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If you had to think about the most exciting day you ever had in a science classroom, which
day would that be?
Now, looking back through the years---we have a few.
The time we participated in an earthworm dissection.
The time we took apart an owl pellet.
The osmosis eggs.
All of the fruit flies in genetic experiments.
Oh, I could go on, but I will never forget one day in my 9th grade science class.
My teacher brought in pond water.
And I put one drop of pond water on a microscope slide and saw the most amazing thing ever…I
saw, an amoeba.
A single celled amoeba on that microscope slide, and
I was forever stuck on science from that point on.
Because I could not believe this little cell was there, alive on this slide, still eating
because that’s what amoebas do a lot.
To imagine that every person is actually made of billions of cells---of course not amoeba
cells but animals cells--- billions of animal cells, that's fascinating.
In fact, it really makes you reflect on some of the incredible statements of the modern
cell theory.
The modern cell theory includes the following: First that the cell is the smallest living unit
in all organisms.
Second that all living things are made of cells.
One or more cells.
The amoeba I observed was a single-celled organism, so unicellular.
Humans are made of many cells, so multicellular.
And third, all cells come from other pre-existing cells.
Cells have their own little world inside them.
They carry genetic information!
They can divide!
Many have functions and processes that their organelles, structures inside them, can take
care of.
On our planet, we can divide cells into two major groups.
As a cell, you’re either a prokaryote or an eukaryote.
Bacteria and arachae are prokaryotes.
But everything else---plants, animals, fungi, protists----are eukaryotes.
Both prokaryotes and eukaryotes have genetic material.
Both have cytoplasm.
Both have ribosomes, which are small organelles that make proteins.
Both have cell membranes which control what goes in and out of the cell.
But what makes them different is a big deal.
Prokaryote---the "pro" rhymes with "no"---they have no nucleus which holds the genetic material
and controls the cell’s activities.
Prokaryotes have no membrane-bound organelles.
Membrane-bound organelles are fancy organelles like the nucleus and mitochondria and Golgi
apparatus.
Eukaryotes---the "eu" rhymes with "Do"----they do have membrane bound organelles.
So, now you may be wondering what do the organelles do---what are their functions?
Well you know our style---we love our science with a side of comics.
So, we want to take you on a tour of the ride of your life---into the inside of a cell!
To start our trip, we’re first going to have to get through this cell membrane, also
called a plasma membrane.
It’s selectively permeable which means that it only lets certain select materials in and
out.
By doing so, it keeps things in the cell stable---also known as keeping homeostasis.
We have an entire video on just the membrane
itself---which is found in all cells, but for now, we’re just going to have to squeeze
through this protein in the membrane.
Now, inside the cell, we find ourselves in this jelly-like material called cytoplasm.
It surrounds all of these internal cell structures, and you’ll find it inside both prokaryotes
and eukaryotes.
Now organelles that are floating around in the cytoplasm can have more support than
you might think.
Cells contain a cytoskeleton which is a collection of fibers that can provide support for the
cell and its organelles.
The cytoskeleton can even play a major role in cell movement.
The cytoskeleton actually deserves its own video because it is very complex---and
its organization can vary depending on what kind of cell you’re looking at.
Moving through this cytoplasm, let’s start with ribosomes.
They are NOT membrane-bound organelles and they are going to be in both prokaryotes and
eukaryotes.
They make protein,
which is really important because that’s what so much of genetic material---DNA codes
for---protein.
Ribosomes can be free in the cytoplasm,
but they can be attached to another organelle too, which we’ll talk about a bit later.
We are now going to focus on organelles, the membrane bound. So, we are going to be focussing on organelles that you would find in an
eukaryote cell.
This takes our travel to the big boss, the nucleus.
Now in eukaryotes, it holds the genetic material.
Genetic material as in DNA for example.
Both prokaryotes and eukaryotes have DNA but if you’re an eukaryote, you have a nucleus to put it in.
The nucleus controls the cell's activities and
inside it, it has a nucleolus, which is where ribosomes can be produced.
Attached to the membrane of the nucleus or nuclear membrane, you can find the endoplasmic
reticulum.
ER for short.
It does a lot of processing of molecules for the cell---like protein folding----and it
also is highly involved in actually transporting those molecules around.
Like a highway!
There is rough ER which has ribosomes attached to it, making it---as you can imagine---rough.
And them smooth ER which doesn’t have the ribosomes.
Rough ER specifically tends to be involved with protein producing and transporting, because
remember that ribosomes make protein.
Molecules that leave the ER can be sent away in vesicles that actually pinch off of the
ER themselves.
Now, smooth ER has many additional roles including detoxification, which is one reason why your
liver cells tend to have a lot of smooth ER.
Another additional role of smooth ER is that it can make some types of lipids.
Next, the Golgi apparatus.
It’s the ultimate packaging center.
It can receive items from the transport vesicles that pinched off the ER.
It has enzymes that can modify molecules it may receive and it sorts the materials it
receives as well.
It can determine where to send those molecules---including some that may eventually be sent to the membrane
so they can be secreted, which means, items that can sent out of the cell.
So, with all that’s going on in here, you might start to wonder…what’s powering
this thing?
The mighty mitochondria
or mitochondrion, if just talking about one.
They are like power plants!
The mitochondria make ATP energy in a process called cellular respiration.
It’s not a type of power plant that you might think of…it runs on glucose, which
is a sugar, and needs the presence of oxygen to efficiently make ATP energy.
Now at this point, we need to mention that eukaryotes are not a one-size-fits-all. Animal cells can have differences from plant cells.
We have a…fork in the road here.
For example, plant cells not only have mitochondria, but they also can have these awesome organelles
called chloroplasts.
Chloroplasts actually make glucose by using light energy in a process known as photosynthesis.
They tend to have a green look to them because they have a pigment that captures light energy
and reflects green light.
Now, both plant and animal cells can have vacuoles---now vacuoles can have a lot of different functions
but many types act as storage of materials.
Plant cells can have one large vacuole called a central vacuole while animal cells can have
several smaller vacuoles.
Remember how we already said that all cells have membranes? They do.
But plant cells additionally have a cell wall which is a layer that offers additional protection
and shape maintenance that animal cells do not.
Hmm now how do we get out of this animal cell that we’ve been in?
Well, we could get out like a protein would.
So, if we were a protein, we would only be made because of instructions from DNA and
remember that in eukaryotes, DNA is found in the nucleus.
We would be made by a ribosome.
The ribosomes could be attached to the rough ER.
And the rough ER highway would provide a vesicle to send us to the Golgi apparatus where
sorting can take place.
And…if we’re tagged for being secreted...we’re sent off through a vesicle from the Golgi to
the membrane.
And…out we go!
Just keep in mind that in our quick tour, there are still so many more awesome organelles
found in lots of different types of eukaryote cells to continue exploring, so to the Google for
more!
Well that’s it for the Amoeba Sisters and we remind you to stay curious!