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AP®︎/College Biology
Course: AP®︎/College Biology > Unit 2
Lesson 1: Cell structures and their functionsOrganelles in eukaryotic cells
Eukaryotic cells have membrane-bound organelles. The nucleus stores DNA. The endoplasmic reticulum and Golgi body are involved in protein maturation and transport. Mitochondria are where ATP is made. Chloroplasts carry out photosynthesis. Vacuoles are storage compartments that sequester waste and help maintain water balance. Lysosomes contain enzymes that help break down waste.
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Where does the word "Eukaryotic" and "Prokaryotic" come from?(2 votes)
'Pro' is a prefix which means primitive. 'Karyot' in the other hand means nucleus. That said, a Prokaryotic living is a creature which has primitive/unidentified nucleus. However, Eukaryotic means a creature which has an identifiable nucleus. I think these are from Greek, however I'm not so sure.(47 votes)
Why is there an "m" in RNA?(9 votes)
The 'm' in mRNA stands for messenger. So the full name is messenger Ribonucleic Acid.(26 votes)
At4:50Sal says "You gotta love these names in Biology", but they can't just randomly name the parts of a cell based off of like something their child said randomly when they were 2 years old. So how to scientists name these cell parts off of what do they name them? E.G. Golgi Bodies(6 votes)- Sometimes the honor of naming something goes to the scientist who discovers it. Cell parts often have names which describe their function or appearance.
For instance, when Robert Hooke discovered cells in 1665, he decided to use the term "cell" (which came from the Latin word cella meaning "small room").
The pathologist Camillo Golgi discovered what he called the "internal reticular apparatus" in 1897. Other scientists referred to it as the Golgi apparatus, however, and eventually the name stuck.
Golgi bodies are the only organelle named after a person!(24 votes)
Is the Golgi Body and Golgi apparatus the same?(8 votes)
Yes, they are the same. They are named after Camillo Golgi.(7 votes)
What does the smooth E.R. do, if the rough E.R. is responsible for protein synthesis?(4 votes)
The smooth E.R. makes lipids and it is also prominent in the liver because it gets rid of toxins. Hope that helped:).(12 votes)
I know that there are muscle cells, fat cells, blood cells and other types of cells in the body. Does every single cell have this same anatomy? Are there components that are present in every type of cell? If Sal's example cell is the prototypical cell that we memorize as students, can we identify what type of cell it is just based on the anatomy, or do we have to look at what DNA is present in the cell?(0 votes)
Not every cell has the same anatomy. Two examples of this are red blood cells and muscle cells. Red blood cells eject all of their organelles when they mature so that they be more flexible when travelling through narrow spaces like capillaries. Meanwhile, muscle cells are so unusual that specialized terminology was created just to name the parts of it.
For the purposes of identification, looking at the cell's form would usually be enough to identify the cell. Because form follows function, a cell would be shaped as such to carry out a certain job. For instance, take a heart muscle cell and compare it to a neuron. Heart muscle cells, on one hand, have much more mitochondria that the average cell, and has units that allow them to contract. The heart muscle cell needs these to beat without becoming fatigued. On the other hand, a neuron is unable to contract and does not have many mitochondria, but is long and branched to allow for communication.
Does this help?(12 votes)
At2:09I thought the rough ER were connected to the perinuclear space, not the nuclear pores?(3 votes)- I think you are correct that it isn't connected to the pores. I found this image showing that the ER lumen is continuous with the perinuclear space, but it's not shown connected to the nuclear pore.
https://www.cell.com/current-biology/comments/S0960-9822(06)02669-8
Since you spotted it, you could let Sal know by pointing out the mistake in the tips&thanks tab, then a correction can be made for the next students to see. (click in the box as if you are writing a tip, and underneath an option will appear to report a mistake)(4 votes)
How come a plant has chloroplast (an organelle that contains chlorophyll which makes plants green) and is still a different colour. For example, an apple has millions and millions of plant cells which have billions of chloroplast but still is red?(1 vote)
Not all plant cells have to contain chloroplasts, but apple fruit does a bit and photosynthesizes especially when it's unripe and green. Then I think some apples ripen to red as their chlorophyll lessens and other pigments increase. However, potatoes, for example, don't have chloroplasts in them because they exist to store starch while the potato plant's leaves photosynthesize.(4 votes)
- Is it pronounced R-eye-bosomes or ribosomes?(3 votes)
- At2:05and later, sal said that the endoplasmic reticulum is connected to the pores in the nuclear membrane. But in literally any other source, it would be that the endoplasmic reticulum is connected to the outer nuclear membrane. The double nuclear membrane isnt even mentioned here. Why?(3 votes)
4:50Video transcript
- [Instructor] What we're
going to do in this video is give ourselves a little bit of a tour of eukaryotic cells. And the first place to start is just to remind ourselves what it means for a cell to be eukaryotic. It means that inside the cell, there are membrane-bound organelles. Now, what does that mean? Well, you could view it as
sub-compartments within the cell. Membrane-bound organelles. And in this video in particular, we're going to highlight some of these membrane-bound organelles that make the cells eukaryotic. So let's just start with
some of the ingredients that we know is true of all cells. So you'll have your
cellular membrane here. I drew it big, so that
we have a lot of space to draw things in. So this is our cellular membrane. I'll do some nice shading so you appreciate that it'll
actually be three-dimensional. We see so many slices of cells that sometimes we forget
that they are more spherical, or that they have
three-dimensional shape to them. They're not all spherical. They can have different shapes. Now all cells, and there
are some exceptions that we've talked about
in previous videos. I should say, most cells will have some genetic information in them in the form of DNA. So that is our DNA, right over there. Now, one of the key characteristics
of a eukaryotic cell is that the genetic information is going to be inside a
membrane-bound organelle. And that membrane-bound organelle, or the membrane that
surrounds the DNA here, that is the nuclear membrane. So let me draw the nuclear
membrane right over here, and I'll put some shading
in to appreciate that that also is going to be in three
dimensions, around the DNA. So that is the first
membrane-bound organelle that we're gonna discuss, the nucleus. Now the nucleus, it turns out, is connected to another
membrane-bound organelle. And we're gonna study
this in future videos, but right here I'm drawing holes or pores in the nuclear membrane. And those pores connect to something, it's a very fancy word called
the endoplasmic reticulum. And the endoplasmic reticulum is essentially these
layers of these membranes. So I'm gonna do my best job at trying to draw an
endoplasmic reticulum. Imagine extending from these pores, going into a space that has
really these layered membranes that have a lot of surface area. And I'm not gonna go all
the way around this nucleus, but in many cells it will go around, all the way around the nucleus. And this right over here, and
this is just a rough diagram. That is our endoplasmic, endoplasmic... Not blasmic, endoplasmic... Endoplasmic reticulum, which I've mentioned in previous videos would be an excellent name for a band. And what goes on in the
endoplasmic reticulum is when you are in the process of taking that genetic
information from DNA, and as we talk about in other videos it gets transcribed into mRNA. So that mRNA is now
containing that information. That mRNA will make its way
out of that nuclear membrane through one of these pores, and then make its way to a ribosome that is attached to the membrane of the endoplasmic reticulum. And so that's a ribosome there. I'm gonna do a bunch of ribosomes. And so as we've talked
about in previous videos, ribosomes are really where you take that genetic information from that mRNA, and then you translate it into a protein. So the ribosomes are
the protein synthesis, so let me label that. So this right over here is a ribosome. And some ribosomes might be attached to the
endoplasmic reticulum. Some of them might just be floating out here in the cytoplasm, so that would be a free ribosome. Free ribosome. And even from the point of view of the endoplasmic reticulum, the parts of the endoplasmic reticulum where you have ribosomes attached, this is known as rough
endoplasmic reticulum. It's the ribosomes that
are making them rough. It looks that way in a microscope. So I'll just say rough ER, for endoplasmic reticulum for short. And then you also have parts
of the endoplasmic reticulum where you do not have ribosomes attached. And because that looks smooth
through our microscope, it has been called, you can imagine, smooth endoplasmic reticulum. There are things known as golgi bodies. Once again, another fascinating name. You gotta love these names in biology. That look kind of like
an endoplasmic reticulum, but detached from the nuclear membrane. So let's say it's something like that. That's my best drawing there. That's a golgi body. And these are really good
at packaging molecules, even proteins that might've
just been produced, and packaging them so
that they can be used outside of the cell, for example. And we'll go into detail in other videos, where a protein might
go to the golgi body, get a little envelope around it, get some little processing going on, and then make its way outside of a cell. Now another, and this is maybe one of the most famous membrane-bound organelles
outside of the nucleus, is what's known as the
powerhouse of the cell, and that is the mitochondria. So I'll draw this mitochondria in magenta, because that's a nice powerful color. So mitochondria. And I love mitochondria because it's fascinating
how they even came to be. Mitochondria actually have their own DNA, and all of your mitochondrial
DNA comes from your mother. So that's actually very interesting for tracing maternal lineage. But mitochondria, this is where your, I'm gonna say let's see what
we could see inside of this. This is where you ATP is produced. This is your mitochondria. It's really the powerhouse of the cell. What's interesting about mitochondria is evolutionary biologists believe that the ancestors of mitochondria, because mitochondria have their own DNA, they might've been independent
organisms, independent cells. And at some point in
our evolutionary past, they started living in symbiosis inside of what would be
the ancestors of our cells. And over time, they became so codependent that they started to replicate together. And mitochondria, in fact, became part of these eukaryotic cells. Now if this eukaryotic
cell was a plant cell or maybe an algae cell, you would have something
called chloroplasts there. We don't have them because
we don't have photosynthesis, but this is a chloroplast. And if you could see inside, you could see the little
thylakoid stacks right over here. You could see the thylakoids
if you could see inside. And so this right over
here is a chloroplast. Chloroplast. And this would be plants and algae. Animals do not have these. And these are where you have
your photosynthesis take place. Photosynthesis. Now there's also some
membrane-bound organelles that are maybe less famous
than the mitochondria or the chloroplast, or
for sure the nucleus, and that might be
something like a vacuole. And in plants, vacuoles
tend to be very big. I could draw it, this is three-dimensional so I'll draw it on top of
something that I've drawn before. So if a vacuole right
over here, this is a... And in a plant it could be a fairly
significant compartment inside. And in fact, it can even give
structure to the plant itself because it is so big. And it contains water and enzymes. It's viewed as kind of
a storage compartment. But it can also contain enzymes
that help digest things, that help break things down so that they can be used in some way. So that is a vacuole. And they don't just exist in plants. They can also exist in animal cells. But in plant cells, they can
be very, very, very visible. Now, something that is somewhat related to some of the function
that a vacuole plays, that are most associated with animal cells but now there's evidence that they also exist in plant cells, is the idea of a lysosome. So a lysosome right over here, that also is a compartment. And it's going to contain a
whole series of enzymes in it that is useful for lysing, you could say, that is useful for breaking down either waste products as the cell lives, or even foreign substances that might not be helpful for the cells. So it's gonna contain a bunch of enzymes, and it helps break down things. Now, I'll leave you there. These aren't all of the
structures in eukaryotic cells, but these are enough of the structures so that you can appreciate that there are a lot of
membrane-bound organelles in eukaryotic cells. And to be clear, even if I were to show all of the membrane-bound structures, that's not all the complexity of the cell. The big thing to appreciate is that cells are incredibly complex. There's all sorts of structures in here that help transport things
and move things around. If you could shrink yourself
down and look inside of a cell, it would look more complex
than the most complex cities. There's all sorts of activities, things being moved
around, shuttled around. The cell itself is replicating
and copying things. And so this is just the beginning. We're just starting to scratch the surface of the complexity of the
most basic unit of life.