Video transcript
- [Voiceover] You've probably
heard of stem cells by now. You probably know that
every cell in our body, whether it's a muscle cell or a nerve cell or a skin cell or a red blood cell, or any other type of cell really, they all came from a common group of stem cells during development. All of these really,
really specialized cells like this muscle cell here with its little contractile proteins, and this nerve cell here
that can send signals, and this waterproof skin cell here, and this red blood cell
that carries our oxygen, all of these came from
these stem cells up here, which were completely unspecialized. How does something like this happen? It's actually pretty interesting. Let me first give you an analogy here. Just imagine a library, right, like the one you used to go to when you were a teenager
or something like that, and the one that you
hopefully still go to. It has all the books
you can imagine, right, but depending on which books you borrow and which books you read, you are changed. You end up knowing a totally
different subset of stuff compared to someone who read different books than you, right? But all the books that you both read are still in this one library. There's actually a really similar system with our genes and with our DNA. Recall that inside the nucleus
of each cell is your DNA. This is our library, this is
our set of genetic instructions for building our entire body. Within our DNA library
here we have our books, which are segments of our
DNA that we call genes. Genes give our cells specific instructions on how to make different
kinds of proteins. Having different proteins around, that changes the way our cells look and it changes the way our cells act so it gives our cells
really different abilities. What I mean with the exception of the red blood cells which lack nucleii, every single somatic cell in your body contains the exact same DNA. Yet this muscle cell here, right, it looks and it acts
differently to this neuron here. That's because they're each reading different books in our DNA library. They're using different
genes to make their proteins. Just a bit of terminology here, when a cell is actively
using certain genes, it's said to be expressing those genes. A gene being expressed
is said to be turned on, and one not being expressed is turned off, so just keep that in mind. Why am I telling you all of this? Because in the end it all relates to how our stem cells all the way up here end up differentiating into our
specialized cells down here. The bottom line is in
order to differentiate to, for example, specialize
into our muscle cell here, this stem cell up here turned
on its muscle cell genes. Here's its DNA and I'm
highlighting its muscle cell genes that it turned on right now. It also turned off some other genes. By turning on its muscle cell genes, now proteins get made within the cell that changes how the cell looks. See now it's a bit elongated, right, this muscle cell here. It also changes its functions. Now our muscle cell has
contractile proteins in it to help it be a nice useful muscle cell to help us move around, right? Now our neuron here,
our stem cell turned on its become-a-neuron genes here, right? It turned off some other ones, and then the cell started producing all the proteins it needed
to turn into a neuron. Like the proteins that would
make it elongate like this and grow out these little
spiky things up here called dendrites, okay? Let me also say that remember our stem cell up here was pluripotent. It could turn into any of
our somatic adult body cells. But once it's specialized
into these mature cell types, these can't go on to
differentiate into other cells. They actually can't
de-differentiate either. They can't go backwards up
to stem cells naturally, at least in us humans. So these cells stick
around to form our bodies. By now you must be wondering what determines what
genes in the given cell are turned on or off? In other words, how the
heck does this cell know it's time to specialize
into a different cell type? It turns out that cells decide what they're going to grow up to be based on cues they get. These cues can be from
their internal environment or their cues can come from
their external environment, their outside environment. Let me just show you two major ways this can happen here, these cues. In the development of lots
of different organisms, us humans included, we start out with one
cell, right, the zygote. Our zygote has these little proteins called transcription
factors floating around in its cytoplasm. Also the precursors of
these transcription factors are there too, little bits of MRNA. Two things to note. First, transcription factors
will activate certain genes and turn them on. That's what transcription factors do. Second, notice that all these
little transcription factors are clustered around in one area. This is important because when
the zygote starts to divide, where do all these
transcription factors end up? Like you see here, they
only end up in the cells that divided off in that original region where they all were
clustered around, right? So these cells up here don't
have any or don't have much, and these cells down here have a whole heap of transcription factors. Now you can imagine that different genes will get activated in
these different cells. That'll determine what each of
these cells specializes into because now they're gonna
make different proteins. This mechanism here is
pretty appropriately called asymmetric segregation
of cellular determinants. It's this big mouthful here
but if we break it down here, you can see asymmetric because
it really just refers to how these transcription factors are not symmetrically distributed among the daughter cells here. This cellular determinants
bit is just referring to the transcription
factors or their precursors. That's one way that cells can be made to specialize into different things, just having different
transcription factors around. But the second way to
specialization that I'll mention is called inductive
signaling or just induction. Induction is kind of like
really strong encouragement, almost like peer pressure, where one cell or actually
usually a group of cells can induce another group
of cells to differentiate by just using some signals. The signals could be
passed a few different ways so they could be passed by diffusion. They could be released from one group and just diffused over to the other group where they'll bind receptors
on the other groups and cause the cells over
there to differentiate. Or the induction could be done by direct contact between cells, right? You can see these little surface proteins on each of these cells binding each other. That's direct contact. Or you could have signals
passed through gap junctions, which are little connections, or actually I should say connexons between cells that are connected and that could induce
the cell to specialize, this cell over here. I called this a connexon
because in cellular biology, these proteins that make
up part of a gap junction are collectively called a connexon. Anyway, induction is absolutely key in forming lots of our body parts, like our limbs are formed by
partially through induction. Our ears and our eyes and
lots more of our body parts are formed through
induction in development, in embryological development. So induction is really important
in cell specialization. On that note, I'll just remind
you remember the goal here with the cytoplasmic determinants, those transcription factors
I talked about earlier and then all these signals
that you get in induction, remember the goal is to get cells to change their gene expression, right? To flick on or flick off certain genes, which ultimately is what
causes cells to differentiate into other more specialized cells.