteins.

681
00:39:34,690 --> 00:39:36,070
Notch and numb they're called.

682
00:39:38,750 --> 00:39:42,000
And now you get the two
cells behaving differently.

683
00:39:42,000 --> 00:39:43,575
One remains a stem cell.

684
00:39:43,575 --> 00:39:45,010
It keeps dividing.

685
00:39:45,010 --> 00:39:49,390
The other one
becomes post-mitotic

686
00:39:49,390 --> 00:39:51,170
and does something
very differently.

687
00:39:51,170 --> 00:39:53,850
It migrates away.

688
00:39:53,850 --> 00:39:57,100
And in many cases the
migration is simply,

689
00:39:57,100 --> 00:39:58,820
like over here on
the cell cycle,

690
00:39:58,820 --> 00:40:03,040
the nucleus just moves
away from the ventricle.

691
00:40:03,040 --> 00:40:04,100
It can be doing that.

692
00:40:04,100 --> 00:40:06,480
The attachments can remain.

693
00:40:06,480 --> 00:40:08,790
Cajal saw things like this.

694
00:40:11,960 --> 00:40:14,780
These are the way they look
in Golgi in many cases.

695
00:40:14,780 --> 00:40:16,730
You might have been
looking at two cells here.

696
00:40:16,730 --> 00:40:22,070
But in some cases they might
be cells with two nuclei.

697
00:40:22,070 --> 00:40:26,430
Here's a cell that's lost
its external process.

698
00:40:26,430 --> 00:40:29,930
All of these in here, they've
regained the attachment

699
00:40:29,930 --> 00:40:31,770
to the pia.

700
00:40:31,770 --> 00:40:35,050
And when the nucleus just
moves further and further

701
00:40:35,050 --> 00:40:39,370
from the ventricle and never
returns, we say it's migrating.

702
00:40:39,370 --> 00:40:45,330
We say it's migrating by nuclear
translocation, the first type

703
00:40:45,330 --> 00:40:47,850
of migration.

704
00:40:47,850 --> 00:40:50,040
Here's his picture of
the chick spinal cord

705
00:40:50,040 --> 00:40:53,520
on the third day of incubation.

706
00:40:53,520 --> 00:40:54,765
Chicks grow very fast.

707
00:40:54,765 --> 00:40:57,404
They're a favorite
among embryologists

708
00:40:57,404 --> 00:40:59,320
because you can cut a
little window in the egg

709
00:40:59,320 --> 00:41:01,111
and you can look at
these things happening.

710
00:41:03,620 --> 00:41:06,470
And note that some of the cells
are right near the ventricle.

711
00:41:06,470 --> 00:41:09,990
But all of them that he shows
in this particular picture

712
00:41:09,990 --> 00:41:11,570
are attached to the pia.

713
00:41:15,070 --> 00:41:18,800
So it's really similar to roof
plate and floor plate there.

714
00:41:18,800 --> 00:41:21,669
It's just that this
has a lot longer here

715
00:41:21,669 --> 00:41:22,710
and there's more of them.

716
00:41:26,430 --> 00:41:32,490
Well, if you look at
other day three pictures,

717
00:41:32,490 --> 00:41:36,010
let's just look
at that right now.

718
00:41:36,010 --> 00:41:37,495
Here's another
day three picture.

719
00:41:40,340 --> 00:41:42,840
Golgi is selective.

720
00:41:42,840 --> 00:41:46,120
Sometimes you're getting more
advanced cells, when you're

721
00:41:46,120 --> 00:41:47,970
looking at developing
animals, sometimes

722
00:41:47,970 --> 00:41:52,990
you're getting the
early developing cells.

723
00:41:52,990 --> 00:41:57,110
But you see on that same day,
perhaps later in the day,

724
00:41:57,110 --> 00:42:03,780
he was able to identify ventral
and dorsal roots forming.

725
00:42:03,780 --> 00:42:06,620
How did he do that?

726
00:42:06,620 --> 00:42:10,890
By recognizing something
that he was probably

727
00:42:10,890 --> 00:42:12,110
the first to recognize.

728
00:42:12,110 --> 00:42:14,346
And he named them.

729
00:42:14,346 --> 00:42:18,510
The active growing tips
that we call a growth cone,

730
00:42:18,510 --> 00:42:21,620
processes extending out.

731
00:42:21,620 --> 00:42:24,239
And when he saw
that happening here,

732
00:42:24,239 --> 00:42:25,780
and he looked at
them a little older,

733
00:42:25,780 --> 00:42:28,360
he would see the growth
cones further away.

734
00:42:28,360 --> 00:42:31,390
He could see that
an axon was growing,

735
00:42:31,390 --> 00:42:34,300
forming a ventral root.

736
00:42:34,300 --> 00:42:40,490
He started seeing that in
day three of the chick.

737
00:42:40,490 --> 00:42:45,620
He also saw growth cones begin
in the developing spinal cord.

738
00:42:45,620 --> 00:42:51,590
And here he saw some of those
cells of the neural crest that

739
00:42:51,590 --> 00:42:56,720
weren't in the CNS, he saw
them with two growth cones.

740
00:42:56,720 --> 00:42:59,180
One growing out
towards the periphery.

741
00:42:59,180 --> 00:43:06,187
Another one growing right
into the neural tube.

742
00:43:08,756 --> 00:43:11,280
And that was Cajal's work.

743
00:43:11,280 --> 00:43:16,720
So here I'm asking how
did neural scientists come

744
00:43:16,720 --> 00:43:20,660
to know that there at least two
major modes of cell migration

745
00:43:20,660 --> 00:43:23,550
in the embryonic [INAUDIBLE]?

746
00:43:23,550 --> 00:43:25,990
Here's what happened.

747
00:43:25,990 --> 00:43:28,390
I just described
nuclear translocation

748
00:43:28,390 --> 00:43:34,596
as a type of migration,
like this picture here.

749
00:43:34,596 --> 00:43:38,570
When these cells are moving like
this one, it's moved very far,

750
00:43:38,570 --> 00:43:40,950
it's moved way out
towards the pial surface.

751
00:43:40,950 --> 00:43:44,220
It never comes back because it's
not in the cell cycle anymore,

752
00:43:44,220 --> 00:43:46,470
yet we say it's migrated.

753
00:43:46,470 --> 00:43:50,314
And eventually it
loses its process.

754
00:43:50,314 --> 00:43:53,080
It usually uses both
of its attachments,

755
00:43:53,080 --> 00:43:55,710
to the pia on the one side and
to the ventricle on the other.

756
00:43:58,510 --> 00:44:02,325
That had been described,
had been seen by Cajal.

757
00:44:02,325 --> 00:44:05,930
It was described by Kent
Morest, who was at Harvard

758
00:44:05,930 --> 00:44:09,490
and then moved to the
University of Connecticut.

759
00:44:09,490 --> 00:44:14,090
And then a man named Pasko
Rakic, also at Harvard,

760
00:44:14,090 --> 00:44:17,736
but then he moved
to Yale, he worked

761
00:44:17,736 --> 00:44:19,110
on a different
part of the brain.

762
00:44:19,110 --> 00:44:20,820
He worked on primates.

763
00:44:20,820 --> 00:44:25,720
He discovered evidence
that in primates that

764
00:44:25,720 --> 00:44:28,050
is not how cells migrate.

765
00:44:28,050 --> 00:44:31,410
They attach to a glial
cell that was elongated.

766
00:44:31,410 --> 00:44:34,310
And they used the glial
cell sort of as a ladder,

767
00:44:34,310 --> 00:44:36,390
and they moved along it.

768
00:44:36,390 --> 00:44:39,111
So he said that's the way cells
from the central nervous system

769
00:44:39,111 --> 00:44:39,610
migrate.

770
00:44:39,610 --> 00:44:42,890
And there actually became a sort
of a conflict between these two

771
00:44:42,890 --> 00:44:43,665
views.

772
00:44:43,665 --> 00:44:45,430
Which was really silly.

773
00:44:45,430 --> 00:44:47,180
Because as you might
expect, both occur.

774
00:44:50,160 --> 00:44:54,280
And I want you to know how
that argument was settled.

775
00:44:57,090 --> 00:45:00,950
By proof that
nuclear translocation

776
00:45:00,950 --> 00:45:04,435
is not just in the spinal
cord, but right in the brain.

777
00:45:04,435 --> 00:45:07,910
It can be the major
mode of movement.

778
00:45:10,910 --> 00:45:13,030
Now we know there's other
kinds of cell movement

779
00:45:13,030 --> 00:45:14,945
too, among other
substrate factors.

780
00:45:14,945 --> 00:45:17,140
But we're just gonna
talk about this.

781
00:45:17,140 --> 00:45:20,320
And we'll talk more about
guidance by radial glial cells

782
00:45:20,320 --> 00:45:24,720
much later when we talk
about development of cortex.

783
00:45:24,720 --> 00:45:31,610
But let's talk about a study
by these two people, Morest

784
00:45:31,610 --> 00:45:35,065
and Valerie Domesick, who was
a student [INAUDIBLE] here

785
00:45:35,065 --> 00:45:39,240
at MIT that went to
work with Morest.

786
00:45:39,240 --> 00:45:43,010
This will be just
briefly the last topic.

787
00:45:43,010 --> 00:45:47,030
They were studying
a cell in the tectum

788
00:45:47,030 --> 00:45:48,660
that was very interesting.

789
00:45:48,660 --> 00:45:53,390
Because if you
look at the adult,

790
00:45:53,390 --> 00:45:55,430
you would see the
cell and its dendrites

791
00:45:55,430 --> 00:45:58,430
here near the surface
of the tectum.

792
00:45:58,430 --> 00:46:02,280
The initial part of this
axon had this peculiar bend

793
00:46:02,280 --> 00:46:05,490
that looks like the crook
in a shepherd's staff.

794
00:46:05,490 --> 00:46:09,340
So it was called the
Shepherd's Crook Cell.

795
00:46:09,340 --> 00:46:11,160
That was the name of it.

796
00:46:11,160 --> 00:46:13,720
They looked at earlier
and earlier periods.

797
00:46:13,720 --> 00:46:15,720
They kept seeing the crook.

798
00:46:15,720 --> 00:46:19,640
But they found the period
where the axon was just

799
00:46:19,640 --> 00:46:20,865
beginning to form.

800
00:46:20,865 --> 00:46:23,430
It had the peculiar bend.

801
00:46:23,430 --> 00:46:25,660
There's the growth cone.

802
00:46:25,660 --> 00:46:28,910
And then they saw
that at that stage

803
00:46:28,910 --> 00:46:32,812
the cell body was way down
here, near the ventricle.

804
00:46:32,812 --> 00:46:35,930
The cell body hadn't moved yet.

805
00:46:35,930 --> 00:46:37,590
It hadn't migrated.

806
00:46:37,590 --> 00:46:40,910
And yet the axon
was already forming.

807
00:46:40,910 --> 00:46:44,800
So you have to realize that
the cell extends all the way

808
00:46:44,800 --> 00:46:47,470
from ventricle to the
midbrain surface here.

809
00:46:47,470 --> 00:46:51,610
The axon is forming here, long
before the cell body is there.

810
00:46:51,610 --> 00:46:57,320
And then the cell body is
moving, as you see here.

811
00:46:57,320 --> 00:47:01,890
And finally it gets to the
point where the axon originates.

812
00:47:01,890 --> 00:47:06,390
They looked at many embryos
closely spaced in age

813
00:47:06,390 --> 00:47:08,990
and they saw all these changes.

814
00:47:08,990 --> 00:47:11,665
And they reported it at
the American Association

815
00:47:11,665 --> 00:47:14,380
of Anatomists
meeting, where a group

816
00:47:14,380 --> 00:47:22,780
called the Cajal Club met.

817
00:47:22,780 --> 00:47:25,740
It was a favorite meeting of
neuroanatomists at that time.

818
00:47:25,740 --> 00:47:28,450
It was before there was a
society for neuroscience.

819
00:47:28,450 --> 00:47:29,825
But their talk
was so convincing,

820
00:47:29,825 --> 00:47:31,110
and Rakic was there.

821
00:47:31,110 --> 00:47:32,970
He agreed afterwards,
OK, there's

822
00:47:32,970 --> 00:47:34,860
gotta be at least two
kinds of migration.

823
00:47:34,860 --> 00:47:36,325
Because I know
that that's not how

824
00:47:36,325 --> 00:47:39,200
it happens in the neocortex.

825
00:47:39,200 --> 00:47:42,737
So that's the story of how we
became more certain that there

826
00:47:42,737 --> 00:47:44,320
were two different
kinds of migration.

827
00:47:46,860 --> 00:47:49,195
So that's where we're
gonna stop today.

828
00:47:52,110 --> 00:47:55,610
We've already talked about this.

829
00:47:55,610 --> 00:47:58,320
I guess we've finished,
except for review.

830
00:47:58,320 --> 00:47:59,740
So I'll post these slides.

831
00:47:59,740 --> 00:48:01,430
You can go over them.

832
00:48:01,430 --> 00:48:05,380
And we'll be able to talk
about the next chapter

833
00:48:05,380 --> 00:48:08,630
about spinal cord on Friday.