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BIOL 2320_Microbiology for Non-Science Majors - 09_29_22_Lecture
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00:04 mhm mm. All right. Alright , let's go ahead and get
00:32 So again, um material we've been about this week, uh Tuesday.
00:39 is not is not on exam Alright, so we've started unit two
00:46 here on Tuesday. Okay, so is the material that's gonna be on
00:51 be on exams to. Okay. is a ways away. Okay,
00:58 um of course exam ones tomorrow um saturday, depending on when you signed
01:06 . Um So um weekly blackboard mastering assignment um will be on schedule
01:18 week again, but not due until , so just remember that. So
01:26 today um the we're gonna go into this chapter Chapter eight will cover over
01:37 couple of days is molecular genetics, we're gonna you're not gonna be expected
01:42 know the details of how many replicates details of protein synthesis. Okay,
01:50 more an overview type of thing. , overview knowledge of it.
01:56 you need to know some of the , but not, I don't expect
02:00 to regurgitate here is all the dirty of how you do these processes.
02:06 more what's the what's the what's this ? Kind of a thing.
02:10 so as we go through this, I don't cover for that reason.
02:18 don't cover everything that's in that There's a lot of details in
02:21 Okay, so be aware of Which is why I put For the
02:25 edition the current edition of the textbook . Okay, so if you don't
02:30 that addition, then certainly use your notes as kind of a guide
02:36 Um because for that because I don't through all the details minutia of these
02:42 . It's more what it represents. isn't why it's important these kind of
02:47 . Okay and so kind of to it in because obviously here we're kind
02:53 wanted to emphasize as much as we uh from my medical healthcare type
03:00 Right So of course microbiology. It's disease. Okay so you know it's
03:06 basic processes. Well number one these things that obviously occur in all living
03:12 . Right? Um whether you're a or a cockroach or a rat or
03:16 human or a bacterium. Okay. obviously replicate D. N.
03:20 We all expressed genes. Right. DNA RNA protein flow of information.
03:28 regulate genes and so all of that's and mutations occur across you know all
03:34 many things of course. And so it's you know one of the one
03:40 the or these things or how we're related on on this planet among other
03:45 . Okay so naturally you're infectious types organisms, pathogens that cause disease.
03:53 they express violence genes. Right. features that allow them to cause
04:00 Okay mutations occur. Right. That say a infectious agent that normally resides
04:10 a particular animal to make the leap infecting a human. Okay in fact
04:15 I. D. S. Right infectious diseases occurred. One of the
04:20 of course mutations occur and now they're to recognize selves and humans and infect
04:26 . So you know it's these processes certainly do relate to you know the
04:32 uh microbes that cause disease. For . Okay so kind of you know
04:37 way to look at it as we through this. Okay and so some
04:40 this is going to be because everybody is very varied backgrounds in terms of
04:48 they've had before. Okay and this gonna be one of those areas.
04:52 um so some of the review so would be kind of pressure. So
04:57 will be kind of, I'm not sure I may need to may need
05:01 go back and look at this So that's why we have some kind
05:04 introduce some basic concepts in the So if you've seen this before well
05:10 see it again but you know it's won't hurt to see it one more
05:14 . So and we start always start section with this question because this will
05:20 will absolutely weed out those that really the process and those that don't.
05:26 so two part question. So let's at this question. So the process
05:31 transcription and translation. So it assumes know what that is okay is carried
05:36 in the test tube to a test is added from a hippo hippopotamus.
05:42 . R. N. A. . RNA ribosomes from a fish
05:46 N. A. From a zebra a plane race other necessary enzymes.
05:51 nucleotides and amino acids. Okay, um assume in that test tube some
06:01 protein is made. Okay. The of which animal will it represent that
06:08 protein that is synthesized? Um Who is it coming from? Okay.
06:15 we have few choices here. Is just hippo only the hippo only efficiently
06:20 zebra or some combination? Okay. hold that over. So of course
06:28 the operative process you were talking Right transcription, translation. So you
06:35 to have some remembrance of that and involved in those components because this
06:42 sorry? Uh It is open. . So because um this uh this
06:52 of course gene expression of what's going here. Okay, expressing the gene
06:57 the form of protein. Okay. so we'll go through kind of the
07:01 of this, what this means. and if you're not sure here,
07:07 fine. So this this part of lecture is about trying to hope to
07:12 you understand that. So if you're 100% sure that's no problem. Okay
07:20 your best guess. Okay Then we another question coming after this one and
07:32 take a break for a bit. . Right. Alright. On the
07:53 down from four 321. See okay B. And E. Sensibility
08:06 Okay, so as I figured um . N. A. Right so
08:14 . N. A. So the of information, right. D.
08:16 . A. two r. a. two proteins. That's the
08:24 what they call central dogma of How information flows in all living
08:31 Uh flow of information is about um these seemingly random letters right? You're
08:39 G. C. S. And . S. Right? It seems
08:42 be like this random order. But they're not it's not by far
08:46 not random. But nonetheless getting that a workable form. Right? Because
08:51 what does all the work in cells US right, proteins, two different
08:55 , Right, carry out metabolic structural functions, this and that.
09:00 . So that getting that it's encoded course, as we as we all
09:06 in the D. N. Right? So but D.
09:09 A. In itself and those random random letters can't do the work.
09:15 ? You have to get it into form that can that's the protein.
09:18 ? So it's a route we take do that. Okay. So certainly
09:23 protein made in this test tube, definitely gonna be one of your choices
09:27 a fish because D. N. . Dead spot. Right here,
09:31 D. N. A. Right of course the blueprint, right?
09:36 what we're expressing expressing in gene in DNA. Whatever this protein is.
09:40 , so fish is definitely gonna be may be the only one but there's
09:46 to be in your answer there. is there something else? What's another
09:51 if present? Can also yield to of that protein anybody which type of
10:00 name. What's The Other 1? . RNA? Messenger RNA. So
10:11 you got this all these components and got D. N. A.
10:15 there certainly DNA will be expressed because got the components to do that.
10:20 if you also have this just hanging , okay because that's because that's in
10:27 DNA to RNA to proteins of course fits in these fit in the middle
10:33 , right in that part and um make the protein. Okay so you
10:40 plop the transcript itself. So M messenger RNA transcript all mean the same
10:45 . You can you can plop that and that will be translated. Okay
10:50 it's gonna be the hippo and Okay so um let's look at the
10:58 question. Right so just again it's kind of testing your knowledge of basically
11:02 translation. So let's look at the one. We'll kind of do some
11:07 stuff here. Alright, so this is about genotype. So there's lots
11:12 terms of course when you start talking this subject and genotype is one of
11:17 . So which is among these faults a genotype. Okay. It is
11:25 . It is usually represented as N. A. It's not always
11:32 it can change it only represents the characteristics of an organism. Um Not
11:42 faults. They're all true. Okay count down 10. 54.
12:38 21. Alright. Okay. Um is false. Let's see. Um
12:51 he is the false statement. Okay of course it's heritable. Right?
12:58 are. We all know genotype genotype the D. N. A.
13:02 course. Okay jeans making up the of jeans and well basically the
13:12 N. A. And orgasm. . Obviously it's heritable. Right.
13:17 it was expressed representative D. A. Okay that's true for
13:23 But when is it not representative in ? Who would do that? It's
13:29 microbe that can do is uh we've seen a lot of cases of one
13:36 type of this in the past two viruses. RNA or RNA viruses like
13:44 . So the genome for it is . Okay and that's true for many
13:49 of viruses. Measles mumps, um mumps, rabies, uh Ebola West
13:58 virus. Lots of viruses that cause disease are actually RNA viruses so that
14:02 have an RNA genome but it is true that it's usually represented D.
14:07 . A. Okay. Um it's always expressed. So Point C.
14:12 very important because um as important as as it is to express jeans when
14:20 need them. It's equally important to . Control is a huge part of
14:25 process. Um It can be quite in humans and other you carry
14:31 Um But for any organism you want be able to turn on genes that
14:37 need and only those that you need a certain point and then be able
14:40 turn them off just as quickly. . Because again you have to always
14:45 , right? Because out in nature is competing with each other.
14:49 Any kind of edge you can get edge. Can be being efficient,
14:55 ? Makes you a better competitor able survive better. So, certainly controlling
15:00 genes are turning off and on going play a big part in that.
15:03 , so that's that's a huge Um the it can change certainly mutation
15:10 can create changes in those bases and a different type of genotype and consequently
15:20 change the protein that's made. Um now the the verbal characteristics.
15:26 genotype is the um I'll call it . Right for for specifying the various
15:36 in the cell. Okay. we can take that blueprint and work
15:41 it and make copies and convert that a protein. Okay. Um,
15:48 because of the fact we have control jeans, right, No one organism
15:53 this planet is expressing every single one its genes. Okay, There are
15:58 you haven't expressed since zygote plus 10 , Right? Because you needed those
16:06 to kind of get you from the to 10 days worth of development.
16:11 . And then as you're going to stage, um you know, once
16:15 get out of the womb. Right there's a bunch of genes that you
16:19 need anymore because you're fully developed. ? So but there are lots of
16:27 um Not everything you have in your you necessarily see. Right? Um
16:34 have lots of metabolic reactions going on you. You don't you don't see
16:37 going on. But there's nonetheless there there are traits. So and so
16:43 why the term phenotype. Right? heard of that. I'm sure Sophina
16:50 represents those that part of the genome being expressed right to produce a particular
17:00 , right? Which may not always observable. Okay, certainly we can
17:04 blue eyes. Right? But you not see certain types of metabolic reactions
17:09 on and what they do. so but anyway, so it's it's
17:14 uh so that phenotype genotype connection Okay, so we'll talk we'll start
17:19 that. Okay, so here are of you in lab. So this
17:24 look familiar. Um The until next we'll start doing this one lab.
17:30 lactose bras. But regardless the point is um different viewpoints genotype phenotype.
17:38 , so what we can see this an example of what we can see
17:42 terms of features of a microbe. , so ability to use this sugar
17:48 of sugar. If you can ferment change the ph and acidified. And
17:53 that's why it looks yellow, there's ph indicator. Changing yellow when acid
17:58 one is not So indicates it can can't use lactose sugar easily observable
18:04 right? We can do the same by growing it on the plate.
18:08 know, producing colonies. And with the same kind of ph
18:12 We produce different colored colonies depending on they can ferment or not ferment
18:17 Very basic kind of thing appear. blood auger. Right? If the
18:23 capable of releasing this enzyme that can blood cells and you'll see a clearing
18:28 . Okay, So all different types phenotype. Okay. And so of
18:34 , uh expressing different genes right to these different types. All right.
18:41 , here's another way to look at . Okay, So this is um
18:45 you're in the lab, I think week you talked about the unknown
18:49 Right? You're gonna be doing starting next week. So, um If
18:55 you have the capability, okay, could send out for one of these
19:01 from one of your local uh scientific company. Okay. And this will
19:06 you to do all the tests at time and get your answer in 24
19:11 and be done with the unknown project you just kick your feet back.
19:14 ? Unfortunately, we're gonna make a it out a little longer than
19:17 Okay, This is what we call is one of these rapid I detest
19:23 test kits. And so basically it multiple chambers, right? They're all
19:28 , This is different. These tests different types of fermented sugar that sugar
19:33 react with this chemical and produce this product these kind of things. Different
19:38 tests. And so there's actually a loop. So imagine this is a
19:43 loop and this is the the Right? And you take the cap
19:49 and exposes a sterile needle. You a colony on a plate and then
19:54 go and it pulls out. And you basically as as a little needle
20:00 goes along each compartment it's inoculating each compartment itself. So that way you
20:05 play everything at one time. And then you incubate and then you'll see
20:11 of these chambers will will show up different colors. This one's already been
20:17 . So you see different colors relating different results. Some are negative or
20:21 and kind of total it up. get this number code and you look
20:24 in a little booklet and it tells it's most likely this. Okay.
20:29 simple. And so um we're just focus on one box. This is
20:34 area. This you re a Okay so ability to you to hide
20:39 your area is a future that's commonly . Especially among these we're looking here
20:46 enteric bacteria or e coli just sam etcetera. Right? And so um
20:53 positive it shows up as a this of fuchsia pinkish color. Okay and
20:59 okay what does that mean? That's an observable peanut type. Right Yuria
21:06 the enzyme yuri is positive. this is what they're actually going on
21:10 the boxes in that compartment. so we have this in the in
21:14 medium, in that in that If the orgasm has the enzyme it'll
21:18 that down. Right. This creates ph change. Okay, So the
21:23 gene is responsible for this. So genotype, the phenotype says it's
21:30 for that. Well then obviously it have genotype possessing a gene.
21:34 so how is it able to um convert that product? Right. It
21:40 to make the protein to do Right? You have to do transcription
21:45 right? To generate that yuri is . Right? And this is the
21:52 every jean must go whether you're whatever form type you are. Okay.
22:00 everything basically uses the same basic There are gonna be some some you
22:06 , slight differences but the way they and and work basically the same.
22:13 so um ultimately we get the So, so we talked about the
22:19 central dogma. Right, So D A R N. A. And
22:25 of protein up here. Okay, here, right there. The area's
22:30 . So, following that pathway. , survivors. OEMs uh tr NH
22:36 talk about those in a second. And then performing the protein. There's
22:41 protein here and now we have our . Right, so again, this
22:47 one example bacteria on average have 3000 so genes. So when they turn
22:54 things on this is basically what's gonna every time. Okay so but we're
23:00 focusing here on here is control. also gonna be controlled. Right?
23:05 Maria unless it's in nature. And your area were not present around
23:11 anywhere. This wouldn't be occurring Right. That's the control mechanism.
23:16 do that if it's not needed? one thing you can never see in
23:22 of these illustrations is the amount of it takes to do this.
23:28 It takes a lot of energy to the synthesis to make an M.
23:32 . A. To translate into protein put together the OS. Is to
23:37 all this stuff takes energy because we're building stuff right? And Embolism.
23:43 ? That's gonna take a lot of . And so one of the primary
23:47 why don't do this. We don't to because you'd be wasting energy.
23:52 so um so uh so we go genotype to phenotype. Right? So
23:59 that's how they're linked to the genotype a a observable phenotype. When we
24:07 through this expression process, right? to the R. N.
24:10 Steps to get to that protein. so um so again phenotype obviously represents
24:20 function of proteins. Right? The of proteins going on that are present
24:25 any given time and that can change what's there's a term you need to
24:31 this but there's a term called Okay genome and then there's proteome and
24:45 represents the totality of D. A. In a an organism.
24:50 . For a bacterium that can mean chromosome. Plus if the hands associated
24:56 right. All that be the The proteome is basically one of the
25:02 being expressed at that given tie. . And where is the genome is
25:08 constant? Right? Because it's always . Right. The chromosome is always
25:13 . Plasmids are usually always there. And so that stays the same.
25:19 ? What changes can be what's being ? Right. X. And Y
25:24 in A. And B. Is . Well then does it switch
25:28 Does it change over time? That's the proteome can change. What are
25:32 actual proteins present at any given Okay. Um Now the how are
25:42 genotype connected? They're connected through um the RNA. Right. It's different
25:49 making up this part of the Okay so um and that involves different
25:57 . As we saw a plane raise R. N. A. Messenger
26:01 . Are part of that process. ribosomes of course. So um changes
26:07 genotype. Right? You have a , right mutation in the genotype which
26:13 talk a little bit about at the how these how these occur um A
26:20 in the A. G. T. And putting those together.
26:25 change A. To something else. . G. That can have a
26:29 effect. Maybe. Maybe not. but that's how you can see a
26:33 in the genotype. Okay. The is preserved through um replication. Okay
26:43 when the cell divides all right So it still gets a copy of
26:49 genome. Right? So you preserve through generations. Right inheritance of copying
26:55 genome in inheritance. So um and think of a way to think of
27:00 is D. N. A. the the book on reserve in the
27:05 . Okay. Can take it home you. It's always there. Okay
27:10 you want information from it generally you copy the whole book. You maybe
27:15 chapter here chapter there. So you chapter. Right? That's now you're
27:21 that's your R. N. Okay that's your RNA and ribosomes and
27:25 . And so the the um the you get at the end it could
27:30 the protein, right? Xerox machine copies and then you have the working
27:35 is your paper. That's the That may be one way to think
27:39 it. Okay so Uh so again here at genome as you just
27:48 Right. So for a for us genome basically are 46 chromosomes right there
27:55 our in ourselves. Um for for creates it can be beyond that.
28:02 . And so um so of course like us we we um pass things
28:11 vertically. So vertical means basically think parent a child. Right. But
28:16 also have the capability as do archaea what we call horizontal transmission. Okay
28:22 um so these are cells existing in population. Okay, neighboring cells.
28:30 . That it can exchange genetic information . Okay and there's different mechanisms of
28:37 . We'll look at that next time like five different mechanisms or four different
28:42 that enable this. Okay. Uh as mentioned before I think you know
28:48 vertical transmission occurs through binary fission and . Right? So zero making identical
28:55 . Right? As we all know A new coli um There's thousands of
29:02 of e. Coli and N. . Coli in your gut. They're
29:07 all going to be identical. There's be slight variations. Okay um and
29:14 variation is the key, right? in any living thing population variation is
29:20 key to survival having more variants in population means um there are options for
29:28 . Population conditions change. Well then there's a particular subset in that group
29:34 has the most favorable combination of genes they survived. Okay so the more
29:39 you have the better. Okay. humans vary between each other by about
29:49 .15%. Somewhere in there is a between unless your identical twin but that
29:56 exists between us. So that's that . So so for something that seemingly
30:02 through a kind of xerox mode of identical through vertical transmission, binary
30:10 No because a they can do horizontal and gain new genes that way of
30:17 mutation. They mutate a little bit rate than we do. So that
30:22 variation. So even though they can't sexually which is a big positive mechanism
30:29 us because sexual reproduction leads to the . Right? They don't do that
30:33 they still can of course gain genetic . Okay. Very important. And
30:39 you know if these horizontal mechanisms of how antibiotic resistance often gets transferred from
30:45 to cell. Okay. Um and the replication. So you may again
30:52 not going into the process of replication there's a term you should know this
30:57 conservative. Right? That's how that's life replicates its D. N.
31:03 . Okay and so basically what it is each strand. So here's a
31:09 stranded DNA. Okay so each strand putting them apart. Okay. Is
31:15 template for synthesis. Okay. And kind of the language, the how
31:24 work with the clinic acids and due their structure is that you have these
31:31 labeled five and three relates to don't about it. But it relates to
31:36 nuclear types. And the number of run nuclear types. But anyway so
31:41 nucleic acids uh have these two different of five and three what they call
31:47 five prime and three prime. It doesn't matter if your D.
31:50 . A. Or RNA. The same thing applies. Okay so
31:55 any case each one is a template gonna be able to make a copy
31:59 these two templates. Okay these are two copies. Right? So remember
32:03 complementary base pairing. Right. We're making identical copies. So for example
32:09 sequence is a T. G. . three prime. Sometimes just looking
32:17 that part. Um We're not making T. G. Okay. So
32:25 other thing to remember is this I'm this now because when we get the
32:30 there's a designation for viral types. call them. Especially with RNA
32:38 Right? They can be plus or . Okay. And so you actually
32:45 plus and minus designations on nucleic acid ? Right so one of these is
32:52 plus. Okay and so over here may be the plus the minus
33:00 Right? So similarly then the complementary will be relative looking up top
33:08 B minus now. We plus. . So what we call um since
33:18 that's a plus trend and anti So it basically means is since strand
33:28 strand is the is the strand and the coding information between the essential
33:33 Okay. The antisense strand is the of that? Okay, we can
33:40 the antisense strand. Okay, copy and make a plus trained. Okay
33:54 this is when you get the virus is an RNA virus is this will
33:58 a great daily remember this. Okay this is just this is just how
34:03 work with nucleic acids. That's all is. Okay. It's it's this
34:07 the five and three. It's why have this and this on nucleic acid
34:12 . It's just how they work. . And it's why you don't
34:16 when you copy a template, you make the identical copy like this.
34:21 make the complementary copy. Just the that that's the rules of working with
34:28 acids. So it's gonna be um . T. A. C.
34:34 then the orientation this and this. , just didn't make this up.
34:40 ? This is how it's been for . Okay. Um And so just
34:46 couple of things remember. It may helpful. Okay. But the but
34:51 always and again it doesn't matter if if it's this D. N.
34:57 . D. N. A. . I'm gonna be RNA RNA.
35:02 it could be DNA RNA all R. N. A.
35:09 Possible. All right. 123. all those combinations are possible. And
35:18 same rules apply. One's gonna be and 55 and three. You copy
35:23 ones. The ones gonna be plus minus all that applies. It doesn't
35:29 whether it's just because your familiarity. sure it's mostly with the only DNA
35:34 . Right? But you can have other combinations. Okay. But the
35:39 rules apply. Okay, complementary base prime uh plus minus all that.
35:49 so um the uh okay so when say sense strand. So for example
35:57 D. N. A. Strand contains the actual code. Alright that
36:04 make the protein. That's the plus . Okay the R. N.
36:09 . That's a plus strand. Okay let me just throw this out at
36:15 . Okay if I say there's a RNA strand and the minus RNA strand
36:27 of those RNA. S. Will directly translatable into a protein.
36:33 Plus. Okay how do you? um yes plus trade plus train is
36:40 one containing the relevant information. Okay um so the plus RNA strand would
36:47 been copied from a white type of . A. Plus or minus?
36:56 one? Yes thank you copy from strand. So that plus R.
37:03 . A. Would have been copied a minus strand. Um So remember
37:11 right because when we get the RNA right because in my other class the
37:16 of course we just went through the viruses and I could see eyes going
37:23 when you go through RNA virus life really always dependent on this remembering the
37:28 minus relationship. And when you copy plus you make a minus and again
37:33 just it's just the rules of nucleic . Okay that's that's what we're following
37:37 . Okay um Alright so let's any we'll keep hammering on this a little
37:45 more here but let's look at this . Ok so here's a question this
37:51 going to get us into as you're this um uh the so we talked
38:00 um expression how just from the overview D. N. A. To
38:09 native protein expressing the gene. Um it's okay. Getting a little bit
38:16 the nuts and bolts of that. , it's kind of what this is
38:20 . Okay, so the genetic code the sequence deputizing the gene turned by
38:28 river zone is based on the Messenger sequence determines how many chromosomes are present
38:38 none of the above. Okay, can't down from 10. Okay.
39:53 it does not really determine the sequence nucleotides in the gene. Okay.
39:58 genetic code is what's used to convert genotype into a protein. Okay,
40:05 there's like a code book for it the genetic code is that what determines
40:09 sequence of nucleotides in a gene is uh that's what you inherit.
40:15 And so it's the particular, that sequence determines what the protein will
40:20 Okay, but the rivals um it's the messenger RNA A. Okay,
40:29 is how you decipher the language. , so you're gonna take that transcript
40:36 then. Use the code book right tell you. Okay, this is
40:41 um this is going to turn out be this is the kind of
40:44 It will be because the code specifies the particular Emiel assets. Remember that
40:55 real assets make up a protein. . And so the code specifies what
41:04 would be because it corresponds to a set of nucleotides. Okay. And
41:10 that code is going to help us this out. So here we're looking
41:14 um kind of the overall process. we see A D. N.
41:18 genome, right? DNA template And um and then we see right
41:26 plus And so we kind of have the pickup sequence right here.
41:34 And so you see the designations plus minus strand. Right? And so
41:42 plus strand is the sense strand? coding strand? Anti sense the minus
41:47 . Okay, so we have our types sense antisense. Okay. And
41:54 we're gonna go transcription, translation transcription basically going to make a copy of
42:01 D. N. A. So . N. A. As you
42:07 , there's of course the precious right? You want to we want
42:10 protect it, We want to preserve . And so if we want to
42:16 with it, let's make a And a copy of it. And
42:20 mess with it there. But leave alone. Okay. And so that's
42:27 first process this transcription. Okay, fine because we can always make tons
42:34 transcript if we need to. because DNA is always gonna be
42:41 We always go back and copy more a gene if we need to
42:44 that's what the control is kind of . But if we need to we
42:47 make more, right? It's like xerox machine. It's like the chromosomes
42:52 book on reserve. If you want of the pages we take the xerox
42:55 to make as many as we want go back and make more.
42:59 The same thing. So so to the transcript you need to proliferate,
43:04 the copying enzyme for that. And a transcript. Okay and so the
43:10 is the M. RNA. The RNA. All that's synonymous with each
43:15 . Okay um then I'll just throw in um that this kind of is
43:24 we call A. D. A dependent. The only reason I
43:31 that up that's what we we've That's what almost everything has because the
43:39 polymerase is copying copying this right, that to make that transcript.
43:49 And so the uh other types. we're gonna look at RNA viruses in
43:57 next chapter. Um They have some those have what's called an RNA dependent
44:04 they copied the RNA is into other is right. We don't do
44:08 Okay. And so I just mentioned just just for that reason. Okay
44:16 And so with the transcript then and this is showing a very basic
44:22 You see 1 1 copy here. ? Um the uh in reality hundreds
44:33 not thousands of copies can be made inactivity expressed gene you'll make hundreds if
44:40 thousands of transcripts from that same Okay um Then also remember the the
44:48 poly ribose um or polly's own thing talked about before. Okay, as
44:56 as the transcript is visible. And this ribosome binding site is
45:04 Okay, at the very beginning of transcript then arrives home sees it and
45:11 down right and begins to translate. ? So remember this will be coded
45:17 ribosomes, Right? That's that polly function. So in bacteria and
45:21 So it happens. Lots of protein very quickly. Okay, party zone
45:26 . So um so the translation process what involves kind of that code book
45:34 genetic code, the transcript is gonna those elements and then it's up to
45:42 . R. N. A. of act as the mechanism to recognize
45:49 RNA bases these things. Okay, and so on. And to match
45:58 up with the right amino acid. . And so the ribbons um is
46:02 of that platform where everything comes it holds onto the transcript. It
46:11 a space spots for the trn to in and out. Okay, so
46:15 kind of is the platform where everything happening in terms of protein synthesis.
46:21 . And in fact the the rival themselves also carry out the connecting of
46:29 amino acids, right? They actually catalyze that part of the process.
46:35 , so a lot of stuff happening where the ribosomes are at all this
46:40 occurring and the end result is the of poly peptide. Okay, so
46:47 again this is happening, you can you know lots of transcripts coming out
46:52 here. Lots of riders was bound the transcript and lots of protein being
46:56 . Okay? So um now I that's that's as much in detail as
47:04 need to know about this. Um let's look at this.
47:11 Just a kind of um really? we can understand the sense and antisense
47:17 thing. Okay so uh this is same DNA sequence from the previous
47:24 Okay. And just indicating the plus minus strands here. Okay so the
47:32 going to copy making a copy of sense strand. Okay, so and
47:40 gonna do that right by we're gonna this right here by copying the antisense
47:51 . Right? So if you look the sense M. R.
47:53 A. And the sense D. . A. Right? You can
47:56 how they're identical. Alright. G G G. G. G.
48:03 . Uh except where there's a year so. Right, so in
48:08 N. A. Right? RNA have you instead of tea by
48:18 Okay. So but they match up those spots. So 80 G.
48:25 A U. G. G. . A. Same G.
48:28 A. G. G. G. G. G. So
48:30 all the plus M. R. . And the coding DNA strand
48:36 Okay. And they're identical because the . R. N. A.
48:41 made by copying the minus strand. ? So actually copying that. So
48:49 the army plain rice is copying the strand? Right? That's the
48:54 right? Because in doing so we basically an identical copy of the
49:01 N. A. In an RNA . Okay so that's why we call
49:06 antisense strand the template because when we it in transcription or making an identical
49:13 of the DNA now and because of coding strand, an identical copy of
49:18 coding strand because that's what contains the information right? To make the
49:23 Okay so that's the nature of this anti sentence. And when you copy
49:30 . Okay um any question about Does that make sense? I
49:37 Yeah. Um no pun intended. sense. Okay. Make anti
49:43 Right. Alright. Never mind. Okay so here is uh looking at
49:50 genetic code. Okay so a couple things. So again this is kind
49:55 the playbook if you will code book decipher in M. RNA. So
50:00 that we're looking at the transcript Okay. And you can tell that
50:06 ? You know that because we have a citizen here right? We don't
50:11 any timing showing up. Right? um so it represents R.
50:17 A. Okay uh specifically messenger And so um it's redundant because there's
50:25 . There's only 20 amino acids. . But these um there's more there's
50:32 more than 20 code. So the on. Right is a three base
50:37 base set. Okay. And each base set Groups of them code for
50:45 20 amino acids. Okay, so have 64 three base code on
50:51 Okay, coding for 20 amino Hence the term it's redundant.
50:57 repeats itself. Right? And you see that, right? Here's scr
51:02 Syrian and there's 44 code ons for . Right? And so on.
51:06 can see this in the various groups . So multiple code owns for
51:10 I mean. Okay, so um here's our D. N. A
51:19 . We copy and make our RNA. And now, so we
51:22 our coding information. Now, we to kind of decipher what's going on
51:26 . Right? We still haven't gotten protein yet. This is where the
51:29 is coming. Right, So you like a sentence, right? If
51:33 were to look at a sentence and sentence, we had all the words
51:37 all continuously put together and no space between. But you need to have
51:43 elements of grammar punctuation, right? figure out what the sentence is.
51:46 same here. Okay? So that in the form of the coordinates.
51:50 ? So you look for a start . Right? So we know the
51:54 of a sentence is the first letter in the first world. Right?
51:59 what directs us to the start of sentence here. It's where's the start
52:03 in. Alright. And so we certain punctuation marks. If you will
52:10 and then stop. Right? So period at the end of the
52:16 Right? This tells us where the is. So for this the stop
52:19 on. Right? So once we the starting point, okay then it's
52:25 3123123123. And those are your code . So au Jesus start at some
52:31 there'll be a stop one of these stop code ons U A A U
52:36 G U G A. Okay, you get there, that's the
52:41 Okay. And then you've got your peptide which will be uh in this
52:49 A G. Is machining and protein you do not need to memorize these
52:55 obviously. So but just kind of the process. Okay, so this
53:02 all this here is translation of What's going on that you're not seeing
53:09 the nitty gritty details of. Is um this there's gonna be a ribosomes
53:22 here basically occupying two of those slots it's kind of a big molecule.
53:30 , So it looks something like Okay, and this is where you
53:36 T RNA is coming in. Let just do it this way.
53:40 so again, I'm just showing this for completeness of anything else.
53:46 what is this? A U. C C. A. Okay,
53:50 we have the rest of the transcript so we have um rivals. So
53:58 comes in two parts as a small and the big unit, right?
54:03 our rivals. Um And then we'd T RNA molecules coming in,
54:10 That recognize that code on and bring amino acid. That's M.
54:15 T. Short from a tiny And so I always draw my Tr
54:20 . A. S. Like So if it recognizes a U.
54:27 . Then it must have a complimentary A C sequence. Alright, that's
54:34 it links up with a code Right? So this is code on
54:42 . Antico to. Right? So is specific for T. All
54:49 And so you have the amino acid there. Right? So that's how
54:52 work. Right? So that's kind the the kind of really the adapter
54:57 . If you will like a putting three pronged, you have a two
55:00 outlet. You need a three You put that little adapter thing in
55:02 middle. Right? So this thing can recognize the code on at the
55:10 time. Bring the correct amino Right? So then this one will
55:14 in here, right? And I that was pro lean. So
55:19 R. O. And then the own helps to make the link between
55:22 two. And so then the next comes in, right goes this way
55:26 then here comes the next one, next amino acid, a short amino
55:32 and then just keep making a peptide . The zone moves along.
55:37 So again um I expect you to that level of detail. Just kind
55:42 know the overall process going on. . Um the uh any questions about
55:51 part? Okay. All right so look at mutations. So what happens
55:57 in mutations is we're making change to genotype? Okay. Make a change
56:05 the genotype and of course are going make a change in the um protein
56:15 you have a change in the genotype you copy that into a transcript.
56:18 course it's reflected in the transcript as . Okay. And then ultimately when
56:24 the protein when you translate that Okay so um now mutations themselves or
56:34 in genetic sequence um various things cause as I'm sure you're aware UV light
56:41 cause it radiation different types of chemicals what we call collectively called mutations that
56:48 mutations um The ones that are most of course are those that occur in
56:58 gametes. Okay. Um talking about in humans. So in the Gambia
57:05 because you can pass those on to Children of course. Okay. Um
57:10 we call germline mutations. Okay. you know you got you got you
57:17 get sunburned. Right, you're definitely mutations all the years. You have
57:22 system to kind of get rid of bad cells that have been mutated but
57:26 know if it does turn into something I eat skin cancer or something.
57:32 really the only one affected you're not to pass that on to your
57:35 Okay. But if you have a that occurs as a result of this
57:39 in your, you know, eggs sperm, then that could have implications
57:45 on. Okay. Um now the of the mutation. Okay. You
57:51 a change in the base. What's outcome? Is it going to be
57:57 ? 100% of the time? Okay. Um In fact most mutations
58:05 not bad. Okay. They're either . There's no no no difference.
58:12 . And it's no effect. Right all. Um They can be in
58:21 cases lethal. And generally they either there either is no effect or to
58:26 . It's really most of the That's the outcome. Okay. Um
58:32 it can be certainly be beneficial. . And whether it's any of
58:39 you have to look at successive Look at production of offspring.
58:47 Especially if you're trying to assess if beneficial, right? Benefiting the
58:52 Well, if it is then that change is occurring and more and more
58:57 of the population as it grows, it's hanging around because it's something
59:02 Okay. Um and so you can really assess benefit in that way.
59:09 . Is it helping it survive and ? Okay. Um so we use
59:17 term so we're looking at microbes, in particular. Uh we often use
59:21 use this term oxygen. Okay. think we introduced that during growth,
59:28 can't remember. But uh I remember oxide trophy is one that's deficient in
59:33 pathway. And so very often in production of making amino acid. So
59:40 have to have you have to give for example the history aka trove.
59:46 you'll have to give it this amino if you wanted to grow.
59:50 Because it's it's mutated in that particular . Um spontaneous mutation. We have
60:00 living things have a system in place kind of clean up mistakes. So
60:07 us, you know uh if you self cycle um we have a phase
60:15 being a replication occurs. It takes long time because we have lots of
60:19 and uh copy but there's a part this south cycle where it makes it
60:25 kind of stops before it goes any . If you remember your so I
60:31 remember it. Pro phase any phase phase tele face. I think I
60:36 those right in the right order. before it even goes into that
60:42 it stops and it goes, let's if there's any mistakes. Let's fix
60:46 mistakes before it goes forward. we're a pretty good system for
60:51 As do many other living things. so um because you don't want to
60:56 don't want to not fix these mistakes obviously it's gonna have implications.
61:02 Um from bacteria Archaea It's kind of rate that's higher ours is like one
61:09 one pretended 10th. I think we a pretty low just call spontaneous mutation
61:16 is just kind of a mistake. just happens it doesn't get fixed right
61:20 us. That's a really low rate bacteria. It's like one in 10
61:24 the 61 in a million. Okay so because bacteria grow so fast you
61:30 you can see these changes in in know in the course of a week
61:35 so or less. Okay and so are even worse. They don't there's
61:42 no machinery to make them help repair . So the viruses are notorious for
61:48 lots of mistakes that don't get Hence really high mutation rate. Um
61:54 so what we're gonna look at here three kind of mechanisms of mutations.
62:01 and um these are very common. are like one base changes. Okay
62:08 can create these effects. Okay so point mutation means a one base
62:16 Okay and so here our top strand the um template strand uh that will
62:26 copied into Amarna. Right so we're look at changes to the DNA up
62:30 . Okay so this is our un uh strand. Okay so we transcribed
62:38 produce this protein. So this is normal quote normal non mutated strength.
62:44 and so we're gonna make a change right in that in that cytosine in
62:52 . And so when we do that can we're changing that to a
62:58 T. Okay to A. And then when that's transcribed. Okay
63:05 transcribed so that it contains an Now and not a G.
63:10 Okay so if you look at our there it is right there and we
63:18 a substitution. So you can Alright so here's our three or
63:27 So we're the same in those first amino acids. Okay. Not surprisingly
63:35 nothing has occurred where the change occurs after. So at the point where
63:39 change occurs now we see the Okay and so we changed it to
63:44 searing. So searing versus glycerine Alright. Searing. And so that's
63:55 call miss sense mutation, a different acids substituted for the one that was
64:01 . Okay. Um that can have effects. Okay so remember proteins fold
64:10 right into a very specific shape. so a change in video acid can
64:16 that shape change. And the protein anything it's all about its shape because
64:21 bind bind molecules as part of the and that of course it depends on
64:27 specific shape and binding and if you that you're going to alter its function
64:32 . And so altered amino acid by mutation depends on the chemical nature of
64:40 amino acid. Okay so a Syrian I seen there is some difference there
64:48 Syrian has has a hydroxyl group on . Um Glassine does not has a
64:56 I mean there are groups functional right? Glassine has an H.
65:01 Syrian, Oh h so it's not big a difference, but it could
65:06 enough. And so the function it depends on where where in the
65:13 . Right? So protein of course be hundreds thousands of mos is
65:21 Right? So if this is the , right? And this is maybe
65:26 active site, let's say right here the action is happening. Well what
65:31 um what if the substitution of the sense mutation occurred out here?
65:37 May not have much of an Okay, but what if it occurred
65:41 here? Okay. Be a huge . Right? So so location kind
65:46 has plays a part in here So so location uh chemical difference between
65:52 substitution, Right? It's something that's hydrophobic and now it's become something super
65:57 filic definitely could be a difference. those are kind of factors it depends
66:03 um Okay, so that's a You asked a substitute for a different
66:09 . Okay. Uh that's what happens um sickle cell, sickle cell anemia
66:17 red blood cell the the uh the um in in those individuals has a
66:24 base change and one amino acid change it changes the whole shape of the
66:28 and it doesn't work the same doesn't bind oxygen, like it
66:31 And so that's just do the one just like this. Okay um So
66:39 is the next one. So again is the normal molecules we're gonna change
66:44 there. Okay so we're going up So this is a nonsense mutation.
66:51 so um what happens is you form premature stop code on. Okay.
66:59 so um so basically again uh that's Can be lethal but there can be
67:08 chance for it's okay. Maybe you have 100% function. Maybe you have
67:13 between 2030, 40, 50 60 on location. So a misinterpretation,
67:18 cell has a chance to survive a mutation generally. No, those are
67:26 much lethal. Okay because you're basically the protein. Okay, taking a
67:32 of it off and in this case large chunk is taken off.
67:36 so the point is nonsense mutation. change occurs all right, this is
67:42 . T. Two and a. makes a you change down here.
67:49 so we formed a premature you G. The stock code up basically
67:54 shorten the protein and that generally is to be lethal. Can't function with
67:59 . And so the third one here a frame shift. Okay, so
68:06 again is another single base change. the other ones are substituting one base
68:14 another, like the MS sense and , you're taking this base out and
68:19 one in. Okay, one for . The frame shift is out is
68:26 out completely. Right, so this um is being removed altogether. Okay
68:34 so uh that means now we've um that point point so you can also
68:42 just called the deletion when you take out, you can also shove another
68:46 in there. Right? It's called insertion. Okay? In either case
68:50 every point After that. Right? here. Right, so we have
68:58 123 and now we've substituted that and changed the media acid and everything after
69:05 . You see how losing Alan Are not. These are the normal
69:11 female. Allie and I seen. , so we're changing everything after that
69:16 . Right? That's also generally lethal you're changing you're not cutting the protein
69:22 but you're actually adding something different at point after the change. Okay and
69:28 that typically leads to complete loss of . Okay so um the the so
69:37 MS sense kind of have a chance survive that but for these two things
69:42 . No. Okay so um let's I think it's probably a good place
69:51 stop. We'll pick up with this next time, folks. Thanks,
69:55 see you uh next week. Yeah. Mhm. Yeah. Uh
70:36 you thinking that something in there is . Oh okay so you like
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