Cell Biology | DNA Replication 🧬
Ringkasan
TLDRThis video by Ninja Nerds thoroughly explains the process of DNA replication, detailing the stages: initiation, elongation, and termination. The speaker emphasizes the replication's purpose—cellular replication—and elaborates on critical aspects like the semi-conservative nature of DNA replication where each new double-stranded DNA includes one old and one new strand. Key enzymes such as helicase, which unwinds the DNA, allowing replication machinery to function, and DNA polymerase, responsible for synthesizing the new DNA, are discussed. The lecture also covers the directionality of replication (5' to 3') and the crucial roles of RNA primer, Okazaki fragments on lagging strands, and telomeres, which protect chromosome ends from shrinking excessively. Additionally, the video touches on the clinical significance of topoisomerases as targets for cancer drugs and the role of telomerase in extending telomeres, paving the way for potential cancer cell immortality. This comprehensive guide on DNA replication ends with discussions on the implications of this fundamental biological process in cancer and therapy.
Takeaways
- 📚 DNA replication is essential for cell division.
- 🔄 It follows a semi-conservative model, ensuring genetic continuity.
- 🧬 Primarily occurs in the S phase of the cell cycle.
- 🧭 DNA replication proceeds in a 5' to 3' direction.
- 🔗 Okazaki fragments are essential for lagging strand synthesis.
- 🔄 Telomeres protect chromosome ends from shortening.
- ⚙️ Helicase unwinds DNA at replication forks.
- 🛡️ Topoisomerases prevent DNA supercoiling issues.
- 💡 DNA polymerase proofreads to ensure fidelity.
- 🔬 Telomerase counteracts telomere shortening in some cells.
- 🧴 Cancer cells may exploit telomerase to maintain immortality.
Garis waktu
- 00:00:00 - 00:05:00
The video begins with an introduction to DNA replication. The purpose of DNA replication is to allow cells to replicate and create more cells. In the cell cycle, DNA replication primarily occurs during the S phase, enabling the duplication of genetic material. It's explained that each cell begins as one, goes through phases, and results in two cells with replicated DNA. The concept of cell replication involves making identical daughter cells from one parent cell. Additionally, DNA replication is described as a semi-conservative process where old strands of DNA serve as templates for new strands, ensuring genetic stability.
- 00:05:00 - 00:10:00
In this section, the focus is on the direction of DNA replication, which always occurs from the 5' end to the 3' end, critical for nucleotide addition. The instructor emphasizes the anti-parallel nature of DNA strands, detailing how DNA polymerases synthesize new strands in this directional flow. DNA replication is also bi-directional, occurring simultaneously at multiple points along the DNA to ensure efficient duplication. Replication begins at origins of replication, characterized by adenine-thymine-rich areas, making the process more efficient due to fewer hydrogen bonds.
- 00:10:00 - 00:15:00
DNA replication unfolds through three stages: initiation, elongation, and termination. During initiation, specific regions called origins of replication are targeted, often adenine-thymine-rich areas, due to their weak hydrogen bonding. The pre-replication protein complex separates these strands. Single-stranded binding proteins stabilize unwound DNA, preventing re-annealing and protecting against nucleases. Helicase enzymes unwind the DNA at replication forks, consuming ATP. This initial stage sets the platform for further replication processes by creating conditions for subsequent enzymatic actions.
- 00:15:00 - 00:20:00
The role of topoisomerases in alleviating supercoiling caused by helicase activity is elaborated. These enzymes, particularly types 1, 2, and 4, perform functions crucial for relaxing DNA, cutting and re-ligating strands to manage tension. Topoisomerases can be targeted by specific drugs to prevent DNA replication in cancer and bacterial cells, highlighting their clinical significance. Certain drugs inhibit topoisomerases by increasing nuclease activity or preventing ligase action, causing DNA fragmentation and inhibiting replication, useful in cancer treatment and bacterial infections.
- 00:20:00 - 00:25:00
Primase enzyme activity marks the start of elongation by laying down RNA primers, which DNA polymerase III extends. DNA polymerase III synthesizes new DNA strands from the 5' to 3' direction, requiring an RNA primer's 3' OH group for attachment. The leading strand synthesis is continuous, whereas the lagging strand forms Okazaki fragments due to its discontinuous nature, requiring multiple RNA primers. This distinct replication strategy ensures both strands are efficiently copied despite their anti-parallel orientation.
- 00:25:00 - 00:30:00
The removal and replacement of RNA primers with DNA involve DNA polymerase I, which also uses 5' to 3' exonuclease activity. After primer removal, DNA polymerase I synthesizes DNA to fill the gaps and uses a proofreading mechanism to ensure accuracy. On the lagging strand, where gaps remain between DNA segments, ligase enzymes fuse these sections to create a continuous double strand. This detailed enzymatic coordination guarantees that the newly formed DNA strands are complete and fully synthesized.
- 00:30:00 - 00:35:00
Proofreading and error-checking during DNA synthesis are crucial, with DNA polymerase III employing 3' to 5' exonuclease activity to correct mismatches, enhancing replication fidelity. Once synthesis is complete, DNA polymerase I excises RNA primers, replacing them with DNA nucleotides and also performs proofreading. These steps underline a meticulous quality control process inherent in DNA replication, ensuring genetic accuracy and integrity across replication cycles.
- 00:35:00 - 00:40:00
The video details the significance of topoisomerases in targeting by chemotherapy and antibacterial drugs. Topoisomerase inhibitors used in chemotherapy interrupt the replication of rapidly dividing cancer cells. For bacteria, particularly fluoroquinolones, target bacterial topoisomerases, impairing their replication process. This clinical application underscores the importance of enzymes in both DNA replication and as targets in medical treatments, linking foundational science with practical healthcare solutions.
- 00:40:00 - 00:45:00
Discussion on telomeres centers on their role as protective DNA sequences that safeguard chromosome ends from degradation during replication. Over time, repeated cell division shortens telomeres, leading to eventual genomic instability and cellular aging. Telomerase enzyme activity is highlighted as a key mechanism in compensating for this loss by elongating telomeres, particularly active in stem cells and cancer cells, allowing unlimited division and growth. This biological insight connects cellular replication dynamics to broader processes like aging and oncogenesis.
- 00:45:00 - 00:50:00
The segment emphasizes that telomeres, non-coding regions, protect gene-containing DNA by acting as buffers. Due to the inability of enzymes to replicate chromosome ends completely, telomeres progressively shorten with successive cell divisions. The Hayflick limit describes the point at which telomere attrition limits further cell division, highlighting a natural barrier to infinite replication, intertwined with potential for genetic instability if compromised.
- 00:50:00 - 00:55:00
Telomerase, with its reverse transcription capability, extends telomeres, compensating for replication-induced shortening. This enzyme's high activity in stem and cancer cells enables the maintenance of telomere length, bypassing the Hayflick limit and allowing continued replication. By synthesizing DNA from an RNA template, telomerase counteracts natural cellular aging processes, facilitating prolonged cellular longevity in certain cells, a fundamental mechanism with profound implications for understanding cancer proliferation and longevity.
- 00:55:00 - 01:00:00
The potential for cancer cells to exploit telomerase function to maintain telomere length and evade growth limitations is discussed. By upregulating telomerase, cancer cells can circumvent normal senescence pathways, promoting unchecked proliferation. This mechanism underscores a pivotal aspect of oncogenesis, however, offers a potential therapeutic target in cancer treatment. Understanding telomerase's role in cellular longevity and cancer provides a strategic framework to explore new treatment avenues.
- 01:00:00 - 01:07:13
Final discussions link the detailed process of DNA replication to broader scientific and clinical contexts. Key understanding includes mechanisms of enzymes involved in DNA replication, their regulation, and implications for disease and therapy. The session reiterates the critical role of telomeres and telomerase, interconnecting cellular processes with aging and cancer, and highlights the importance of integrating biochemical knowledge with medical applications for advancing treatment strategies.
Peta Pikiran
Pertanyaan yang Sering Diajukan
What is the purpose of DNA replication?
DNA replication allows cells to replicate and create more cells by duplicating the genetic material within them.
What is the semi-conservative model of DNA replication?
The semi-conservative model means that each new DNA molecule consists of one old (parental) strand and one newly synthesized strand.
During which phase does DNA replication occur?
DNA replication primarily occurs during the S phase of the cell cycle.
What direction does DNA replication occur in?
DNA replication occurs in a 5' to 3' direction.
What is the role of helicase in DNA replication?
Helicase unwinds the DNA, creating a replication fork for the synthesis of new DNA strands.
What are Okazaki fragments?
Okazaki fragments are short DNA sequences synthesized on the lagging strand, interrupted by RNA primers.
Why do cells have telomeres?
Telomeres protect the ends of chromosomes from deterioration and prevent the loss of important genetic information.
What is the role of telomerase?
Telomerase extends telomeres, allowing for continued replication without losing important genetic coding regions.
How does DNA polymerase proofread?
DNA polymerase proofreads by removing incorrect nucleotides and replacing them with the correct ones.
What enzymes are involved in relieving DNA supercoiling during replication?
Topoisomerases relieve supercoiling tension ahead of the replication fork.
Lihat lebih banyak ringkasan video
- 00:00:14what's up ninja nerds in this video
- 00:00:15today we're going to be talking about
- 00:00:17dna replication but before we get
- 00:00:19started
- 00:00:19please continue to support us by hitting
- 00:00:21that like button commenting on the
- 00:00:22comment section and please subscribe
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- 00:00:27go check that out all right ninja nerds
- 00:00:29let's get into it all right ninjas when
- 00:00:31we talk about dna replication the first
- 00:00:33thing that we need to talk about is a
- 00:00:34couple of fundamental points very
- 00:00:36important things that we're going to
- 00:00:37build on throughout the process of this
- 00:00:38lecture and so the first thing i need
- 00:00:39you guys to know is what in the heck do
- 00:00:41we do dna replication for
- 00:00:43and the whole point is is that in order
- 00:00:45for
- 00:00:46cells to be able to replicate and make
- 00:00:49more cells
- 00:00:50we need the dna within those cells to
- 00:00:53replicate
- 00:00:53because the dna is pretty much the
- 00:00:56the genetic portion of the cell it's
- 00:00:58what makes a cell
- 00:01:00what it is so in order for us to really
- 00:01:02understand dna replication i really want
- 00:01:04you to understand that the whole purpose
- 00:01:05of it
- 00:01:06is to allow for cell replication
- 00:01:09okay or sometimes we refer to this as
- 00:01:11the cell cycle
- 00:01:13okay so the cell cycle i know you guys
- 00:01:16know the cell cycle
- 00:01:17when in the cell cycle what's kind of
- 00:01:18the really quick part of it
- 00:01:20you start off you go g1 then you go
- 00:01:23s phase g2 phase and then you go into
- 00:01:26the mitosis part
- 00:01:28and then out of that you get two cells
- 00:01:30where you take one cell
- 00:01:32that cell enters into the g1 s g2 goes
- 00:01:34through mitosis and makes two cells
- 00:01:37the big thing i want you to know is that
- 00:01:38dna replication primarily occurs within
- 00:01:42a particular part of the cell cycle when
- 00:01:43a cell's replicating making more cells
- 00:01:45it primarily occurs within the s phase
- 00:01:49so in the s phase that is where dna
- 00:01:53replication is occurring so the first
- 00:01:57fundamental that you need to know is why
- 00:01:59do we perform dna replication
- 00:02:00in order for our cells to replicate make
- 00:02:03more
- 00:02:04cells so whenever they go through their
- 00:02:05cell cycle the particular point when the
- 00:02:08dna is actually replicating
- 00:02:10is in the s phase of the cell cycle now
- 00:02:13real quick what in the heck is cell
- 00:02:15replication it's really simple
- 00:02:16i'm taking this cell here which has 23
- 00:02:19maternal and 23 paternal chromosomes
- 00:02:23and all i'm doing is i'm making two
- 00:02:25identical cells that look
- 00:02:26just like this so i have to replicate
- 00:02:28the dna within this chromosome
- 00:02:30and the dna within this chromosome and
- 00:02:32i'll make two of this
- 00:02:33and two of this and that's going to give
- 00:02:35me these two identical daughter cells
- 00:02:37and that's the basic process of cell
- 00:02:38replication
- 00:02:40so that's the first thing i need you
- 00:02:41guys to know the second thing that i
- 00:02:43need you guys to know about dna
- 00:02:45replication is that it
- 00:02:46occurs in what's called a
- 00:02:48semi-conservative
- 00:02:49model what the heck does that mean zack
- 00:02:51i got you
- 00:02:52so the next thing you need to know is
- 00:02:54that dna replication is
- 00:02:57semi-conservative
- 00:03:00semi-conservative means let's take that
- 00:03:02a piece of dna here right
- 00:03:03so dna has two strands and we're going
- 00:03:05to call these we're going to give them
- 00:03:06two names
- 00:03:07we're going to call these blue dna
- 00:03:09strands parental strands
- 00:03:11or let's call them old strands
- 00:03:14what i'm going to do is when i want to
- 00:03:15replicate this dna i have to separate
- 00:03:18them and we'll talk about how we do that
- 00:03:20when you separate the dna into separate
- 00:03:22strands here
- 00:03:23i have two old parental strands
- 00:03:25separated
- 00:03:26what i'm going to do is i'm going to
- 00:03:28replicate
- 00:03:30the dna in a complementary
- 00:03:33fashion so what does that mean
- 00:03:35complementary
- 00:03:36that means if for example this
- 00:03:38nucleotide was adenine
- 00:03:40or a this would be t if this was t this
- 00:03:43would be a
- 00:03:44this was g this would be c if this was c
- 00:03:46this would be g
- 00:03:47you get the point i'm going to make
- 00:03:49nucleotides that are complementary on
- 00:03:51that
- 00:03:52but do you see how the color is
- 00:03:54different and i synthesized a
- 00:03:56new strand or a a daughter strand
- 00:04:00if you will that's one aspect of it i'm
- 00:04:01going to do the same thing to this other
- 00:04:03strand so i'm going to use this old
- 00:04:04parental strand
- 00:04:05and make a new strand with complementary
- 00:04:07nucleotides on the other
- 00:04:09old parental strand i'm going to again
- 00:04:12make dna that is complementary
- 00:04:16to this old or parental strand so the
- 00:04:19whole concept here is that i start with
- 00:04:21old if you will let's use the term old
- 00:04:25and i make new
- 00:04:28mixed with the old
- 00:04:33that's really the easiest way of
- 00:04:34understanding dna replication is i'm
- 00:04:37taking
- 00:04:38two old parental strands separating them
- 00:04:41and making two new dna strands that are
- 00:04:43complementary to them
- 00:04:45so what i did is i took this dna and
- 00:04:48made
- 00:04:48two new double-stranded dna molecules
- 00:04:51isn't that cool
- 00:04:52and when i did it i did it in this
- 00:04:54semi-conservative
- 00:04:55process the next really important thing
- 00:04:58that you guys need to know
- 00:05:00is that dna replication occurs in a very
- 00:05:03very specific direction dna replication
- 00:05:07has to occur okay the direction
- 00:05:10okay replication direction
- 00:05:14is very important it's kind of annoying
- 00:05:17we'll mention it a lot
- 00:05:19throughout the process of this lecture
- 00:05:21but dna direction always has to occur
- 00:05:23from the
- 00:05:24five prime end to the three prime
- 00:05:27end i can't stress that enough super
- 00:05:29important it's going to come up a lot
- 00:05:32what the heck does that mean really
- 00:05:33quickly do you guys remember from the
- 00:05:35dna structure video
- 00:05:36what was on the five prime end of a
- 00:05:37nucleotide the phosphate group
- 00:05:40what was on the three prime end of the
- 00:05:41nucleotide the oh group
- 00:05:44so when i'm adding nucleotides i'm
- 00:05:47adding
- 00:05:47a phosphate group onto a three prime
- 00:05:50group of the preceding nucleotide let's
- 00:05:52show you an example of that
- 00:05:53so let's say that we took this old dna
- 00:05:55strand we're gonna do replication
- 00:05:56following the semiconservative model
- 00:05:58here i have two old parental dna strands
- 00:06:02separate them i'm going to replicate it
- 00:06:04via the semiconservative model
- 00:06:06but i'm also going to follow this
- 00:06:07process where i have to replicate five
- 00:06:09to three
- 00:06:10so let's say on one end of this old dna
- 00:06:13strand i have a three prime end here
- 00:06:14what does that mean
- 00:06:16that means there's an o h group here on
- 00:06:18the five prime end of this dna strand
- 00:06:20i have a phosphate group here okay same
- 00:06:23thing here
- 00:06:23oh group and then the phosphate group
- 00:06:27right here so that's basically what the
- 00:06:29five prime three prime end is
- 00:06:31and you guys remember that dna is
- 00:06:32antiparallel so if it's three
- 00:06:34prime on one end five prime on the other
- 00:06:36end the other dna strain has to be
- 00:06:38flipped
- 00:06:39so it's five prime on the same and then
- 00:06:40it's three prime and three prime on the
- 00:06:42same end that it was five prime that's
- 00:06:44important
- 00:06:45so when dna replication occurs
- 00:06:49it has to occur five to three so here's
- 00:06:52the three prime end
- 00:06:53when i make a new dna strand it has to
- 00:06:55be
- 00:06:56five prime first three prime end here
- 00:07:00and then what will i do i'll add another
- 00:07:01nucleotide
- 00:07:03and then this connection here will be
- 00:07:06between what
- 00:07:07i'll have a three prime end here and a
- 00:07:09five prime end of this next nucleotide
- 00:07:11i'll have a three prime end here i'm
- 00:07:13gonna add another nucleotide
- 00:07:15so when i make nucleotides i make them
- 00:07:17and synthesize them from
- 00:07:18five to three okay
- 00:07:22same thing if i'm going to do it off of
- 00:07:23this strand here's the five
- 00:07:25end here's the three end of the parental
- 00:07:26strand if i want to make the new strand
- 00:07:29this is the five prime end so i'm going
- 00:07:31to be synthesizing dna in which
- 00:07:33direction
- 00:07:34in this direction here right and again
- 00:07:37doing this according to the
- 00:07:38complementarity rule
- 00:07:40okay so that's the important thing i
- 00:07:42need you guys to remember is that
- 00:07:44dna replication occurs in a five to
- 00:07:46three direction
- 00:07:47the last fundamental thing that is
- 00:07:49really important here
- 00:07:50is that dna replication
- 00:07:54is bi-directional
- 00:07:58and you're like why the heck do i need
- 00:07:59to know that i think oftentimes when
- 00:08:01we're looking in textbooks
- 00:08:04we only focus on one end where dna
- 00:08:06replication is occurring
- 00:08:08but what's really important is we're
- 00:08:09going to talk about this in a second but
- 00:08:10what we do is we take the dna and we
- 00:08:12already have an idea that we're going to
- 00:08:13separate the two older parental strands
- 00:08:15away from one another
- 00:08:16so that we can create new dna from that
- 00:08:19when we do that we create these little
- 00:08:21ends here these little y-shaped regions
- 00:08:23called replication forks
- 00:08:26okay so it's called the replication fork
- 00:08:28and you have two of them one on this end
- 00:08:30one on this end
- 00:08:31there's going to be enzymes called
- 00:08:33helicases which are going to come in and
- 00:08:34unwind the dna
- 00:08:35on both sides moving it in this
- 00:08:38direction
- 00:08:39and moving it in this direction
- 00:08:42and then enzymes called dna polymerases
- 00:08:45which we'll talk about they're also
- 00:08:46going to move into these areas
- 00:08:48and follow the helicase synthesizing new
- 00:08:51dna
- 00:08:51off of that parental strand in a
- 00:08:53bi-directional fashion
- 00:08:55so the big fundamentals i need you guys
- 00:08:56to take away is that why do we do it
- 00:08:58dna replication in order for cells to
- 00:09:01replicate and make more cells
- 00:09:02it occurs in a semi-conservative fashion
- 00:09:05taking old
- 00:09:06making a mixed old and new double two
- 00:09:08double-stranded dna molecules
- 00:09:10it occurs in a five to three direction
- 00:09:13and it occurs
- 00:09:13bi-directionally from what's called the
- 00:09:16origin of replication or where these
- 00:09:18replication forks are
- 00:09:19okay now that we have the fundamentals
- 00:09:22let's now talk about the steps of dna
- 00:09:24replication
- 00:09:25all right so the first thing that we
- 00:09:26have to talk about when we're talking
- 00:09:28about the stages of dna replication
- 00:09:30there's three stages of dna replication
- 00:09:32initiation elongation and termination
- 00:09:34okay initiation elongation and
- 00:09:36termination
- 00:09:37initiation is really an easy process
- 00:09:39it's not too hard to remember
- 00:09:41so what happens is let's say that here
- 00:09:44i have my double-stranded dna okay and
- 00:09:47let's say there's a particular
- 00:09:49region in that double-stranded dna which
- 00:09:52is
- 00:09:52really really a nice little area that i
- 00:09:54want to go and i want to separate the
- 00:09:56dna so that i can
- 00:09:57create two separate dna strands parental
- 00:09:59strands that i can use as templates to
- 00:10:01make new dna
- 00:10:03that area is going to become our origin
- 00:10:06of replication
- 00:10:07all right so this area is really what's
- 00:10:09going to be our origin
- 00:10:13of replication and why do we need to
- 00:10:17know this okay
- 00:10:18so whenever we need we're picking this
- 00:10:20spot how do we determine what that
- 00:10:22we're picking that spot like okay i know
- 00:10:24that there's a bunch of regions on the
- 00:10:25dna
- 00:10:26why is the this point here the
- 00:10:28particular origin
- 00:10:30and there's a really cool reason why
- 00:10:32there's particular
- 00:10:34nucleotides in this region which are
- 00:10:37really highly concentrated with
- 00:10:40adenine and thymine so it's an adenine
- 00:10:44and thymine
- 00:10:45rich area now let's talk about this for
- 00:10:48a quick second
- 00:10:49why would i pick adenine and thymine as
- 00:10:52the area that i
- 00:10:53really want to target as compared to
- 00:10:55guanine and cytosine do you guys know
- 00:10:57why
- 00:10:58so adenine and thymine how many hydrogen
- 00:11:00bonds are there between them
- 00:11:02two how many hydrogen bonds are there
- 00:11:03between guanine and cytosine
- 00:11:05three it's going to be easier to break
- 00:11:09two hydrogen bonds and it is going to be
- 00:11:11able to break three hydrogen bonds
- 00:11:13so in this area there's going to be
- 00:11:15particular areas which are really
- 00:11:16concentrated with adenine and thymine
- 00:11:19nitrogenous bases or nucleotides and
- 00:11:21that's going to be
- 00:11:22better suited as the area we want to
- 00:11:24kind of separate
- 00:11:26why because there's only two
- 00:11:29hydrogen bonds and that's going to
- 00:11:32require
- 00:11:34less energy
- 00:11:39okay to break those hydrogen bonds as
- 00:11:41compared to
- 00:11:42guanine and cytosine okay so that's the
- 00:11:45first thing we have particular areas now
- 00:11:47the next thing i need you guys to
- 00:11:48understand is
- 00:11:49in eukaryotic cells is there only one
- 00:11:52origin that okay there's just one area
- 00:11:54here
- 00:11:55where there's a lot of adenine and
- 00:11:56thymine i just have enzymes bind to that
- 00:11:58portion and separate it
- 00:11:59and the enzymes just work from the
- 00:12:00center and go to the ends
- 00:12:02no what's really important that you guys
- 00:12:05need to know is that in eukaryotic cells
- 00:12:08there is multiple
- 00:12:12origins sometimes represented or e c
- 00:12:15origins of replication
- 00:12:19so that's really really important so for
- 00:12:21example i may just be representing this
- 00:12:22one portion but there may be another
- 00:12:24origin of replication right here
- 00:12:26and another origin of replication here
- 00:12:28which is really rich in adenine thymine
- 00:12:31nucleotides okay so that's one important
- 00:12:33thing
- 00:12:34the next thing is what type of structure
- 00:12:36is going to bind onto these areas
- 00:12:38and help to break the bonds between the
- 00:12:40adenine and thymine
- 00:12:41what do we have there's a really
- 00:12:43interesting protein
- 00:12:45it's got one heck of a name they always
- 00:12:47do don't they
- 00:12:49and this protein here is called the
- 00:12:50pre-replication
- 00:12:52pro pre-replication protein complex one
- 00:12:54heck of a name
- 00:12:55so here we're going to draw a cute
- 00:12:57little enzyme here okay this is a cute
- 00:12:59little enzyme
- 00:13:00and this enzyme is going to come in and
- 00:13:02bind
- 00:13:03onto these areas and when they bind onto
- 00:13:05the areas they separate
- 00:13:06the adenine and thymine nucleotides in
- 00:13:08that area to separate the dna
- 00:13:10what is this protein here called that
- 00:13:12separates them it's called a pre
- 00:13:15replication
- 00:13:18protein complex
- 00:13:22so again it binds to the origin of
- 00:13:24replication and separates the
- 00:13:26adenothymine
- 00:13:27uh nitrogenous bases now once it does
- 00:13:29that what's that going to look like well
- 00:13:31let's take the next step
- 00:13:32we had this protein bind on to the
- 00:13:33origin of replication where there's a
- 00:13:35lot of adenine and thymine nucleotides
- 00:13:38we separated the bonds between them the
- 00:13:40two hydrogen bonds
- 00:13:42and we create this little like bubble if
- 00:13:44you will you know what we call this
- 00:13:46it's not hard it's called the
- 00:13:48replication bubble that's literally what
- 00:13:49it's called i know it sounds crazy
- 00:13:51but now we kind of form this little
- 00:13:52bubble due to this whole process and
- 00:13:54it's called the replication
- 00:13:58bubble now once we form this replication
- 00:14:02bubble there's a couple things that i
- 00:14:03need you guys to know we have separated
- 00:14:05the nucleotides so if you imagine here
- 00:14:07we're not showing them but let's say
- 00:14:08that here i show a couple
- 00:14:09you know here's my nitrogenous bases
- 00:14:11that are coming off this
- 00:14:12sugar phosphate backbone right which is
- 00:14:14made up of again the
- 00:14:16deoxyribose sugars the phosphate groups
- 00:14:18all that
- 00:14:19and these are just my nitrogenous bases
- 00:14:21that are popping out off of it right
- 00:14:23so i'm going to have these exposed now
- 00:14:26so these were once
- 00:14:28really connected nicely together like in
- 00:14:30these regions i really separated them
- 00:14:32so they're really kind of like
- 00:14:33vulnerable right now and you know what's
- 00:14:35really important
- 00:14:36these when you separate them they want
- 00:14:39so badly
- 00:14:40to re-anneal with one another all right
- 00:14:42so what is this
- 00:14:44protein that really helps to protect
- 00:14:47these
- 00:14:47vulnerable separated parental dna
- 00:14:50strands
- 00:14:51you know it's really ironic uh you know
- 00:14:53sometimes
- 00:14:54science is there's a big old protein
- 00:14:56that comes and binds to this end it
- 00:14:58would do the same thing on this one
- 00:15:00and this protein you know what it's
- 00:15:02called it's called the single
- 00:15:04stranded binding protein i'm not even
- 00:15:08joking that's literally the name of it
- 00:15:10and it's perfect it's not hard to
- 00:15:12remember why because
- 00:15:14it's a protein binding to a single
- 00:15:16parental strand so you would have one
- 00:15:18over here i'll just draw a portion of it
- 00:15:20but you'd have the same thing over here
- 00:15:22another single strand of binding protein
- 00:15:24binding onto this parental strand and
- 00:15:26what is the purpose of these single
- 00:15:28stranded binding proteins that's what i
- 00:15:29really want you to remember
- 00:15:30one of the functions is that it prevents
- 00:15:36the parental strands from re-annealing
- 00:15:41what the heck does that mean what's that
- 00:15:43term re-annealing from reconnecting to
- 00:15:45one another
- 00:15:46right so that's important so it present
- 00:15:48prevents the parental strands from
- 00:15:50re-annealing
- 00:15:52to one another because they honestly
- 00:15:54they really want to click back to one
- 00:15:56another
- 00:15:57the other thing that they do is that
- 00:15:59when you have
- 00:16:00these uh parental strands separated as
- 00:16:02kind of these single strands if you will
- 00:16:04they're very vulnerable to very nasty
- 00:16:07little enzymes there's some nasty little
- 00:16:09pac-man-like
- 00:16:10enzymes that want to come to the area
- 00:16:12and break the
- 00:16:13phosphodiester bonds these are called
- 00:16:17nucleases so what these single-stranded
- 00:16:20binding proteins do is they kind of act
- 00:16:22as a barrier
- 00:16:23and protect these single strands from
- 00:16:26exonucleases or endonucleases
- 00:16:28so again it prevents it protects
- 00:16:33from nucleases
- 00:16:37okay so so far free replication complex
- 00:16:40binds to the origin of replication or
- 00:16:42the at rich area separates it forms a
- 00:16:44replication bubble
- 00:16:45single strand of binding proteins bind
- 00:16:47to the single strands prevent them from
- 00:16:49kneeling and protect them from nucleases
- 00:16:52the next thing is once you form a
- 00:16:53replication bubble you form these two
- 00:16:56ends here
- 00:16:57okay and these two ends we already kind
- 00:16:59of mentioned it a little bit
- 00:17:01this end here where it kind of like
- 00:17:02makes like a y shape if you will
- 00:17:06this right here is called your
- 00:17:08replication fork
- 00:17:11okay there's going to be an enzyme that
- 00:17:14we're going to talk about in just a
- 00:17:15second
- 00:17:15ah frickin we'll talk about them now he
- 00:17:18hops in here
- 00:17:19this little enzyme is like the energizer
- 00:17:22bunny
- 00:17:22he's got so much energy as long as you
- 00:17:24keep feeding them
- 00:17:26and he hops in here look at this cute
- 00:17:28little enzyme look at this guy
- 00:17:31this enzyme will come in at this point
- 00:17:35here
- 00:17:36and really unwind the dna at
- 00:17:39both replication forks
- 00:17:43what is the name of this enzyme that
- 00:17:45really works
- 00:17:46in these replication forks unwinding the
- 00:17:48dna in front of them
- 00:17:50this enzyme is called helicase
- 00:17:56and the big thing i really want you to
- 00:17:57know about the helicase enzyme
- 00:17:59is that he requires a ton of atp
- 00:18:03in order to perform this process okay
- 00:18:07so step by step again real quick
- 00:18:09pre-replication
- 00:18:10complex binds to the origin of
- 00:18:11replication at rich area separates it
- 00:18:14single-stranded binding proteins bind
- 00:18:15protect them from exonucleases and
- 00:18:17endonucleases
- 00:18:18prevent re-annealing whenever you do
- 00:18:20that separating them you create a
- 00:18:22replication
- 00:18:22bubble at the ends of them you have
- 00:18:24replication forks
- 00:18:26helicases highly atp dependent hop in
- 00:18:28there and start unwinding the dna
- 00:18:30in front of them after they do that
- 00:18:33something happens which is really
- 00:18:35important
- 00:18:35that we definitely need to know let's
- 00:18:37come down here and this is a really
- 00:18:39important area that i really really need
- 00:18:41you guys to understand
- 00:18:43so let's say that we come back to this
- 00:18:44point here
- 00:18:46again what we have binding right here to
- 00:18:48these two ends
- 00:18:50single stranded binding proteins we're
- 00:18:52not going to show it on the top but the
- 00:18:53same thing here
- 00:18:54and then again what enzyme let's just
- 00:18:56focus on this area right here just on
- 00:18:58this replication fork
- 00:19:00what enzyme would be in this area here
- 00:19:05really working and unwinding the dna in
- 00:19:07front of it
- 00:19:08again that's called helicase
- 00:19:12what happens is as helicase continues to
- 00:19:14unwind the dna the whole purpose of that
- 00:19:16as it unwinds the dna separates the
- 00:19:18strands so that enzymes would be able to
- 00:19:20use those parental strands to make new
- 00:19:22dna
- 00:19:22okay but there's a problem that happens
- 00:19:25as dna helicases just you know going
- 00:19:27through those mofos and unwinding the
- 00:19:29dna constantly in front of it
- 00:19:31it bunches up the dna in front of it
- 00:19:35distal to it okay from that replication
- 00:19:37fork so distal to the replication for
- 00:19:39downstream the dna starts bunching up
- 00:19:42and it creates things these things
- 00:19:44called super coils
- 00:19:46okay it creates these things called
- 00:19:47super coils
- 00:19:50and this is caused by the helicase
- 00:19:52really unwinding the dna
- 00:19:54why are super coils bad if you really
- 00:19:56bunch up the dna in front of it it's
- 00:19:58going to really impede the helicase
- 00:20:00from continuing to unwind the dna it's
- 00:20:02going to face a lot of restriction
- 00:20:04because it's really bunched up here so
- 00:20:06it'll just keep getting bunched up until
- 00:20:07you relieve
- 00:20:09those super coils so we need enzymes
- 00:20:12that can come
- 00:20:12in there and fix these supercoils where
- 00:20:15the dna is
- 00:20:16really really tightly wound so how do we
- 00:20:18do that
- 00:20:19all right so what little enzymes do we
- 00:20:21have or special little things that come
- 00:20:23into the play to really alleviate these
- 00:20:25super coils
- 00:20:26these enzymes are crazy interesting so
- 00:20:29these guys are really cool
- 00:20:34and they are called topo
- 00:20:38high sama races they're shape of the t
- 00:20:40right so they're called what
- 00:20:42toppo is
- 00:20:47now topoisomerases there's actually a
- 00:20:49couple different types
- 00:20:50okay there's particularly type 1
- 00:20:56type 2 and then there's type 4.
- 00:21:00for the most part they all do the same
- 00:21:02kind of thing and what is that
- 00:21:04okay this enzyme has two little
- 00:21:08arms if you will let's say here it has
- 00:21:09one little arm
- 00:21:11and another little arm on one arm
- 00:21:14it can go to where this area of the
- 00:21:16supracoil is let's say that the
- 00:21:17supercoil's right here
- 00:21:19it can use a little enzyme a little
- 00:21:21domain of it
- 00:21:22and cut this dna strand
- 00:21:26if it cuts the dna strand what does that
- 00:21:28allow for it to do
- 00:21:29it kind of allows the dna to kind of
- 00:21:30unwind a little bit and
- 00:21:32unravel and so there's a particular
- 00:21:35name to this domain on that
- 00:21:37topoisomerase enzyme
- 00:21:38it's called a nuclease
- 00:21:41domain and what does it do it creates a
- 00:21:44cut
- 00:21:45or breaks the phosphodiester bond in the
- 00:21:47dna strands one maybe two dna strands
- 00:21:49allows it to unwind there's a problem
- 00:21:51with that though
- 00:21:52if i just cut the dna strand and allow
- 00:21:55it to continuously unwind
- 00:21:56that may be problematic the dna could
- 00:21:58continue to fragment
- 00:22:00i don't want that so what i do is
- 00:22:03i use this other arm and after the dna
- 00:22:07super coils have been alleviated so
- 00:22:08let's now kind of draw
- 00:22:10new dna after the super coils have been
- 00:22:13alleviated
- 00:22:14so we alleviated the super coils we got
- 00:22:16rid of all of those
- 00:22:17overwinding of the dna
- 00:22:20look now it's beautiful it's not
- 00:22:23overwinded
- 00:22:24but we have a break in that dna and
- 00:22:26that's a problem so now we need to use
- 00:22:28the other
- 00:22:28arm of this topoisomerase where we cut
- 00:22:31this portion here
- 00:22:33and allow it to unwind we need to use
- 00:22:35this portion
- 00:22:37called the ligase domain
- 00:22:40and once it's unwound this portion here
- 00:22:43what does it do
- 00:22:44it re-stitches this area back together
- 00:22:48after it's unwound the super coils
- 00:22:50okay so again the topwise sama races
- 00:22:52what were their function again
- 00:22:54two unwind
- 00:22:57the super coils now
- 00:23:01why in the heck did i take all this time
- 00:23:03to mention the topoisomerases and
- 00:23:05there's different types
- 00:23:07let me explain why topoisomerases
- 00:23:10can be in both cells so we primarily
- 00:23:12haven't really discussed
- 00:23:13that dna replication can occur in
- 00:23:15bacterial cells and it can occur in
- 00:23:16eukaryotic cells or we call it bacterial
- 00:23:18cells like prokaryotic cells
- 00:23:20and eukaryotic cells human cells
- 00:23:22primarily
- 00:23:23they have type one and two
- 00:23:25topoisomerases
- 00:23:27and in prokaryotic cells they primarily
- 00:23:29have two
- 00:23:30and four so again type one and two are
- 00:23:33primarily for
- 00:23:34eukaryotic cells
- 00:23:38and then type 2 and 4 are primarily for
- 00:23:41prokaryotic
- 00:23:43cells big thing i need you guys to know
- 00:23:46is
- 00:23:47is that type 1 topoisomerase
- 00:23:51does not require any atp to unwind the
- 00:23:54supercoils so let's put that next to it
- 00:23:56that just for this one just for this one
- 00:24:00it no atp is required in order for it to
- 00:24:04perform this unwinding of the super
- 00:24:05coils
- 00:24:06but for type 2 and 4 let's pick a
- 00:24:08different color so that we don't confuse
- 00:24:10it here
- 00:24:11for type 2 and type 4 these do
- 00:24:14require atp
- 00:24:18in order for them to unwind the super
- 00:24:20coils there's also one more thing i
- 00:24:22don't want to get too far in depth in it
- 00:24:24that type two and four can do that are a
- 00:24:25little bit different from type one
- 00:24:27and that's that if you really look in
- 00:24:29the the textbooks
- 00:24:31they can actually take and cut that
- 00:24:33little
- 00:24:34supercoil area allow for unwind and then
- 00:24:36insert in what's called negative
- 00:24:38supercoils which also helps to kind of
- 00:24:39relax the dna and
- 00:24:41prevent that kind of bunching up region
- 00:24:43let's not get too far into depth in that
- 00:24:45what i really want you guys to know
- 00:24:47is why in the heck did i spend so much
- 00:24:49time talking about these topoisomerases
- 00:24:51in your usmles you have to know
- 00:24:54particular drugs that we can target on
- 00:24:56these
- 00:24:57and eukaryotic cells i want you to think
- 00:25:00about a reason just try to think for a
- 00:25:01reason
- 00:25:02why would i want to target this enzyme
- 00:25:06in eukaryotic cells when this is
- 00:25:07important for dna replication
- 00:25:09if these enzymes aren't really working
- 00:25:11dna replication won't occur
- 00:25:14when a eukaryotic cell what if i have a
- 00:25:16cancer cell
- 00:25:17so if i have cancer the cells will
- 00:25:20continue to replicate
- 00:25:22so they'll replicate and replicate and
- 00:25:23replicate well
- 00:25:25i could maybe use some drugs that could
- 00:25:28target these topoisomerases in my cancer
- 00:25:31cells
- 00:25:32and prevent them from replicating how do
- 00:25:34i do that
- 00:25:35well there is a particular name of
- 00:25:37there's a couple drugs that you guys
- 00:25:38definitely need to know
- 00:25:40for topoisomerase one in eukaryotic
- 00:25:43cells
- 00:25:43the cancer drugs that we can use for
- 00:25:46topoisomerase
- 00:25:47one is called irenotecan
- 00:25:52and what's called topotechin and again
- 00:25:55these are
- 00:25:56anti like they're chemotherapeutic drugs
- 00:25:59that are going to inhibit the
- 00:26:01topoisomerase one in the cancer cells
- 00:26:03the type two in eukaryotic cells
- 00:26:07we can use drugs called etopocide
- 00:26:11and tinopocide and i'm going to explain
- 00:26:15how they do that because that's really
- 00:26:16important i really want you to
- 00:26:17understand how they do this
- 00:26:18but that's for the eukaryotic cells
- 00:26:21think about prokaryotic cells
- 00:26:23if you were infected by a bacteria and a
- 00:26:25bacteria infected your lungs
- 00:26:27and it just kept replicating and
- 00:26:29replicating within your lungs could
- 00:26:31i maybe target the topoisomerase two and
- 00:26:33four and prevent that replication
- 00:26:34process of the bacteria in my lungs
- 00:26:36yes so in bacterial infections
- 00:26:40let's say because it's a prokaryotic
- 00:26:41cell and bacterial infections
- 00:26:44these bacteria will continue to keep
- 00:26:46replicating
- 00:26:48so if i use particular drugs that can
- 00:26:50maybe prevent the dna from replicating
- 00:26:53in these bacterial cells
- 00:26:54that's important and we can do that via
- 00:26:57inhibiting the topoisomerase primarily
- 00:26:59type 2
- 00:27:00and we use the drug called
- 00:27:04fluoroquinolones
- 00:27:08some of you may have heard of these
- 00:27:10ciprofloxacin levofloxacin
- 00:27:12oxyfloxacin all of those guys they're
- 00:27:14inhibiting
- 00:27:15the topoism race too but i really want
- 00:27:18to take a second because i never
- 00:27:19understood this completely until i
- 00:27:21really dug into the mechanism of how
- 00:27:22they actually do this i really want to
- 00:27:24quickly say how they do it
- 00:27:26what these drugs are really doing
- 00:27:29is these drugs so let's kind of just put
- 00:27:31here drugs
- 00:27:33they're exciting in increasing the
- 00:27:36activity of the nuclease domain
- 00:27:38what the heck is that going to do that's
- 00:27:40going to just chop
- 00:27:42all those like portions of the dna and
- 00:27:45it's going to continue to fragment them
- 00:27:47right
- 00:27:48remember we had another another domain
- 00:27:50of this enzyme that re-annealed them and
- 00:27:52kind of stitched it back together to
- 00:27:53prevent that fragmentation
- 00:27:55that was the ligase binding domain what
- 00:27:57if i use drugs
- 00:27:59to enhance the nuclease domain
- 00:28:02but inhibit the ligase domain so now
- 00:28:06i'm going to have this enzyme go in and
- 00:28:08kind of cut where the supercoils is
- 00:28:10but i'm never going to re-stitch it
- 00:28:12together the dna will just
- 00:28:14fragment over time and that's important
- 00:28:17because then you can't replicate the dna
- 00:28:19within what kind of cells eukaryotic
- 00:28:21cells like cancer cells
- 00:28:22or bacterial cells and that's why those
- 00:28:24drugs are important doesn't it make
- 00:28:26sense
- 00:28:26all right cool it's important to take a
- 00:28:28clinical application and tie it
- 00:28:30to the the basic foundational science
- 00:28:33okay
- 00:28:34so we kind of went through talked about
- 00:28:36the topoism races
- 00:28:38that was the big thing and how they
- 00:28:39unwind the super coils
- 00:28:41let's get back to the foundational
- 00:28:42science and now that we've talked about
- 00:28:44that the next thing that we have to go
- 00:28:46into
- 00:28:46is elongating the dna all right ninja
- 00:28:49nerds so we already know we have a
- 00:28:51replication bubble
- 00:28:52we got a replication forks we have our
- 00:28:55protein here called the single strand of
- 00:28:56binding protein which is stabilizing
- 00:28:58these single strands
- 00:29:00we have the helicase enzymes that are in
- 00:29:01these replication forks working like a
- 00:29:03son of a gun
- 00:29:05to unwind the dna we've got those
- 00:29:07topoisomerases over here that are
- 00:29:09kind of unwinding those coils
- 00:29:12okay now we've really separated this
- 00:29:16we've stabilized it and we're ready to
- 00:29:18begin elongating the dna
- 00:29:20okay here's what's really interesting
- 00:29:23there's an enzyme that comes into play
- 00:29:25here
- 00:29:26and it does something really cool
- 00:29:29it's called primase so an enzyme called
- 00:29:32primase will come into play here so what
- 00:29:36primase does
- 00:29:37is it's an enzyme that
- 00:29:40lays down okay that get makes what's
- 00:29:43called
- 00:29:43rna primers so this takes a really quick
- 00:29:47turn where we've got to understand
- 00:29:48zach you just said that we're making dna
- 00:29:51why the heck
- 00:29:52would i make rna there's a reason why
- 00:29:56there's an enzyme that we'll talk about
- 00:29:57a little bit later called dna polymerase
- 00:29:593 that will
- 00:30:00make dna but the only way it can do that
- 00:30:04is if it has some type of primer or
- 00:30:08three prime ohn to build off of so
- 00:30:11what's the purpose of this primase this
- 00:30:13enzyme
- 00:30:14it lays down rna primers which enable
- 00:30:19dna polymerase particularly type
- 00:30:22three to
- 00:30:26make dna and i'll kind of show you that
- 00:30:29in a little bit in a second okay
- 00:30:31so primase comes in so imagine here i
- 00:30:34just have like this cute little enzyme
- 00:30:36here called primase
- 00:30:38okay and this cute enzyme comes in here
- 00:30:41and let's say here what's this strand up
- 00:30:43here this top part remember we're going
- 00:30:44to say that this is
- 00:30:45three prime end where the o h would be
- 00:30:48this is the five prime end where the
- 00:30:50phosphate would be
- 00:30:51and again the opposite strand here would
- 00:30:53have to be antiparallel
- 00:30:54so five prime end here three prime end
- 00:30:57here right we already know that
- 00:31:00the primase is gonna come in and it's
- 00:31:02gonna read the nucleotides and it has to
- 00:31:04go in a particular fashion
- 00:31:05it reads it from the three all the way
- 00:31:08to the five end
- 00:31:09so what does it do the first thing it
- 00:31:11does is it reads
- 00:31:14the dna strand from three to five
- 00:31:18after it reads it from three to five
- 00:31:20what did i tell you that's super
- 00:31:22important what does dna replication
- 00:31:24occur even though this isn't dna
- 00:31:25it's the same concept it synthesizes
- 00:31:29rna primers or nucleotides in a
- 00:31:33five to three fashion so it's going to
- 00:31:35take and make a couple nucleotides
- 00:31:37generally it's about 10 nucleotides
- 00:31:39we're only going to draw a couple here
- 00:31:40but it'll have has to be again five
- 00:31:42primes starting here
- 00:31:44and i'm just going to make a couple i'll
- 00:31:45make like four nucleotides here
- 00:31:48okay so here it's going to have five
- 00:31:52all the way to the three prime end here
- 00:31:54okay that's my five prime end here that
- 00:31:56i just
- 00:31:57started with and i'm synthesizing it in
- 00:31:59the three direction
- 00:32:01now the reason why this is important is
- 00:32:03on that three end what do we have here
- 00:32:05the o h that's what's on the three prime
- 00:32:07end
- 00:32:08i need that o h the reason why
- 00:32:12is another enzyme called dna polymerase
- 00:32:16type 3
- 00:32:17comes in so there's an enzyme called dna
- 00:32:20polymerase type 3
- 00:32:25and he comes in and he needs that three
- 00:32:28prime oh from the rna primers in order
- 00:32:30for it to continue to build nucleotides
- 00:32:32so again a big thing i need you to
- 00:32:34remember is it needs
- 00:32:36the three prime o h of
- 00:32:40rna primer in order to carry out its
- 00:32:43activity if it doesn't have it it can't
- 00:32:44do it
- 00:32:45so now that it has that this dna
- 00:32:48polymerase comes in
- 00:32:49and it says okay i have my three primo h
- 00:32:51region perfect
- 00:32:53now what i'm going to do is i'm going to
- 00:32:54read my dna and i'm going to do it the
- 00:32:56same way that the primase did
- 00:32:58i'm going to read the dna from the three
- 00:33:00direction
- 00:33:01to the five direction so i'll read it
- 00:33:03boom boom boom
- 00:33:05once i read and figure out what kind of
- 00:33:07nucleotide is then i'm just going to
- 00:33:08synthesize
- 00:33:10those nucleotides in the 5 to 3
- 00:33:13direction
- 00:33:14and it's the same process here so now
- 00:33:16let's make a different color since it's
- 00:33:18a different enzyme
- 00:33:20we kind of picked red over there so
- 00:33:22we're going to start off and we're going
- 00:33:24to say okay
- 00:33:25i'm going to take that oh and i'm going
- 00:33:26to add a phosphate group
- 00:33:28onto it of a of another nucleotide so
- 00:33:31when i do that i'm going to continue to
- 00:33:33keep synthesizing
- 00:33:34in a five to three direction moving
- 00:33:36towards the replication
- 00:33:38fork again when i do that i read it
- 00:33:41i say okay let's say that this is
- 00:33:43adenine i'll put a thymine
- 00:33:45this is guanine i'll put a cytosine this
- 00:33:47is cytosine i'll put a guanine
- 00:33:48and so on and so forth and i'll just
- 00:33:50keep reading the nucleotides three to
- 00:33:52five
- 00:33:53and making a dna strand in what
- 00:33:55direction
- 00:33:56five to three okay
- 00:34:00and again important to remember it
- 00:34:03needed this three prime end of that oh
- 00:34:05of the rna primer to build off of it
- 00:34:08now here's what's really interesting the
- 00:34:10primase will give it kind of a little
- 00:34:11leading point and the dna polymerase
- 00:34:13will just
- 00:34:14go all the way towards the replication
- 00:34:15fork
- 00:34:17this strand is very continuous where
- 00:34:19there's just one rna primer and then dna
- 00:34:21the rest of the way
- 00:34:22this strand is very important we give it
- 00:34:24a particular name
- 00:34:25the strand that's very continuous where
- 00:34:27the dna polymerase moves towards the
- 00:34:29replication fork
- 00:34:30is called the leading strand
- 00:34:34okay it's called the leading strand on
- 00:34:36this other string which we're going to
- 00:34:38talk about is called the lagging strand
- 00:34:40something different happens where you're
- 00:34:42still going to have
- 00:34:44the are the primase it'll come to this
- 00:34:46area okay on this other strand and again
- 00:34:48this is the three end on this part
- 00:34:50five end on this part and what it'll do
- 00:34:53is
- 00:34:53it'll read it from three to five and
- 00:34:56then synthesize a couple nucleotides
- 00:35:00from five to three so this is the three
- 00:35:01end it's going to synthesize from five
- 00:35:04to three and again the same thing will
- 00:35:07happen we created
- 00:35:08a primer of a couple nucleotides with a
- 00:35:11three prime
- 00:35:12o h end that the dna polymerase type
- 00:35:14three can build off of
- 00:35:16so now the dna polymerase type 3 will
- 00:35:18just pop on and say oh perfect i have my
- 00:35:203 prime n to use
- 00:35:22i'm going to go ahead and just read the
- 00:35:23dna from 3 to 5
- 00:35:26and synthesize it from 5
- 00:35:29to three okay
- 00:35:32so i'm gonna do all that perfectly
- 00:35:36now something interesting happens where
- 00:35:38it's gonna look it looks perfectly the
- 00:35:40same you're like zach i don't get the
- 00:35:41difference here
- 00:35:42let's say that the gila case continues
- 00:35:44to unwind the dna
- 00:35:46so it continues to unwind the dna
- 00:35:48something interesting happens that we
- 00:35:50have to talk about
- 00:35:51okay so now let's come down here so
- 00:35:52let's say let's pretend
- 00:35:54right that for a second here we have
- 00:35:57that primer
- 00:35:58let's kind of continue off this let's
- 00:35:59say that the helicase unwound the dna a
- 00:36:01little bit more
- 00:36:02and we along we kind of opened up the
- 00:36:03dna and created a more
- 00:36:05longer length of nucleotides so again
- 00:36:08let's say that here we had that primase
- 00:36:10came in here read this from one end
- 00:36:13again this would be your
- 00:36:15three prime end this would be your five
- 00:36:17prime end so it'll read from three to
- 00:36:18five
- 00:36:19and synthesize from five to three
- 00:36:21creates a little primer with a three
- 00:36:23prime oh end
- 00:36:24the dna polymerase 3 says okay perfect
- 00:36:27i have everything i need i can continue
- 00:36:29to grow and let's say that it just came
- 00:36:30up to like this point here
- 00:36:32but then you kind of unwind the dna
- 00:36:34again that dna polymerase 3 doesn't stop
- 00:36:37it just
- 00:36:38keeps on going and keeps on moving
- 00:36:40reading the dna from three to five and
- 00:36:43continuously synthesizing nucleotides
- 00:36:45from five to three so again this would
- 00:36:47be your five prime end
- 00:36:49this would be a three prime end on this
- 00:36:52other chain this is on the leading
- 00:36:53strand it continues
- 00:36:55on the lagging strand here's where it's
- 00:36:56a little bit different
- 00:36:58let's say that we continue to move on
- 00:37:00here and let's say that like
- 00:37:01at this point here this was where the
- 00:37:04previous rna primer was from above
- 00:37:06where it had again reading this portion
- 00:37:09of the dna this is the five prime end of
- 00:37:11this part
- 00:37:12three prime end of this part it read
- 00:37:14this sequence of dna from three to five
- 00:37:16and let's say that it synthesized a
- 00:37:18couple nucleotides to give your rna
- 00:37:20primer
- 00:37:21from five to three and then what do we
- 00:37:23say happen from that part above
- 00:37:26we have the dna polymerase three use
- 00:37:28that three prime oh end
- 00:37:30read the dna from three to five and
- 00:37:33synthesize the nucleotides
- 00:37:34from five to three here's what happens
- 00:37:39the primase lay down a primer here but
- 00:37:41the dna polymerase
- 00:37:42iii has to use that primer to continue
- 00:37:44to keep building off
- 00:37:45if you unwind the dna a little bit more
- 00:37:47now now you have a couple of the
- 00:37:49nucleotides
- 00:37:50so now let me kind of just so we have
- 00:37:52enough room here
- 00:37:53let's say i draw a couple more
- 00:37:55nucleotides
- 00:37:57so now here i have a couple more
- 00:37:58nucleotides now that primase
- 00:38:01after it just made down this primer for
- 00:38:03the dna polymerase three to use
- 00:38:05it comes down to the next part of the
- 00:38:07replication fork and it says okay here i
- 00:38:09got another three prime
- 00:38:11end here let me again read from three to
- 00:38:13five
- 00:38:14and synthesize a couple nucleotides from
- 00:38:16five to three so i laid down my rna
- 00:38:18primer
- 00:38:19dna polymerase says okay cool i got my
- 00:38:22three prime oh end here
- 00:38:24let me go ahead and use that to make
- 00:38:27my dna and i'm going to read the dna
- 00:38:29from three to five
- 00:38:30and synthesize it from five to three
- 00:38:34do you notice something really
- 00:38:35interesting here on this strand which we
- 00:38:38called again what did we call this
- 00:38:39strand
- 00:38:40well we had one primer and then dna for
- 00:38:42the continuous way towards the
- 00:38:43replication fork
- 00:38:44we called this the leading strand so the
- 00:38:47big thing i want you to know is that you
- 00:38:48have one rna primer
- 00:38:51and then a continuous dna strand from
- 00:38:53that point on
- 00:38:54on this strand called the lagging
- 00:38:59strand something different happens here
- 00:39:02where you have a couple rna primers
- 00:39:05okay and then kind of stretches
- 00:39:09of dna between those rna primers
- 00:39:12this kind of like broken up portion
- 00:39:14where there's rna
- 00:39:15dna rna dna and if we continue to keep
- 00:39:18elongating it we'd have more rna dna rna
- 00:39:20dna
- 00:39:21this gives a particular name which is
- 00:39:23called
- 00:39:25oka zaki fragments
- 00:39:29okay okazaki fragments and again it's
- 00:39:32basically where you have multiple
- 00:39:34rna primers
- 00:39:37and multiple stretches of dna
- 00:39:42stretches okay so multiple dna stretches
- 00:39:45and then multiple rna primers it's a mix
- 00:39:47of them
- 00:39:48and that's a problem okay because you're
- 00:39:50going to see now there has to be another
- 00:39:52thing that we have to do
- 00:39:54we want everything when we replicate dna
- 00:39:56it has to be all dna we can't have it be
- 00:39:58dna with a little bit of rna so we're
- 00:40:01only using these primers as just kind of
- 00:40:03a point to build off of after we've
- 00:40:05built some stuff
- 00:40:06we're just going to go in and cut those
- 00:40:08things out because we don't really need
- 00:40:09them anymore
- 00:40:10so now let's talk about the next part
- 00:40:12which is
- 00:40:13we've started to kind of create these
- 00:40:15primers that we needed to build the dna
- 00:40:17off of
- 00:40:18now we don't need the primers and we got
- 00:40:20to get rid of it how do we do that
- 00:40:21the next thing that you guys need to
- 00:40:22understand is okay we've used our rna
- 00:40:24primers for the dna polymerase 3 to kind
- 00:40:26of build off of and
- 00:40:27make dna from we don't need those
- 00:40:29primers anymore we got to get rid of
- 00:40:31them so let's draw the diagram that we
- 00:40:32had previously
- 00:40:33which again we only had what a little
- 00:40:36stretch of rna primer here
- 00:40:39and then the rest of the length down
- 00:40:41going towards the replication fork which
- 00:40:43again what is this strand here called
- 00:40:45the leading strand is going to be all
- 00:40:48dna okay
- 00:40:52so now this is really important we're
- 00:40:54going to talk about one more thing
- 00:40:55in just a second and again if you guys
- 00:40:57remember on this strand the lagging
- 00:40:59strand
- 00:41:00we had a couple rna primers
- 00:41:04that were in between
- 00:41:07the stretches of dna creating what's
- 00:41:09called okazaki fragments
- 00:41:12on the lagging strand right we talked
- 00:41:14about that
- 00:41:15so now the next goal here is that we
- 00:41:17have to remove
- 00:41:18those rna primers but before we do that
- 00:41:21i got to mention one more thing
- 00:41:22so before we talk about how we remove
- 00:41:25these rna primers i really want to take
- 00:41:27a quick second here
- 00:41:28to explain something else that dna
- 00:41:30polymerase type 3 can do
- 00:41:32so we know that it reads the dna okay
- 00:41:35from three to five and then synthesizes
- 00:41:36nucleotides off of the rna primer from
- 00:41:38five to three
- 00:41:39but it also has one other function it's
- 00:41:41called a proofreading function which is
- 00:41:43very important before we talk about the
- 00:41:45rna primers
- 00:41:46and this proof reading function is
- 00:41:49helpful to prevent
- 00:41:50mistakes and what it does is
- 00:41:53let's say okay it reads three to five
- 00:41:56reads all the nucleotides from a three
- 00:41:57to five direction and then synthesizes
- 00:41:59nucleotides in a five to three after it
- 00:42:00does that it says okay
- 00:42:02let me check my work it goes back and it
- 00:42:05finds the connection
- 00:42:06between this point says okay is this a
- 00:42:08good connection yeah that's a good one a
- 00:42:09and t are connected together
- 00:42:10oh g and c are connected together a and
- 00:42:13g oh
- 00:42:14this isn't a correct uh complementary
- 00:42:18kind of base pair
- 00:42:19i need to cut that out so it
- 00:42:22reads from three to five and if it finds
- 00:42:26any mistakes it uses what's called a
- 00:42:29three prime to five prime exonuclease
- 00:42:36activity where it says okay let me read
- 00:42:40here
- 00:42:40i'm gonna read it and i says okay three
- 00:42:43to five i'm reading
- 00:42:44a t and again it's complementary base it
- 00:42:46should be
- 00:42:47t should be a g a oh not a correct one
- 00:42:51i'm gonna cut that out read it again
- 00:42:53make sure i have it okay it was g
- 00:42:55that has to be c and synthesize the
- 00:42:58correct nucleotide in the five to three
- 00:42:59direction
- 00:43:00so big thing i need you to remember for
- 00:43:02dna polymerase type three
- 00:43:04reads dna three to five synthesizes
- 00:43:06nucleotides five to three
- 00:43:08proof reads back in three to five and if
- 00:43:10that's incorrect
- 00:43:12uses a three to five prime exit nucleus
- 00:43:14to cut it out
- 00:43:15and put in the correct complementary
- 00:43:17nucleotide very important
- 00:43:20okay now we got to get rid of these rna
- 00:43:23primers
- 00:43:23how do we get rid of the rna primers
- 00:43:25well the dna polymerase 3 is not the
- 00:43:26answer
- 00:43:28the next enzyme as if there isn't enough
- 00:43:30enzymes
- 00:43:32is called dna polymerase type 1. so dna
- 00:43:35polymerase type one
- 00:43:40comes to the rescue and what it does is
- 00:43:44it starts here and it finds this okay so
- 00:43:46let's say here we had our three prime
- 00:43:48end here
- 00:43:49five prime end here the new strand would
- 00:43:52be synthesized from five
- 00:43:54to three what this enzyme will do is
- 00:43:57it'll come
- 00:43:57in and it'll cut out these primers
- 00:44:01going from the five to three direction
- 00:44:04so it removes primers or it plucks those
- 00:44:07little
- 00:44:07primers out in a five to three
- 00:44:12exonuclease
- 00:44:15activity right particularly for what to
- 00:44:18pluck out
- 00:44:19the rna primers so this guy will come in
- 00:44:22and it'll say okay
- 00:44:23pluck remove that one pluck remove that
- 00:44:26one
- 00:44:27and then what it'll do is once it plucks
- 00:44:29those out it then says okay
- 00:44:32i'm gonna read this strand from three to
- 00:44:34five
- 00:44:35so it reads the one that it plucked out
- 00:44:36and says okay that's a adenine
- 00:44:38what do i need to add here i need to add
- 00:44:41in
- 00:44:41thymine oh this is thymine i need to add
- 00:44:45in here
- 00:44:46adenine so it plucks off the primers
- 00:44:49then what does it do it reads the dna
- 00:44:55from three to five and then it
- 00:44:58synthesizes
- 00:45:02from five to three
- 00:45:06you know what else it can do one more
- 00:45:09function
- 00:45:10let's say okay it plucked off the rna
- 00:45:12primer reads it as adenine
- 00:45:14puts a thymine reads it as guanine
- 00:45:16accidentally puts an adenine
- 00:45:18has to go back and proof read it though
- 00:45:20because that's always the thing that
- 00:45:21they have to do
- 00:45:22proof reads it and says not a good
- 00:45:24connection
- 00:45:25i don't want that what do i need to do i
- 00:45:27need to pluck that thing out of there
- 00:45:29and put the correct nucleotide
- 00:45:32so the last thing dna polymerase type
- 00:45:34one can do
- 00:45:36is again it has that proof reading type
- 00:45:38of activity
- 00:45:40where it can do what it can read from
- 00:45:43three to five it
- 00:45:44finds an incorrect base pair connection
- 00:45:47it cuts it out and when it cuts it out
- 00:45:50it cuts that at a three
- 00:45:52to five exonuclease type of fashion
- 00:45:56okay so the big difference that if you
- 00:45:59ever get asked between
- 00:46:01what in the heck is the difference
- 00:46:02between dna polymerase type one
- 00:46:04and dna polymerase type three really the
- 00:46:07big difference
- 00:46:08is that this guy can do everything type
- 00:46:10three can do
- 00:46:11it's just it has that five to three
- 00:46:13prime exit nucleus activity where it
- 00:46:14plucks out the rna primers
- 00:46:16everything else is the same though now
- 00:46:17the next thing is dna polymerase type
- 00:46:19one we talked about on the on this
- 00:46:20leading strand on the lacking strain
- 00:46:21it's a little interesting
- 00:46:23it'll come in and again it'll use its
- 00:46:25five to three prime exonuclease activity
- 00:46:27so again let's use our combination here
- 00:46:29of what we know
- 00:46:30this was three this was five so
- 00:46:32antiparallel this has to be
- 00:46:34five to three for the old strand the new
- 00:46:37strand would then be
- 00:46:38what read three to five synthesize
- 00:46:425 to 3. so this dna polymerase will come
- 00:46:45in and it'll start moving down
- 00:46:47and at this point it'll pluck off an rna
- 00:46:50primer and then what will it do
- 00:46:52read 3 to 5 and synthesize
- 00:46:56five to three come to the and then
- 00:46:58proofread it is it correct
- 00:46:59oh it is okay if it's not use my three
- 00:47:02to five primax nucleus to cut it out
- 00:47:04and then put in a new one it goes to the
- 00:47:06next one plucks off the rna primer
- 00:47:09and does the same thing reads three to
- 00:47:11five synthesizes five to three proof
- 00:47:13reads three to five
- 00:47:15then it just keeps doing that and
- 00:47:16plucking these things off here's the
- 00:47:18difference though in the lagging strand
- 00:47:19it creates like a couple gaps these
- 00:47:20actually don't
- 00:47:21completely kind of fuse together so
- 00:47:23let's kind of draw where we had
- 00:47:25this here and we'll create a little
- 00:47:27space between these points here where
- 00:47:29the rna primers were
- 00:47:31so there's kind of a little space here
- 00:47:33let's draw it here in orange
- 00:47:34so on the lagging strand it creates like
- 00:47:35a little space where it can't like
- 00:47:37really fuse these ends
- 00:47:39where the primers were to the original
- 00:47:41dna
- 00:47:42okay so it plucked the rna primers off
- 00:47:44and put nucleotides but it wasn't able
- 00:47:45to perfectly fuse these ends on the
- 00:47:47lagging strand
- 00:47:48one more enzyme you're like dude i can't
- 00:47:51do no more
- 00:47:52i promise one more this enzyme
- 00:47:56is called ligase so it's called ligase
- 00:48:00now ligase
- 00:48:02will come in on that lagging strand
- 00:48:06and fuse the dna
- 00:48:10ends together okay
- 00:48:14those basically where those okazaki
- 00:48:17fragments were
- 00:48:18it'll come and it'll say okay here's
- 00:48:20these ends here
- 00:48:21i'm going to fuse these points together
- 00:48:24so that it's
- 00:48:25perfectly connected and continuous
- 00:48:28and now we have a parental dna
- 00:48:32with a new daughter dna strand again
- 00:48:35a parental dna strand with a whole new
- 00:48:37daughter dna strand that is all
- 00:48:39continuous and all in sequence no rna
- 00:48:41primers no nothing
- 00:48:43no breaks it's perfectly set now the
- 00:48:45last thing that i want to talk about
- 00:48:47here before we go on to termination is
- 00:48:49we've elongated our dna we now took the
- 00:48:50old parental dna and made new dna
- 00:48:53the reason why i want you to remember
- 00:48:54this is that there's it's very important
- 00:48:56for us emilies to connect foundational
- 00:48:58sciences with clinical significance
- 00:49:00and so in people who have hiv
- 00:49:04okay their t cells okay their t cells
- 00:49:08have are infected with the particular
- 00:49:10virus called a retrovirus
- 00:49:12and it's causing this virus to get
- 00:49:13incorporated into the dna and then from
- 00:49:15every point that on that these t
- 00:49:17cells replicate they continue to
- 00:49:19replicate more of the hiv genome
- 00:49:21so there's drugs that we use to target
- 00:49:25this hiv virus and particularly the t
- 00:49:27cell replication process and these drugs
- 00:49:30are called
- 00:49:31nucleoside reverse transcriptase
- 00:49:33inhibitors you're like holy crap
- 00:49:35what the heck does that mean i just want
- 00:49:37you to remember that they're drugs that
- 00:49:38are used for hiv
- 00:49:40and they inhibit the replication process
- 00:49:43and t cells that have been affected with
- 00:49:44hiv let me explain how this works this
- 00:49:46is really cool
- 00:49:47let's say here i just i quickly put down
- 00:49:49an rna primer
- 00:49:51okay and i have my dna polymerase three
- 00:49:55it comes in here and it starts making
- 00:49:58some dna
- 00:49:59right uses that three prime end of the
- 00:50:01rna primer and starts making dna
- 00:50:03i give them a drug let's kind of put
- 00:50:05here an nrti
- 00:50:07and again there's many different names
- 00:50:08of these like didenosine zydovidine
- 00:50:12there's a whole bunch of these but what
- 00:50:14i want you to remember is
- 00:50:15imagine these as what's called
- 00:50:19nucleosides
- 00:50:21okay and what they do is imagine here's
- 00:50:24my
- 00:50:24my basically my my ribose sugar and then
- 00:50:27here i'm going to have my phosphate
- 00:50:29group
- 00:50:29and then here i have like adenine okay
- 00:50:33what they do which is really interesting
- 00:50:35is usually on your
- 00:50:36your deoxyribose sugar you should have
- 00:50:38an oh right and you need that oh
- 00:50:41on that three prime end in order for the
- 00:50:43dna polymerase to continue to keep
- 00:50:44adding
- 00:50:45what they do is is they remove the three
- 00:50:48prime oh region so now
- 00:50:52the dna polymerase 3 will get another
- 00:50:54nucleotide
- 00:50:55it'll read this and say okay this is
- 00:50:57adenine i'm going to put a thymine or
- 00:50:58something like that
- 00:51:00and i'm going to add in this drug this
- 00:51:02drug kind of floats around kind of
- 00:51:04interestingly
- 00:51:05and the dna polymerase iii will then say
- 00:51:07okay here this is a
- 00:51:09another nucleotide just like the ones
- 00:51:10i've been adding let me add this one on
- 00:51:13the only problem is is it doesn't have a
- 00:51:15three prime o h region
- 00:51:17so you know what happens here since
- 00:51:19there's no three prime oh
- 00:51:22you dna polymerase can't build off of
- 00:51:25that
- 00:51:26remember what i told you dna polymerase
- 00:51:28type three needs a three prime oh region
- 00:51:30to build
- 00:51:31if you give a drug that doesn't have
- 00:51:33that can you continue to build off of it
- 00:51:35no so all the dna replication from this
- 00:51:37point
- 00:51:38is inhibited are you able to replicate
- 00:51:41all the dna within these t cells that
- 00:51:43have been affected with hiv
- 00:51:44no so that's how it does it they're
- 00:51:47what's called
- 00:51:48kind of like analogs nucleoside analogs
- 00:51:50where you're kind of like dna polymerase
- 00:51:523 doesn't know the difference it's just
- 00:51:53taking nucleotides and adding on
- 00:51:55and all of a sudden just by kind of
- 00:51:56chance you have this drug that it
- 00:51:58attaches on it doesn't know the
- 00:51:59difference
- 00:52:00it goes to add another nucleotide on
- 00:52:02it's like hey that didn't add on what
- 00:52:04the heck i can't add this nucleotide on
- 00:52:06and the dna never gets completely
- 00:52:07replicated so it's a good it's a good
- 00:52:09clinical point to understand
- 00:52:11that covers our elongation let's hit it
- 00:52:13home with termination
- 00:52:14and take a quick second to talk about
- 00:52:15telomeres all right this is actually the
- 00:52:17easiest one of all you're probably like
- 00:52:19oh
- 00:52:19please zach i can't do any more i know
- 00:52:22this this is a lot but let's say that we
- 00:52:25have another enzyme okay that helicase
- 00:52:26enzyme we're getting to the point where
- 00:52:27dna replication has been completed
- 00:52:29we got that enzyme what was that enzyme
- 00:52:31that was working at these replication
- 00:52:32forks and just continuing to unwind the
- 00:52:34dna
- 00:52:35you know in front of it what are they
- 00:52:37called the helicases
- 00:52:39and then you had those enzymes the dna
- 00:52:41polymerases type 3 and type 1 and all
- 00:52:43those guys that were coming and
- 00:52:45basically reading the dna three to five
- 00:52:46and synthesizing it five to three proof
- 00:52:48reading in the three to five all that
- 00:52:50good stuff
- 00:52:51and you've synthesized the dna and the
- 00:52:54helicases are
- 00:52:55meeting each other at kind of
- 00:52:57replication forks that are about to abut
- 00:53:00one another when this happens
- 00:53:03when the gila cases meet and you kind of
- 00:53:06unwind this portion of the dna
- 00:53:08what's going to happen the helicases are
- 00:53:10just going to kind of say oh
- 00:53:12well hey buddy i guess i don't need to
- 00:53:14keep unwinding anymore
- 00:53:15and what will happen is you're just
- 00:53:17going to kind of have this point here
- 00:53:20where the dna polymerase is will just
- 00:53:22hop off of the dna
- 00:53:24because at this point there's nothing
- 00:53:25else for it to read
- 00:53:28and so usually once it gets to that
- 00:53:29point they'll just say hey
- 00:53:31i guess the helicases are done there's
- 00:53:33no more unwinding for me
- 00:53:35and then after that the dna polymerases
- 00:53:37will say hey i've already kind of
- 00:53:39hit all the nucleotide regions here
- 00:53:42i'm done and i've replicated all of my
- 00:53:44dna
- 00:53:45so that's important so it's basically
- 00:53:47again where there's multiple origins of
- 00:53:49replication and they're constantly
- 00:53:50moving towards one another whenever they
- 00:53:52moved and hit one another
- 00:53:53the dna replication at that point stops
- 00:53:56now there's something else that you have
- 00:53:57to remember though
- 00:53:59dna replication will you know start at a
- 00:54:01point and then work bi-directionally
- 00:54:03it's eventually going to go to the ends
- 00:54:06of the dna or the chromosomes which we
- 00:54:07call the telomeres
- 00:54:09there's a particular nucleotide sequence
- 00:54:11at that end where the dna
- 00:54:13polymerases have a really hard time
- 00:54:15being able to replicate
- 00:54:17and that's very important we'll talk
- 00:54:18about that next okay but again
- 00:54:20termination of dna replication it's
- 00:54:21really simple it's when the dna
- 00:54:23polymerases
- 00:54:24are moving towards one another at a
- 00:54:25replication fork and they've just
- 00:54:27stopped at that point
- 00:54:28they hop off and they no longer perform
- 00:54:30their function there's one other part of
- 00:54:32it which is with the telomeres which
- 00:54:33we're going to finish off with
- 00:54:35all right so the next thing that we're
- 00:54:36going to talk about is telomeres right
- 00:54:37so
- 00:54:39dna replication there's a little
- 00:54:40interesting issue that happens at the
- 00:54:42telomeres so one thing i need you guys
- 00:54:43to know is that
- 00:54:44telomeres they really shorten over time
- 00:54:46so let's say that here
- 00:54:48we look at some chromosomes which again
- 00:54:50made up of dna and proteins well let's
- 00:54:52primarily think of it as dna
- 00:54:53and let's say that this goes through
- 00:54:55goes through a replication cycle
- 00:54:57a couple times i want you to notice what
- 00:55:00happens to the ends right so when you
- 00:55:01look at a chromosome there's
- 00:55:03two primary kind of like structural
- 00:55:05points
- 00:55:06the point in the center right which is
- 00:55:08called your centromere
- 00:55:12and then the ends okay these points here
- 00:55:16and these are called your telomeres
- 00:55:20now what happens is over time as your
- 00:55:22cells continue to keep replicating the
- 00:55:24dna replicates watch what happens to the
- 00:55:26telomeres
- 00:55:27they get shorter and shorter
- 00:55:31and shorter as that continues
- 00:55:34to happen there's a worry with this and
- 00:55:37let me explain what that worry is
- 00:55:40obviously your dna has particular areas
- 00:55:43which
- 00:55:43code for rna rna can then get translated
- 00:55:46to proteins what are those called
- 00:55:48they're called genes so let's say that i
- 00:55:50have a gene right here
- 00:55:52the telomeres will be there and their
- 00:55:54primary function
- 00:55:57is that they will it's common for them
- 00:55:59this to happen
- 00:56:01where the telomeres were short and short
- 00:56:02and shortened but the whole purpose of
- 00:56:04them
- 00:56:04is that telomeres don't code for
- 00:56:06anything that's very important let me
- 00:56:08write that down
- 00:56:09telomeres
- 00:56:12do not code for any rna
- 00:56:16so do not code
- 00:56:19for rna in other words you can't take
- 00:56:21the dna from a telomere make rna make
- 00:56:23protein that's important
- 00:56:25but let's say here there is a gene there
- 00:56:27that can make rna
- 00:56:28the telomeres will kind of sacrifice
- 00:56:31themselves
- 00:56:32because dna replication doesn't occur at
- 00:56:33this point for a particular reason we'll
- 00:56:35explain why
- 00:56:36and so because of that they prevent
- 00:56:40gene loss so they kind of like take the
- 00:56:43hit for us if you think about it
- 00:56:44they're like don't worry i don't code
- 00:56:46for any rna so you don't have to
- 00:56:47continue to replicate me
- 00:56:49so with each replication cycle the
- 00:56:51telomeres will shorten and shorten and
- 00:56:53shorten
- 00:56:53but that's okay and for a particular
- 00:56:56reason because they do not code for rna
- 00:56:58and they help to prevent gene loss but
- 00:56:59here's the problem eventually you're
- 00:57:01going to get to a point
- 00:57:02where the telomeres will shorten so much
- 00:57:04that it can interfere
- 00:57:06with the genes once that happens where
- 00:57:09the cell has reached the replication
- 00:57:10limit where it can't replicate
- 00:57:12anymore it's reached its maximum number
- 00:57:14there's a particular term
- 00:57:15that you guys need to know and it's
- 00:57:17called the hayflick limit
- 00:57:20it's called the hay flick
- 00:57:23limit and that is basically the maximum
- 00:57:25amount of times that this
- 00:57:26this kind of dna can replicate before it
- 00:57:28starts to involve
- 00:57:29genes now let's talk about
- 00:57:33why these telomeres are shortened really
- 00:57:35quickly
- 00:57:36let's say here we take and let's say
- 00:57:38that we use this as our example
- 00:57:39this is our leading strand and this is
- 00:57:42our lag
- 00:57:42strand right again let's just say here
- 00:57:45we have our three prime end
- 00:57:47we're going to use our rna primer here
- 00:57:50and then from here
- 00:57:51the rna primer was made by the what
- 00:57:53enzyme primase dna polymerase type 3
- 00:57:56will then add on to that 3-prime end and
- 00:57:58start making dna continuously
- 00:58:01all the way down the leading stream
- 00:58:02remember it was continuous
- 00:58:04so this will happen all the way down
- 00:58:07okay
- 00:58:08on the leading strand the lagging strand
- 00:58:11is where it becomes a problem
- 00:58:13remember you have that three prime end
- 00:58:16right
- 00:58:17and the five prime end the prime ace
- 00:58:19will have to add on to that three prime
- 00:58:20n so let's say it adds on
- 00:58:22right here at this three prime end when
- 00:58:24it does that
- 00:58:26it gives a little primer and then again
- 00:58:29dna will build built off of that here's
- 00:58:31another primer
- 00:58:33and then dna would be built off of that
- 00:58:34right so we kind of know that process
- 00:58:36this is pretty much
- 00:58:37you know a review of what we just talked
- 00:58:40about
- 00:58:41but here's what's different here watch
- 00:58:44what happens you guys your minds are
- 00:58:46about to get blown
- 00:58:48remember dna polymerase one what does he
- 00:58:50come in and do
- 00:58:51comes and plucks off the rna primer
- 00:58:55and then makes dna right
- 00:58:59on the leading strand on the lagging
- 00:59:01strand it'll come off and pluck this
- 00:59:02portion here
- 00:59:04okay that rna primer and when it plucks
- 00:59:07off the rna primer it still has a what
- 00:59:10remember this is the three prime end
- 00:59:12what would this be here
- 00:59:13five prime three prime so
- 00:59:17remember five prime this is a three
- 00:59:19prime end right here it still has a
- 00:59:21three prime
- 00:59:21n that it can use to build off of and
- 00:59:24make dna at this point here
- 00:59:29but watch what happens down here comes
- 00:59:31down to this end here
- 00:59:33plucks off these rna primers
- 00:59:37uh oh do i have a three prime end that i
- 00:59:40can add off of somewhere
- 00:59:42i don't dudes why because look this is
- 00:59:45my five prime
- 00:59:46end i have no three prime end here that
- 00:59:49that dna polymerase can add
- 00:59:51on nucleotides to so dna replication
- 00:59:54won't occur at these points here
- 00:59:57and that is problematic because guess
- 00:59:59what
- 01:00:00this was the old dna strand you
- 01:00:03replicated and made a new dna strand
- 01:00:05this one's going to get shorter it's
- 01:00:06shorter than the original one
- 01:00:08guess what happens when this one
- 01:00:09replicates it'll get the new strain will
- 01:00:12be shorter than
- 01:00:13it and then the next one and the next
- 01:00:15one and the dna will continue to get
- 01:00:16shorter and shorter and shorter
- 01:00:18and eventually start involving those
- 01:00:20genes
- 01:00:22so thank goodness in particular cells
- 01:00:24where we have a
- 01:00:26need a lot of replication to occur we
- 01:00:29have a special enzyme that comes in and
- 01:00:31says hey
- 01:00:32i'm going to elongate those telomeres
- 01:00:33for you so that way whenever dna
- 01:00:35replication does occur
- 01:00:36you don't start really taking away too
- 01:00:39much of the telomeres and involving
- 01:00:40these really important genes
- 01:00:42so what is the name of this special
- 01:00:44enzyme that we should give great thanks
- 01:00:45to
- 01:00:48this wonky looking enzyme here has two
- 01:00:50arms
- 01:00:51and this enzyme is called telomerase
- 01:00:57and telomerase is a really interesting
- 01:01:00kind of ribonucleoprotein
- 01:01:04one arm comes here okay so remember
- 01:01:06we're just looking at this portion here
- 01:01:08so we're only zooming in
- 01:01:10on this lagging strand about right here
- 01:01:12okay and zooming in on it
- 01:01:14so here we're on this portion where we
- 01:01:16didn't finish and synthesize the
- 01:01:18nucleotides because again we didn't have
- 01:01:19that three prime oh region here to add
- 01:01:22nucleotides off of the dna polymerase so
- 01:01:24what the telomerase does is it takes one
- 01:01:26arm
- 01:01:27and brings that arm out and on this arm
- 01:01:30is something really
- 01:01:31really cool it expresses nucleotides
- 01:01:37and a particular type of nucleotides
- 01:01:40that you guys really need to know okay
- 01:01:44and so what are these nucleotides that
- 01:01:46it has
- 01:01:48well what it expresses is
- 01:01:51complementary nucleotides that are
- 01:01:54commonly seen on the telomeres telomeres
- 01:01:56always have
- 01:01:57and the easiest way there's a mnemonic
- 01:01:58to remember them telomeres always have a
- 01:02:00particular repeat of nucleotides on them
- 01:02:03on their three prime end and the easy
- 01:02:05way you can remember that repeat
- 01:02:08is the mnemonic tell them all
- 01:02:12genes gotta go that is the repeat that
- 01:02:16you
- 01:02:16constantly see on that three prime end
- 01:02:19of that parental dna
- 01:02:21so what telomeres does is it comes in
- 01:02:23and says hey i have
- 01:02:24all the complementary rna nucleotides
- 01:02:28to this sequence that's commonly seen
- 01:02:30here so let's kind of write down what
- 01:02:32would the complementary portion be
- 01:02:34if it was t it would be a
- 01:02:38t it would be a a it would be
- 01:02:41u g all the way across
- 01:02:45it would be c c c so it expresses that
- 01:02:48with its one arm
- 01:02:50the other arm is really cool
- 01:02:54the other arm will then use
- 01:02:57this rna strand as a
- 01:03:00template to make dna that's
- 01:03:02complementary to it
- 01:03:04so if it does that it's going to take
- 01:03:05this rna read it and then what would be
- 01:03:07the complementary
- 01:03:08t t a
- 01:03:12g g g
- 01:03:17this is really interesting you want to
- 01:03:19know why
- 01:03:20i elongated my three prime n okay which
- 01:03:23is important i elongated it so that way
- 01:03:25next time this dna replicates i won't
- 01:03:27really
- 01:03:28take too much of the dna and involve
- 01:03:29those genes because the telomerase
- 01:03:32but what i did is i used rna
- 01:03:36and from that i made dna
- 01:03:41i need you guys to understand what
- 01:03:42that's called what is that called when
- 01:03:45you go from rna
- 01:03:47to dna reverse transcription
- 01:03:52this is called reverse
- 01:03:55transcription and so what this kind of
- 01:03:58telomerase does
- 01:03:59in a way is it has again it's a protein
- 01:04:03with
- 01:04:03it which expresses nucleotides it
- 01:04:05expresses rna
- 01:04:07and then it has this other arm this
- 01:04:08other arm that reads the rna
- 01:04:10and says oh okay this is a i'm going to
- 01:04:13make t
- 01:04:14on the parental strand that's a i'm
- 01:04:15going to make t on the parental strand
- 01:04:17so it can take rna and make dna
- 01:04:19elongating the telomeres
- 01:04:21why would we want to elongate the
- 01:04:24telomeres we obviously know to prevent
- 01:04:25gene loss and so we don't
- 01:04:27shorten those telomeres significantly
- 01:04:29and what cells would you want there to
- 01:04:31be a lot of telomerase
- 01:04:32enzymes are a lot high activity highly
- 01:04:35replicating cells
- 01:04:36cells that are replicating so much that
- 01:04:38those telomeres would shorten if we
- 01:04:40didn't have it
- 01:04:41so this is important you need lots of
- 01:04:44telomerase enzyme
- 01:04:46and what kind of cells
- 01:04:50primarily in like stem cells so if
- 01:04:54you're
- 01:04:54like if you're a zygote and you're
- 01:04:55starting with one cell you need those
- 01:04:57cells to have lots of telomerase
- 01:04:58activity to replicate
- 01:05:00and make the whole human body or your
- 01:05:03hema hematopoietic stem cells which are
- 01:05:05making red blood cells white blood cells
- 01:05:07all those different things you need
- 01:05:08those to be able to replicate and have
- 01:05:10enough telomerase enzymes so that it can
- 01:05:11replicate without hitting and losing
- 01:05:13those genes
- 01:05:14that's important one last thing clinical
- 01:05:16point
- 01:05:17telomerase what if we figured out a way
- 01:05:22cells certain damaging and really nasty
- 01:05:25cells
- 01:05:26figure out a way to evade
- 01:05:29uh the cell replication where they can
- 01:05:31just continue to keep replicating
- 01:05:33without
- 01:05:34not being able to stop what are that
- 01:05:35what is that called
- 01:05:37cancer neoplasia so cancer cells you
- 01:05:40know what they can do
- 01:05:41that we believe that they can do is they
- 01:05:44upregulate the activity
- 01:05:47of their telomerase enzymes and if they
- 01:05:50up regulate the activity of their
- 01:05:51telomerase enzymes they continue to
- 01:05:53elongate the ends of the dna
- 01:05:55on the chromosomes which allows for them
- 01:05:57to continue to keep replicating and
- 01:05:59replicating and replicating
- 01:06:00without shortening the telomeres enough
- 01:06:02that it starts to involve genes within
- 01:06:04that cells
- 01:06:05that's really interesting so
- 01:06:09really big thing i need you guys to take
- 01:06:10away telomeres
- 01:06:12shorten with every dna replication we
- 01:06:16can prevent that with telomerase enzymes
- 01:06:18which perform what kind of process here
- 01:06:21reverse transcription use one arm which
- 01:06:22is rna and build
- 01:06:24dna on the parental strand to elongate
- 01:06:27that
- 01:06:28and what types of cells normally would
- 01:06:30you see lots of telomerase activity
- 01:06:32normal stem cells highly replicating
- 01:06:34cells in our body
- 01:06:35or cancer cells which dysregulate or
- 01:06:37upregulate the telomerase enzymes
- 01:06:40all right ninja nerds that covers
- 01:06:42everything for dna replication
- 01:06:44all right ninja nerds so in this video
- 01:06:45we talk about dna replication i hope it
- 01:06:47made sense and i hope that you guys did
- 01:06:49enjoy it alright engineers as always
- 01:06:51until next time
- 01:07:01[Music]
- DNA Replication
- Semi-conservative
- Cell Cycle
- Leading Strand
- Lagging Strand
- RNA Primer
- Helicase
- DNA Polymerase
- Okazaki Fragments
- Telomeres