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BIOL 2321_Microbiology for Science Majors - 2321_MW1130_3_9_23_Lecture
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00:10 Hm. Ok, folks. Um, couple of things. So
00:48 ending unit two days. Ok. We're gonna finish up this photo trophy
00:55 then I just want to spend a of minutes because I'm getting a few
01:01 about this for those who will come about the, about that reduction,
01:06 table reduction, potential table. Uh And understandably I can you look
01:10 that and go, what's that Ok, so I, we're
01:14 I'll spend a few more, few on that. Um, if you
01:17 any questions, uh, let me but, um, because it
01:23 it is an important concept now. , um, anyway, so we'll
01:28 a little bit of time on that the end uh, before we go
01:33 then, um, so remember the quiz, uh, it will cover
01:38 from 6, 13 and 14, you're gonna have like uh 10 days
01:47 , to start and finish it. , um, somewhere within that time
01:51 . So a lot of a lot time to do that and it's
01:54 I'm just doing it that way because got spring break in the middle.
01:56 I said what the heck. Smart work. The last one there
02:00 this unit is due on the also after spring break. So,
02:05 let's see, anything else? quite a few people come by this
02:10 and interestingly, uh, wearing right? That have like logos that
02:18 from my era, right? Not , like a CDC, something that
02:21 out. The A CDC. Is here the A CDC person in my
02:26 class? So, uh I ask , who's AC DS? Do you
02:29 who a CD is? She actually she couldn't name anybody in the band
02:34 she knew who it was, you , I think, um uh who
02:38 it? Oh, you had, , I asked you about what are
02:42 famous for? You know? But what there is this thing they're
02:46 for anybody know, smoking dope, pot is their thing pot. Uh
02:54 had a scene where they, this , they come out of this
02:56 It's like this green smoke coming out . So, anyway, OK.
03:00 tell your parents. I'm telling you . Um, boys, gentlemen.
03:04 , uh, oh, Zeppelin led . Uh is that person here?
03:10 Led Zeppelin? Sure. Anybody know led Zeppelin is. Oh, my
03:15 . OK. I'm gonna teach a on because I, I'm a big
03:20 person. Uh and I play as and um actually my obsession right now
03:26 white stripes and Jack White. which is for me is that's contemporary
03:30 me. OK? Because that's like two thousands, right? But Jack
03:33 is still playing anybody in white Jack White, there you go.
03:39 um uh anyway, all right. to science, right? OK.
03:46 So recap, right? So last . Um All right. So it
03:54 through reset where if I put this thing on it. So um metabolism
04:02 the other thing I should mention because doing this all the time these days
04:05 you see me after spring break, like, not gonna recognize me because
04:08 is coming off. OK. So just, this is coming up.
04:15 anyway. All right. So back track. Um so a table,
04:20 ? So we look at um started me right in the stage of metabolism
04:26 poly and uh pate oxidation. If look away and fermentation and electron
04:35 et cetera, et cetera. And we looked last time at anaerobic
04:40 right? Same process, same right? Uh It just that we're
04:47 um what's at the end? Changing that. OK. Right
04:53 OK. What we accept? So so different types of molecules and molecules
04:59 accepts or number, depending on the reduced or oxidized the component is it'll
05:08 different roles, right? So here's of the dividing line right there
05:15 right? Whether it serves a role an energy source, like oxidize it
05:22 electron source or as an acceptor right here. For anaerobic respiration.
05:30 So we went through that and so the process covering Lioy, which of
05:36 , Lioy, remember we, we by what's the source, right?
05:41 inner game, right? Then uh Trophy is kind of that um
05:49 Maybe you find it in lipes, find it in heros. It's
05:53 it's a feature that's um very common the energy release you get from
05:58 Ok. Um The genesis we talked and then remember a simulator dissimulator
06:05 It's a similar to earth. The organism is hanging, right? It's
06:09 it. It's part of it is ? Or at least in the dissimulator
06:15 and in that case, others are to use it. OK? So
06:20 processes can be both types. Um Then uh that's when we,
06:27 that's when we end it and we into a little bit of photo
06:33 And so in phototropic. Um So , uh so what you see over
06:39 these guys are here, I don't to memorize these names, but
06:45 I think my uh battery just Uh Let's do this. We've got
06:52 . In fact, just give me sec 112, that thing. There
07:08 go. OK. Um So don't to memorize these names, but these
07:12 all members of cyanobacteria. OK? They are the bacterial, the only
07:19 types that photosynthesize just like a plant allergy does. OK? Uh With
07:26 using water oxidizing it giving off OK. So um very many different
07:35 of these guys, very important, in aquatic uh um ecosystems, uh
07:42 , marine environments um along with of , plants and algae, the uh
07:47 OK, so what's common among So the commonality among all photos,
07:51 they some kind of molecule that absorbs , right? Um that molecule in
07:57 process uh you have an excitation occurring of the Exor of light. Um
08:05 then uh of course, having the is pretty common, right? Certainly
08:09 respiration. But so too photos in your membrane where you're gonna stuff it
08:14 of these molecules child. And that's you're gonna have be able to generate
08:20 gradient that proton gradient. And then you know, of course, the
08:24 captures linked to homo energy like providing energy to chemical energy, right?
08:31 that's pretty much common to all photocopy for the process of actions is not
08:40 , right? So this is where sort of systems were just like just
08:47 um respiration, like transport needs something give to it. So too
08:54 right? So water does that advance and bacteria. Um And that's what
09:01 call SSIs reactions. OK. but we started with a process that
09:08 not Chl based, it's a non based system. That's what we looked
09:13 at the end last time. So I wanted to begin with a
09:19 that relates to that. Ok. that's this one here. Let me
09:26 that. So which should which is , false, false regarding bacterial or
09:35 based photocopy? That's the other OK. So let me go ahead
10:20 count down 29. Um I hope have the chance to have one day
10:32 fun next week. I don't spend entire time studying for this for god's
10:37 . OK? Um You gotta at have one day off. You don't
10:42 the whole week off. Ok? maybe a few days from there is
10:46 . Ok. Ok. Um If able some aren't, you know,
10:51 have to make, you have to more. I work more shifts but
10:57 something good in there. You Don't go all teaching Chong on me
11:03 . Ok? You don't know what is. Just Google it. You
11:12 big green cloud of smoke. But you know you should know anything
11:17 that, right? All right. see what we got here.
11:25 So we gotta go back and look um oh God, let's go out
11:31 . Jesus More batteries. So let use a podium mic. Sorry,
11:36 crazy. Ok. Let me try . Testing, testing, testing,
11:44 first thing. Ok. Can you me from? Can you hear
11:48 Ok, here here? Ok. right. All right. So I
11:53 need this one anymore then. All . So uh we need to
11:58 you need to go back and review factor adoption baseload trophy. OK.
12:04 uh if you're one of these you appear what color purple,
12:11 right? Because you absorbing, you're um um uh you're absorbing uh what
12:22 trying to say, green light. . And reflecting. So you
12:27 OK. So you're not absorbing blue red wavelengths, you're absorbing green wavelengths
12:33 light. OK. Um uh Requires electron donor. That's one of the
12:41 about that system is it doesn't use , right? It's not, it
12:46 have a electron transport system that's receiving for that purpose, right? It's
12:51 of light. And so the pigments that photons of light and that unique
12:58 with the retinal, right, absorbs and the absorption of light leads to
13:05 kicking out the protons to form a rate, right? Which is then
13:08 to an A T P. So so it doesn't require an electron donor
13:13 the system. OK. Um Doesn't like chlorophyll, does not use like
13:18 . So the correct one here is C right? They are photo
13:24 OK. They are photo hetero um light system they possess is strictly just
13:29 produce A T P S, But they they eat organic organic
13:36 OK. Um So that is I realized. So OK. Which is
13:50 . You get credit for it. worry about it. Goodness.
13:54 I I can't tell you for my . OK. Um OK. So
14:00 reread the question here, which is . We're going back through the
14:04 There's only one true statement here. for messing me up. It was
14:08 intentional. Um Any questions about Ok, so that's my bad,
14:13 that is the correct answer, Ok. Sorry about that. Um
14:20 try not to do that but I promise you. All right. So
14:26 your adoption based photo. Ok. ok, let's go on to,
14:33 we're gonna look at three types of . OK. The one you're most
14:39 with, I assume the chlorophyll based plants and algae and santa bacteria.
14:45 . Um The oxygen photosynthesis and we call it that because the process itself
14:52 oxygen. OK? Um The other use the components of oxygen and
15:03 but they only use half of right? So in other words,
15:07 photosynthesis has two parts, right? the system two and one,
15:12 So when we look at the other of phototropic, They either have just
15:18 systems, two or just photos systems . So it's separate. OK.
15:24 And that's the basic difference, What the two parts do are the
15:28 things they do in oxygen and photosynthesis just just put apart. OK.
15:34 that's essentially in a nutshell difference with three types. The other difference of
15:38 , is this other type of sophy where the bacteria has either support
15:44 one or two. OK. Uh only seen in bacteria, you don't
15:51 it in, in any kind of , you don't see it in any
15:54 of plant or algae. Those things have the two to get.
16:00 So uh of course, this oxygen is what dominates earth. Of
16:07 um producers, right? These are producers, right? Um they uh
16:14 they class or remember uh they fix , right? They auto um the
16:21 but remember your chemo aro like can fix CO2. But in terms
16:28 you know, Overall co2 fixation and , these these types here, the
16:34 that die, OK. It says convert 10% of their co2 in the
16:39 . That's much more than what these tropes to. OK. Uh Of
16:44 , they're the foundation for most They're the most powerful in the ecosystem
16:50 the CO2 fixation provides organic material that other levels feed on, right?
16:55 producer levels. So um obviously very . So um so a chlorophyll,
17:02 the chlorophyll based systems and the bacterial we'll talk about in a second,
17:07 similar, very similar to a couple modifications of very similar structure. Um
17:13 so, of course, what they in common is the fact that you
17:16 an area of the molecule here. a very mild pole that's gonna fit
17:21 membrane. These are all things stuffed membranes, OK? And of
17:25 the light absorbing part in yellow, what chromophil refers to. Anything that
17:30 four absorbs light, the uh the stains in lab, if you're
17:35 lab, the the crystal violet and sass these all have also promo force
17:41 them which they give you that, color. Um OK. So uh
17:48 so we take the chlorophyll molecules. it's not just them, but it's
17:53 molecules plus proteins plus accessory pigments. ? Things like xantho and, and
18:01 kind of things kind of help to the range of OK. And so
18:07 arranged the internet complexes and tending to signal they're receiving is photons of
18:13 OK? If you wondering why I'm here kind of weird because this is
18:17 I got to magnify my voice, ? Microphone, I ran out of
18:21 . So anyway, um just bear me. So uh so you see
18:28 the arrangement, right? So it's a packed in the membranes and
18:32 absorption of light uh is all very on the angle of these molecules and
18:38 ability to absorb maximum amount of And so they're packed full because it's
18:44 of random which of these will initially light. OK. So, but
18:49 they do, they then will that is passed until you finally get to
18:53 reaction center. OK. And so it as it is passed, this
18:59 passed on, you get a kind a drop, drop, drop,
19:01 in energy, but in the middle a pair of uh proteins that are
19:08 for molecules rather that are, that adjusted are and if they can,
19:15 they draw light, they're able to out these electrons they possess. And
19:19 what really starts the whole process. . And so electrons are knocked out
19:25 then that goes on to a series characters, right? So in
19:29 the complex here, the what you call a photo system, OK,
19:33 is this combination of these antenna complexes reaction center or photo system is is
19:40 getting up, getting electrons. So they get kicked out, then they
19:44 to be resupplied. OK. So essence, the photos system has become
19:50 , right? They've lost electrons through absorption of light energy. OK.
19:55 then what feeds that in, in , in the um oxygen, this
20:01 water, right? Water gives up to the system to keep feeding
20:05 OK. And so um it's redox , right? But it's kind of
20:11 , that's the initial driving. So in terms of the uh stuffing
20:16 into membranes then. So OK. don't be confused when we're talk when
20:23 specifying bacteria that need a sign of , um the um uh chlorophylls,
20:32 ? So, I mean, chloroplasts if they don't have chloroplast,
20:35 ? But you, you're familiar with term and that term in the context
20:40 chloroplasts, OK. Uh But in that do this uh it's not a
20:46 health, right? The thyroid is the name given to the the cytoplasm
20:52 which is highly folded up, And connected by these uh little
20:59 right? It's, it's literally that part of its cytoplasmic membrane.
21:03 It's not an organ health. It's a chloro, OK. But they
21:07 call it a thyroid because it's stuff of these chlorophyll pigments. OK?
21:15 it's where you're going to generate the gradient across. OK. So in
21:19 context of a cyanobacteria, thyroids are , you know, the parts of
21:24 membrane that are stuck full of the uh in a plant cell, it
21:29 be in oppa but not in the cell. OK. So just remember
21:34 distinction. OK. So when we at uh absorption, so chlorophyll is
21:40 and B. Uh and again, , what's in in plant technology is
21:45 same thing as in cyanobacteria. So the absorption of red and blue
21:51 , OK. And because that's what absorb, they reflect green, they
21:56 green because of that. OK. so you see the peaks here and
22:02 and we look at bacterial chlorophyll based , very similar in structure to
22:07 There's a couple of chemical modifications, um the light absorption is different,
22:14 ? So you see the peaks our light really absorbed is out on
22:19 range here. OK. And that's the lower end OK. Compared to
22:27 . OK. And so when you at um kind of in a where
22:33 all coexist. OK. The hierarchy kind of if you think about a
22:39 body of water, right? the top will be your um oxygen
22:47 your algae whatnot. Typically occupy the layers. And so light,
22:53 And then that lower energy light trickles , right? So this this input
22:58 light with this energy will then go down. And that's what's picked up
23:03 these other types that um utilize bacterial . So these are the types that
23:08 either photos systems, one or not both. OK. So different
23:13 of photo tropes. And um uh uh often times one of them is
23:19 type of kind of lives, you , very low depths and sediments
23:24 And so um they draw very low light, uh infrared I R infrared
23:31 , right? OK. And so that uh wavelengths of light, the
23:37 the number, the less energy it , right? The smaller number more
23:42 it has. OK. So um in oxygen photosynthesis, OK. So
23:51 uh so think of so we'll know the flow of electrons, OK.
23:56 they are flowing, right? So going from water or the two and
24:01 . So it's, it's it is It goes 2-1 because source system two
24:07 discovered first. OK. But it out to be uh our first system
24:11 was discovered at first, I'm obviously, but it's second kind of
24:14 the order of how electrons flow. . Um Ultimately to N A B
24:20 OK, which forms NAV P. right. So it looks like it's
24:24 there's sort of two uh light energy we knock out electron and then there's
24:32 light in restoration, there's a series components that you see these electrons and
24:40 pass them off. OK. Same in, in photos. OK.
24:47 so the um the energy from right? And so it's the same
24:52 , right, reduction potential, Strong donors, strong acceptor, a
24:58 , a negative delta G here, ? That will generate a proton with
25:03 force right to pump protons out. . And so then the A T
25:08 S sent right here. OK. as a result, protons flow back
25:15 and uh ad P form, Just like we saw previously when we
25:20 about expiration. OK. Same Um although the components of the the
25:27 acceptor are different than, than what have in respiration, the concept is
25:31 the same, the cameo motions proton capture energy back as they flow through
25:36 T P A S. OK? so this, this, this Is
25:43 associated only with Sytem two. So you see photos system two, you
25:49 both the ATP making proton pump part the process right is associated with PS
25:55 . OK. Um so as I earlier, as these electrons are lost
26:01 PS two, you need to keep it keep supplying electrons. OK.
26:08 that's where photos comes in. Um Think so they call it,
26:13 call it light driven oxidation. So light branch electrons out right now with
26:18 oxidized, you gotta get them And so that's how water then comes
26:23 to supply those electrons. And that's , of course oxygen Comes from.
26:28 from the water that becomes oxidized to electrons to PS two. OK.
26:36 , uh so that's this part of flow Uh water, the PS two
26:44 um then the P S one. these come back down. Now,
26:48 again at low energy. OK. lead absorption by P S one here
26:55 , knocks it out. OK. then more electron carriers here. Although
27:02 no proton gradient. A T P associated with this part. OK.
27:07 just flowed to NDP which forms N P H. OK. So uh
27:13 the P S one, that's what's with it. OK. So when
27:18 look at the two other types of that are tropes, they're either gonna
27:23 just the two system or the And as a result, one has
27:29 A T P formation gradient associated with . The one with the P S
27:35 uh has the NDP H formation associated it. OK. So, um
27:41 of course, this energy ad P A T P OK. All goes
27:48 uh CO2 fixation, right? But all but A large portion because CO2
27:55 takes a lot of energy. So remember we're building up this,
27:59 molecule into something like C six H 06, Right? And that's,
28:09 is a big molecule obviously compared to co2 is a building block to make
28:13 . So you're gonna put it back lot of energy to do that.
28:16 that's what that does. OK. I'm sure you've gone through this
28:22 Uh so this is your oxygen OK. Both photos systemss generates
28:29 OK. Then um here's electron OK. Let me uh get an
28:37 here. There we go. So our flow. And um now,
28:44 now if you look at these other systems, OK. Well, sorry
28:50 , this, this just illustrates the thing I just talked about but showing
28:54 kind of in an actual membrane. . You don't need to worry about
28:57 names of these uh different components. . Uh Cytochrome plato, don't worry
29:05 that. OK. Uh But do know what U C P S two
29:09 that? Of course. OK. again, for reaction supplying electrons and
29:16 um the flow. So you have components, Cytochrome uh quinone, these
29:21 common to I'm sorry, respiration as . So um and then uh also
29:30 , here's where the proton gradient comes , right pumping protons out and your
29:34 T P set days. OK. this is all part of photos
29:38 OK. And then photos one shows here. OK, receives electrons um
29:45 absorption and uh ultimately forming N AD H OK. So you know a
29:53 of the two processes, although you ele electrons from P S one are
29:58 supplied by P S two, right S two hopefully is those electrons are
30:04 in P S one that then goes N AD P OK, as you
30:09 here. OK. So um now any questions about this part that can
30:24 . So we'll go with bacteria that tropes that have P S one and
30:30 , and with those P S OK. So uh you call these
30:34 green sulfur bacteria because many of them H two S for example, although
30:41 are, there are other substrates that be used as a donor H
30:45 um even Xin an organic compound. And so uh so they do have
30:51 , this is essentially the supply, is a reaction, right? It's
30:57 provides the electrons to the system. . Right here. Mhm OK.
31:06 so um you can see right, little way back of light,
31:11 8 40 compared to like in the hundreds that we saw with uh oxygen
31:17 . So lesser energy um but uh absorption, not electrons out to electron
31:25 and then fly to N AD to N A DH OK. And so
31:30 , photos one and that's what it's with the N AD P H
31:34 OK. And so it doesn't mean can't make a T P, of
31:38 , right? They just, it's not based on the same system as
31:44 is A P S two. Because you see they produce as a
31:49 of, for example, um the two S being the donor, we
31:54 it, we do form protons. . So it can't form a proton
32:00 . OK. And have an A P A. And so it's
32:03 that's how it manages A T P . OK. And so uh so
32:09 it is, it is an So it, it's a CO2,
32:13 gotta have a T P and an P H to do that.
32:17 So that's how it's able to do . Um You do see in many
32:22 the species, this complex right OK. Um It's not an
32:29 OK. Technically an organelle uh because are have lipid bilayer, right?
32:34 does have uh some fossil lipids, they're not arranged in a bilayer like
32:39 typical membrane. It has that plus of protein that are a part of
32:44 , but stuffed in, stuffed in are the l bacterial chlorophyll molecules.
32:50 . All these little green blobs are bacterial chlorophyll. OK. And uh
32:55 call this organelle, didn't say or call this structure OK. A right
33:03 zone is what this is full of bactero cordial paper. So it absorbs
33:09 , right? We see the light occurs here and electrons are knocked out
33:16 uh supplying uh the system. So that's the second in a nutshell
33:21 this one is. So there's no formation, right? Because of the
33:27 They use, right? So when oxidize each, any of these
33:32 they don't, oxygen is not a . So, hence an oxygen
33:37 OK. So no 02 is formed . OK. Um so that's the
33:45 sulfur bacteria. OK. Then the one is has two. So it
33:52 the ability to have the uh proton and, and um A T P
33:58 through the P S two light absorption . OK. And so uh the
34:05 about it is this is even lower than the previous. OK. So
34:13 we're like, it's almost like far , it's a really low energy and
34:18 a consequence for that. And that when the P S two is such
34:24 low energy absorber of light or absorber low low energy light. OK.
34:31 not enough to be able to extract from apo reaction. OK. So
34:38 ends up happening is uh that's why don't see a specific molecule here as
34:43 door because it's so low energy you even use that. And so what
34:48 is uh light absorption, the electrons are then shuttled actually come back to
34:55 . OK. So it just kind cyclic in a cyclic fashion, just
35:00 return back So that will keep resupplying P S two. OK. Uh
35:06 , because it absorbs really low energy . OK. Uh And so
35:12 it uses this, of course, a T P, the types of
35:15 that do this are photo heteros. . So they um came. So
35:24 , whenever you see this, regardless of what's in front of
35:30 OK. It means that it must these more complex organic forms, they
35:37 fix CO2. Do not, If you ever, whenever you see
35:41 hetero term, no matter what's in of it, it doesn't fix
35:44 OK. So it gets its carbon ox metabolizing uh more complex organic
35:50 right? And so uh but it ability to use light to make a
35:56 P OK. So in a similar like uh the bacteria adoption based
36:02 OK. Um Those also for So um so to summarize all this
36:11 one slide, OK. Archaic OK. Two photos systems,
36:20 Um Electron flow my P uh water here they back up some water is
36:32 be sitting here, right? Oxidized feed it right? Water P S
36:37 P S one to N AD P or N AD P to N AD
36:40 H get electron flow. Now, we look at uh the other two
36:45 systems, OK. So we've got that can have PS just PS one
36:53 . Your green sulfur types, Um Oops here, right? Green
37:04 types P S one form an AD H. They are also autotrophs.
37:09 . Big CO2. Um don't right? Because they use something other
37:14 water as a donor. OK. , that's one type of photo and
37:21 the other type is the non non types they call them. OK.
37:28 so uh need to raise that. the purple on sulfur types um uh
37:36 the photos systems, two that's associated the gradient ad P formation bring to
37:41 photos systems, right? So um they're, they're hetero photo heteros.
37:48 . So that's essentially the three types phototropic. OK. So remember that
37:52 question coming up that the photos one bacteria that have that the ones
37:57 have the photos systems. Two uh are only found in among bacteria.
38:06 ? Unlike the oxygen photosynthesis, you that in santa bacteria but also in
38:12 and algae. OK. But those other two types, this one and
38:16 one are only in the bacterial world photos. OK. Um All
38:23 Any any questions about that? So look at a question and then it
38:29 of uh we wrap this up and we're gonna talk a little bit about
38:38 the, the reduction potential. Same a little bit. OK. So
38:44 you got questions about that, free fire away. So this question was
39:28 correctly. OK. I promise, promise. Yeah. It OK.
39:55 count down 19. The Stranglers. we go. 21. Oops,
40:19 increased it a little bit. All . Try again. All right.
40:27 , 32. Ok. Uh. . So which one is true?
40:37 Halo Akea? Are they bacterial chlorophyll their adoption? This is the adoption
40:46 one. Ok. So that's, it's Santa bacteria and oxygen photosynthesize
40:56 They're oxygen and they produce oxygen non sulfur bacteria. Light absorption by
41:04 bacterial oxygen linked to a pro That's . Yeah. What's not true about
41:12 ? Mhm Bacterial chlorophyll based. Never . OK. Green sulfur bacteria.
41:21 possessing photos systems. One linked to AD P H formation. Yeah.
41:28 Yeah, that's true. So that's only one. That's true F
41:35 right? Um 28. Is that ? Kudos to you? OK.
41:45 um All right. Well, you uh you got a week and almost
41:51 weeks to sort that out. So you got questions. Uh Are
41:55 any questions? Any questions? So let's uh look at this
42:02 All right. Maybe I'm back. . Maybe not. OK.
42:06 not that one. This one. . So one of these questions.
42:12 . I wanted to put this up and then then explain. OK.
42:16 let's see what we do here. . Let me pause that. Oh
43:12 . Let's count down. OK. , right? OK. Let's,
43:46 go through this. OK. Um get that. OK. So let's
43:55 at the table. All right. understandably I get you look at that
44:00 go W T F, right? OK. A it's any think of
44:11 as I don't think of it. is, it's a, it's
44:13 it's a ranking, it's an evaluation molecules as electron acceptor. So first
44:21 foremost, it's an evaluation of that cop. Number one, OK.
44:28 two is for each line, So look at the two boxed
44:34 for example. So each reaction, , you have two molecule pairs like
44:44 , right? Or like this, ? So the acceptor form of the
44:52 becomes reduced, right? It's the sector becomes reduced to form the that
45:02 product. OK. So for um plus right becomes reduced. It's the
45:10 and forms the reduced H two OK? So don't, don't even
45:15 at, don't even focus on OK? So we're looking at it
45:20 electronic sector as H plus. How is it? Right? And so
45:25 in your ranking, you're gonna have are gonna be good, some are
45:29 be bad, right? So in case, it's uh worst,
45:35 At the top, best at the , right? Worst the best in
45:44 of a dividing line. And so did the signs come in the the
45:48 numbers and the signs in front of numbers over here. So you have
45:54 potential. So first and foremost is table of reduction potentials. OK?
46:00 , that's how you measure the goodness you will of an acceptor.
46:05 What's its reduction? Potential? One basic way to think about this is
46:12 a, a very good without And so that you see the word
46:16 a question, strong, right? , I think it was somewhere
46:22 Stronger, strong, right? If strong, that means it's, it
46:27 to as being better um as being as being good at, at that
46:32 , whether it's a donor or it's good at that. It's
46:36 but that's what that refers to. . So um OK. So the
46:42 , so like I said, one way to think about it is the
46:44 good ones, right? So this our dividing line and then basing that
46:50 now again, just focusing on just temporarily just on um this reduction
46:59 OK. So positive reduction potentials, molecules that have high plus values,
47:08 are very good at accepting electrons. think of it. So electrons are
47:12 charged, right? What are they positive charge? Right. So those
47:16 are really positive reduction potential, love those negative electrons. That's one way
47:22 think about it. OK. If a negative value reduction potential, what
47:28 you do? You go get him from me? Right? Negative repels
47:32 , right? So that's one way think about it. You try to
47:36 whatever you can to help, remember stuff, right? That's one way
47:39 think about. OK. So um what does that mean? All
47:44 So ranting of acceptor, that's what table is, right? OK.
47:49 now let's we go back to this over here. OK. Eraser.
47:54 me erase that. OK. And it's what is the donor coming?
47:59 if something is, is bad at one thing or maybe it's good
48:04 the other, maybe the reverse is . OK. So that's something we've
48:08 focused on. So if we're looking the, at the uh this
48:17 right? Or um down here, ? That or let me erase that
48:23 or this one, OK. From on this side, it uh
48:30 right? On this part of the , right? That's the exception.
48:33 were just, we were just looking that, we just ranked them,
48:35 ? We saw this guy here is . This one's good. OK.
48:40 , what about the other side? . What about this guy? H
48:45 , right? What can it Right. Well, it can't accept
48:50 ? Electrons, it's a reduced form the molecule. OK. So if
48:56 want to evaluate this thing as we already know H plus is bad,
49:00 . But what about as a Well, then we're looking at the
49:03 reaction, right? Because we have see um what that looks like and
49:10 way to look at it is like , right, H two to form
49:16 plus, right? Uh in two , right? That's, that's,
49:23 what the donor would do, If we can evaluate it as a
49:26 , that's what it's gonna look right? H2 gets ox and gives
49:29 electrons, right? We're looking at it as a donor. OK.
49:34 that means we're looking at the reverse , which means the signs flip.
49:41 . So where it was a um for example, positive, so remember
49:48 relationship between reduction potential and delta right? A negative reduction potential,
49:54 acceptor equates to have to use energy make it be an acceptable. Even
50:00 it may be bad, you have , you, you can put in
50:04 if you have energy to put into , maybe it will still be
50:08 OK? Uh But you have to a lot of energy into it to
50:11 it a good acceptor. OK? So the um so again, if
50:20 , if you look at the reverse , what's the evaluation of the
50:23 Well, if it's a bad it's very likely it's gonna be a
50:27 donor. OK? And the good , the form of the donor is
50:30 one that's on this side. So you're evaluating H plus as an
50:37 or H two as a donor, ? That's, that's the pair,
50:41 ? And if you're looking at the , because this is, this is
50:45 to you as evaluation of the acceptor the reaction is going left to
50:51 If you're evaluating the donor, then have to flip it around.
50:56 Think of if you put, if put the donor in the acceptor
51:02 now you have it all arranged like table, but the donor is now
51:05 the left, right. What would do? You'd have to reverse the
51:09 , do that, right? So other words, you want to put
51:11 blue column on the pink side where pink poems at, you have to
51:16 the reaction. So that's why the G, right? And the delta
51:23 for this reaction is positive, Equates to a negative reduction potential.
51:29 the reverse this one we already know a negative delta G, right?
51:35 because that's gonna change, right? plus becomes a minus now.
51:41 And so we already know hydro right? H two is used a
51:46 in the bacterial world as a way get energy. It's a good
51:49 right? And so the whole thing uh so let's go back to the
51:53 . OK. So requires energy. this is just reading straight off the
51:58 , right, right there. That's OK. It requires energy to reduce
52:05 electrons, going to sulfate to form two S. That's, that's what
52:09 is right? And we can Yeah, it does, right.
52:14 that's true. OK. Hydrogen sulfide be considered a strong donor. I
52:22 we just established that. Right. . That's literally what was my example
52:26 the previous slide. So that's true course, OK. Um nitrite is
52:33 stronger terminal acceptor then sulfate. That again, that's, that's what
52:41 table is doing, it's evaluating And so we can read that right
52:44 the table, right? And so remember strong means better, better equates
52:50 positive production potential, negative delta G energy off, right? And so
52:55 too is true. OK, which the is the correct answer.
53:00 So um so that's the, that's whole thing about we had an example
53:07 uh a couple of days lectures not this um of, of it
53:14 involved Saxon eight. Uh let's see guy here, right? It involved
53:20 and I think it was nitrate and , all right. So nitrate,
53:26 know, very good electronic sector, ? Uh negative delta G,
53:32 And we looked at Suon eight you know, that actually turned out
53:38 we're looking at the suing as a , right? Reverse the reaction,
53:43 ? Actually turns out not to be great donor because it's requires energy,
53:47 ? But remember this is all right? So if you're a
53:52 if your acceptor is that much it can overcome that bad being a
53:57 and the collective energy still is a delta G OK. So it's all
54:01 putting together, I mean, of , optimally, you wanna have the
54:05 donor, which is one that really up electrons, right? Well,
54:12 uh will give off energy, not use energy and combine that with
54:15 terminal acceptor. That also is when gives off energy and is more
54:20 right? That's what makes that flow , right? Is combining the right
54:26 and acceptor together, right? Because how it all connects, right?
54:30 all connects uh like let me just back to here real quick. Um
54:37 like OK, right here. Uh go back to this. OK.
54:45 all connect. Yeah, thank Hold on. All connects. That's
54:53 I'm gonna get it. Uh It all connects right here,
55:00 That's where it all connects donor right? Optimal. You have
55:04 you got your protons being pumped right? You have a negative delta
55:09 in that transport system, energy knocks protons, you get energy back A
55:14 P but you have to keep supplying , a source, have an acceptor
55:18 . It's all all work together, ? So go back way back to
55:24 analogy, right? You don't think works, tie it off right over
55:29 head and tied off. It all . All right. So um that's
55:37 hope that help that explanation. Long explanation. Sorry. Um But
55:44 think about it. This is that's what I was saying to
55:46 You're not gonna get it the first . You see it not probably not
55:49 the second time, but you have kind of just absorb, right?
55:52 If you need to just look at look at the video lecture again but
55:57 you have questions, of course, me know here. I wanna put
56:00 up. OK, go could we talking about nothing about metabolism? Do
56:04 remember anything about viruses? Ok. we started this whole unit with?
56:10 . Um let me pull this thing and let's see what we remember.
56:24 . Mhm. So if you've forgotten , I probably understand that. But
56:30 and so you got time to get back in your head. Yes.
56:53 good one or a bad one. I forgot all about viruses.
57:08 jump down from five ft 21. . D hey, let's see.
57:29 single trans. Let me see if remember. Um OK, I,
57:34 on the in the metabolism zone for few weeks. Uh template for
57:40 Um So might as well make a . No A is false. It's
57:45 template to make a transcript, So the plus is the transcript that
57:51 be translated. OK. Um So is false. Um Bacter of H
57:58 13 forms A. No, it not. False. One goes
58:04 OK. Uh CRISPR type of bacterial . No, it's a type of
58:09 by the bacteria. OK. Nope, that's Lioy R N A
58:16 . No, they typical, they do their thing outside the nucleus.
58:21 This is the ability to affect multiple types in a single host,
58:27 That's tropism, it's false. Um , this is describing host range.
58:35 . A viruses all possess no retroviruses not. H is correct. 32
58:44 to the 32. OK. All , folks see you have a good
58:51 next
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