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  • So now let's talk about the structure of DNA and the structure of RNA.

  • This would be RNA on one side. And this would be DNA on the other. The one thing that jumps

  • out is that RNA is a single helix. And DNA is a double helix. But if we look at the structure

  • of both of these, which are called nucleic acids, they're mostly made up of just three

  • parts. And so both of them have, let me get a color that works, both of them have a sugar.

  • In RNA that sugar is going to be ribose sugar. In DNA it's going to be deoxyribose sugar.

  • They then have a phosphate group. And then they have bases on the inside. And so if we

  • look at this would be RNA right here. On RNA you have a phosphate attached to a ribose

  • sugar attached to a phosphate attached to a ribose sugar attached to phosphate ribose

  • sugar phosphate ribose sugar. And so the backbone which on here would be this kind of greenish

  • part that goes down here, is simply a phosphate attached to a sugar attached to a phosphate

  • attached to a sugar. That's relatively boring. It's the same all the way down. Now if it's

  • DNA it's going to have a deoxyribose attached to a phosphate deoxyribose. And it's going

  • to be the same side on both sides of that backbone. What goes off the inside, attached

  • to the sugars is going to be the base or the nitrogenous base. And so in RNA, it's adenine,

  • guanine, uracil and cytosine. So you've got cytosine, guanine, adenine and uracil. If

  • you look at DNA the bases that we have are cytosine, guanine, adenine and thymine. And

  • so this is another difference between the two. In RNA it's going to be a uracil. In

  • DNA it's going to be thymine. But if you look at the structure of those two chemicals it's

  • almost identical. And so they serve the same purpose. DNA is simply a double helix. So

  • it's going to have bases on either side. And so if we have an A on this side, then we'll

  • have a T on the other side. Okay. Next I want to talk about DNA replication. When does DNA

  • have to replicate itself? Well every time a cell makes a copy of itself, in other words

  • every time you go from cell one and let's call that the zygote to two stem cells, we

  • have to duplicate the DNA inside there. In other words every cell in your body has the

  • same exact DNA as that first cell. And so how does DNA copy itself? Well Watson and

  • Crick actually suggested, since you have a double helix, and so this is the original

  • strand of DNA on this side. Since it's a double helix what you can simply do is unzip it in

  • the middle. If you unzip it in the middle then we can build a new strand on the this

  • side. A new strand on this side and now you have two strands of DNA. So we have one strand

  • of DNA to start. And then we have two strands of DNA when we're done. That one and that

  • one. Now the machinery of how it works is a little funky. You can only add new letters

  • on the 3 prime end. And so on one side the DNA polymerase which is an enzyme that simply

  • adds new bases or new nucleotides to the other side of the DNA, it'll run really smooth on

  • this side which is called the leading strand. On the other side it kind of has to back stitch

  • or work in the opposite direction. But essentially what you have is when you're done it's unzipped

  • and now we have two new strands of DNA. And they're identical to that first strand. And

  • so then that DNA is split into each of the cells as we go through the cell cycle. Next

  • I want to talk about central dogma. So after they figure out the structure of DNA, mostly

  • Francis Crick goes on and he actually coins this term the central dogma. He then wants

  • to figure out well, how does DNA actually make us? It's the secret of life how does

  • it actually make us? Well the central dogma explains how DNA makes RNA. And that process

  • is called transcription. RNA will then make proteins. The proteins make the phenotypes.

  • And the phenotypes eventually make you. And so the central dogma explains how we can go

  • from DNA to actually you. The first step is going to be called transcription. I always

  • remember the script means to write. And so what we have is we have our DNA. So this is

  • going to be our DNA right here. This is going to be a gene. So it's a portion that we actually

  • want to make a protein out of. There's an enzyme called RNA polymerase. So what RNA

  • polymerase, just like DNA polymerase is going to do, is it's going to drive down the DNA.

  • So RNA polymerase will drive down the DNA. And as it does that it make a copy behind

  • itself. And that copy is going to be messenger RNA. So if we go again, after RNA polymerase

  • is done and it leaves, we now have messenger RNA. And so we started with DNA. That's going

  • to be this double strand right here. But after RNA polymerase has gone by, we now have messenger

  • RNA. Or there's a message. Now the DNA right here will stay within the nucleus. And so

  • the DNA is protected. It's like the master code inside the nucleus. It will never leave

  • the nucleus. But the RNA is free to leave the nucleus. And actually make proteins. Or

  • make things. Okay. How does it make things? Well that RNA is going to move out into the

  • cytoplasm. So here's our RNA. It's this long stretch. And so what it'll do is it'll feed

  • through something called the ribosome. So this big big green structure is going to be

  • called a ribosome. Every three letters of the RNA is going to match on three letters

  • of a tRNA. That's what this is. It's a different type of RNA. It's called transfer RNA. And

  • that transfer RNA is going to bring in one amino acid. Amino acids are the building blocks

  • of proteins. And so what'll happen is that amino acid will attach on to the string of

  • all the other amino acids in this protein. And then everything shifts over. So now we'll

  • have the next one come in. And the next one come in. And the next one come in. And so

  • what do we do here? Well we're going from RNA. In this case it's the messenger RNA.

  • And what we're going to end up with right here is going to be a protein. Oops. Let me

  • right that more correctly. A protein is going to be what you're made up of. So when you

  • look at my hair or the keratin of the color of my eyes, those are all proteins. And the

  • proteins are actually made by the ribosomes and those are actually made in the cytoplasm.

  • So now we've gone from the message of the DNA to the message of the RNA. And now we've

  • translated that into a protein. So translation is moving the messenger RNA actually into

  • a protein. So what do the proteins create? Proteins eventually create phenotypes. And

  • so phenotypes are going to be what you physically look like. And so remember when we talked

  • about evolution, the peppered moth in general will look like this. It's going to be this

  • white appearance. But if you add one gene to that or one mutation, what you'll get is

  • this appearance. In other words just by changing the gene a little bit, we can get this huge

  • phenotype. That phenotype change is going to be the physical characteristic that you

  • have. And so this is how DNA and changes to the DNA will eventually create changes in

  • the messenger RNA. Which eventually create changes in the proteins. Which eventually

  • create changes in the phenotypes. So the phenotype is what you physically look like. So any kind

  • of a change in the DNA can have changes in our physical characteristic which then is

  • selected for or against in the environment. Now Richard Dawkins who writes a lot on the

  • idea of a selfish gene and how genes are actually the units that are actually being selected

  • for, has coined this term which I like. It's called the extended phenotype. In other words,

  • a beaver has a number of different phenotypes. It has a bunch of number of different physical

  • characteristics. Like the flattened tail. The big teeth. Tiny little arms. These are

  • all created by DNA. But what else do beaver's produce? Well they might produce a beaver

  • dam or a beaver lodge. Is that a phenotype? Is it actually made by genes? No. But it's

  • an extension of genes. In other words, does this allow a beaver to survive or not? For

  • sure it does. And so it's also going to be selected by natural selection as well. So

  • not only the physical characteristics that you have but that behavior that you have can

  • be selected for as well. Last thing I want to talk about is genetic engineering. And

  • so going way back to the Frederick Griffith experiment, what we found is bacteria can

  • actually share genetic information. They can share these little plasmids. And those plasmids

  • or that auxiliary DNA can actually give them a new trait, like the ability to be virulent

  • in the Fredrick Griffith experiment. But what scientists have figured out is since DNA is

  • interchangeable, since we can take DNA from a human, we can cut that out and we can insert

  • it into a bacteria, it'll work perfectly. And so what scientists have done is they've

  • actually inserted genes from humans into the plasmid of bacteria and the bacteria can make

  • copies. And they can actually make proteins. And so most all of the insulin that is made

  • today is made not by gathering it from animals or growing it in animals or using cadavers

  • was what they used to do. They're actually having bacteria, with the genes of the humans

  • inside it to grow the insulin. And they've actually figured out now that you can actually

  • insert the genes for insulin into safflower. And so we'll be able to grow proteins, human

  • proteins, in plants which makes it really really cost effective and available to all

  • the growing number of diabetics that we have today. So that's DNA. That's RNA. And I hope

  • that's helpful.

So now let's talk about the structure of DNA and the structure of RNA.

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B2 中高級

DNA和RNA--第二部分 (DNA and RNA - Part 2)

  • 105 15
    Cheng-Hong Liu 發佈於 2021 年 01 月 14 日
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