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  • DNA. We talk about it so much---it is the ultimate director for cells and it codes for

  • your traits. It’s a major component of what makes you, you. When you have a really important

  • molecule like DNA that is ultimately responsible for controlling the cellit would make sense

  • that when you make another cell (like in mitosis), you would also have to get more DNA into that

  • cell. And that introduces our topic of DNA replication, which means, making more DNA.

  • First let’s talk about where and when.First where---it occurs in the nucleus. If the cell

  • has a nucleus. Remember, not all cells have a nucleus. This video clip is actually going

  • to focus on the types of cells that do have a nucleus though known as eukaryote cells.

  • Prokaryotes, which are cells that lack a nucleus, do things a little differently. Next When

  • does this happen---this typically happens during a stage known as interphase. Interphase

  • is when a cell’s growing, it’s carrying out cell processes, and it’s replicating

  • its DNA. You know what it’s not doing at the exact same time? Dividing. You don’t

  • want a cell to be replicating DNA and dividing at the exact same time. That’s a little

  • bit too much multitasking. So DNA replication does not happen during cell division (aka

  • mitosis). In fact, the cell replicates its DNA before division processes like mitosis

  • and meiosis. Because once you make that new cell, you better have DNA to put in there.

  • I think DNA replication would actually make a great video game. It’s actually quite

  • exciting. I’m going to introduce the key players in DNA replication so that you can

  • get some background information. The majority of these key players that I’m going to introduce

  • are enzymes. In biology, when you see something end inase, you might want to check as

  • it is very possible that it’s an enzyme. Enzymes have the ability to speed up reactions

  • and build up or break down the items that they act on. So here we go with the key players.

  • Helicase- the unzipping enzyme. If you recall that DNA has 2 strands, you can think of helicase

  • unzipping the two strands of DNA. Helicase doesn’t have a hard time doing that. The

  • hydrogen bonds that hold the DNA strands together is pretty weak compared to other kinds of

  • bonds. DNA Polymerase- the builder. This enzyme replicates DNA molecules to actually build

  • a new strand of DNA. Primase- The initializer. With as great as DNA polymerase is, poor DNA

  • polymerase can’t figure out where to get started without something called a primer.

  • Primase makes the primer so that DNA polymerase can figure out where to go to start to work.

  • You know what’s kind of interesting about the primer it makes? It’s actually a piece

  • of RNA. Ligase- the gluer. It helps glue DNA fragments together. More about why you would

  • need that later. Don’t feel overwhelmed. Well go over the sequence in order. Please

  • keep in mind, that like all of our videos, we tend to give the big picture but there

  • are always more details to every biological process. There is more involved than what

  • we cover. DNA replication starts at a certain part called the origin. Usually this part

  • is identified by certain DNA sequences. There can be multiple origins within the DNA strand.

  • At the origin, helicase (the unzipping enzyme) comes in and unwinds the DNA.

  • SSB proteins (which stands for single stranded binding proteins) bind to the DNA strands to keep

  • them separated. Primase comes in and makes RNA primers on both strands. This is really

  • important because otherwise DNA polymerase won’t know where to start.

  • Now comes DNA Polymerase. Remember, it’s the important enzyme that adds DNA bases.

  • Now you have 2 strands right? But theyre not identical.Remember they complement each other. They

  • also are anti-parallel so they don’t really go in the same direction.

  • With DNA, we don't say it goes North or South. The directions for the DNA strands are a little different.

  • We say that DNA either goes 5’ to 3’ or 3’ to 5’. What in the world does that

  • mean? Well the sugar of DNA is part of the backbone of DNA. It has carbons. The carbons

  • on the sugar are numbered right after the oxygen in a clockwise direction. 1’, 2’

  • 3’, 4’ and 5.’ The 5’ carbon is actually outside of this ring structure. Now you do

  • the same thing for the other side but keep in mind this strand is flipped just because

  • DNA strands are anti-parallel to each other. So let’s count these---again, clockwise

  • after the oxygen. 1’, 2’ 3’, 4’ 5’. And the 5’ is out of this ring. This strand

  • on the left runs 5’ to 3’ and the strand on the right here runs 3’ to 5’. Well,

  • it turns out that DNA polymerase can only works in the 5’ to 3’ direction. Sothe

  • strand that runs 5’ to 3’ is fine. It is called the leading strand. But the other

  • strand will make it a little tricky. DNA polymerase can only go in the 5’ to 3’ direction.

  • (NOTE: Reads in 3' to 5' direction). Primase has to set a lot of extra primers down to

  • do that as shown here. It takes longer too. This strand is called the lagging strand which

  • is pretty fitting.On the lagging strand, you tend to get little fragments of synthesized

  • DNA. These are called Okazaki fragments. Okazaki. What an amazing name. The primers have to

  • get replaced with DNA bases since the primers were made of RNA. Ligase, the gluing enzyme

  • as I like to nickname it, has to take care of the gaps in the Okazaki fragments.Now at

  • the end, you have two identical double helix DNA molecules from your one original double

  • helix DNA molecule. We call it semi-conservative because the two copies each contain one old

  • original strand and one newly made one. One last thing. Surely you have had to proofread

  • your work before to catch errors? Well, you definitely don’t want DNA polymerase to

  • make errors. If it matches the wrong DNA bases, then you could have an incorrectly coded genewhich

  • could ultimately end up in an incorrect protein---or no protein. DNA polymerase is just awesomeit

  • has proofreading ability. Meaning, it so rarely makes a mistake. Which is very good. That’s

  • it for the amoeba sisters and we remind you to stay curious!

  • Follow us on Twitter (@amoebasisters) and Facebook!

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DNA複製:細胞的極限團隊運動細胞的極限團隊運動 (DNA Replication: The Cell's Extreme Team Sport)

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    Amy.Lin 發佈於 2021 年 01 月 14 日
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