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High school biology - NGSS
Course: High school biology - NGSS > Unit 2
Lesson 1: Cell division and organism growthCell division and organism growth
In multicellular organisms individual cells grow and then divide via a process called mitosis, thereby allowing the organism to grow. The organism begins as a single cell (fertilized egg) that divides successively to produce many cells, with each parent cell passing identical genetic material (two variants of each chromosome pair) to both daughter cells. Cellular division and differentiation produce and maintain a complex organism, composed of systems of tissues and organs that work together to meet the needs of the whole organism. Created by Sal Khan.
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I love how he described himself as a "handsome organism."(9 votes)
I don't really understand what are homologous pairs and sister chromatids. Can anyone help me?(4 votes)
Homologous pairs are basically just pairs of two different chromosomes which have the same genetic functions, but are two different variations of the same genetic code. For instance, two homologuous chromosomes both can be relevant to deciding your hair color. One would say your hair should be brown, the other says it should be blond. Both of them are correlated to hair genes.
Sister chromatids are two long strands of chromatin which are completely identical. That's because one chromatid is a replica of the other. The process of replication occurs when preparing for mitosis.(9 votes)
Do cells continue to multiply in our body after we are fully grown?(4 votes)
Some of them do. We don't keep getting taller or anything, but some cells like skin cells always reproduce. And cells reproduce when they heal, like when you break a bone or get a cut.(5 votes)
At the end of the video, the last image of the two cells right next to each other they have those spindle arms still left connecting the two do these gradually get cut off and separate the cells?(4 votes)
Apparently, the spindle arms of the mitotic cell do separate and break down to allow the cells to divide. Source: https://courses.lumenlearning.com/wm-nmbiology1/the-steps-of-mitosis/. If I'm wrong about anything, please notify. Thank you!(3 votes)
A truly "handsome organism."(4 votes)
Wait, so what happens if the mitosis process just goes wrong some how and the body produces wayyy too many cells? Like a tumor would be created from too many dead cells, but what if your body started to create an over abundance of living/operating cells?(2 votes)
It's really hard to say, but I'm sure that it would probably result in a growth spurt.(3 votes)
- Homologous pairs are basically just pairs of two different chromosomes which have the same genetic functions, but are two different variations of the same genetic code. For instance, two homologuous chromosomes both can be relevant to deciding your hair color. One would say your hair should be brown, the other says it should be blond. Both of them are correlated to hair genes.(3 votes)
- if the cells in the vid are not human cells, then what are they?(2 votes)
The Apply: cell division and organism growth lesson still doesn’t make much sense. Could someone help me out?(1 vote)
Video transcript
- [Lecturer] In this
video, we're gonna talk about cell division and organism growth. Or another way to think about it is, how do we start with fertilization? And we talk about this in other videos, but in sexually reproducing species, each individual starts off as a cell that is the result of the fusion between a sperm and an
egg, between two gametes. And each of these gametes have half of the genetic material
needed to make that organism. So once they fuse, once the
fertilization has happened, you are now diploid. So you're haploid when you have half of the genetic material, as
each of these individually have each of these gametes, and then you become
diploid once it's fused. Well, once it's fused, that fertilized egg will then start to divide and replicate. And so a short period of time later, you might have eight cells
that has divided in two, it'll first divide into two, then those two will become four, those four will become eight,
the eight will become 16, and you keep dividing,
and before you know it, you have trillions of cells on the order of 30 to 40 trillion and you could create this
very handsome organism right over here. But an interesting question is, how does that division happen? And are the cells identical? Do they have the same
identical genetic material? But if they are, how do they differentiate into all of the different types of cells that make this handsome organism? The skin cells versus the heart cells versus the nerve cells? And this process of cell division in which a parent cell divides
into two new daughter cells, each of which is genetically
identical to the parent cell, is known as mitosis. And so let's dig into
mitosis a little bit. So let's start with two daughter cells from a previous round of mitosis. Now, this would not be a human cell. What we're looking at is four
chromosomes in two pairs. And the way that they've color-coded it, two of these are blue
and two of these are red. While a human cell would have
23 pairs or 46 chromosomes, but this is a eukaryotic cell. The genetic material is inside of the nucleus right over here. And just to understand what
these long strands are, these are chromosomes in
their non-condensed form. And a chromosome you can really view as a long strand of DNA, and you're going to have
segments of that DNA that code for specific proteins, and those segments are what we call genes. In a given chromosome pair, you will code for the same genes, but you might have different
versions of the same gene. Maybe this gene right over here contributes to hair color in some way, and then this other one
contributes in the same way, but it might lead to a
different hair color. So each of these chromosomes in a pair, we call them homologous
or homologous pairs. They're coding for the same genes. They're the same set of genes, but they might have different versions of those genes or different alleles. So that's what we're seeing here. Now to prepare for mitosis,
what we need to see is each of these chromosomes
need to replicate, and once they do, the
cell might look like this. Now it's hard to see it here, but the two copies that are now replicated and connected at the center,
we call them sister chromatids. And we can see that a little bit clearer in the early phases of mitosis. So first, we see that the chromosomes have condensed into what
we classically imagine as chromosomes when we look
at it into a microscope. This is really happening
in preparation for mitosis, in preparation for cell division. And so you see those two homologous pairs, and you can see each of those chromosomes actually now consists of
two sister chromatids, one over here, one over there. As we go through mitosis, they're going to separate
into individual chromosomes that are actually just
copies of each other. Now, the other thing that we're seeing in this early phase of mitosis is that the nuclear envelope
starts to break down, and we're gonna see why that's important, because we're gonna have to
separate the chromosomes. Now, the other thing that we see, and in other future biology classes you'll go into much more detail, is the mitotic spindle
is starting to form. Now, we don't have to
go into all the details of the different parts
of the mitotic spindle, but imagine a bunch of structures
made primarily by protein that are actually going to act to allow the mitosis to happen,
to grab the chromosomes, to pull them apart, to allow
the cell to change its shape so that it will eventually
be able to divide. But after that, we go into
the middle phase of mitosis. So as we enter into the
middle phases of mitosis, we can see now that the chromosomes are aligned at the center, and they've actually now been attached to the mitotic spindle, which
is going to be important, because that's the machinery
that's going to pull them apart and bring them to the
different sides of the cell. And as we continue through
the middle phases of mitosis, we see that right over there, that those sister chromatids
are now pulled apart and they are copies of each other. They became copies of
each other back here, where the DNA originally replicated when it wasn't in its condensed form. But I think you see where this is going. As the mitotic spindle
pulls on these chromosomes, we then enter into the
late phases of mitosis. And you can see here that
the sister chromatids, which are now individual chromosomes, have been pulled to either side
of that now elongated cell. You can see that once they're there, a nuclear envelope begins to
form again on either side, and then the mitotic spindle breaks down and the splitting of the cytoplasm finally into two daughter cells
is known as cytokinesis. So it's pretty mind boggling to realize that this is going on in
your body continuously, and this is what allowed
all of us to start as a single-celled
organism, a fertilized egg, and become an organism made
of tens of trillions of cells. Now, I haven't gone into detail yet. Even though the great
majority of our cells have the exact same genetics, they are actually able to differentiate, express different parts of the genetics based on the roles that they need to play, but we will talk about
that in future videos. It's also important to realize that mitosis isn't just
about growing an organism. It's also about maintaining an organism and doing tissue repair for an organism. So I'll leave you there. Look at your hands, look at your arms, look in the mirror and just realize that you are an organism
of 30 to 40 trillion cells that all started with one cell through many, many,
many rounds of mitosis.