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BIOL 2321_17742_Microbiology for Science Majors - 03_24_22_Lecture
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00:05 Alright folks welcome. There's a few up I guess everybody's studying for the
00:11 . Mhm. Um So obviously tomorrow . Um Let's see, we can
00:20 . So remember you have one of coming up due on sunday and it
00:24 just the stuff Like five questions on stuff from Okay, Tuesday. The
00:31 21 22. Let's see. You , smart work do um and so
00:38 we'll continue on three So chapter 7 . So now we kind of take
00:44 have have have been on that freaking for I guess three weeks now uh
00:51 gears to aspects of bacterial genetics. so um I kind of always introduced
01:03 section with some kind of what they like basic questions but it's more like
01:09 guess trying to mm hmm jog your maybe about the process is a process
01:17 gene expression. Which I think you over Yeah. Yeah we went over
01:21 intro bio. The how do you do you decipher a the genetic code
01:30 be no acid and that kind of . So uh we're not gonna do
01:34 here only you know, talk about in kind of passing so to
01:39 But um so obviously as soon as know that. So but we will
01:44 with some kind of refresher type Okay so it does absolutely helps.
01:52 think if you you've kind of forgotten to go back to the year and
01:56 I'm talking about is the whole transcription process, right? Not necessarily that
02:03 nuts and bolts and super detailed because of wood represents and how it works
02:11 very basic terms. So uh we'll through some of that today. For
02:16 . Alright. So like I said probably the review committee of you but
02:21 don't think it'll hurt. But as talked about material genetics of course,
02:26 if we're talking about gene regulation which talk about in Chapter 10. The
02:31 part of it reminds me. So flip plastic. So again like before
02:36 a bunch of questions. Great questions focused on that day. But you
02:44 in between we'll talk about different things gene regulation which is what 10 in
02:49 one and part two are all about regulation. Um So it absolutely helps
02:55 understand if you have that understanding the gene expression process. Okay, what's
03:01 ? So I do not go into details of is he's copied. Here's
03:11 you're hurting. Excruciating details of parking . No, I do point out
03:17 few things specific to bacteria that may be aware of. Okay. But
03:23 really more um there's a whole bacterial are organized. This is how they
03:29 to compare to eukaryotic systems. So of on that. And so we
03:33 go through just in terms of diet gene regulation but you are not expected
03:40 know that I'm just sure you in of contrast. Okay. Compared to
03:46 so anyway as we as we go it'll be clear every time.
03:52 um, I think I know you wanna hear this yet, but I
03:57 next week already The 7th, I it was a Thursday Of next
04:05 Uh, that will actually will be Friday for you. So the 8th
04:10 I think is when the next wait minute, is that? So two
04:15 before is when the constant schedule are ? So That's going to be um
04:20 , April one. It looks like one will be the when it costs
04:26 schedule opens, which is next Next friday. So just the that's
04:30 exam three. Okay, so, , we're gonna actually finish up the
04:36 at three rather quickly. Okay, one of the last exam just to
04:42 you know. So the last example course occurs during the final period,
04:46 it's not it's not a comprehensive Okay. It just covers the last
04:53 the course. These are four Okay, so that would come in
04:56 the final period. Okay, so , so let's go on to the
05:04 thing is I think this is a here. Okay, there's a question
05:08 I used to teach. No, before I do that. So
05:12 like with chapter 21 22. I didn't. No way. Did
05:16 cover the entirety of those chapters. , so again here again in seven
05:20 eight the same thing. Right, pay attention to because you're going through
05:25 chapters in the book that to specific are only being covered. Okay.
05:32 All right, so here's the first . So, this is a question
05:37 always had every spring when I talked bio. The part to metro
05:44 And It was one. Yeah. , sorry. I mean reveal.
05:50 so I was uh this was always an exam uh during the spring semester
05:56 the what's now called? 1307, guess. So. Part of my
06:02 questions. Okay, Because it really separate. Who knows the process and
06:06 doesn't? Okay, so the process transcription and translation is carried out the
06:12 tube, you know, to a tube is added. Okay, from
06:17 hippo we're gonna take M. And a trh in ribosomes from a
06:25 . We're gonna take the DNA. , from a zebra. We're gonna
06:28 our people embrace in other necessary rival nucleotides amino acids. Okay.
06:38 then we're gonna see, okay, a some new protein. New protein
06:47 be synthesized. Okay, uh the is uh from which animal is the
06:55 coming from. Okay, so you've multiple choices here. Okay,
07:03 let's see you open this up. see what you got. Okay.
07:22 , so don't overthink it too Okay, mm hmm. Okay.
08:08 mm hmm. 321. Alright. to go back and hit the books
08:18 with you. Okay. Alright, um who answered? Um I remind
08:32 as well. Who answered. As in dog. So what are
08:36 two particles? Yeah I told you pick it up. Good morning
08:48 So fish D. N. Uh will be copied. So there'll
08:53 some fish protein in there from There could be a hippo protein from
09:00 M. I. All right so the old um central dog.
09:06 The this this DNA RNA proteins. so we have been important fish everybody
09:17 guess that one mostly. But the as well. So the M.
09:20 . Right so D. N. . Uh um are gonna make a
09:24 transcript of D. N. Of a genius. Okay and then
09:28 gets translated into proteins? Okay um hippo and fish. Okay because of
09:38 and that. Okay um so I a question. This one's another one
09:46 to the same topic for a certain investment found in the region of the
09:52 designated X. Comprises a specific sequence D. N. A.
09:58 Okay. The sequence can be converted protein only when cells are grown on
10:04 . Another kind of sugar As a carbon source. Okay but the following
10:10 among a two D. Is false information about this bacteria. Okay.
10:17 is it that X. The Phenotype is not revealed when cells were
10:24 on glucose as a carbon source. . The conversion of the DNA sequence
10:30 a protein requires Robin zones X. the gene. The first stage in
10:37 the DNA sequence into a protein requires a copy of the X sequence.
10:43 of these are false. Um all our true statements. Oh God.
10:55 up again. Sorry. Okay. . If he answered answer again.
11:02 hmm. Yeah. Okay. Um have. So the uh it is
11:39 of the they're all they're all true . Yeah. So the exponent type
11:46 only be revealed if um that we going on galactose. Okay. Um
11:54 to we'll talk about the lactose opera that's when he expressed when black folks
12:00 present and the glucose is not Okay. As well. We'll see
12:04 that works. Um the point there no, no worries. Little organism
12:14 violence will express all of its genes one time. Okay, regime regulation
12:20 so important really. He can go into some field of biology about
12:30 evolutionary biologist or whatever type you're likely you're studying is a phenomenon of gene
12:41 . Okay, so um it's obviously important to express produce but it's equally
12:50 to control when they're expressing how much expressed. Okay, uh there are
12:58 you haven't expressed since you were a plus five days. Okay. Because
13:04 don't obviously need those proteins now. , You're through with your development from
13:08 to a fetus to adult. so certain of your jeans are kind
13:14 in mothballs, so to speak. , I'm not going to be expressed
13:17 . But certainly some are expressed all time. Okay. Like genes involved
13:21 metabolism, Like also so aspirations, things. So, um, so
13:27 is a hugely important aspect of Okay. Um, and certainly
13:34 the basics of gene expression, DNA RNA protein. So DNA sequence
13:38 gonna express a gene. You need convert that into a an army molecule
13:44 can then be translated into proteins using . Okay, of course X is
13:51 gene. Right? These these seemingly Stimulation nucleotides 80 gcc. This just
13:59 like a random collection. Right? the sequence is anything but right there
14:04 specific sequence that dictates a particular media , sequence that produces a polyp.
14:10 time for most parts remember jeans. most jeans fit that description. Methodologies
14:17 because the end product of the gene also just be an RNA molecule.
14:21 . And those are still referred to jeans as well. Okay. Um
14:26 certainly the first stage of converting the as mentioned is making RNA copy.
14:31 , so um again, I'm sure see is very basic to you but
14:36 a more kind of just refresh your about this stuff. Okay,
14:42 let's look at a couple of examples . So, gina type of theater
14:46 . Our terms obviously we use in context of genetics. And so uh
14:53 often hear definition. Field type is things I can see, you know
14:58 my own eyes. Right? Uh have a certain amount of sort of
15:03 , has a certain amount of fur whatever the characteristic is. Right?
15:08 you did what you call that? prototype trade being expressed. Okay.
15:14 of course remember that you're not gonna able to see everything with your own
15:18 . Right. Although very essential metabolic going on in your body. That's
15:22 prototype to necessarily see it as the with your naked eyes necessarily. But
15:30 but nonetheless it's part of your Okay. Of course. I'm all
15:36 that here's some examples. Right? we're looking at bacterial cells,
15:39 We can look under a microscope in case like a microscope and see the
15:45 . But then what is it actually ? What's in the genes are being
15:50 ? You can see for example, we grow it in certain ways unlike
15:53 lactose broth. But it produces a color reactions that tells as well.
15:57 has that phenotype or not. so we all of course, no
16:02 type are related, write a right? D. N.
16:07 Uh is is will produce the so uh by the way to express
16:14 the plate, Right. Black Non lactose fermenting blood augur right.
16:21 ourselves licensing red blood cells. These all prototypes being shown because they have
16:26 genes that expressed in particular protein that them to, excuse me, enables
16:32 to use black folks or not, them to life's blood cells or
16:38 Okay so possessing certain genes in their to express certain prototypes. Okay so
16:46 we look at both these things uh . If you have a general results
16:51 the functioning of one or more So that's the lack of that guy
16:59 uh red blood cells coming into the zones around the cells showing that phenotype
17:06 it's expressing what resting. Mhm. . But expressing what's the functional
17:16 It's expressing positive in this example. place DNA to RNA to quality's.
17:28 . So if you had typed Germany from the functioning of one of your
17:33 the year I call. Alright. parable is right but it's that relates
17:39 to pigment proteins. Right? That producing that red coat. Okay.
17:44 and so escaped from most few times you see because some genes being expressed
17:52 producing some kind of protein that's in whatever it does and that creates a
17:57 create invisible. Not always visible but creates a phenotype but there's lactose from
18:02 or what had. Okay so um here's an example. Um So you
18:11 do very common ideas to do christian Catherine bacteria is a rapid identification.
18:19 . To diagnose the pathogen And I find it in the right the right
18:25 treatment. So this is a typical the kind of tests um a little
18:33 old fashioned tents because nowadays they use um methods to quickly I.
18:38 Things. But you can do it way to just get the result a
18:41 bit slower uh a day or But anyway, so it was either
18:46 lab, right? Do your Okay. You actually launch your chemical
18:52 tests, right? Just like these here. Yeah, he's too
18:57 All right. And so so uh tubes here. Right? So and
19:06 a different form to do those is this. So each compartment is a
19:11 biochemical tests. Okay? You see 10, a dozen or so biochemical
19:17 . Okay? And so uh not here. There's a wire needle that
19:23 through the whole thing. Right? so what you do is the needle
19:28 has a cap on it here. uh and you take the cap off
19:33 you flame it and you take the and you just, you know,
19:37 it in some of your culture on plate, right from a colony.
19:41 ? Get some of that material And then you just go flying
19:45 flies through all the apartments and inoculate one simultaneously or almost simultaneously.
19:51 And so now you cannot create all compartments in one shot. Right?
19:54 they put an incubator and you're gonna what happens, right? And so
19:58 you'll see is this obviously this has done to this one because we see
20:04 color changes, right? So this the jury abroad has turned like this
20:07 color which is positive for analysis uh . It's kind of a bluish color
20:12 is positive normally it's green if it's positive. Anyway, so you see
20:17 color changes and that so it's okay . What is negative for that bubble
20:22 ? Right. You total them up then you look it up on the
20:25 and tells you here's what you Okay. So anyway, so again
20:29 . Right, seeing a phenotype. , just focus on 111 part
20:33 The Yuria test. Okay, so a positive result. Okay, what
20:37 that actually mean? Okay. In of genetics? Okay, well of
20:42 relates it means that that bacteria has enzyme. Okay. And under the
20:48 conditions in that little chamber. It carried out this reaction.
20:54 Maria in the medium hydrolyzed by the WCO to pneumonia, pneumonia basic creates
21:01 color change. Okay, that that back to a gene, right?
21:06 it has your infuriating and which was under the conditions growing in that
21:13 Okay uh so we have the process . Right producing M. R.
21:17 . A copy of D. A. In the called messenger
21:22 Right then we translate that using ribosomes then producing a protein. Okay.
21:30 that protein of course is the the act on the substrate and carry out
21:37 reaction. Okay so this is one thousands of genes bacterial in hands.
21:43 . And um it would only be under certain conditions. Right. Um
21:49 uh so it expands the range of . Right? Some are what the
21:54 instituted. We'll talk about that later . The genes are always expressed because
21:57 typically critical function. Genes that are needed. Right. Others depends on
22:03 conditions around the cell. Right? is in particular nuclear present.
22:08 Let's use it and then we'll express gene and use it. If it's
22:11 present, then don't because remember I on this a lot this semester but
22:18 can't see any diagrams this one or in the book is how much energy
22:24 used in these various processes. And so there's all kinds of energy
22:30 because, you know, energy from synthesizing the right to them if transcribing
22:39 synthesizing a protein, it all takes lots of them. Okay, so
22:45 the more reason to only express what need when you need it because otherwise
22:49 a waste because remember although you do things experiments in labs, pure culture
22:56 , they're out there in nature competing each other. But thousands of other
23:01 . Right. So you've got to super efficient. Right? Or else
23:06 won't survive. So um so just to real quick acceptance.
23:14 Because it's important to know this because the context of regulation. Right.
23:21 this is the path to make a . How are you going to regulate
23:25 and if it's made. Okay well gonna have affected at these different levels
23:31 of transcription, right? Level of . Even at the level when the
23:36 is already made or even here level DNA before anything, all of those
23:43 up in total points. And we're to see examples of that as we
23:47 through this material. Okay. So you don't have to feel for this
23:53 that's gonna be harder to kind of . This is how we're controlling
23:57 Okay, so um come back to review. Right? Because we've talked
24:03 since anti sense in the context of viruses. Right, viruses in
24:09 And so they're staying close minded Anderson has nothing to do with the
24:15 that their viruses that has to do the fact that they have nuclear
24:18 Right? It's all about gasses. relationship between the sense antisense strands and
24:27 um so here is a example of and the Children to sense versus senses
24:36 code that contains the information and that be converted into a Alright, the
24:45 strength with complementary strengths. Okay so we look at um transcription and
24:53 Okay um here what we're doing is making a copy of the anti sets
25:00 is also called the template. Mhm. So we're going to copy
25:07 template because of the rules of based . Right? If we copy the
25:13 , the antisense strand then we will basically making a copy of the sense
25:19 . And so that's what that copy . And we get this strand the
25:28 . R. N. A. ? Which is gonna be this is
25:31 plus since plus strand antisense minus this going to be a plus.
25:40 And we're gonna take a closer look that sequence for a second. But
25:44 thing is um so a couple of wrong with bacteria. Alright, the
25:49 here is not separated. Right? policy information. Right? The current
25:56 together the same time. There's no like in new carriers. Right?
26:02 The the elements here. So there's be a rambles on biden said we'll
26:08 about this later. But part of transcript is contained elements that facilitate the
26:15 . All right. So part of secret is gonna have to arrive because
26:18 of the things you see in a we're here a gene, right?
26:26 have promoter. Alright, that's what polymerase binds to. Right? So
26:34 only buying two riders on binding RNA polymerase binds to promote both these
26:40 . Combined sites in the promoter orient molecules in front of what of the
26:47 information. Right? So promoter orients commemorated in front of the gene.
26:52 every gene, basic structure of a is promoted. Then we call the
26:57 gene part that's transcribed. Okay, , for the right result, it
27:02 to be oriented as well. I don't wanna just plopping down right
27:08 here somewhere. Okay, on the will not there but over like down
27:14 . Okay, you want to orient at the beginning so it so it
27:17 the whole molecule. Okay, that's oriented is the arrival of the binding
27:22 so analogous to promote. So you the monitors in front of what needs
27:28 be either transcribed or translated and then work properly. Okay. Um the
27:34 thing is is obviously for simplicity say . I completely show You know,
27:44 , 1 protein magnetic, one pipe chain. Um This thousands of these
27:52 can be made. Okay, they're talked to me for a single
27:55 you can make hundreds of transcripts from single gene. Okay, so quantity
28:01 these things is not something you can easily either, but I know that
28:05 that can't happen well like you can levels of expression. Okay, a
28:11 or live. Okay, and there's factors that play into that as
28:16 See um Okay, so let's look the sequences Here compared to compared to
28:27 two. Okay, so it kind just a relationship between the three and
28:31 it's it's the same for any whatever is coming from the relationship is the
28:38 . Okay, so here's our N. A. Transcendent and he
28:42 , okay, again this complementary base . Right. G. To
28:45 A. T. T. Okay we make a copy of our template
28:50 or sense strange. Alright so just the right punctuation marks here. Alright
28:56 is R plus R minus. We call this. The template are not
29:04 . Alright, coding. And so making a copy of the antisense
29:11 Alright. We create the M. . And if we just compare the
29:16 right, compare that to that, see that they're identical, right?
29:21 where there's a timing, right? our enemies don't have five means that
29:25 right. So you can see here . C. A G C.
29:29 . A. T. G. U. G. And then you
29:33 just compare these all along the way there again identical, right? Except
29:42 there's a five minutes you're so but than that they're identical, right?
29:46 that's what we're trying to do We want to make a copy of
29:50 essential information of that sense of So we're gonna copy the temperature in
29:55 to get that. Okay, so old plus minus minus plus thing.
30:00 so um the it's one of the . The um okay we'll come back
30:12 me. All right, so um that's what it was the the.
30:25 so which see here? Okay um is the transient entity here, the
30:36 that kind of comes and goes not so permanent at least now the life
30:43 the cell. This one is actually comes and goes this one is pretty
30:47 permanent until obviously cell dies. The part one here is what are in
30:55 period of the transient ones because they and go okay they are in
31:02 A long lifetime bacteria bacterial especially may many minutes and they're gone okay.
31:11 . N. A. Is a thing. Right? And so I
31:15 just the analogy of D. A. Is the the book on
31:19 and library that you can't take Right? Um So if you want
31:25 from that book you've got to go Xerox machine and make copies of
31:29 Okay um And those copies now are RNA. M. RNA is there
31:36 working copies? Right. So once have your information ready this is take
31:42 paper roll it up and throw in garbage when you're done with it.
31:44 right. If you need more you always go back get the book and
31:47 more copies. Right? That's really it's cool. So RNA are working
31:53 of of DNA segments of genes. And so because the silk can always
32:00 more of them as needed. Because is hanging around forever. Okay
32:08 they're made once they're made then they always be translated. And of course
32:13 don't want that going on because an that was transcribed at one point and
32:19 was needed and it was so because was needed right? You know 55
32:24 later it may not be but if hanging around it will be copied.
32:27 that's a waste. Right? So inherently have don't have aren't as stable
32:35 D. N. A. So um so here's what we're gonna
32:42 about. Like any questions I guess is more listen to me for you
32:49 . Um but if you have questions me know. All right. So
32:53 of these terms includes all of the . You may not be familiar with
33:00 couple of things but that's your best . Okay. Yeah, cheers.
33:47 hmm. Mhm. Okay. So yes it's going to be genome
34:18 is the most all encompassing. So if you go from one genome
34:28 will go to a regular melon. gene. Yeah. You have a
34:37 type. Okay. And so we'll about regulations and operations next. Um
34:46 scope. Okay. So speaking of then leads us into here um making
34:54 Gm. So prepared genomes uh order magnitude smaller than ours than eukaryotic
35:02 Um 10 to 6 when you order of the 5th. 10 of the
35:06 . And their size in terms of pairs hundreds of thousands to maybe five
35:13 on the Larger and Echo has like times 10 to the 64 million base
35:21 . Um smaller ones are about 0.5 right? And so um so in
35:28 of genome transcriptome and proteome really all all that refers to is again the
35:33 old D. N. A. ? The R. N.
35:37 two protein. And so the genome course represents the totality of all the
35:46 which can be for bacteria and Well of course we its chromosome but
35:51 any extraneous uh plasmas small circular pieces DNA that may have that too was
35:59 of the genome in present. The is we're just gonna be one of
36:03 R. And a memoir and essays are in the cell at any given
36:06 . Right. And then of course represents the proteins being expressed. So
36:12 and so we already asked this question which is permanent. Which is transient
36:17 of course will be the proteome transcript transit. Right transcription will come and
36:23 and of course as they come and , proteins come and go,
36:26 the protein is gonna have depending on type. They can generally have longer
36:32 have longer lifetimes than the RNA is made from. Okay. But they
36:38 have a have a fun time. . Certainly the genome chromosome is going
36:44 be the permanent part of that. , now is mentioned kind of the
36:50 as we just mentioned of bacterial chromosomes remember that they can also possess past
36:59 generally carrie On average maybe around 10 . 5, 10 is probably the
37:07 common we're talking about uh you know single metabolic pathway typically or it can
37:15 fewer than that. It's like an resistance gene or something like that.
37:20 you know it's not gonna represent a because they're they're small. And so
37:24 these are the things that they can transferred between sides as we'll see next
37:29 . Okay And so uh so the . So here's what we're going to
37:34 the picture of. Just for contrast . Do you carry on system?
37:41 so precarious. So this term here kind of an older term. Okay
37:46 tron and it really just means It's an old term for jean.
37:50 so polly you can have a mono tronic message. A party sis tronic
37:57 . So we learned that the organization bacterial genes they can have multiple genes
38:04 to a single promoter. Okay that's that's not an organization you see.
38:09 you carry it. Okay so what means is a structure like that with
38:17 genes in a single transcript produces a sis tronic RNA. Okay many genes
38:25 one transcript. Okay so upfront and again those are precarious genetics terms we
38:33 have regular structure. And you carry . Okay so let's look at you
38:37 out first again, just for You're not going to be tested on
38:42 in trump et cetera. But it just to contrast with these with bacterial
38:48 . So um okay so here's the . N. A. Here would
38:51 a representative jean. Okay and you out june has uh and so the
39:00 that's the business part of the system say is right here. Okay.
39:05 gonna be this is what's transcribed. . And of course very common.
39:12 you're pro critical you carry out the is part of energy orients the preliminary
39:19 . What needs to be transcribed? . So Exxon's an entrance. So
39:26 genes are organized with these intervening sequences . N. And that's what stands
39:34 . Exxon already expressed sequences. And what happens in the eukaryotic transcript is
39:40 of processing. Okay. And of lots of control. So you have
39:47 by parts of the predatory parts that far away. Right? They call
39:54 means far away. Right? Proximal close. Okay so you have both
39:59 . Okay. Uh you also have other elements of probably a sequence.
40:07 what's called part of the processing is camp is put on it.
40:15 Captain tail. Okay so you have remember that. And then also of
40:20 the processing of taking in Exxon's and introns. Right? So the coating
40:28 you have what's called the pre Are typically called. This is the
40:34 you have that's transcribed but before it be translated. Right? So this
40:39 this is not translatable. Okay guys gonna move the N. Tron is
40:46 put the cap and tail. And it already has a tail that
40:49 put the cap on. Okay. so a structure like this here is
40:56 . And my that's something that can transcribed translated. Excuse me.
41:02 And so um and so yeah, remember this is happening in the nucleus
41:10 these have to exit the nucleus and outside and be translated. So the
41:16 facilitate the exit. Right? any M RNA is lacking. Capital
41:23 just basically degraded very rapidly. Not at all. Okay. And unlike
41:32 uh RNA you carry that money is your state compared to the.
41:37 So these can last up to hours even days or weeks in some
41:41 Okay. But they don't have to enhances. Okay, so so lots
41:50 RNA processing occurs with eukaryotic cheats. . Um and so you know even
41:58 it can people calls exon 12 and . You can combine these. So
42:05 of the part of the splicing process called can produce transcripts that contain
42:13 Just exon one and two or two three or X on one and 33
42:18 combinations. Okay. I mean they'll they'll be related in function.
42:23 We'll have different projects but they'll be , you know, in terms of
42:26 common pathway but that's how it In your curiosity. Yeah. Under
42:33 none of this occurring activity. so different organization. Uh different
42:41 No introns. Exons under that Okay. Um certainly the control the
42:49 . Obviously energy so that that will similar. Um So now when we
42:56 look at the imperial system, okay have um again is common to energy
43:07 . Okay, no matter what Um But then they will group genes
43:14 the same pathway. So it's It was to make uh to make
43:22 right? All the enzymes involved in that would be on a single
43:28 Okay. And so we called structural . Are those genius. Okay the
43:38 elements. So here's our memories that bind transcribe and then the transcript can
43:46 this strong It will be one one segment. Right? Not three not
43:55 A. A. And B. C. It's all together on one
44:00 . Um And then of course translated the subsequent proteins enzymes typically and then
44:07 are very common and can be part the pathway. Yeah we see
44:11 Okay now uh control. So again is important. So bacteria have anarchy
44:19 hamburger called offering sequences. These are the promoter and the start was dropped
44:25 . Okay so again remember these structures promoted an operator. A regulatory
44:35 They represent D. N. Sequences but they were apart they're not
44:42 and translated into anything. Okay there be just control. Okay. Other
44:47 buying them, protein planning the facilitated but they themselves are not transcribing translating
44:53 . Okay. Their regulatory genes so Alright so um A. And so
45:04 do we call the opera in there everything that's on here. The opera
45:07 is just won't you be this part to hear is the opera promoter
45:17 Okay, now there will be associated genes nearby and far away maybe.
45:25 we don't call them part of the . Okay. They're separate.
45:29 And so regulatory proteins that control typically typical for it to interact with the
45:42 . Okay, so regular parade protein operator can work hand in hand to
45:47 expression. Okay, so one of things I remember is that um these
45:55 binding of of where there are people raise to a promoter arrived home to
46:02 some binding sites a to a operative . Right. These things are not
46:13 . Permanent bindings. Okay. They and go right off on off on
46:19 different things influence whether it stays on lot or not on a lot.
46:25 , so just remember that. if you see something bound,
46:30 Like this, that that's a not permanent thing. It can very easily
46:36 knocked off and we'll see how that . And that's that's the control.
46:40 ? When it's bound where they're not . Okay. And one of the
46:43 that cause it inbound or outbound, the essence of the control.
46:48 Different things will bring that about. . Everything from. What is it
46:54 . Alright, whatever. So, example to this. Okay, so
47:00 , you know, you can visualize if something is sitting on the
47:03 that's a physical block. Right thenardier . Can't get around. So of
47:09 it's gonna stop expression. Okay, again, it's a continuum. All
47:15 . You can be completely shut off you can be on or somewhere in
47:22 modeling all depending on the mechanism of and what's going on? What's the
47:29 experiencing at this time? So it's a fluid kind of a thing.
47:36 . Um and it should be that , right? Because these guys are
47:42 . They're gonna they're just, you , pretty quick on the fly to
47:47 conditions and be able to control these , especially if you can control
47:52 Imagine, you know, if this if this were a picture pathway,
47:57 ? And you have to hold each of these individually. That's not very
48:02 . Right? But they were all , you know, a different promoter
48:07 then you have to control those Right? So they're all part of
48:11 common pathway. It makes sense to in control amount once. Right?
48:14 you can turn them all on once turn off all of us.
48:17 So that's much more efficient. You can turn off pathways X and
48:22 . You need to turn on A B. If you need to Oh
48:25 . So much more efficient. Um, but there are some
48:32 Okay, as this this is why was just sitting here, There are
48:37 bacterial genes that are just the one one gene type. Okay, but
48:43 are in the opera? Okay kind structure. Okay now um Okay so
48:54 so if we just go back to question. So honestly uh nucleotides that
49:02 up DNA. Okay so that will up a gene. Okay Multiple genes
49:08 make up a Iran. Okay then operations of course contain multiple genes.
49:18 operations can be coordinate li controlled as in a regular. So that's where
49:25 is controlling multiple operations. Okay so example that is what actually what we're
49:33 about in terms of metabolism previously is nitrogen. And so I did before
49:39 talk about that. So just quickly talk about super factors at the end
49:42 this but it helps to bring it now. So bacteria he is guided
49:53 the promoter through the sigma factor. the sigma factor is a transient part
50:00 the primaries. So it can bind unbind. Right? So when it
50:04 diploma raise it guides it to the . And then once once the preliminaries
50:10 to synthesize the sigma factor jumps off combined another preliminaries. Okay that's how
50:17 has worked to help guide the preliminaries the promoter that sits in front of
50:22 team or the opera. So um so the super factor this can be
50:28 control point because they control where they where proliferations go and affect transcription then
50:36 you can manipulate sigma factors that's a to control expression. And so that's
50:41 you control these regulations. Right? this could be a sigma factor here
50:46 controlling these different operas. Okay. so what's an example of this?
50:53 we talked about last time matching triangle . And gentrification. Right. So
51:01 in itself is actually a regular called regular that controls different aspects of assimilation
51:14 . Right? So think of all roles of nitrogen in the south Right
51:18 Make Amino Acids Right to Make Nuclear two. Um uh I hear
51:27 Um And so how how can this kind of control where things are going
51:32 it's needed? Right so uh these what we call global nitrogen control as
51:40 allocate resources appropriately. So if it's um bringing that related to settle uh
51:51 how's it going? So how can control that? How do we control
51:54 those here? This pathway? That ? So because the importance of nitrogen
51:59 to the cell and the multiple pathways . Well you can control the operations
52:05 are specific to each part of this . Right? That's of course more
52:10 that way. Okay and so uh also there's an example of irregular we'll
52:16 next week which is um involved in transformation, transformation of the uptake of
52:25 . N. A. The There's actually a whole process to carry
52:28 out and it's actually lost multiple options it's all under control of the
52:33 Okay for transformation. So um so you have kind of these big processes
52:40 involves lots of different operations. That sense to control these things all together
52:44 once. So that um uh really efficiency and for to not waste
52:53 Right? And so yeah, allocated example but they didn't win.
52:58 So that's what it's all about. this contractual control is so important.
53:02 ? Without it. Things will just willy nilly and you know with all
53:07 of energy. So you have to that in and do this through various
53:12 of control china. Um Any questions that? Yeah. So we have
53:19 talking about for three cells that have . N. A. What about
53:23 ones that have RNA? They have they have two motors uh virus.
53:31 . Because that would be the only doesn't have a genome. And
53:38 they they they would have to have motors because there are some That's actually
53:47 good question. And I actually never about that until you mentioned so.
53:53 yes, because I never I never never seen readings here about but
53:58 there has to be because how else you gonna oriented transcription? So our
54:04 . So yeah, there certainly are GM will have rise of iron
54:09 So that's that's that's the the orientation you need for an army general and
54:16 gonna serve as because is not going be um it's it's it's about um
54:26 that you certainly don't have right in . So you don't have those moments
54:32 I don't think it's more of a of what motivates on D.
54:35 A. But certainly it's things like are buying this type of orientation that's
54:39 sure. Okay. But there may something um similar to rajan's promoted.
54:47 . Um that's what it's all about , anything departure sequence. So there
54:51 to be that you can't not be . You know, you can begin
54:57 and translating in the middle of sequence you don't like that is a functional
55:03 actually some kind of the talent. , that's what buying section promoters.
55:13 really is about orienting the molecule where needs to be in front of the
55:18 information. Um So Klansman's um these have mentioned already smaller auction units
55:32 these of course are naturally occurring in but of course in the last 40
55:41 plus we've use them of course in lab for uh the competent D.
55:47 . A. Work, right? cloning these kinds of things at the
55:52 minute service. We call vectors for out all kinds of molecular biology experiments
56:00 ? Because they're small, they replicate quickly and they have and they can
56:07 that of course because they have their origin of replication. Remember that term
56:12 ? We talked about that when we about the chromosome replication. So it's
56:16 sequence is what enables it to be . Okay. And so because of
56:21 , we can take this plasma and can put it in a cell and
56:24 will copy it for us. in terms of the common DNA work
56:27 cloning, that's why they're generally convenient use. And of course we have
56:34 plasmids and rebuild them for our own . There's all different ways to use
56:40 from if you want to sequence a of DNA, you can insert into
56:44 plasma and make lots of copies of . You can uh you can uh
56:51 at the protein translation of different You stick a sequence, you stick
56:55 there. There's all kinds of utilities plasmas, which is why they've been
57:00 for years and they're still used. . But, you know, the
57:03 being is that these are naturally Okay. And so, you
57:08 for in our mark perspective, especially week, we'll see how these things
57:14 be passed from the sell of the . Alright, so their small size
57:19 that to happen. Okay. And uh but, you know, many
57:24 will have different types of sequences in . This you see uh antibiotic resistance
57:33 tetracycline, that's those are the genes enable it to be resistant to these
57:39 antibiotics. Okay. But there can be other genes, like a metabolic
57:43 maybe in here as well. So just depends on the plasma type.
57:48 so because a plasma has its own sequence, it basically makes it independent
57:55 the problem. You have to kind do its own thing, so to
57:59 . Okay. Hence the word Okay, so copy number. And
58:05 other thing we should mention is there be multiple origins of replication as
58:14 It may have 123 or more. . And replication from different forwards can
58:21 different types of functions. In other we'll see that it took a particular
58:28 reputation is used when it's going to transferred to another self. Right.
58:32 a congregation. We'll talk about that week. Um Others may enable it
58:37 be copied at a higher rate. the high low copy number. What
58:42 means is is some may have one two copies of the patterns we
58:47 Low copy number. other cells may 40-50%. Okay, relates to the
58:54 they have and how often it gets . Okay, so and both have
59:02 disadvantages. Okay. Remember maintaining amount plasmids can I mean a lot of
59:08 usage by themselves to maintain those right? Or to copy them all
59:12 etcetera. So low copy number can a benefit in that. Okay,
59:17 don't have to make use so much to maintain this thing. Okay.
59:21 but some of these can also integrate the chromosome so they can exist outside
59:28 chromosome in the cell but then they integrate into the chromosome as well.
59:34 as I mentioned some of these can transferred. And so different names.
59:38 usually it's kind of relate to what of what kind of functions. So
59:44 factors are those that carry genes for resistance? Okay. F factors are
59:51 that are transferable. So there's a collection of jeans you need to have
59:55 the plasma to be mobilized. We it and transferred to other cells.
60:02 , now uh kind of this little is if the plasma is an
60:08 Factor that means you might that might you to believe that's all it's for
60:17 . But an R. Factor break down. You have to factor in
60:22 . The it factor is only the of but the plans were that contains
60:27 genes to make a transfer. So our traffic. So it's an
60:30 Factor handing F. Factory that makes then transferable. Right? So the
60:36 factor part, that's the important That's what makes it transferrable. So
60:42 have enough factory that makes it So that's so remember that.
60:49 so is a designation saying, oh time has the gene to make a
60:56 , right? And it may have addition to that these other things,
61:01 cannonball pathway a in the back Okay, so if the X factor
61:06 that mixes transferrable um okay, so this is their likes to the orange
61:18 or glorification type. So um if going to carry out conjugation,
61:24 transfer it's gonna copy the plans and copy is going to another cell.
61:32 look at the process of congregation next . But for now in order what
61:37 that is copying from a story that what's called rolling circle replication. So
61:46 kind of replication you're familiar with and we've seen before is this by direct
61:51 how your chromosome two copies. so you have a story,
61:55 You open strands apart when you have replication forks, right? That whole
61:59 and you create two copies, Are pro social court Libya wrapping?
62:05 same principle is bidirectional replication growing circle little different. Okay, so what
62:14 is a nic. A nic is a a breakage of the colon bond
62:21 the strand together. Just 11 bond called the nick. Right? So
62:26 the three prime hydroxyl, if you your replication um what a three prime
62:35 group is exposed on D. A. That's where DNA polymerase can
62:41 on and begin extending from that. , and so what what it
62:49 it of course, hangs on the prime hydroxyl group but then begins to
62:54 the template strand in red. Gonna copy that to make the red
63:00 , right? The inner blue one the template and the red one is
63:04 new DNA being made from that right? So that's what happens here
63:08 then as that's going around, right this outer blue strand here is being
63:17 and not that that's what you see little loop for me, that's what's
63:21 on. As a new strand is around popular template, that other one's
63:26 off. Okay. And so As continues, you see how what you
63:32 to envision that there's two cells here's one and here's the other.
63:40 , so so too, so one their congregation, this is what's happening
63:47 self together. And let's circle applications on, and one copy is being
63:51 into the other set. Okay, now you have a double stranded DNA
63:59 and now this one will be Okay. And um it generates the
64:08 trained in this case. Okay. complete the to make a double stranded
64:12 . Alright, this is what you see in congregation with that next
64:16 Okay, this rolling circle replication. um Alright, inheritance of plasma.
64:26 this is kind of where the low copy number can make a
64:30 Okay, so uh since since um replication, it's independent of the
64:40 uh Plasmids aren't replication of plasmids aren't to when their soul is going to
64:47 , but obviously the chromosome is tied that process, right? So it's
64:51 Divide. Obviously. Step one is the problem. Okay, the classmates
64:56 obligated to do that. Okay, if you have a high copy number
65:02 plasma, like this guy over Right? Well, just by,
65:07 know, my cell division because there's many copies of itself divides whether in
65:13 plane on that plane, you it's gonna daughter cells won't hear it
65:19 least one plant. Just by chance there's so many in the self.
65:22 ? So having a high copy you do that kind of that
65:26 Okay. That but if you you know, there's so many intimate
65:31 dollar stores are. It's when you on, right? Compared to if
65:34 just one copy. All right, only one daughter self assured of getting
65:42 pleasant on both. Okay, but the of course the other overriding
65:48 here is selective pressure. Right? is on that plasmid that the cell
65:55 to keep it in the first Right? Just be selective pressure on
66:00 to keep it Okay, um, hmm. With, like I
66:07 you can just, you cannot guarantee both cells and we're gonna inherit that
66:12 to sell device. So there is called a quasi I call it a
66:17 my tonic spinner. But it's not by any means, but it kind
66:20 looks somewhat like it. Okay. what these par P A R proteins
66:25 all about. PRS for partitioning partitioning being happened to selves. And so
66:33 facilitates the process so that both when make a copy that both end up
66:38 each end up in the dark Okay. And I don't expect you
66:43 the details of this, I'm just show you here real quick in this
66:48 . Okay, so you see a and here are two copies.
66:54 here and here. And these part . Um Different types. They'll they'll
67:00 some some binding to the plasma. will then buy into it and then
67:04 to prelim arise and extend as you here the strand getting longer and then
67:11 bind each other, right? They'll each other and then hook up and
67:17 go extend, going to opposite sides the cell, can I? And
67:23 now that was sure when the cell each sort of copy. Okay,
67:31 a way to kind of like I , I got quantity kind of function
67:38 it ensures that each cell gets a of that plastic. Okay,
67:42 only a thing for for low copy types. But back to this.
67:47 , so, selective pressure. so basically the example of this of
67:52 is uh here's Nicolai with 10 resistance temper cycling. And it's on this
68:00 here. Right, So this is the resistance gene test basically crumbles on
68:07 and you have one that's sensitive So it doesn't it doesn't have that
68:12 carrying the resistance gene. So of , if you grew uh this
68:17 this guy will grow on on this even would contain tetracycline because it has
68:25 jeep has a selective pressure on. on this plate that's certainly selective pressure
68:30 keep that class. Okay. Otherwise won't survive. Okay so whether it's
68:36 high topic then it doesn't matter. got that selective pressure directly on it
68:40 it's gonna hold on last, Because that's how it's going to
68:44 Okay now certainly this this one obviously roll on it. Okay? Now
68:53 uh if you put this guy the one on this medium, okay without
69:03 obviously you regret. Okay But then a matter of so once once you
69:09 it on here and it grows okay you then yeah passenger, you transfer
69:16 ? Subculture subculture it e subculture it you do that because it won't live
69:29 . Once you put on the plate not gonna live there won't be forever
69:33 . Month or so. Typically transferred fresh medium to keep it viable.
69:38 so keep doing that. And doing play with detective cycling. It is
69:43 chance that something won't get rid of fewer. More and more cells will
69:48 passwords. You keep transferring it if don't maintain that selective pressure.
69:54 Because remember again it's a it's an energy thing right? Keeping in the
70:00 with me and you have to maintain have to use energy to maintain the
70:06 so that the pressure on them is a way to help them hold on
70:09 it, right? But if you maintain that pressure over time they can
70:15 after several generations Washington, just wasting and it's never encountering the to keep
70:25 . So it will eventually be So, um so these plans and
70:32 certainly have their certain conditions, they absolutely be helpful. Right? So
70:37 cells are growing the tetracycline and it's gonna want to have that,
70:41 that may not necessarily be a situation always arises in nature all the
70:48 Right? So, it's kind of and that's why the pressures of
70:53 they'll eventually losing that for so many of division. Is that any questions
70:59 that? Okay, So, like said, the ball was after
71:05 These things, these things are super in everything they do, right?
71:09 they're not, they're gonna not Okay. So, um so let's
71:19 yeah, let's um this is probably good spot. So I think we
71:25 have a couple of things to finish this section. We can do that
71:28 monday, folks. Thanks. And , good weekend. Good luck on
71:35 exam. You mean that let's just this
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