| 00:06 | Oh thank you. Mhm. Ok , let's go and get started. |
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| 00:55 | is annoying but it will disappear in than a minute. Okay, I |
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| 01:03 | so. Let me just do this . We got there we go. |
|
| 01:14 | that will disappear shortly. So um uh let's see. So I sent |
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| 01:23 | email this morning. So I think already aware of these announcements. Um |
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| 01:32 | . Go away. Go away. I see. I don't get |
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| 01:44 | Alright, hold on, let's All right. Oh thank you. |
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| 01:57 | . Alright. Um Alright blackboard Do monday open tomorrow basically covering stuff |
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| 02:06 | week. Chapter eight part one We'll talk about today mastering. So |
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| 02:12 | of those is due on monday. So schedule schedule opens I guess basically |
|
| 02:20 | tonight. Okay, so in eight I guess. So uh for exam |
|
| 02:27 | exam two is 20 21st. 22nd this month. Okay. Um so |
|
| 02:35 | couple weeks away so we'll finish up we'll finish up um this section Units |
|
| 02:48 | um but we still have until the . We have a little bit of |
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| 02:52 | over on that day but don't expect much. Chapter 12 is relatively |
|
| 02:57 | I'm not covering everything in there. kind of overview of some of the |
|
| 03:02 | of more larger I guess types you encounter in health care of those I |
|
| 03:10 | I mentioned last time bungle diseases maybe you might encounter. Um But again |
|
| 03:17 | depends on kind of where you end in the world. Some of these |
|
| 03:21 | kinds of diseases are are more common other parts of the world in |
|
| 03:25 | but specifically talking about protozoan diseases, like that, malaria for example, |
|
| 03:32 | others. So anyway, so it's relatively kind of really quick overview |
|
| 03:37 | those types but but certainly with the couple of lectures, we'll talk about |
|
| 03:43 | . Okay. Which I'm sure we're familiar with one virus in particular. |
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| 03:49 | most of them we want to be friend, not our friend, our |
|
| 03:54 | , Covid. Okay, so we'll about the nature of viruses today is |
|
| 03:58 | kind of definition, what are they the variations of them? So there's |
|
| 04:05 | kind of thing and kind of the of a life cycle. But we're |
|
| 04:09 | this more specifics um as we go to next week. So, but |
|
| 04:15 | need that. I just want to up this last bit of just to |
|
| 04:22 | of what we talked about on Tuesday of the horizontal gene transfer. So |
|
| 04:28 | to put that in perspective again, went through this kind of diagram where |
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| 04:32 | big, big circle of blue circle the coli it could be it could |
|
| 04:39 | any species really right, but we're on microbes. It could be another |
|
| 04:43 | type, What have you that they define a species by all the genes |
|
| 04:49 | and all the members of that species be homo sapiens, for example. |
|
| 04:54 | , and there will be a collection all the genes that are known in |
|
| 04:58 | species only Anyone given species in that group is going to have a subset |
|
| 05:06 | those genes. Okay so E coli average is about 4 48 100 of |
|
| 05:12 | 10,000 genes that are known to be E. Coli. And then a |
|
| 05:17 | then well not that small subset but E coli eyes. Okay we'll have |
|
| 05:23 | in common. It's basically what defines E. Coli. But uh typically |
|
| 05:28 | be things like involved in critical functions DNA replication protein synthesis. These are |
|
| 05:36 | all the coal I do they're gonna genes that are gonna be specific for |
|
| 05:39 | . Okay that they all share. so the point of this is that |
|
| 05:46 | you might think that okay because you bacteria divide by binary fission. Everybody |
|
| 05:52 | the same and we know that they're right that they do acquire variation through |
|
| 05:57 | that we talked about and through horizontal transfers. Right So these mechanisms of |
|
| 06:04 | cells in the population could can can with each other. Okay and so |
|
| 06:13 | went through the mechanisms uh last time . Conjugation trans deduction transposition. So |
|
| 06:21 | know you should have you know be to spot which one is which okay |
|
| 06:26 | do have a fairly distinctive features, they could take a D. |
|
| 06:31 | A congregation to be involving a Certainly cell to cell contact. Right |
|
| 06:37 | unique to it, transaction virus. the is the connection there transposition? |
|
| 06:45 | A transpose on. Okay that contains transpose ace to kind of help cut |
|
| 06:52 | kind of cut and paste function if will. Okay um so so and |
|
| 06:59 | remembering that with all these mechanisms right this piece of DNA coming into the |
|
| 07:06 | right? Either through transformation conjugation. duck sh in right? That that |
|
| 07:13 | . N. A. We'll have somehow combined recombined right with the |
|
| 07:20 | If it's a plasma it can stay out here by itself but we know |
|
| 07:25 | that also it can also integrate. so really the main thing is about |
|
| 07:31 | part two. Chapter eight. Okay with that mind this next thing is |
|
| 07:36 | not a clicker question. Just kind a let's see what we can do |
|
| 07:39 | with this. Okay so again just identifying the four types and whether the |
|
| 07:45 | for the four types for and they're be more than one answer here. |
|
| 07:48 | for conjugation what would fit with anybody throw something at it throw something |
|
| 07:56 | me? He got seven choices. one? Come on. Three |
|
| 08:03 | Yes. Three. Anything else? yes correct. Okay um transformation and |
|
| 08:21 | . There is a term that relates transformation to um Anything else? |
|
| 08:33 | Yes of course. OK um Trans sh in. Yeah of course one |
|
| 08:40 | . Um for transposition five. Yeah . Anything else? Yeah 4. |
|
| 08:54 | and five and actually five you can with all these they can be a |
|
| 09:00 | recombination can be a feature of all four of these things. Okay, |
|
| 09:05 | again, just you should be familiar kind of the basics of how you |
|
| 09:09 | identify each one. What's unique to of thing? Okay. Um any |
|
| 09:14 | about any of those processes? Alright. So let's look At |
|
| 09:23 | So we're gonna switch to 13. talk about viruses. Okay, for |
|
| 09:26 | next couple of lectures here. So as I mentioned, so we're gonna |
|
| 09:31 | gonna you should be able to say word virus that. Okay, here's |
|
| 09:35 | it is. The basic definition here some here's the here's the basic |
|
| 09:40 | there's a basic feature that defines all which will learn shortly. There's gonna |
|
| 09:45 | variations that can be that we'll see that. Um You should know the |
|
| 09:51 | life cycle. Okay. We'll go that. There'll be specifics for certain |
|
| 09:57 | and we'll go through that as Um No where to host ranges. |
|
| 10:03 | classification and kind of just very very terms and the we start in terms |
|
| 10:09 | life cycles. So the viral life can be somewhat complicated. And so |
|
| 10:16 | why we typically always start with the bacterial viruses because they're gonna be |
|
| 10:21 | Okay. And so a bacterial viruses simpler, relatively speaking in terms of |
|
| 10:29 | life cycle than an even entry into cell. Remember virus needs a host |
|
| 10:34 | course, which I'm sure we all . And so that the entry process |
|
| 10:39 | a bacterium and the life cycle of bacteria viruses generally simpler than than an |
|
| 10:44 | virus. Anybody know why would be very reason why it would be not |
|
| 10:50 | a complicated thing. And a bacterium to eukaryotic cell small. True. |
|
| 10:57 | the what's the basic difference between one your cells and the bacterial cell? |
|
| 11:01 | cell is a carry out. So goes with the complication of the cell |
|
| 11:07 | . Right? So you carry out organelles like a nucleus and in a |
|
| 11:12 | particular um golgi apparatus. All this in there. Right. And viruses |
|
| 11:18 | those things animal viruses. And so can be they can be in different |
|
| 11:23 | and in the animal cell depending on kind of virus they are. So |
|
| 11:26 | that reason, because the cell it is complicated. More so than the |
|
| 11:32 | . The viral cycle can be a bit more complicated. So that's how |
|
| 11:36 | start with the bacterial viruses first. that reason. Okay, so um |
|
| 11:44 | let's start here with this question. . And this is a clicker question |
|
| 11:49 | open it up. So which of following is false concerning viruses. This |
|
| 11:55 | of goes really to the features of virus and there are some features common |
|
| 12:01 | all viral types. Um so things uh some features like an envelope. |
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| 12:15 | and so forth. Okay. Okay, counting down from 10 |
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| 12:48 | Okay, pause for any stragglers. right, counting down from three. |
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| 13:03 | . Um, yeah, they are a a cell. Nor are they |
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| 13:09 | precarious cell. Okay, so that's one of the more defining features. |
|
| 13:14 | that Okay? Um, we always the term a cellular to describe the |
|
| 13:21 | . Okay. And so certainly the basic all viruses have this um |
|
| 13:28 | They have a genome of course, they're surrounded by a protein coat. |
|
| 13:31 | all have that. But then there's be lots of variations beyond that. |
|
| 13:35 | that protein coat is what's called a . Okay. The uh, I |
|
| 13:42 | I should say state this now. you kind of get it in your |
|
| 13:46 | because we'll talk about this next Is there's also something called a viral |
|
| 13:51 | . A prion. Okay. And in this same they're always lumped together |
|
| 13:57 | viruses. Okay. But these are considered viruses. Okay. And |
|
| 14:07 | when you get to this part of notes, it says the same |
|
| 14:09 | But I figured I'd just start getting your head now. So they're not |
|
| 14:14 | , viruses have a particular structure to . Right. These are their infectious |
|
| 14:19 | in the prime. But they're just very viral is basically just a piece |
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| 14:24 | RNA. And that's it. Viral is a protein and that's all there |
|
| 14:29 | to it. Okay, So you the structures of the virus, but |
|
| 14:33 | though they're very simple, they still infectious. I think it can cause |
|
| 14:37 | . But we'll talk about those I just want to point that out |
|
| 14:41 | . So certainly they're tiny. Um in terms of size and because |
|
| 14:46 | small, right, they're going to a genome that's going to be relatively |
|
| 14:51 | as well. But it can be or DNA single strand of double stranded |
|
| 14:56 | variations. Um and an envelope. an envelope is what they may |
|
| 15:01 | Envelopes are generally features of animal Not bacteria viruses. Okay, uh |
|
| 15:07 | talk about that as well. so um so let's look at kind |
|
| 15:12 | comparing these types. So here our of bacterial cells and viruses. |
|
| 15:21 | So you can you have a bit a quasi viral type. So by |
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| 15:29 | I mean a parasites and viruses are because they need a host. |
|
| 15:33 | So you do have bacterial types in category that um have I mean they're |
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| 15:40 | bacterial cells, there's no doubt but actually have a lot of functions they |
|
| 15:44 | do on their own. So actually life cycle actually involves living inside of |
|
| 15:48 | cell. Okay. And rocket CIA types uh you particularly get those through |
|
| 15:55 | bite of a tick. Okay. but they're the type that will infect |
|
| 16:00 | and kind of that's kind of their . They hang out in there and |
|
| 16:02 | where they grow. Um So those can't for that reason they can't have |
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| 16:07 | similarities to a virus. Okay, course you can see here certainly that |
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| 16:12 | are parasites. Right. Um, plans for membrane. There's no such |
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| 16:19 | as boundary vision. Okay. they can pass through filters that would |
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| 16:27 | stop a bacterium of course, reach small size. Um, their metabolism |
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| 16:34 | really no energetic metabolism in the Okay. Um, ribosomes are typically |
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| 16:41 | as well. Right? Uh, to be antibiotics. No. |
|
| 16:45 | You can't There's antibiotics don't work on virus. Right? Because really because |
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| 16:49 | don't have the components of the cell because antibiotics target particular processes in a |
|
| 16:55 | like protein synthesis and identification. And virus doesn't have that internally. |
|
| 17:01 | so, but there can be antiviral that work against viral specific things, |
|
| 17:08 | antibiotics don't. Okay, um, on this is something we'll talk about |
|
| 17:15 | the context of your innate immune You have a defense that involves interferon |
|
| 17:22 | will stop a viral infection. so, um, so speaking of |
|
| 17:28 | filters, right, being able to through those that's actually how they were |
|
| 17:33 | . Okay, that's what we see Janowski and beiring. So they were |
|
| 17:39 | at this tobacco mosaic. What? looking at the this disease that in |
|
| 17:45 | plants. Okay. Um, and normal plants, of course they |
|
| 17:51 | You're usually looking green leaves. Tobacco do because these ones have that kind |
|
| 17:55 | appearance. Okay. And they can't and they die. Okay. |
|
| 18:03 | um, so at this time it like 18 nineties, I want to |
|
| 18:07 | early 19 hundreds. So the germ was well known by this time. |
|
| 18:13 | so it became they thought, okay this plant disease must be due to |
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| 18:18 | sort of microbe. Okay, let's cokes postulates to figure this out. |
|
| 18:23 | ? So instead of using a rabbit or model, they used obviously the |
|
| 18:28 | . And so they basically took the leaves, took a disease one, |
|
| 18:34 | it up, okay. And made like a paste out of it and |
|
| 18:37 | um paste, then ran it through filter and then they have filters in |
|
| 18:42 | time that could stop the cells that bacterial sized. So I thought, |
|
| 18:47 | , easy enough, we'll put it a filter, it'll stick on top |
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| 18:50 | the filter and that's that's where we'll a micro they did that and applied |
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| 18:55 | to a normal leaf and a normal never became diseased. It was just |
|
| 19:00 | normal. And they go, what's this about? I guess somebody |
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| 19:04 | ideas to say, okay well let's what went through the filter infiltrate and |
|
| 19:09 | there something in there maybe? And they did that then they found the |
|
| 19:16 | , the plant became diseased. And they said, okay this is something |
|
| 19:19 | weird because it's super small. They even aware of things. Microbes that |
|
| 19:24 | be that small. And so that's kind of led to discovery of |
|
| 19:28 | that's actual virus here. And it on the small end in terms of |
|
| 19:33 | sizes 20 nanometers 200.2 microns. That is the lower end size. |
|
| 19:40 | really we're dealing with something small even by virus standards. And so um |
|
| 19:48 | But at this time they didn't have capabilities to to see these things. |
|
| 19:52 | came like 30 years later the electron was discovered. But nonetheless, so |
|
| 19:59 | viruses and of course they can span ranges as mentioned. Um as big |
|
| 20:05 | Ebola. We don't talk about it . But there's been virus is discovered |
|
| 20:09 | the last five years that are approaching are over a micron. They're called |
|
| 20:16 | viruses. And uh there they are that affect different types of like amoebas |
|
| 20:22 | things. They're not super prevalent but are they are supersized. Okay. |
|
| 20:28 | again most most of what we know terms of viruses fits in this |
|
| 20:32 | Okay. And then they have different , what we call helical. Uh |
|
| 20:36 | gonna have like these geometric shapes like um as we'll see. So but |
|
| 20:43 | course the thing is that they um a cell. They take it |
|
| 20:47 | They don't have a lot of functions their own. So they have to |
|
| 20:50 | a cell and take it over and make it a virus factory. |
|
| 20:55 | So what they do and so um long and when I studied the notice |
|
| 21:01 | college and learning about viruses. uh was I never heard of a virus |
|
| 21:07 | didn't do anything, they had let's say good purpose. Okay, |
|
| 21:11 | all over disease causing all this bad . But In the last 10, |
|
| 21:17 | , 20 years that has changed. viruses do have are ecologically important. |
|
| 21:24 | they can control populations of species in environment when you do that, you |
|
| 21:30 | kind of minimize the effect of having dominant species where it's really only one |
|
| 21:35 | predominates and get more diversity and viruses have found to be very important in |
|
| 21:41 | that. Okay, so the point not all viruses are bad. They |
|
| 21:46 | have an important role in the but certainly you are familiar with viruses |
|
| 21:53 | mostly disease causing. Okay, so and almost everything on earth can be |
|
| 22:01 | has has has a virus that infects . Right? So be it an |
|
| 22:06 | , be it algae or proto zones animals? Of course plants they all |
|
| 22:13 | likely can succumb to a viral type specific for them. Okay, so |
|
| 22:18 | are pretty well distributed. Um here's the next question. So this |
|
| 22:23 | of goes into the the uh life and what kind of what needs to |
|
| 22:32 | first in order for that to This is really the probably one of |
|
| 22:36 | most important things from the perspective of virus, what it needs to |
|
| 22:40 | Okay, and while you're answering So this term very in. |
|
| 22:48 | You see, variant virus, I those interchangeably. They don't they don't |
|
| 22:53 | anything different to me. Right. if you see that term it's just |
|
| 22:57 | virus. Okay, Berrien virus, thing. So basically these are all |
|
| 23:25 | elements of viral life cycle or can okay, but there is an order |
|
| 23:33 | it. Okay, let's count down . Yeah, it is gonna be |
|
| 23:47 | for sure. Okay, so we're the host. Okay, so um |
|
| 23:55 | where it begins or ends for the . Okay. And so those you've |
|
| 23:59 | seen I'm sure you've all seen pictures of coronavirus and it has those little |
|
| 24:04 | things all over the surface. It's those things that it recognizes on |
|
| 24:09 | of your cells and then been able infect. Okay. If your cells |
|
| 24:14 | have those then it wouldn't be able infect. Okay. And so certainly |
|
| 24:21 | this is gonna be a feature of viral life cycle translation of proteins. |
|
| 24:27 | replication of genome. Uh this one for all viruses. Right. Obviously |
|
| 24:33 | bacterial viruses. That's not the There's no nucleus. Right. But |
|
| 24:37 | many it is. Um so um we look at uh definition. |
|
| 24:45 | as mentioned already a Sailor is the we use right there. We have |
|
| 24:49 | features that we associate with most Okay. Um can divide on their |
|
| 24:54 | can produce proteins on their own can replicate on their own a metabolism. |
|
| 25:03 | things you don't associate with viruses. . So hence the term a |
|
| 25:06 | So they require a host. Obligate it's a requirement. So obligate |
|
| 25:11 | Okay. The caps it is the covering. Okay so all viruses the |
|
| 25:17 | basic have that protein covering that covers genome. And the genome can be |
|
| 25:23 | . D. N. A single double stranded. Okay. So if |
|
| 25:27 | look at a basic viral life So as we go through this this |
|
| 25:35 | I pointed out asterisks where there can variations. Okay. And the way |
|
| 25:40 | best um I think uh comprehend this to look at what's what's infecting the |
|
| 25:49 | . And we have host proteins on surface of some sort and that's and |
|
| 25:54 | viral proteins on the surface of its . They recognize each other kind of |
|
| 25:59 | , lock and key kind of a . Okay. And so it'll have |
|
| 26:04 | use certain parts of the host uh . Okay. And so what I've |
|
| 26:12 | to risk those what can vary. some viruses need those. Some don't |
|
| 26:17 | carry it with them and some So some viruses are more deficient in |
|
| 26:22 | of what they have and other viruses it varies by viral species. |
|
| 26:28 | But certainly ribosomes, the other machinery protein synthesis, ribosomes, tr. |
|
| 26:33 | . A. S. Nuclear Those are all gonna be needed. |
|
| 26:37 | . They don't they don't bring those them. Okay. Again they don't |
|
| 26:40 | a metabolism. So as as they're the hosts, remember? They're they're |
|
| 26:45 | stuff from the host. So that they're taking their stopping that host of |
|
| 26:50 | . Right? That host certainly wouldn't as happy and as as functional um |
|
| 26:58 | having that virus inside doing what it's to it. Okay. So the |
|
| 27:01 | is certainly suffering, right? It's parasitic relationship. The host isn't is |
|
| 27:05 | benefiting from that of course. So takes a toll on in terms of |
|
| 27:09 | that toll on the cell is growing . Not like like not like a |
|
| 27:15 | would perhaps probably dying likely gonna die or later. If not sooner. |
|
| 27:22 | , so there is a consequence of . Okay. In terms of the |
|
| 27:26 | . And so um now the so of basic cycle. So viral genome |
|
| 27:35 | uh and that can differ whether it's bacteria virus, bacteria viruses generally only |
|
| 27:42 | genome matters. Everything else stays Okay. For animal viruses, the |
|
| 27:48 | thing can come into the cell. . Um Now, once the genome |
|
| 27:53 | in the cell it can begin to copies. So what you have to |
|
| 27:57 | is, right, this is what's in. Okay. And then what |
|
| 28:01 | gonna have are a bunch of they're gonna exit the cell eventually. |
|
| 28:08 | . And if you're going to do , okay, You're gonna have to |
|
| 28:13 | lots of virus babies. Right, gonna exit the cell. Well then |
|
| 28:19 | have to number one make a genome goes in each one. Right, |
|
| 28:24 | our genome. Right? We have this thing. The little boxes I |
|
| 28:32 | around these genomes. That's the Right? That's this. That's |
|
| 28:36 | Make lots of protein. You need make our proteins. You need to |
|
| 28:39 | copies of genome. You need to it all together. Right. And |
|
| 28:44 | that takes quantities of material. Because one's coming in and then a |
|
| 28:51 | a bunch of them are coming Okay. So that means a lot |
|
| 28:54 | stuff is going to be going on the cell to make that happen. |
|
| 28:57 | . One of the stuff doesn't make of genome. Okay. The now |
|
| 29:01 | happens to that genome? If it's packaged packaged into a virus capsule, |
|
| 29:07 | it may some virus life cycle is okay, I'm not gonna do that |
|
| 29:11 | . I'm gonna stick out and put in the host chromosome. Okay. |
|
| 29:16 | that's what it does. So things herpes virus does that. It uh |
|
| 29:22 | you've ever had experienced fever blisters, ? Where all of a sudden it |
|
| 29:25 | out, that's a herpes virus that's this genome into that cell. And |
|
| 29:32 | you haven't noticed anything. Right? you have those fever blisters that's actually |
|
| 29:37 | virus coming out of the chromosome and viral copies now? And what can |
|
| 29:42 | can trigger that can be stress stress one of the triggers for that. |
|
| 29:46 | that manifests itself is like a fever . Okay. One example HIV is |
|
| 29:52 | one that does this. Okay so just different different viruses have different strategies |
|
| 29:57 | that's one is to integrate into the and while it's doing that the host |
|
| 30:02 | completely fine and it just grows and whatever is going on with it. |
|
| 30:07 | . But while that host cell is right of course it's making copies of |
|
| 30:13 | viral genome as well. So viruses getting more and more in terms of |
|
| 30:19 | cell divides. So we'll talk about couple of those life seconds but that |
|
| 30:23 | a strategy. Okay so eventually even it does that it's gonna have to |
|
| 30:29 | our particles if it wants to perpetuate we have to go and make |
|
| 30:34 | Okay so what's happening here then is the cell is taking the virus will |
|
| 30:41 | it over then and use it to copies or make viral particles. So |
|
| 30:47 | making it a replication factory basically. what they call inter sailor replication |
|
| 30:53 | And so again what's this involved? and translate viral genes and proteins then |
|
| 31:00 | these units put genomes in right and exit and then go on to infect |
|
| 31:07 | cells. Okay so that ultimately is will happen here. Okay and it |
|
| 31:15 | be immediate. It could go to route very quickly and overwhelmed to sell |
|
| 31:23 | and kill it or it may go way hang out for a while then |
|
| 31:30 | this. Okay. Or it may do that at a slow rate. |
|
| 31:34 | it can span the spectrum. It crank out viruses very quickly. It |
|
| 31:38 | just do them slowly. You cannot it at all and hang out in |
|
| 31:43 | cell. Uh So again all depends the viral type. Okay. Um |
|
| 31:49 | you know if it does have the of just sitting the chromosome doing |
|
| 31:53 | you don't even know you're infected, . Until this begins to happen. |
|
| 31:59 | , so again it's a lot of here depending on and the virus |
|
| 32:04 | Okay. Um Okay so and well we revisit this whole virus life cycle |
|
| 32:12 | we look at specific ones. But kind of the basics. Okay, |
|
| 32:18 | in terms of structure, right, already know we have a protein structure |
|
| 32:21 | that. The captain uh can shape vary, you can have these 20 |
|
| 32:27 | um geometric structures, uh some can kind of fila mentis or helical, |
|
| 32:33 | call it like you see here Ebola that type? Um The genome of |
|
| 32:37 | can vary. DNA RNA single double the envelope. Okay, so if |
|
| 32:43 | have an envelope then you have a around your caps it right. That |
|
| 32:50 | be an envelope. Okay. That comes from when it exits the |
|
| 32:57 | Okay, so you'll have a Okay and here is the viral particle |
|
| 33:03 | assembled. Okay. And when it it will do this that and here's |
|
| 33:14 | viral particle so it kind of pinches , so to speak. So as |
|
| 33:19 | exits. It does that and eventually it has that the host membrane |
|
| 33:27 | So that's where the envelope comes from from the host cell membrane itself. |
|
| 33:31 | . As it exits and it can it can direct synthesis viral proteins, |
|
| 33:42 | role proteins that can assemble and be into the membrane. And so when |
|
| 33:49 | exits then it has its viral proteins . Okay, um and that's important |
|
| 33:58 | course for recognition finding the right host binding to it. Right. So |
|
| 34:05 | uh that's a process that envelope viruses go through. Okay. Now as |
|
| 34:11 | said before, it's your animal viruses will do this. Not your bacterial |
|
| 34:15 | types, but animal viruses will do . Okay. And uh we see |
|
| 34:21 | there. And so the the let's here. So a naked virus, |
|
| 34:31 | one that doesn't have an envelope. . And so flu virus has an |
|
| 34:37 | . Um This is one that wouldn't could be a virus which is |
|
| 34:41 | D. N. A. Type D. N. A virus. |
|
| 34:43 | guess the simple herpes virus is one like that. So it doesn't have |
|
| 34:46 | envelope but it can it doesn't mean not infectious because it certainly is. |
|
| 34:52 | . So the envelope is just a . Some have some don't. Okay |
|
| 34:57 | and uh naked virus would not have envelope. Okay, those glycoprotein spikes |
|
| 35:03 | knobby things, those are typically for recognition of the host infected. Um |
|
| 35:12 | can be other certainly other proteins sticking there with different functions to. |
|
| 35:17 | flu virus has has types of surface that summer for entry and some of |
|
| 35:24 | exit of the cell actually. So can it can it can have different |
|
| 35:27 | . Okay um now the complex viruses kind of like the name implies you |
|
| 35:36 | kind of a typical structure we just right, that caption structure but then |
|
| 35:41 | have additional parts to the thing. , so you can see the different |
|
| 35:46 | shown here below. That's what we complex viruses. Right. And so |
|
| 35:52 | is typical for bacterial virus, this of structure. Okay, so down |
|
| 35:57 | these parts are really about the So we recognize the host cell surface |
|
| 36:05 | through these tail fibers they call Right? Because it's gonna sit on |
|
| 36:09 | surface of the cell. Okay. then this part what they call the |
|
| 36:14 | will actually compress. Okay, that's . Like a spring. It kind |
|
| 36:19 | squeezes down and that actually shoots the genome D. N. A. |
|
| 36:26 | the that's held in the captain is into the cell cytoplasm. That's typical |
|
| 36:33 | a bacterial virus. Okay, because all that goes in the cell is |
|
| 36:38 | genome. All this stuff stays outside cell. And basically it's just an |
|
| 36:45 | shell. And they call those things . Really? That's what you see |
|
| 36:49 | here. Right. So this one has its genome in its caps it |
|
| 36:56 | this one looks like it's yeah it's . So you can see how part |
|
| 36:58 | it is still in the capsule and in this little sheath area and it's |
|
| 37:03 | of it's here. So it's in process of going into self the one |
|
| 37:07 | the middle. That's a ghost. nothing in the captured the genomes already |
|
| 37:11 | itself. That's that's typical for viral bacterial virus type in china. Um |
|
| 37:19 | again don't don't worry about the variant mean the same thing. Okay, |
|
| 37:25 | uh infectivity. Right. So the is what it's all about for the |
|
| 37:30 | to be able to recognize a particular cell type and effect. If it's |
|
| 37:34 | there it won't. And that's where range comes in. So there's host |
|
| 37:39 | and then there's um then there is book says it calls it something |
|
| 37:47 | Yeah. So there's actually a term . You don't need to worry about |
|
| 37:52 | because your book doesn't use it. the term is called trope is um |
|
| 37:57 | , so you have tissue specificity and have host range. Okay, similar |
|
| 38:05 | different. Okay, so host range rabies is a perfect example, |
|
| 38:11 | Because we all know we all know can affect humans, dogs, |
|
| 38:16 | bats, um squirrels. All kinds different mammals. Right? So it |
|
| 38:22 | a wide host range. It can all those different animals. Okay. |
|
| 38:28 | HIV narrow right? It infects um humans and it also has a narrow |
|
| 38:37 | specificity. So when you talk about specificity now you're going from you're not |
|
| 38:43 | about how many different hosts can It's how many different cell types within |
|
| 38:49 | host can infect. Okay so a virus, okay it actually has um |
|
| 38:58 | very broad host range. Many different but a very narrow um tissue |
|
| 39:04 | Okay because it only affects nerve Okay um so a Ebola has relatively |
|
| 39:16 | host range um but it can affect different cell types in the body. |
|
| 39:22 | . And that's really what Gives it how tells you about how I gives |
|
| 39:29 | this lethal itty. It's so So if you get infected by Ebola |
|
| 39:34 | best you have a 50% chance of right upwards of 90% mortality. So |
|
| 39:41 | times out of 10 your life you it. Okay because it can affect |
|
| 39:45 | cell types in the body. People that die from Ebola or it's |
|
| 39:49 | type of viral disease called a hemorrhagic virus they call it because it can |
|
| 39:55 | basically your body the fluid just come of you right because they can infect |
|
| 39:59 | cells that make blood vessels and cause to start leaking. It can infect |
|
| 40:04 | different types of epithelial cells in different types and so that explains why it's |
|
| 40:11 | deadly. Okay um a narrow tissue . So as mentioned, maybe virus |
|
| 40:18 | nerve cells. Um nerve cells of central nervous system. Uh cold |
|
| 40:25 | respiratory tissues. Um HIV HIV very . So it affects only one specific |
|
| 40:32 | type and that's what we call t cells. We'll talk about those |
|
| 40:36 | But so again host range. How different um Always equate if you if |
|
| 40:46 | confused. Just think of rabies. . In fact many different animal |
|
| 40:49 | That's the broad host range. But then when you go to tissue |
|
| 40:54 | in a squirrel, how many cell can rabies? In fact? Well |
|
| 40:58 | nerve cells. So narrow tissue Okay um Any questions on that? |
|
| 41:07 | so genome so just mentioned this um is you know, genome size of |
|
| 41:14 | varies by size of the virus. so something like polio virus, uh |
|
| 41:21 | pox, you may have heard that . Those are kind of on the |
|
| 41:25 | end. So you know they'll have 10 times more genes than something that's |
|
| 41:31 | . Like the tobacco mosaic virus. was like 20.2 microns. So that |
|
| 41:38 | will limit things. The so what the virus specific genes? Well, |
|
| 41:45 | that are involved in being able to a host cell, there's gonna be |
|
| 41:49 | genes. The captured proteins are gonna viral genes. Of course. Okay |
|
| 41:54 | there are certainly going to be all viruses don't carry a lot of stuff |
|
| 41:57 | them. There will be certain Things have to viral genes, they have |
|
| 42:03 | code for proteins will have to make a virus proteins and you can see |
|
| 42:07 | here these different protein types okay that part of the Zika virus and you |
|
| 42:13 | if you want to give an average is probably about average size 10-11,000 nucleotides |
|
| 42:20 | represents not a lot of genes. this is just an example of something |
|
| 42:24 | don't you don't need to memorize this . Okay, this is just an |
|
| 42:27 | of of viral genes and that they they have proteins that are virus specific |
|
| 42:34 | they have to have to carry out infection their life cycle. Okay. |
|
| 42:38 | very common that viruses really even bacterial , infectious organisms disease causing microbes, |
|
| 42:48 | or bacterial, there's kind of a element to when they express their genes |
|
| 42:54 | some genes are involved in getting in into the host and then there's genes |
|
| 42:59 | in kind of setting up the infection then some that come later. So |
|
| 43:02 | very common to refer to especially viral as being early or late, early |
|
| 43:08 | late for that reason because there's different of the life cycle that occur at |
|
| 43:13 | times. Um The uh okay here's I just do this in here just |
|
| 43:19 | show you just to reiterate this point infectivity. Okay and they have a |
|
| 43:26 | narrow uh tissue specificity. So these um receptors that will be in your |
|
| 43:32 | the ravioli of course is where you oxygen. So those cells are in |
|
| 43:37 | lungs obviously and exchange auction with the . And so they actually affect these |
|
| 43:43 | of recognize these particular proteins on those and that's where they bind to. |
|
| 43:50 | . And so that goes to the of how covid can cause you know |
|
| 43:56 | a pneumonia like effects. Okay um with respiratory system breathing and build up |
|
| 44:04 | like that. Okay. Um I threw this term in here. I |
|
| 44:09 | expect you to know this but um used to seeing maybe longer you study |
|
| 44:16 | and what not to look at this . You think that your typical virus |
|
| 44:21 | with a caps ID. Okay. here's the genome. Okay. That |
|
| 44:28 | what all viruses would look like. and there's a variation that involves |
|
| 44:36 | Okay, so what can happen is said this structure it can have have |
|
| 44:45 | . So the genome okay, is self gets coded with protein. |
|
| 44:58 | I think so. I'm not gonna the whole thing out but that we |
|
| 45:03 | a new clio cleo capsule. Did . Right, So in essence the |
|
| 45:13 | for this kind of virus is one just simply coast the genome. It's |
|
| 45:18 | its own thing out here. Like a box covering it. It's |
|
| 45:23 | intimately associated with the genome. And that's a variation. Okay, when |
|
| 45:32 | if you see the term nuclear caps that's what we're talking about and that's |
|
| 45:36 | coronavirus has. So here here is genome. It's almost like an intestine |
|
| 45:43 | way they drew it. But I know if you can see there is |
|
| 45:47 | a very thin blue line that goes the thin blue line is the actual |
|
| 45:54 | the more blobby reddish. That's the protein covering it. Right? So |
|
| 45:59 | is basically then the capital structure for and it's surrounded by an envelope. |
|
| 46:04 | so you see that in in not viruses that that's what they look |
|
| 46:10 | They're they're caps it is basically kind protein stuck all along the genome covering |
|
| 46:16 | . Okay so you you do see variation. Okay. Um so flu |
|
| 46:24 | is um unique and bring that up whereas most genomes um viruses have are |
|
| 46:34 | linear segment of DNA. Or Um The flu virus has what's called |
|
| 46:44 | segmented Genome. So the the chromosome broken up into pieces. Right? |
|
| 46:53 | flu virus eight segments. Okay. so those eight segments. So one |
|
| 46:58 | the things is when a virus infects know I mentioned earlier that one virus |
|
| 47:03 | in and several come out but you you can have viruses of the same |
|
| 47:09 | infecting the same cell um flu virus affect. Um and if you have |
|
| 47:17 | to virus to flu viruses infecting at same time they can exchange these |
|
| 47:23 | Okay they can recombine and exchange And viruses coming out of that cell |
|
| 47:29 | be combinations of these. Okay and flu virus has its origins in aquatic |
|
| 47:37 | , initially things like ducks and wild birds that then went to domestic |
|
| 47:44 | like also ducks and geese and Okay. And then uh then to |
|
| 47:52 | swine pigs. Okay. And so remnants of those various hosts are found |
|
| 48:00 | the genome. And here they have coded. So you see like the |
|
| 48:03 | ones, domestic ducks, yellow wild birds, domestic poultry red. |
|
| 48:09 | . And so you see the combinations . Okay and uh of course you |
|
| 48:14 | mix it in with swine as And so these rearrangements occur and that's |
|
| 48:20 | these ancient end numbers come from. these are on the surface this will |
|
| 48:26 | be things here proteins uh green are h blue at the ends. So |
|
| 48:32 | you have a whatever during flu season always one that kind of predominates and |
|
| 48:37 | give it like an agent and end which relates to the type of agent |
|
| 48:43 | proteins they have. These can change season to season because of this recombination |
|
| 48:47 | can occur in these viruses. Um in generally viruses and this is an |
|
| 48:55 | viruses. RNA viruses are really um are made when they're copying their genome |
|
| 49:03 | they're not fixed. So they're very notorious for having lots of mistakes in |
|
| 49:07 | nucleotide sequence and that can lead to that occur especially in the flu |
|
| 49:13 | And so we all know a flu . You get one season will not |
|
| 49:16 | the next season because because they evolve they change for this reason. Okay |
|
| 49:21 | um and all viruses do. But done some reading on this D. |
|
| 49:26 | . A viruses don't tend to be as careless let's say in terms of |
|
| 49:31 | so many mistakes. So making mistakes replication is not uncommon. But we |
|
| 49:38 | very rigorous ways to fix those So we our ability to let a |
|
| 49:44 | go on changes very rare. But as you go to other species |
|
| 49:52 | not so much. And so the because they're parasites, they don't really |
|
| 49:57 | that system in them. So why they? So they tend to have |
|
| 50:01 | rates of mutation for that reason. . They can't go really nearly and |
|
| 50:05 | everything up because then it just won't function. But it can certainly make |
|
| 50:11 | . And some of those stick and of those enabled uh to change how |
|
| 50:16 | looks to the body. Right? changing this these these things that's what |
|
| 50:20 | body sees, right? And if change it up then your body doesn't |
|
| 50:24 | it and that's how it can go . Escape and cause disease. |
|
| 50:29 | Nature of the virus. Okay. and so and that's what we make |
|
| 50:36 | are the parts we use really when make vaccines is to use these. |
|
| 50:42 | . And that will you inject the and they produce antibodies to these parts |
|
| 50:48 | the virus is constantly changing. And know that's how the effectiveness of the |
|
| 50:52 | can vary because we may not have the right construct in the beginning. |
|
| 50:57 | maybe the vaccine is only maybe 10% or something. So that that varies |
|
| 51:02 | season to season how effective the flu is. Okay. So because you |
|
| 51:08 | always predict exactly what the virus will from year to year anyway. So |
|
| 51:16 | always comes back to like what's what's the outside here because that's what it |
|
| 51:20 | and how it gets into the host . Okay. Um so in terms |
|
| 51:26 | virus structure, it's just a right? So just a recap of |
|
| 51:31 | structure. Um so we defined it a sailor. I didn't list |
|
| 51:37 | but there's there's other features here, course requires a host, no metabolism |
|
| 51:43 | . Uh Captain type. Right? it can be that geometric shape or |
|
| 51:49 | can be like a filament or a shape. Okay, genome type of |
|
| 51:55 | , DNA RNA can be naked or , right naked envelope. Other things |
|
| 52:04 | viruses, like a protein spikes, virus specific proteins here. So the |
|
| 52:10 | . Okay, um now uh any at this point? So as we |
|
| 52:19 | , we're gonna leave yet. But we'll end with um bacterial viral |
|
| 52:25 | But let's look at this question Okay this is about you can of |
|
| 52:32 | they do classify viruses. Okay. you probably think having just gone through |
|
| 52:36 | structure you can probably think of. here's how we can compare viruses looking |
|
| 52:41 | X. Y. And Z. there's gonna be some things you simply |
|
| 52:45 | use any time. So which one these could not be used as a |
|
| 53:13 | to identify a virus? All Let's count down. three. |
|
| 53:30 | Yeah you couldn't use fermentation right? it's not like you can't grow them |
|
| 53:35 | a Petri dish. You could affect um you can't um give it glucose |
|
| 53:41 | hope it will inspire or anything like . Right. So you wouldn't use |
|
| 53:44 | . But certainly A C. And E. Are all plausible things |
|
| 53:50 | can do to identify the virus. . What is typically done? So |
|
| 53:55 | taxonomic system uh in place basically uses genome type. Okay and um presence |
|
| 54:06 | of an envelope. Okay so um do not do not memorize this |
|
| 54:12 | Okay uh I just put up there for you know just to show you |
|
| 54:16 | different types of viruses and really the in you know many of the human |
|
| 54:23 | caused by viruses fall in to this which is the RNA viruses. Okay |
|
| 54:28 | everything from coronavirus of course uh two virus to flu virus mumps and measles |
|
| 54:37 | lots of them fall into this RNA category. Okay. But certainly there's |
|
| 54:43 | in in these other groups for But it tends to be a real |
|
| 54:47 | of human disease causing viruses in that that in these two groups. Okay |
|
| 54:54 | so let's look at um viral life . So we did go through this |
|
| 55:02 | . Okay the basics so we're gonna a little bit more specifics in terms |
|
| 55:07 | uh we'll start with bacterial uh virus cycles. And so just remembering recognition |
|
| 55:15 | uh genome copying the genome getting into cell, copying transcribe, translate, |
|
| 55:22 | proteins and assemble making virus. So is what's going to have to happen |
|
| 55:26 | not immediately at some point depending on virus type. Okay so uh the |
|
| 55:35 | entry. So we'll see that animal have a different variation here. Um |
|
| 55:42 | there's a process called uncoated. That's we use to describe how animal viruses |
|
| 55:47 | into the cell uh senses an So obviously taking over the host and |
|
| 55:52 | making it a factory to make new . Ok and then exit and |
|
| 55:58 | So and and there's different ways this happen right? It can they can |
|
| 56:04 | the cell and just lice the They can come out at a lower |
|
| 56:08 | and the host cell is functioning and . Um It can come out and |
|
| 56:15 | out with an envelope. So there's different mechanisms here. Okay. Different |
|
| 56:21 | depending on the virus type. Okay let's look at this question. So |
|
| 56:26 | is where we're gonna start with in of life cycles. Um bacteria |
|
| 56:32 | And so the word fage. so fage is um when you see |
|
| 56:40 | it only refers to bacterial viruses. wouldn't call a human virus. A |
|
| 56:45 | infects human cells. Age pages only the context of bacterial cells. |
|
| 56:52 | the long name is bacterial fade. we just use safe age for |
|
| 56:57 | Okay. And so um the term it has a specific definition, |
|
| 57:05 | Or features that go with that? so let's see how we do |
|
| 57:48 | Okay. Alright. Now from Right. Yes, if you |
|
| 58:13 | B you are correct. Okay. be the one that does that is |
|
| 58:20 | less a genic type. We'll talk both lighting and estrogenic here in a |
|
| 58:26 | . So this is a license genic that can do the let's integrate into |
|
| 58:31 | host chromosome 11 page basically it's endgame in fact make viral particles kill |
|
| 58:37 | get out and infect more cells. kind of their mode of operation. |
|
| 58:42 | the lice A genic fage have have as part of the cycle. But |
|
| 58:46 | also have the let's be dormant for while part of the cycle. But |
|
| 58:51 | other features. So um of course is typical for any kind of viral |
|
| 58:55 | cycle is to copy genome right Make viral proteins. Uh make copies |
|
| 59:01 | genome and assemble viruses. Uh but page that this is true only the |
|
| 59:08 | enters everything else stays out external. , so let's look at these two |
|
| 59:15 | . So the light uh I'm Uh Yeah, page these. Um |
|
| 59:21 | the term so that when you like lice, a genic fage temperate. |
|
| 59:28 | . So there's two those two So virulent means if you're temperate, |
|
| 59:32 | start with the temperate you can go of two ways. Right? Um |
|
| 59:37 | can be angry. Right then. that licensing goes into the lifting |
|
| 59:42 | Right? Or you can just kind chill and hang out. All |
|
| 59:45 | So the license in the temperate that's what they can do. Go |
|
| 59:49 | way or the other. Okay, virulent page or landing page. It's |
|
| 59:54 | mode. Okay. In fact, make viruses kill cell. Okay. |
|
| 60:00 | so whatever type you are you're gonna doing this here on the right. |
|
| 60:05 | attached to host and then have your enter. And so you note that |
|
| 60:12 | the genome is entering. Um this that part. All that other stuff |
|
| 60:18 | staying outside the cell. Okay. for bacterial virus. So um so |
|
| 60:26 | less hygienic cycle temperate phages form the . So that prophet. Is that |
|
| 60:33 | where it integrates its genome into the chromosome that's forming a profane in animal |
|
| 60:38 | . Because animal cells will do this well. And we use the term |
|
| 60:42 | virus for those types of pro virus reserved for animal viruses. Pro fage |
|
| 60:47 | course for bacterial viruses. Okay but if it does this process of pro |
|
| 60:55 | it will at some point have to viruses if it's going to perpetuate |
|
| 61:01 | Right and to do that it has go into the lighting cycle. So |
|
| 61:06 | genic fage has the lighting cycle as of its process. Okay the page |
|
| 61:15 | not have a profane part to its . It only has one mode. |
|
| 61:20 | and so we'll see that here. so um these are what we call |
|
| 61:28 | face that duties are called T even like T two T four T six |
|
| 61:35 | names of bacterial viruses that do Okay and so yeah we start with |
|
| 61:41 | there's attachment and then there's penetration. and so the genome enters in this |
|
| 61:49 | here. Okay um part of the is to actually break up the host |
|
| 61:56 | as you see here. Okay it recycle those parts. Right Remember you |
|
| 62:01 | up the D. N. It's gonna it's going to become |
|
| 62:05 | And of course the virus will use to make its own genome. Okay |
|
| 62:10 | so decorating host DNA synthesis right synthesized DNA. Now from bacterial viruses most |
|
| 62:18 | these if not all our D. . A viruses. Right you get |
|
| 62:23 | variations of RNA DNA et cetera and viruses for bacteria viruses they're generally just |
|
| 62:28 | . N. A viruses. Okay Okay so again synthesis so attachment penetration |
|
| 62:36 | bio synthesis. Now we're making the parts here. Right and then we're |
|
| 62:41 | to assemble mature First create the first fragments and then we create more mature |
|
| 62:49 | parts of the virus and then assemble . Um here. Okay so this |
|
| 62:55 | what we're putting together here and making bacterial virus all the different parts packaging |
|
| 63:01 | . N. A. Okay and really slice of the life of the |
|
| 63:05 | . So they'll they'll have this enzyme listeners. I'm design breaks apart peptidoglycan |
|
| 63:11 | wall. Okay and so um so point so created. Okay so they |
|
| 63:17 | to that in a little cycle. what that basically is is the period |
|
| 63:22 | here from from once the genome has the cell right to kind of |
|
| 63:31 | Alright we haven't yet formed intact particles so we're kind of to that point |
|
| 63:38 | not yet. And they call that eclipse. So it's a point where |
|
| 63:40 | kind of basically assembling everything synthesizing and the viral particles but we haven't yet |
|
| 63:47 | an intact particle yet. So the after that point infection is what's called |
|
| 63:52 | period. Okay so like I said is kind of demarcation here that line |
|
| 63:58 | kind of there so this part here worth pointing out here that recall |
|
| 64:07 | Alright back in the previous chapter. generalized transaction. Is this this is |
|
| 64:16 | it happens. Okay so these fragments you see of the host DNA can |
|
| 64:22 | packaged incorrectly into the heads here. and so that's that's how you get |
|
| 64:30 | transaction. So basically theoretically any any of the D. N. |
|
| 64:34 | In this host can be packaged in . And now it's part of this |
|
| 64:39 | can infect other cells and carry that D. N. A. To |
|
| 64:42 | cell transaction. Right? That's that's this fits in here. Okay. |
|
| 64:48 | That's like cycle. So that's what uh And you know in e. |
|
| 64:53 | culture uh Um you can it can very cloudy right? You have a |
|
| 64:59 | suspension of bacterial cells. You can a drop of fate and effects |
|
| 65:04 | Coli as a live virus. And 30 minutes basically the whole thing becomes |
|
| 65:10 | like water because it's basically infected killed it broken out and infect more |
|
| 65:17 | . And it happens very rapidly It happens at an exponential rate and |
|
| 65:22 | soon they're all wiped out. And it happens for letting virus faget happens |
|
| 65:28 | quick. Um So with misogyny so light. Exactly you see here this |
|
| 65:37 | all it is for a lot of for less. A genic virus it |
|
| 65:41 | have this. Okay But it has other part of the cycle as |
|
| 65:46 | Okay so the type of virus that this is called lambda lambda fage um |
|
| 65:53 | one that infects the choline. And it has when it infects. |
|
| 65:59 | So we still have the same recognition attachment and the you know enters when |
|
| 66:05 | does it actually circular rises like Okay. And then it can |
|
| 66:11 | All right. And so this this the lice a genic cycle or |
|
| 66:17 | Okay. And so uh as this and the host cell is unaffected. |
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| 66:25 | . And is basically free to just and eat food and grow and what |
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| 66:31 | you. Right. And so it . And so success successive generations of |
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| 66:36 | are inheriting the chromosome plus that pro so shown by the dark blob here |
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| 66:43 | the genome. Right? So all members of the next generations are getting |
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| 66:48 | copy of that page genome. so it's more or less like a |
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| 66:51 | time bomb almost. Okay. And what determines whether it stays in |
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| 66:57 | So ginny or then exits? And goes into lighting cycle depends on |
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| 67:05 | factors. So in this pro fade . Okay, it's actually synthesizing directing |
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| 67:13 | of viral proteins whose job is a of sense what's going on inside the |
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| 67:19 | . Okay. What's the energy state the cell? There are certain molecules |
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| 67:23 | the cell that that can tell the what's the energy state? So the |
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| 67:29 | state equates the health. Right. um there's certain indicator molecules in the |
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| 67:34 | you can look for to determine Okay, so so that's what determines |
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| 67:39 | or less hygienic cycle in You don't to know this but really the thing |
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| 67:44 | that tells it to go one way the other is the the um nutritional |
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| 67:52 | nutrients. Okay so if you have nutrients that means that the uh the |
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| 68:07 | the cells themselves the whole cells will quite happy. But the nutrients don't |
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| 68:11 | and grow and grow and grow. compared to a situation where they're |
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| 68:16 | Okay and there's not a lot of . Okay that's kind of the queue |
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| 68:20 | the virus. So if the virus let's go to like cycle okay it |
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| 68:25 | typically be because there is abundant nutrients the cells are growing like crazy |
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| 68:31 | Because when the cells here break out viruses I'm sorry fate break out. |
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| 68:38 | what's the more likely scenario or they'll a host if the host cells are |
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| 68:46 | growing and multiplying like crazy or they're likely to find a host when the |
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| 68:52 | are happily growing. Right? Because there's the chances are so so remember |
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| 68:59 | when um the life cycle happens it's happening to every single infected host |
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| 69:07 | Okay there's a rate at which it and so not all of them are |
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| 69:11 | . Right? So you have a of e coli a proportion that will |
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| 69:15 | infected like this but some won't. so if they're happily growing that's lots |
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| 69:21 | host potential hosts. So that's typically Q. Two let's go and light |
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| 69:26 | because of course the virus wants to itself and so that's that's how it |
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| 69:30 | best do it, right. If starving, there might not be a |
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| 69:34 | of host cells around. So the of it breaks out nobody to |
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| 69:39 | What am I going to do? . So that's kind of that's what |
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| 69:42 | virus is doing inside the cell, of sensing that. Okay. Many |
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| 69:48 | about that. Right? Alright. what I wanted to cover today, |
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| 69:53 | . So we'll see you Tuesday, the weather. |
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