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BIOL 2321_Microbiology for Science Majors - 2321_MW1130_3_30_23_Lecture
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00:02 Ok, see. Right that Ok. Um Hey folks. Uh
00:32 . Uh So we are um we up uh chapter nine today and get
00:42 chapter 10. Um So 10 is , who's, I'm, I'm sure
00:50 number of you. I've already done Operon before, at least once.
00:55 operant control anybody. No. Ok. Um All right.
01:02 then we'll learn to get, so we'll start kind of, we'll
01:07 on LA later today, later this . So, um what else?
01:15 blackboard quiz opens tomorrow? Ok. It will only, it'll cover stuff
01:22 uh 21. No, wait from 78 and nine. Nothing on 10
01:28 10 is on the quiz. That'll be next week. It'll be
01:31 there. Um ok. So, , one thing, so I think
01:37 mentioned in the email uh Friday. tomorrow schedule opens. Ok, for
01:43 three. So if it's important to a specific time, then it will
01:49 open, I guess at midnight Ok. So or yeah. Um
01:57 right. So just a little bit recap. So. Ok. Um
02:07 in Chapter nine. OK. Um gene transfer. Ok. Basically for
02:16 summarize pro right? Generate genetic Ok. Now, those types like
02:31 life. Ok. Um, can pass genes on vertically, right.
02:39 , if you're a bacterium that's binary , right? Um If it's a
02:45 , right, it's, it's um can do it through mitosis. Uh
02:49 of course, uh we have AEX , right? So, uh but
02:54 still is a vertical gene transfer. with binary fission, as you
02:58 that's basically like a xerox machine, ? But as we talked about last
03:02 , um the it's not that Population of an E COLI will have
03:09 small proportion that will uh they'll OK. And you genes can be
03:17 can occur through mutation, of Um But also in bacteria through this
03:23 gene transfer, right this way to members of the population, perhaps other
03:30 in, in, in the OK. And so uh and
03:34 it's, it's, and it is , right? It's not a trivial
03:38 . It can uh it can lead a number of genes, can require
03:43 number of genes this way. Um saw the E coli where a quarter
03:48 the E COLI geno is thought to due to the inheritance of these genes
03:54 through horizontal gene transfer. OK. it's not just a kind of a
03:59 rare thing that happens on then it's significant in the, in the pro
04:03 world. OK. So, um we looked at two of the two
04:09 the four. So the four of mechanisms we get transformation. So I
04:13 basically uptake of naked DNA. And looked at the gram positive and and
04:19 mechanisms of the transformer, right, competence, making it some competent means
04:25 can take up DNA. Um And the gram negative by comparison, a
04:31 little simpler having a pilot that can and bind DNA and bring it
04:36 OK. So the uh remember that , the gram positive model we looked
04:42 was an example of a quorum right? At this time to sell
04:47 , you have enough cells present enough factors accumulate. Then you trigger the
04:53 of forming this transformer zom that can in the DNA. OK. And
04:59 we look at uh conjugation right? that involves cell cell contact the number
05:05 . So the plus or F Uh what makes it that are this
05:11 of genes specific to the process of copy In the form of?
05:20 And so we looked at like three um the basic uh F plus.
05:27 this is about a donor recipient, ? F plus F minus conjugating.
05:34 um the H F R cell Is the transfer integrates into the host
05:42 OK. And in, in doing , it basically uh allows the entire
05:49 then to be moved and copied and . OK. Remember that doesn't happen
05:58 that connection has to be for a time, long time being maybe 90
06:03 , two hours, right, in to pass the whole chromosome and it
06:05 doesn't happen um due to physical effects Brownian motion like bouncing off the cell
06:12 creating instability. So, um so though maybe the entire chromosome is not
06:19 , but certainly a number of genes OK. So, um but then
06:25 in all these processes, right, is important, right? The recombination
06:30 it to become part of the genome the cell. OK? Combining that
06:35 DNA with the genome. OK. so uh then the this F prime
06:43 , OK, also relies on a H F R. OK. And
06:50 this has to do with the, the plans comes out. So I
06:55 know what the but uh numbers are terms of how often it integrates.
07:02 uh but it certainly does happen because F R cells form certainly. Um
07:08 then usually what happens is when it exercises or comes out that's what comes
07:13 . OK? What when it is comes out a clean excision if you
07:17 ? OK. But there's a one a million or so times when it
07:21 happen that way and it takes one the genes from the chromosome with
07:26 So this is what the F prime represents. OK. Taking that chromosome
07:34 that would kind of be side, maybe took away. OK. So
07:41 that means is this is remember the um partial deployed OK. Cell.
07:50 uh contains maybe there's an, there's a gene here, right? Uh
07:58 , if it, if it conjugates , this conjugates then with a cell
08:05 already containing a on a in its , then it has two copies of
08:10 , you have one or more copies a gene in a partial diploid.
08:15 . So um so that catches us to today. Any questions?
08:22 So we're gonna get two more transduction and transposition. OK. Um
08:28 transposition transduction, excuse me is a intermediate. So just go back to
08:34 . Uh So there's 22 mechanisms, is called generalized transduction. OK.
08:43 other one is called specialized and both relate to the type of stage
08:49 So remember your lighting pha right? is a light and then you have
08:54 lio phase, right? You can inside the chromosome and then eventually go
08:59 a light. But that's really what how these two types of transduction
09:06 It's really that OK. So in transduction, this is a mighty p
09:12 this a little P is carrying this . So what happens is uh this
09:19 this goes through the normal viral life here. OK. And uh so
09:25 enters and begins the whole copying the and production of viral proteins, et
09:32 , right? We talked about this part of that is uh degradation of
09:36 whole genome OK. But then when comes to the assembly, right?
09:41 viral particles, um the DNA inserts DNA rather than viral DNA.
09:49 And now you produce, as shown these um uh non purple ones right
09:59 . These are containing host DNA. . And so, uh as so
10:05 cell then uh goes through and it lied and the virus is release and
10:11 new cells and then those containing host . OK. This guy. All
10:19 . Well, um in fact, it is, it should be
10:23 right? It has has the ability recognize the host, right? It
10:27 the tail fibers if you will, can recognize, bind, insert
10:33 But now the DNA is not it's not a virus, it's
10:37 from that previous host. OK. in so they call it generalized because
10:49 any gene or genes that are present this host anywhere on this chromosome can
10:59 um let's draw it here can be by accident, right? A segment
11:05 be inserted. So theoretically any segment the genome can be, you
11:11 incorrectly packaged in the age. And when you get, when it undergoes
11:15 process of infection, as we see , then that DNA can contain any
11:22 the genes that are in that previous chromosome. OK. So that's why
11:26 say generalized. It can be any from the previous host can be transferred
11:29 way. OK. That's, and , and that's what separates it from
11:35 trans function. OK. So it's just an error in packaging as
11:41 virus is making new viral particles. . So the other mechanism um is
11:51 a lysogenic phase. So we talk lambda phase before, right? And
11:55 here it's going to integrate, Because it forms of proof,
11:59 So prop is part of its OK. And so the insertion is
12:06 is specific, right? It's a point where it inserts, that's kind
12:10 where the term specialized transduction comes right? So it's a specific
12:16 And so it's at these sites called , right? P and B,
12:22 ? So, and that's when land into uh E coli genome as part
12:28 its like prophage, that's where it goes into OK is right there.
12:34 so here you see the integrated P DNA. And so again, when
12:40 exits, OK, it may take of that DNA from the chromosome with
12:49 . OK. And it could, this example is showing um uh the
12:57 is being taken as part of the is of that P DNA. Um
13:03 so here's our lamb phase lambda DNA now and galactose gene didn't have that
13:09 it before, right? Because this what's in its genome. OK?
13:14 so this um if it infects then cell, another E coli that E
13:22 can end up getting an extra, . As you see there again,
13:29 diploid, right, partial diploid So uh this looks of course,
13:34 resembles what process we came before they having a weird excision, right?
13:40 the F prime formation, right? it looks very similar to that.
13:44 . So it's all based on the being slightly shifted one way or the
13:51 , right? It could just as have been shifted to this side.
13:55 I'm sorry to this side and you the, the bio uh biotin GE
14:00 it, OK. In this it was more shifted to this
14:05 So we had that galactic. So just about this a bar excision,
14:10 ? Just like the OK. And it's not a common, um,
14:17 and I'm sure it's not a, , it's a relatively rare occurrence but
14:21 does happen. Ok. And, , but again, another way to
14:25 a partial diplo. OK. um, and so again, having
14:32 electric copy of the gene, That thing can evolve independently,
14:37 Maybe in different function, maybe it help the cell survive better or something
14:42 that. Ok. So, so again, very specific.
14:47 so not any gene in a hose be transferred to another E coli.
14:52 ? It's only gonna be what's, here on what's flanking either side of
15:01 end of the phase genome, So anything that's here or here,
15:07 . A few genes, OK. maybe two. That's it,
15:12 And it's typically gonna be whatever on the genes are bio here,
15:18 there, whatever is here. That's it's restricted to. Right.
15:23 you aren't gonna get any gene in genome passed just what's on either
15:27 It's all based on it. Excising of incorrectly if you want.
15:33 So that's specialized transduction. Um Any about that, right? Ok.
15:41 let's look at transformation. OK. transportable elements. So these are,
15:47 , um, these are found, think in almost all what he
15:52 OK. Um They're sometimes called jumping because they, they typically, they
16:00 reside in the cell they're in, ? That's what they do and they
16:07 around the genome. OK. So , they have a way to excise
16:13 , copy and excise and then go another location, the genome.
16:18 Um These were discovered in, in plants. Um And so they
16:24 they have different effects, they can gene expression of certain genes. They
16:30 can insert themselves called the mutations in genes. Um They can carry other
16:38 with them. OK? Um But are ways which you can, which
16:44 transpo element can um be shifted to cell and, and will that,
16:50 where the, that's our interest right? Because it's a, it's
16:54 of the mechanisms of hoon transferring. . Um Now the, you
17:00 you don't get the idea that uh , they can jump around from around
17:05 chromosome that they're doing is zillions of a minute. OK. It's actually
17:11 at a fairly low break. And there are ways to control
17:16 It's not really well understood how it's . Uh But because you don't want
17:21 like that jumping around over the you know, can create all kinds
17:23 mutations and this and that. So is in a kind of a,
17:28 controlled manner that this happens. But , OK, the, uh so
17:34 transpo element, right? So technically, um there's two types,
17:42 ? One's called an insertion sequence. . And that's the most simplest,
17:46 of them, no matter what kind is, all of them have a
17:50 a right? That's the enzyme that it to um excise itself and then
17:56 itself somewhere else, right? That is a part of any transposing
18:01 OK? And so here you see and an insertion sequence is a
18:09 simplest one because all it has is transpose gene. OK? And it
18:16 these inverted repeat sequences. So an repeat is simply just here is a
18:23 T C G T and here's the sequence here in reverse. OK.
18:30 that's simply all it means that's what inverted repeat sequence is. And
18:34 and there's in, in the middle be in this case, a
18:40 OK. So that's a number to sequence. And so, so the
18:45 transposes element is that OK, which , which is basically what you're seeing
18:49 . That's, that's an insertion OK? And um the movement.
18:58 the transpose enables it to excise, ? And then recombine uh elsewhere.
19:07 ? And now there's two ways it be to use uh word document
19:14 right? You can copy and paste you can cut and paste.
19:17 And that's the difference between replicated and repli nonreplicating, right? Nonreplicating you
19:24 just cutting it out and go non um or sorry, replicated means you're
19:32 , it's staying there and you're copying and the copy goes here. So
19:36 have two copies now, right? replicated. Nonreplicating, don't it just
19:42 excise and goes elsewhere? OK. um so the um transpose on
19:53 short for T N is the OK? That's, that's an insertion
20:00 . So something like this that would in addition to the transpose other
20:07 OK? So just like a it's a bigger version, OK?
20:12 now we're pairing other genes with So not only the ability to kind
20:17 excise and recombine, but now carry with it. OK? And so
20:23 the pro world, those can often antibiotic resistance genes. OK? And
20:30 then the question is it's one thing have that in a cell jumping
20:36 right? But to get it out the population and that's what it's gonna
20:41 to exit the cell. So how can happen is what types we call
20:47 transports. OK. So that enables to be transferred to another cell.
20:53 so same basic principle as we saw , you know, the F plus
20:58 minus conjugation. OK. So the has as part of its genes,
21:06 ? The the the genes to enable . OK. And so here's donor
21:13 , right? And um the transposon excise itself right to here and then
21:24 begins to roll in circle replication and copying and then the the movement of
21:31 the uh plasmid or the DNA to recipient cell. But the thing is
21:37 can't exist, it won't exist in state where, where it's like a
21:42 a plasma state. Hang on cell are meant to integrate. OK?
21:48 so it'll go back to this state here. OK? But the thing
21:53 now you got that transposon, both spread that uh whatever genes are with
22:00 transposon to another cell and then that can do the same to other
22:06 So it'll spread can spread through this this way. OK. You
22:10 theoretically another way to do this that can happen is just a scenario
22:18 So here is a chromosome. And here is a transposon T N
22:27 short, right, right there. so say the cell has a
22:32 right? It has an F right F plus it could be possible
22:38 the transposon just jumps into that and into a AAA plasma that already can
22:46 that factor and so that can perpetuate transpo as well. That's been seen
22:52 . OK. So the transposon, difference here in this scenario is the
22:57 itself is not a complicated type entity this is up here. All
23:03 it's simply, it's just a transposon to jump into you and that factor
23:08 that the cell has already and then can be passed on that way.
23:13 . So um so those mechanisms horizon . OK. So kind of the
23:20 here is to see each type, ? Transformation conjuration. Can you identify
23:30 , what's, how do you identify one? What's the unique, what
23:33 the unique features of each one? kind of the the thing here?
23:39 . So um any questions? So let's look at, OK,
23:48 gears here. So chapter 10, didn't look at gene expression.
23:53 So, well, regulate gene right? So remember the points of
23:59 , right? Um Energy, they're to remember the gene expression uses lots
24:07 energy to do that. So you're have to control it very tightly and
24:11 all based, the control is all on kind of what we know
24:15 right? Transcription translation. That's, what I was controlled at those various
24:22 . OK. So we'll look at we look at um lactose operon and
24:30 are examples of this. OK? there's gonna be terminology that you,
24:35 you always use in the context of regulation. OK? Uh repression,
24:41 induction, um corepressor, these are of the terms that are used.
24:46 we'll go through what all those OK. Um And how you would
24:51 them really? So let's start with question here. OK. So um
24:58 is a bacterial cell for the internal turns into an output action. So
25:06 have external stimulus. OK. Uh cell responds to that in some way
25:14 it responds by doing what by producing functioning of various R N A
25:25 protein proteins, DNA double helix or . OK. That should be a
25:34 easy one. Yeah. Yeah. , Yeah, it's counts down from
26:11 , right? So of course, is gonna be functioning of various types
26:21 proteins. OK. That's what we're gonna control the expression of.
26:27 . So if we um look right? So you can imagine a
26:36 cell on the environment surrounded by members its population, other America with other
26:43 uh environmental conditions. What are all things that we'll have to respond
26:47 You? Probably write your own list this right? Temperature. Phh sodium
26:52 , oxygen levels. Um the the movements that are present, right?
26:59 , any and all these things. so it's got to respond to in
27:03 way, OK, whether it's good bad. And so that of
27:08 will evolve. Um The only way can do it is to have some
27:13 of way to convert that outside Into an inside action. So very
27:20 you're gonna have some kind of sensor that will respond or, or,
27:25 convert that response to an internal OK. And so then what's it
27:31 be, what's going, it's typically gonna be expression of some kind of
27:36 or proteins? OK. Not but most of the time that's the
27:41 . And so what does that Well, the regulatory elements we talked
27:47 before in terms of the pro for example, OK. And things
27:54 a regulatory coaching, an operator right? These are the things that
27:57 become, right? Uh Not the thing because we're gonna control on multiple
28:04 . OK. And so um the let's look at this question here.
28:12 . So the fan, let me about that Crypto Fan Opera expression can
28:24 controlled by crypto itself inhibiting one of enzymes responsible for its synthesis.
28:32 So the trip operon um those um code for proteins that make crypto.
28:42 . So the crypto can be self . So crypto does this by interacting
28:47 one of the enzymes that actually makes . OK. And so what kind
28:53 control is this? So there's right? Even the names with different
28:57 of control. OK. Yeah. OK. It's counted down from
30:09 right? Um Who picked your Who picked B as in boy?
30:22 you take is that you are How do you do with the
30:30 right? Cause enzymes, right? one of the enzymes, right?
30:36 or proteins. OK. So that into post translational, right? Translational
30:50 is on OK. Transcription. Um be we'll just say in our
31:02 there's some variations there control a little , right? So just say
31:07 right, DNA. Um so we're a protein, right? By altering
31:13 function. OK? And so this gonna be right there. Once you
31:20 , once you finish translation, post , you've made a protein,
31:25 So that's will always be um a controlling it, right? This is
31:30 old allosteric inhibition if you remember OK. So here are the levels
31:37 here, right? Um And all occur um together, it can occur
31:45 different times, it can occur It doesn't, it doesn't have to
31:48 just one. OK. And so DNA controls the level of DNA.
31:53 look at that next week. Uh the context of phase variation, we
32:00 it OK. So DNA, se are altered such that they affect
32:07 OK? Or you can modify nucleotides affect expression. OK. Um Epi
32:15 is just that right? You're affecting from DNA, that expression. So
32:23 can then go um to transcription, control. And so it's, it's
32:33 what you think. In other most people think it has to do
32:38 the made transcript. OK? It has to do with the enzyme that
32:46 it OK. Are you allowing a to be made or not. That's
32:51 control. OK? It's not when already have transcript. OK. Control
32:58 very common in bacteria. OK. our IKEA, it's how the whole
33:05 at, but a lactose operon it's transcription control. Um whether we're
33:12 let our race bind to a promoter make it work or not, that's
33:18 of control, right? We get um things like technically this is what
33:26 would call a post transcription. So we have made the transcript.
33:37 you, can you affect R am A? Stability and different ways?
33:43 . Um Most, this is probably of a thing in you Caros because
33:50 R N A s can have A N A s in general. Don't
33:54 around for a long time once they're , right? They actually be grade
33:59 they're made to be degraded and um , but in e period, they
34:04 to have, can have a longer . OK. So it may become
34:09 to kind of destabilize and to get of them. In some cases,
34:13 R N A S exists on the of about maybe a few minutes at
34:18 , right? It can be hours days actually for you periodic R N
34:22 s depending on the type. But stability is a way to,
34:25 get rid of them. And so translational control. OK. So this
34:32 the ribosome, right? You gotta it translate or not. OK.
34:40 , post translation. That's protein. , um as we just mentioned,
34:48 , like feedback inhibition, things like , the protein itself can uh
34:54 OK. And so of all what is probably, probably the least
35:04 expensive, probably that. All Maybe that, because you don't have
35:12 make anything so much as you do other ones, right? You have
35:16 make a transcript, you have to the parts that affect transcription,
35:21 Um If I had to guess I'd say that. Um but nonetheless,
35:27 all all can be a part of control engine expression. Um and art
35:35 um of genes. So I've been on, OK, controlling genes,
35:42 genes. Um but there are always right? Genes involved in like p
35:48 aspiration genes involved in uh uh things data replication protein. So, so
35:56 are things that always need to be . So those, those fall into
36:01 category here. OK. Um All . So any questions about that?
36:10 that? So let's look at some the terminology here. OK. So
36:15 look at this question. So an repressor, right? So, repressor
36:22 a control element that affects expression. . Um And there's different conditions that
36:32 make it active or inactive. And fact, when we look at lactose
36:38 conditions are the opposite. Um So what we get here, give you
37:33 hint. It's not two of the I know you like this like
37:37 You're not sure, sorry. It's down. So it is one of
37:47 D or E Yeah. How many had to change their answer when I
38:00 it wasn't true but, ok. down. Hm. All right.
38:15 see. Ok. What is the answer? Um It is e it
38:22 to an operator. So, so an active repressor, I
38:29 even if you're not even sure this kind of the key word here,
38:32 ? Repress or repress. OK? That's not gonna promote transcription. That's
38:39 , that's the purpose of an active is to stop transcription. OK?
38:44 It doesn't require an inducer. It require what's called a corepressor.
38:51 But not in an inducer induces OK? So it's not that it
38:59 , wouldn't be C right? Because essentially what A is. Uh And
39:04 D repress. So that means you're the repression, right? So it's
39:11 doing that either. OK. So only be OK? So we'll look
39:15 these terms inducer uh de repression et cetera. OK. So,
39:24 right. Um So here's just a promoter gene and control elements.
39:34 So um a regulatory protein of some is not always, but most,
39:45 always because sometimes R N A cells can be control elements. We'll
39:49 about that next week. But what focusing on now is those that involve
39:55 proteins. OK? And so it's kind of a generic uh
40:00 but very often the regulatory sequence will the opera, I mean, I'm
40:08 , operator, excuse me would be operator write that. Um And so
40:16 protein interacting with an operator is very the case in OK. So um
40:24 induction de repression. So both of mean we're getting expression, right?
40:30 you see depression occurring or induction it means you're getting expression.
40:37 Um And so here's an example of , let me get this out of
40:41 way. So here, so he to the repressor protein, OK?
40:49 interacting with the operator sequence. So when it's active, it's able
40:54 bind that operator. OK? And doing so, basically, physically blocking
41:03 access of the R A plumbers to OK, to be able to get
41:09 and transcribe. OK? It's not you have the presence of an
41:16 OK? That binds to the So now we've inactivated it.
41:22 We've created an inactive repressor by the of an induction. OK? In
41:27 binds. So the repressor can't it falls off. OK. The
41:34 counter with that is repression slash involving corepressor. That scenario is no
41:43 OK. So basically going between these states, right? Induction,
41:52 uh de de repression, repression, , et cetera. So we're going
41:57 those two states. OK. So depression, we have a repressor protein
42:04 , right? But this time the binds, right? And now we
42:10 the active protein complex. OK. it's the opposite of the previous
42:17 right. So here, the active does not bind anything. And that's
42:24 binds to the operator here. The doesn't bind unless you have this corepressor
42:31 it to make it active completely. opposite of, of here.
42:38 And in a nutshell induction is how operon works. The repression is how
42:45 works. But regardless of this, repressor becomes active or inactive. The
42:54 of that term is the same, , which is an active repressor stops
43:02 . OK? An inactive one allows . So that's, it doesn't
43:07 that's the same no matter what kind opera control you're talking about.
43:11 It's just that the conditions that bring those two states about can be quite
43:17 . But the net result is the either you're allowing or not allowing
43:20 And so that's the thing to Triumph. So um now the other
43:27 to kind of also think about is these bindings, this binding here.
43:33 . These are all um it's not , it goes back and forth.
43:43 . Um Yes, the the binding in the absence, for example,
43:48 in induction, in the absence of inducer, the binding there is very
43:54 but it still comes off, you , every, every so often,
43:58 11 of the million times it comes , right? So don't think of
44:02 things as permanent bindings, there's like constants to get technical and things.
44:07 they come unbind and unbind and different will enhance or promote that binding.
44:14 the point is because we're gonna see scenario where that's important, even though
44:18 bound, it can come off every in a while. OK. So
44:23 look at some other things, So you can have um a activators
44:29 course, or repressors that can be , inactive uh that can stop
44:34 But then things that promote expression, ? So kind of counter to a
44:39 is an activator, right? A of activators enhance expression. So this
44:44 back to what we talked about last and basal level of expression,
44:49 It involved just a and a promoter you a low level basic expression.
44:57 do you jack that up? that can be done by the presence
45:00 activators. OK. Transcription factors can this as well. They come to
45:06 promoter and enhance the binding of that plumb race for that promoter, greatly
45:12 expression. OK. So that's what help do, right? Like the
45:18 says they activate expression by binding to uh with other molecules typically binding to
45:24 um motor and that complex enhances the of the plume is for that
45:30 greatly increase the expression. So that's you go from basal level to high
45:36 . And that can be a lactose . It can go from 1000 fold
45:43 in expression, right? Um and again, there's also conditions that
45:50 affect when this thing becomes a, that the lactose operon scenario.
45:59 So, um OK, so let's kind of get into the la operon
46:08 with this question. OK. So um um so the basics here
46:23 you know, gene control, depression , similar terms are used,
46:35 we feel that period gene regulation that really be crazy. Very complicated.
46:43 . Those are more complicated to be , right? So it can involve
46:49 layers. OK? Um If I mean, I'm not even sure
46:55 undergraduate, they even expose you to um because it is so crazy.
46:59 uh that's why with um even in in re bio, I think you
47:07 a little bit of this, I . Yes, yes. one of
47:42 is true. You change the answer the end. No one of these
47:47 true. OK. Let's go to time around. OK. Let's
48:34 Oh OK. If you and e . All right. So um this
48:48 B uh it would be an active prevents expression not in active.
48:57 Black Opera is an example of No, it's gonna be um transcription
49:02 , not post. OK. Um operon control is a metabolic pathway for
49:11 break down metabolism of lactose. Uh So B Black Y product,
49:19 . It's the lactose detector you will . So uh so pretty good.
49:27 . So do remember this right? the, expresses the genes that make
49:35 proteins to begin the breakdown of completely opposite of what Crypto Fan Opera
49:42 . OK. So, all So lactose opera, so the good
49:49 is you don't have to worry about . OK. Still not knowing what
49:55 function is that thing. OK? can have a decline mutant lacking that
50:02 together. It doesn't affect its ability use lactone. OK? So don't
50:06 to worry about that. So and y um so of course,
50:11 a repressor that interacts with an OK. The lac repressor itself as
50:19 operator sequence too. OK. So Z black Y should I? So
50:27 right here, right? This point here that goes back to that even
50:34 a repressed state, my repress was bound to the operator. OK?
50:46 That binding isn't permanent. Yes, if you already go down low.
50:52 the level of the cell and have camera there taking pictures of it most
50:56 the time it's gonna be bound to operator, right? But there's many
50:59 a couple of times when it's right. That's when can come in
51:03 make a little bit of transcript. . So that's what happens with this
51:08 , right? Not and we're talking the number amount of protein made it
51:13 one or two molecules work, So miniscule, OK? But nonetheless
51:19 as we'll see, OK. So black line function is basically a transport
51:26 protein for lactose, right? It it and brings it in um inside
51:34 cell. Once lactose gets in it's a disaccharide. So we're gonna
51:39 it into uh well, first we're convert some of it into alo
51:45 OK. This is actually the inducer is not, it's actually this slightly
51:50 version called alo lactose is the OK. Then uh as this is
51:55 out by the lac Z beta galactic All right. So, um so
52:02 is at low levels of black Z , which you would have,
52:08 If we're, if we're in this right here, right? And you
52:13 get a little bit of expression, gonna have a couple of molecules of
52:17 Z uh protein in couple of LA . OK. And so the lack
52:23 Y will do this and sit in membrane, the lac, if there's
52:28 lactose present, we'll convert some of to inducer. OK. Now,
52:34 it ramps up, if it ramps , then it will be converting most
52:38 it to the lactose to these two . All right. And that's what
52:44 they funnel into OK. They fall black get make. OK.
52:51 so the only way for this E , let's say it's E coli there's
52:59 things that can ferment lactose. But , the only way you can see
53:04 is with this being in the membrane the eyeball for lacto, right?
53:11 it's there, it can detect If it's not, it will never
53:13 , it could have a zillion molecules lactose around and never know it unless
53:17 have a lack why protein sitting in membrane. OK. So that's why
53:23 has to be this low level. . Again, I'm talking a couple
53:28 molecules work not a lot. But those one or two lack why
53:33 sit in here and they look and a lack of OK. So uh
53:40 of just to reiterate the point right? This is why we're having
53:42 happen because even in right, this state, right? There's a lack
53:49 pressure bound to the operator blocking But the one that a million times
53:58 not found, then you get a bit of expression. And again,
54:03 literally, I literally mean just one two molecules of these things,
54:08 So um that goes in fine. it's out there, OK? Very
54:19 , it will wrap up expression. ? So lactose comes in and is
54:28 by lay into the code and that bind to the repressor. OK?
54:35 it doesn't take a lot of inducer get the effect and you'll go from
54:40 or two molecules to thousands in right? It'll happen that fast expression
54:50 increase and uh then will come rushing , you get lots, then you
54:56 you'll get lots of these, Like peras and then very quickly it's
55:04 in right process, it use the source to grow, right? We
55:09 about before. So, uh but again, just to reiterate,
55:14 have to have a low level of or else you're not gonna see
55:19 OK. So that's why um it this way. OK. And so
55:24 , the the level will, the is 1000 fold or more,
55:29 Very quickly. OK? And it very quickly shut off, right?
55:34 all the lactose is used up, ? Then you can't make any more
55:38 and then go with that. So so we look at both sides
55:44 right? So here's lactose uh right? In the presence of in
55:50 absence of lactose again, logic, ? Why, why have expression if
55:55 isn't there? And other than I , the amount of this occurring in
56:01 scenario is miniscule. So the the lost for that is not great.
56:08 ? So it's fine for that little to happen. Um The um and
56:14 you see here how it happens is repressor, active repressor kind of brings
56:19 both operators from the regulatory lac eye from the, the uh lactose
56:28 And so this is basically it's inaccessible the clim. You can't, you
56:33 transcribe this. OK. Then in presence of lactose, it comes
56:39 converted all lactose and then binds and this site is free and we can
56:46 them All right. So uh press , pressor active. OK. Um
56:54 that's one part of the story. . Black clubs present black accent,
57:02 ? So the other missing piece here glucose. So glucose exerts an effect
57:10 the other layer here. OK. let's look and see what that effect
57:16 . If you can Figure that one , high level transcription of lactose operon
57:25 all of the following except, I'll open it again. Sorry,
57:49 meant that I get my thumb wasn't enough to turn it off. What's
57:53 , what's going down? All Try again. All right.
58:00 Mhm. And there is an OK. So don't pick Fs.
58:28 . OK. Oops it to the . Hold on. There we
58:35 See. Yes. All right. count down. OK. True.
59:10 see it. OK. Here we . OK. Oh, look at
59:21 . C is correct. OK. um obviously you want lactose present?
59:31 makes sense. Um This right creates , this creates the um inactive repressor
59:43 get expression. So I certainly need . And you need the option to
59:47 glucose and you need this, this these are related to each other.
59:56 . A MP levels. It's like a MP levels. OK. So
60:01 to this phenomenon called metabolite depression, . Uh operates so exerts its effect
60:14 the presence of a number of other , not just lack um lots of
60:21 types of sugars as well. Glucose is kind of the the big
60:27 , right? Um glycolysis, Glucose, you could think of that
60:35 glycolysis is made for glucose, Because glucose goes right in no other
60:41 necessary, right? As it comes , right, it's converted to
60:45 six phosphate and then goes right into process, right? Other sugars and
60:51 require an extra step right, in to, to funnel themselves into the
60:56 . OK. With that, this to efficiency relates to efficiency,
61:02 So um so how does this Well, these other sugar promotors if
61:10 will lactose and the like um rely this receptor protein. OK. And
61:18 levels of cyclic A MP. So A MP is actually in the biological
61:26 in us as well common as a signaling molecule for different phenomena, you
61:34 , in, in us it's it's various things um as a way to
61:39 , OK, if something's happening, need to do something. So the
61:42 molecule kind of has that function. . So in a way it's kind
61:47 a energy in the bacterial. So kind of an energy assessor if you
61:54 . OK. So um so remember kind of the related molecules here A
62:00 P AD P A MP, All related. And so really
62:09 in, I'm sure in ourselves as , the A T P AD P
62:14 are kind of a indicator of kind the end health state of the
62:19 OK. Typically bacterial cells have like 1.5 ratio more, a little more
62:23 T P than AD P is an that they're functioning well that they're
62:28 OK. And so these ratios can affected when you see the presence of
62:32 of a MP level changing. So you don't worry about all that
62:38 . This is kind of the basis for what's like a MP and how
62:41 , how it is affecting things. . So for glucose, um high
62:48 of glucose and P levels drop, . Um Because glucose is the preferred
62:54 if it's there and um the low second A P levels rise. So
63:02 , it's an indicator of the energy's energy state of the cell.
63:07 So in the low glucose uh then the cells are kind of on
63:13 lookout if you will for other other sugars lactose being one of
63:18 OK? And so if present, these high cyclic A MP, these
63:25 A MP molecules in red will then to the receptor. The receptor is
63:31 of at a somewhat positive level, it's the cyclic A MP S that
63:36 go up and down, right? if they're high, then there's plenty
63:41 them to bind, right? And you'll create this active complex activator basically
63:48 what it is. OK? And uh that's when the is or not
63:54 around, right? Second P O high, it binds and we get
64:01 of expression. OK? If Glucosure present, then you have low levels
64:05 it's less likely to form this act complex. OK. So again,
64:10 about buying the promoter, increasing the of the prelimerase for the promoter,
64:16 expression. OK. So you have have not just lactose presence but the
64:21 of glucose. OK. So both those things give you a high levels
64:26 , of expression of the lactose OK. So this is all we
64:32 about depression, right? Um They say lactose operon repression because it it
64:40 multiple types of sugars, right? theta repression, glucose has the same
64:44 on other sugars, right? So give it the name metabolite repression
64:48 OK? The tablets are any kind molecule that can be metabolized. You
64:53 refer to glucose as a metabolite, ? But because it's the one exerting
64:57 effect, we don't call it OK. So when we look at
65:02 and again, it goes back to , right? We saw what you
65:06 to do with lactose, right? lactose comes in, you have to
65:09 it into two sugars, right? lactose and glucose, glucose can go
65:12 ahead. But then the galactose has be go through a step or
65:16 So it's like 12 or three steps lactose can be completely utilized. And
65:22 again, the efficiency and energy to that. Uh And that's why glucose
65:27 a big effect. It does. . So um and so when you
65:32 at these here, have both of in a culture, broth, lactose
65:36 glucose together, right? Then glucose course, is used first. That's
65:40 the that's what's meant by um ox , two curves. So there's two
65:50 here, right? There's one glucose is utilized. There's a little
65:54 , right? So remember that's where now has to switch on these other
65:59 lactose operon, right? So there's bit of a lag, then it
66:02 up again. So this biopic, do they call dioxin growth?
66:07 And so at the molecular level, , we've seen this before, this
66:13 that um group translocation uh mechanism of , right? So glucose comes in
66:21 then is immediately converted to glucose, phosphate, right? So glucose never
66:26 in itself, which is why it coming in, right? That's that
66:29 translocation. So uh one of these then, so these are the guys
66:35 hand off the phosphate groups and one these subunits when it's un phosphorated after
66:44 phosphorated glucose, right? It interacts the lac Y and so it blocks
66:50 basically it can't lactose can't come into cell, right? So that's how
66:54 exerts the effect when it's absence, ? In these phosphorated forms, which
67:01 doing nothing because there's no glucose coming , right? That can't affect,
67:06 no effect on the la wine. it's, it's free to function and
67:10 lactose in it if it's there. . So um glucose, present
67:16 absent maximum expression of black. So um OK. Here again,
67:27 the summary. OK. Um Are any questions about this? So
67:35 we're gonna, I'm gonna go through the beginning of the Trip Opera just
67:39 give you a snapshot of that. uh we'll do questions, you know
67:45 comparing black opera Trip Opera. So all on the same page there.
67:50 . But do there's a couple of that relate to these opera. I
67:55 they'll be helpful looking at them. . Any question at the moment.
68:01 . So let's just for comparison. at the Tripen Opera. OK.
68:04 a question. So remember it's going be different, obviously, both in
68:15 , right? How it's controlled. ? one of these are true.
68:57 one of these are true. A all right. Counting down
69:24 OK? Um No, it And the he is from the
69:40 So let's just look at the basics this. Number one oxy lacto.
69:47 is one that it's a biosyn. an anabolic pathway. It makes crypto
69:54 , right? Amino acid, of . And so it involves um five
70:02 genes. All right, one typical operon structure. We're not gonna
70:09 about it today but make a mental of this sequence. OK? Leader
70:16 . So as it's transcribed, that sequence is a part of every transcript
70:27 . Which will be pretty much this of the transcript. OK. Leader
70:32 sequence. OK. That's a part the control as well. We'll get
70:37 that next time. OK? Um These are the five enzymes that end
70:45 producing crypto. OK. Um So fan, so in that state,
70:52 uh it's obviously the uh derepress it's allowed to express, right? So
70:59 repressor protein shown here. So the O repressor is the call it the
71:07 form. OK? You see there when it's the hole or holo
71:15 that's the active form. OK? in this state, um we're having
71:21 , right? And we get we get activation when the is
71:29 OK? And so it binds, the making the whole oppressor.
71:36 So that then will bind to the blocking expression. OK. So similar
71:45 concept to Laos operon, it's about repressor being active or inactive and in
71:50 inactive state, not binding to the , active state binding. So
71:54 that concept is the same. Which is the conditions are different.
71:58 allow that. OK. So the then is if crypto fans being
72:05 but it's present, it, it's made, right? It's right here
72:10 ? Then, then how is, do we keep getting expression? All
72:16 , how do we keep getting this ? If this is present, anybody
72:25 is being made, it's gonna be or something it's gonna be used for
72:31 give an egg. Ok. That's of what's in turkey to make you
72:41 , right. Crypto, right. is an amino acid, which is
72:46 proteins in turkey, right? In . Right. So certainly every,
72:52 protein in the cell has at least crypto. Right. So it's for
72:58 sense of proteins. Oh, it be these for other things, primarily
73:02 in that. Right. So when it likely that crypto fan is being
73:12 ? When would it begin to Because there's a new trip fan all
73:20 a sudden trip fans here and now building up. It's not going
73:23 It's not being used for anything. protein go. OK. That's gonna
73:29 tied to gross right time cell Is it more likely to be synthesizing
73:43 fan here or here? A B obviously stationary phase you're not growing um
73:56 producing a lot of crypto, So it's gonna accumulate. So what
74:00 you gonna do? You're gonna shut off, right. That's how Crypto
74:04 can self regulate both in this right? But also can also interact
74:11 that enzyme. That first question we or one of the first questions we
74:16 , we can that enzyme and stop . So both as posttranslational control and
74:25 of control, right? So it's uh it's how all amino acid
74:32 work like the amino acid, they kind of controls its own destiny if
74:37 will, right? Which makes If relative compare Operon to La
74:44 which is one E collector probably live , if it had to all
74:52 Goodness. Come on. People can without like which one you can live
75:00 , which you can live without wits can live without witch. Oh,
75:07 goodness. You gotta be capable. have got to be capable and you
75:16 it without a tri on or a soft. Of course, you can
75:23 a bazillion things on this planet, kinds of stuff. I'm having an
75:31 to his Aunt Ron. So what you find Aunt Ron? Is he
75:35 live very long? No. Um Can you live without trip
75:42 OK, I can't say put a over your head like I did with
75:45 Respiration experiment. But, you don't eat any trip to fan,
75:49 ? And see what happens, Uh You can live without eating a
75:53 toast. All right. So that's , folks. We'll see you next
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