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BIOL 2321_Microbiology for Science Majors - 2321_MW4_3_7_23_Lecture
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00:14 Pretty funny. Mhm. Yeah, . Just a line here.
00:37 Testing. Ok. Um Let's All right. So, uh next
00:47 of course, uh no classes. spring break. Um so we're gonna
00:55 up. Uh So basically we're gonna up units um, You know,
01:04 ends. Uh right here. My pen is not working, so
01:12 here, catch up there. So the end of unit two. So
01:16 finish up. We'll have probably won't a full class, a full life
01:20 . But uh finish up the photo . We'll start a little bit of
01:24 today at the end, but finish up on Thursday and that we'll finish
01:28 two. So, uh when we back for spring break, then we
01:32 the next unit, of course. two is uh at the end of
01:38 week, uh 24th, 25th. , um and then before you
01:43 it, uh here comes April and we're almost done. So it's flying
01:49 , um All right, the uh so that, um it's normally like
01:57 un quiz is, you know, days Friday through Monday. But this
02:01 Because of the spring break in the . I just said I'll open it
02:05 Friday, but you'll have until the . So you'll have like 10 days
02:10 , uh, to do that. , um, Uh, chapter 14
02:15 working and that's not until after spring . So, uh, nothing coming
02:20 , uh, in the next, our usual due Monday due days because
02:25 the holiday. So, anyway, plenty of time to finish that stuff
02:29 . Uh, so just wanna start a bit of a recap.
02:35 So, um All right. So this unit, uh not a unit
02:42 chapter 1314, we're gonna talk about kind of more maybe more generally.
02:49 looking at really focusing most for the part on metabolism uh heter growth,
02:58 ? Uh like us, we uh ferment uh it's just in our muscles
03:04 , but the bacteria of course, lots of things they can do,
03:06 can ferment, they can diss fire , anaerobically, right? So we
03:12 through like the stages of um of respiration, like causes and respiration and
03:19 the the glucose of pyro prava can to, if you're a fermenter,
03:23 can ferment into these um end lactate ethanol, other types, organic
03:31 , alcohols or if it can respire going through uh to Kuwait formation project
03:39 of the transport system. So, lot more stuff, right?
03:44 um last time we kind of focused on respiration and the that process.
03:54 , remember I draw this thing all time and one of this kind of
03:58 like this up uh up here, ? We have a donor right
04:05 We have a uh acceptor, And then um these redox reactions,
04:11 ? The accepting and handing off of , right? So we're going to
04:16 more positive reduction potential, right? that's what this was all about
04:24 the energetics of that process. how do you, what, how
04:28 you combine these donors acceptor? Uh , what drives that? Right?
04:33 so of course, it's, it's put together the ones that are strong
04:38 , right? That are upon this of the table. OK? So
04:42 our line is kind of like right , right? These are more positive
04:49 potentials, more negative. So if , if you're more positive production
04:56 you're gonna be a good accepter generally oxygen, right? If you're a
05:01 more negative reduction potential, you're likely be a better donor, not
05:06 OK. Uh So it's all about combinations together additively, right? Negative
05:16 G. And that's what, that's will drive the process, all
05:22 that's what you get out of And so that, that, that
05:25 you get is what is used to protons out. OK? And
05:31 you will then capture that in the of A T P S because remember
05:36 basic concept, we started this section , right? Energy releasing processes with
05:44 required processes put those together, And uh that's what we do.
05:49 the pump protons requires energy. And , and that's how this happens in
05:53 restoration. OK? Because the other thing, of course, the putting
05:58 the right combination of donor acceptor allows to maintain flu, right? That's
06:05 sustains the whole process, right? this is where protons get pumped
06:10 OK? So maintaining that flow. it's remember it's all all connected
06:16 Beginning with and so that's a, one way to kind of test yourself
06:20 you build the process right now. . Let's start with proton proton
06:26 right? Well, what what enables to happen? Well, we'll get
06:30 right? Electron transport chain, strong , strong acceptor. There's a aerobic
06:35 , right? What's the, what's source? Right. Yes, we
06:38 N A B H S for the part that we make. But remember
06:42 not the source, right? we're, we're creating a like the
06:47 you eat, right? And so and so it all it all connects
06:53 . Electron donors feed the system, have an acceptor that allow flow to
06:58 , right? Delta G, maybe delta G in the transport electron transport
07:03 chain energy from protons act, And then we get that uh back
07:09 the form of A T P. here is our E coli very similar
07:14 our mitochondrial membrane, of course, components, but same principle.
07:19 And then um we'll start today with . So the proton mode of
07:23 right? So, um that is then is tied to an A T
07:29 A, right? And that's ultimately we form the energy energy,
07:34 A T P S. OK. So that's what we're gonna, so
07:40 gonna zero in now more on OK? And they look at a
07:47 and then get into little trophy and trophy. OK? So let's um
07:55 here. OK? So I kind already and I'm not gonna, I
08:01 showing you the equation right. So P is the proton motor force.
08:06 ? You're not going to do right? Just kind of wanna look
08:08 the different variables here. OK? we have charge, right? The
08:14 OK is basically a product of the charge, right? The charge
08:21 the membrane and all all cells have charge across the membrane. OK?
08:25 I'm gonna say you go to any usually gonna be their exception but usually
08:31 be like you see here, negative , positive outset you do the proteins
08:36 the cell. OK? Um yeah, proteins, certain proteins can
08:42 secreted or what kind of membrane. you know, for the most part
08:46 are, they're inside the site is . OK? And at physiological ph
08:52 typically have a negative charge, that's contributes mostly to this. OK?
08:57 . Uh Yes, you have lots ions and tens of different types,
09:02 two contribute that most, most of contributions from proteins. OK?
09:08 So this is sets up in one the forces, right? So it's
09:13 charge, right? So remember this pumping protons and what what that's
09:19 about, right? That's the whole donor, electron transport chain, energy
09:24 , all that is degenerating that energy pump protons. OK. So then
09:29 course, they're positive, right? gonna be attracted to negative charge.
09:35 , that's like, you know what do like cat, I like an
09:39 . So um so that's one the electrical force. OK. Delta
09:47 . The other force is the concentration protons high uh here below here.
09:55 you have that um concentration difference, ? The gradient, that's the other
10:01 , right? And of course, dealing with uh hydrogens, that's P
10:07 IP H is a function of the of hydrogen. So uh it relates
10:13 . So we have delta P H is basically a function of concentration gradient
10:18 these and just charge uh total charge the membrane. OK. Uh
10:26 uh so we've got two things that , that will bring protons into the
10:31 . OK. Charge attraction concentration right? Remember they're small, they're
10:37 molecules, even though they're small, not gonna have an easy time getting
10:42 the membrane, water heating, The membrane is very hydrophobic,
10:47 So it's not gonna have an easy getting through. But if you give
10:51 a, a passage way then you're gonna get, they'll come in
10:58 and you'll get energy release, So, back to the energy
11:02 energy releasing what energy require. This is happening again. And that's
11:06 this is here too. That there the same concept because we're the energy
11:13 from electron transfers. We couple that needed to pump protons out.
11:18 And so we do it again over , right? So if we,
11:23 we um here, if we give my way to get in, then
11:32 will. And so that's what the T P is about. OK.
11:36 so they'll pass through and again, release from going down the gradient,
11:43 that to form A T P s remember the form A T P S
11:46 energy, right? And so we again that process. OK. Uh
11:52 two processes and releasing energy required. . So, um so I'm just
11:58 , I'm just storing some values in just to show you what the typical
12:02 are. Are they all MS because not e electrical charge differences. And
12:09 um very typical, right? A difference of external versus internal about
12:18 right? That's, you know, most bacterial cells aren't Kia that's,
12:23 know, they try to operate. are the uh what we call neutral
12:28 . That's what we are, We maintain a relatively neutral P H
12:32 six and eight and uh and that's uh internal P H is gonna be
12:37 that, you know. And so because you're generating radiant, all
12:42 that's gonna create a difference in P . OK. And so that value
12:46 delta P H is just really what difference is. So we're looking,
12:50 looking at a delta P H of , right, one unit difference between
12:55 and out, right? So we plug in the number one over
12:59 Then delta, this is a value could be measured. OK? But
13:06 the average functioning bacterial cell, it's this range, right? And it
13:12 , right? It fluctuates because uh the, the delta G here you
13:18 may fluctuate. OK? The P difference may slightly fluctuate. So there'd
13:24 a range of values but for a functioning cell, it's somewhere in
13:28 OK. So you plug it in our ranges are within here one minus
13:34 , 10 to minus 2, 10 normal. So that's typical for a
13:38 happy cell if you will eco all . And um different things can
13:44 disrupt it. And it does P fluctuations can influence the delta P
13:51 you know, the, the uh and ions coming in out of the
13:56 , maybe the uh the laity uh the cell may change that can influence
14:02 charge. So, you know, it it will vary um under the
14:07 , you know, you'll, you'll uh within this range and um and
14:13 allow you to produce, you the optimal amount of E P S
14:17 get from that. OK. So so next is to kind of just
14:23 a little bit at this part the A T P A itself.
14:29 . Uh So two things to remember the charge difference about the charge and
14:35 concentration difference. Those are the two working here. So we call this
14:38 M chemi osmosis mechanism. OK. But it's a, a total of
14:45 22 different things that draw, that protons into the cell. OK.
14:52 Any questions about that? OK. let's take a look at the A
14:57 P A. OK. This is molecular motor uh which I do believe
15:04 applying in different types of nanotechnology because does can move. OK. Um
15:13 the best way to really look at is uh in the, this little
15:19 here. OK. So, all . So before we roll this
15:26 so we've got uh obviously major multi complex and it's, it's universal.
15:37 ? It's found in, in obviously in plants, bacteria, et
15:41 , right? And so um So key parts here are the part that's
15:47 in the membrane, right? The zero. Uh This one is in
15:55 . This is where the actual A P synthesis will occur. OK.
16:03 This is the part that you see protons specifically over here. Um The
16:11 lots of protons actually moves its what's a rotor right here, the
16:18 So uh it's rotary action is what about the really the, the exposure
16:27 the active sites that are in the one complex here. And now they
16:33 exposed. A AD P and phosphate in and then A T P is
16:38 . OK. And it's all based this, um the shape really of
16:45 rotor piece, as you'll see here a second. So here's a cross
16:48 . OK. So you can see let's do this. So here you
16:54 to show this. So here is , what happens is in this,
17:00 piece here rotates and as the are , a P phosphate comes in,
17:10 it's a combination of enzyme action and substrate, but then the protein actually
17:17 as well. And that imparts energy for the process. So you can
17:21 here that this axle they call it part of rotate is not totally like
17:28 a cylinder. It has this kind teardrop shape as that moves, this
17:37 ultimately open this one's open at this and then as it moves this
17:42 it will close. So it ultimately and closes as it goes around,
17:46 3123 sites where this happens. So produce, you can produce three A
17:53 P s uh approximately there's three A sites uh A DB AD P binding
17:59 . OK. And so as it's , maybe an old fuel by protons
18:04 in. So here comes a P S and we turn, then we
18:12 it moves again, I mean, S ac that part will open and
18:21 the products are released. OK. again, it's all fueled by uh
18:26 coming through, continuing to spinning. . But again, you know,
18:30 , work it all back. It's, you don't, you don't
18:33 the spinning unless you have a proton , the proton gradient, unless you
18:36 the electron transport system, you don't that unless you have delivers and acceptor
18:41 , electron flow energy production the whole yards, right? So it all
18:48 . OK. So um so the let's go back here. OK?
19:03 , that's what I want. So if we look at kind of
19:06 of the numbers here, so I think these are for uh your
19:09 E coli under optimal conditions, I that um eight protons are pumped for
19:18 movie oxide. OK. Each So um and so then in terms
19:26 A T P, you get from for every three protons that come
19:31 there's one A T P produced. . So you do the mass,
19:36 ? And um the A T P for N A DH are almost
19:40 right? 2.6 of them. Fa DH two, a little
19:44 And that's only because um the, there's two proton pumps associated with N
19:52 DH, there's just one with FA two. So hence you get a
19:55 bit lesser amount of, of A P production. So um the other
20:02 of this rather than using protons is sodium instead of protons. And that's
20:10 you see in. It's probably obvious you would see it in halo files
20:14 they live in a high salt right? So um so it makes
20:21 that they would substitute sodium ions maybe protons uh pathogens as well. So
20:26 your your bodily fluids have a pretty amount of sodium ions as well.
20:32 so a number of pathogens um uh a sodium pump uh for their AD
20:39 production. But it it's all the principle, same principle ad P A
20:43 all that's the same. Um So we tally down everything up in aerobic
20:52 , OK? Um We can get numbers. All right. So here's
20:56 four stages, right? Um So , review, right? This is
21:03 this is the four stages, what in, what comes out uh
21:09 pirate, et cetera. Um And energy production. So remember the substrate
21:13 versus the oxidative phosphorylation, OK. phosphorylation. Hopefully by now, you
21:20 that when you see that right? means proton pump uh the the four
21:27 here operating uh much more complex, ? Uh the substrate phosphor uh the
21:35 basic way to make an A T if you will, right, using
21:38 phosphorated substrate that will um uh then a phosphate group to a AD P
21:45 make it an A T P. . So we do that at a
21:49 of places in the glycolysis crip But of course, we get a
21:53 more energy molecule formation uh in the of a DH, mostly some fa
21:59 do at, at each of the . We get that. OK.
22:04 of course, they come and do thing at the electron transport chain.
22:09 . That's where these guys do their when they be oxidized and hand off
22:14 electrons. OK. So, um back to our equation from the previous
22:21 slide, we uh if we do that now with the 10 N A
22:28 and two fa DH two that we , that we get a total of
22:32 30 A T P. OK. We as humans, I'm sure you
22:41 uh our theoretical yi is like 37 A P S. Um The thing
22:48 bacterial cells in a is that even this is a theoretical amount, it's
22:55 uh they don't get that close to . They usually, it's somewhere in
23:00 range of about 18 to 22 A P. OK. Is what they
23:09 . Uh So why is that, don't they get the full, you
23:18 , why don't we get, why , why don't we get the max
23:23 its work? Is, is, this is this only used for
23:38 Use it for other things. It this gradient for other stuff, not
23:43 to make a TPS OK. He it to move flagellum if it's motile
23:49 um to um uh move other molecules and out of the cell,
23:55 So remember that proton gradient is a of stored energy, right? Like
24:01 concept, energy releasing energy energy So that proton gradient can be made
24:09 do other stuff, right? Use energy release you get from going down
24:14 gradient and couple that to other processes the cell transport over the molecules.
24:19 and other things. OK. So that's why it never reaches a full
24:26 paper theoretically is using that gradient for things as well. Certainly for energy
24:31 it can vary depending on what, going on with it. OK.
24:37 uh Any questions about that. So um all right. So this
24:46 , this is gonna need this inter respiration. OK. So take a
24:51 at this. So we're just really on this part here. OK.
25:01 So we're looking at over uh this uh if you call it a sulfur
25:07 more or less. So uh these a couple of terms, this one
25:11 for sure is simulation. So mole are assimilated. So the simulator
25:18 we'll talk about a couple of those . Here's one where the product of
25:23 process is basically incorporated into my, . So for us, you
25:27 we can, we eat protein, course, we can break down proteins
25:31 we can get nitrogen from them and from it and we hold on,
25:35 keep it, we use it to make stuff. OK? That's
25:40 simulator process. That the opposite is . There's processes that we don't know
25:46 and it, and it's free go others can use it that are in
25:50 environment. OK? So you it's Asim and disci processes.
25:56 So um so really this is another to kind of, oh I'm
26:00 they even open the stupid thing. we go. Now it's open.
26:06 Is we have H two S and have so here. OK? And
26:15 O so we're basically going, dude, dude. And then to
26:24 , OK. So we're gonna learn for a good chunk of the next
26:32 that there are roles, certain roles molecules. All right, we're gonna
26:37 on nitrogen and sulfur molecules because they're prevalent in the pro world in having
26:48 in respiration and in Lioy, So you kind of have to differentiate
26:55 two things. OK? Because some work best for 11 type of
27:01 others work best for another type. ? That's kind of what this is
27:05 at. Let's see here. The down. So look at both sulfur
27:22 and nitrogen molecules in similar roles. . All right. 8,
27:30 6, 5, 4, Ok. Ok. So,
27:44 who, um, who picked a a big day? 67 of you
27:54 anybody up? Yes. Why did pick it? Um And so the
28:08 last time? No. Ok. , uh it turns out that you're
28:19 . Um so what we're doing is , it's the roll. So back
28:23 the role of the molecule, So in aerobic respiration, right?
28:27 02, right? Going to water high reduction potential oxygen, right?
28:36 electrons become reduced, right? Um S 04 has the same role.
28:44 . So you can think of it molecules that are more reduced versus those
28:49 are more oxidized. This is a reduced form H two S OK.
28:55 is a more oxidized form S So when you are doing the molecules
29:01 are donators versus acceptor, OK. acceptor are always more uh oxidized
29:11 OK. That can receive electrons, ? The ones that are donors,
29:18 ones that become oxidized are are more , think the reduced forms as having
29:24 ready to give up the oxide wanna grab electrons. So that's another
29:28 to think about it. OK. the moles have their ropes in this
29:33 . OK. Um It all goes the energetics, bioenergetics again,
29:39 This is, does it make Does it yield energy then that's how
29:42 do it. OK. Um And that's what this anaerobic respiration is about
29:49 at different terminal acceptor besides oxygen. ? And very common on are different
29:55 of sulfur and nitrogen molecules. So um here is E coli.
30:01 e coli, as I mentioned, number of times is very versatile,
30:06 ? So we can utilize oxygen, ? You see here, but then
30:11 has different options for anaerobic respiration. ? All these nitrate nitrite dios sulfate
30:19 fumer. So they can be right? It's organic, uh more
30:26 organic forms. Uh This is inorganic . OK. Um So it just
30:32 so and it can ferment so it require a analy and ferment.
30:38 Uh Obviously which one it does all on what's available to it.
30:44 And what the conditions are. So sulfur and nitro molecules are very common
30:51 terms of being used for respiration or being used for lit trusts.
30:58 And so which one would be used ? What is really about? Is
31:03 a reduced form of the molecule or it more oxidized? Ok. So
31:08 you look at nitrogen, which I think the most oxidation states of
31:14 um you go from nitrate at the to ammonia, at the bottom,
31:20 or organic nitrogen. The uh so oxidized to more reduced. So these
31:29 , all right, that you that the trots would use,
31:35 Oxidize and get energy. OK. forms are more what you would only
31:43 with, right? Be a internal become reduced. OK. Um Similarly
31:49 uh sulfur molecules or sulfate is one more oxidized. That'll be at the
31:55 , the acceptor H two S produce , they get, get energy,
32:03 electrons from. OK. So, they, he's gonna have their roles
32:08 this way. And since we're in right now, we're kind of looking
32:13 that. And so with nitrogen mo , um sulfur molecules very common that
32:20 sulfur metabolism is very common in different in marine marine systems because uh marine
32:26 has a higher concentration of sulfur than fresh water or terrestrial systems.
32:32 Um Not that you don't see them terrestrial environments, but they, they
32:36 to be more prevalent in marine uh nitrogen, uh different types of
32:42 metabolism, you see uh pretty, widespread. Um So here's dissimulator,
32:49 ? So a dissimulator process ultimately gets of it, right? And so
32:55 what uh the uh reduction of So we have different uh pairs
33:01 So, and that's typical for a type that can respire anaerobically will have
33:07 couple of these, right? It have all, all of them
33:11 right? It may have nitrate, , which is fairly common. Uh
33:15 it may have maybe these two uh is not all of them, but
33:20 have a couple of them. And uh so it's dissimulator because ultimately,
33:27 gonna, that going this way is to return to the atmosphere and nitrogen
33:32 , even nitrous oxide, it's also . Ok. So these are gonna
33:36 , they're not gonna be a That's what we call it, the
33:38 toy process. Ok. Um So look at the nitrogen cycle, we'll
33:44 about this at the start of uh three, which is after spring
33:50 Um So we're really just focusing on side, right? That's what this
33:56 referring to. OK. Deification. uh And so in two, in
34:03 atmosphere, which is 70%, I forget um a lot, a
34:10 of it, right? And so this process of fixation is critical because
34:17 , it's the only biological process that it in the ecosystems. OK.
34:24 uh so remember this is important uh nitrification. So this is how uh
34:32 autotrophs, right? As great as are, right? Sunshine and co2
34:38 water, right? They, they can't make nitrogen, they can't
34:42 phosphorus. So they rely on this to supply that to them. Um
34:48 often it's nitrate, nitrate that plants so very uh important. And so
34:56 , even if you're not, if , if you hate vegetables,
35:00 Um The things you like to eat eat vegetables so directly or indirectly,
35:05 depend on this as well. So um OK. So that's aerobic
35:12 on this site here and we'll, focus on this and later in this
35:19 and this uh when we get the trophy. OK. So again,
35:23 see the roles, right? So these are substrates for respiration,
35:30 Aerobic respiration. This is something you use an oxidizer, right? It
35:36 be an energy source for lithium. . So, different rules for these
35:40 . OK. So here's a So again, sulfur are prevalent in
35:45 ecosystems, um sulfur metabolisms. And um here's the, again, this
35:55 the route sulfur goes sulfate, uh using sulfur compounds. OK.
36:03 uh where you see a lot of kind of sulfur metabolisms and others are
36:09 these thermal vents. OK. So of these as basically underwater volcanoes,
36:15 . Um The areas where they're really , uh they basically have like black
36:21 coming out because of the high concentration sulfur and iron really that kind of
36:26 . It, it gets really thick , but also very hot,
36:30 Because it's thermal, of course. so you'll see a range of microbe
36:36 from. Um and of course, of these inorganic type compounds being spewed
36:42 . OK? And these are raw for different Meho tropes, right?
36:47 also be through anaerobic respiration. So you'll have a hierarchy of,
36:53 know, hyperthermia in your mouth because course, it's hot, obviously,
36:59 maybe more moderate thermop files down here meso files that can't stand the heat
37:04 farther away. OK? But then on top of that, you have
37:08 like liro using these substances, Um The are also Um all the
37:17 they use co2, right? The . and um then you have your
37:24 reducers, right? Using this for respiration, right? And so
37:29 when you have all these metabolisms and kind of eating products of one and
37:35 cetera, that's what we call sin . OK? So sin meeting
37:40 trophy, eat, eating together. um this activity can be quite vigorous
37:48 these events. OK. So much that there are life that uh multicellular
37:56 that's in these areas. OK. Have symbiotic relationships with these organisms.
38:04 . And one type are these giant worms that's these uh have these yellow
38:11 caps on top and these stalks um the area around these events, they
38:16 be like the fields, feels these . Uh but they have in them
38:21 , these sulfur uh reducing auto and um but rather sulfur oxidizing auto and
38:29 , so they, they uh fix two and they appear they getting molecule
38:33 worms to feed off of OK. again, uh when you have lots
38:37 this activity, you can support the of these worms. So characteristic around
38:43 vents. OK. Um So the last bit of part one uh
38:51 I yeah is is again a OK. Looking at these different really
38:59 on the these metals here. But what you have this could be
39:05 environment. It could be a it even be a uh uh a
39:10 OK. The uh obviously, the activity is gonna be highest at the
39:16 , right? That's where the most at. OK. So remember the
39:18 potential. So if it's gonna drop from more positive, OK, to
39:27 negative and you can uh people that this kind of field of work to
39:32 these aerobic a measure, think of as a measure of aero biases.
39:38 anaerobic is it, right? That's be there are probes that can measure
39:43 potential. So negative values equate to ness, aerobic ness if you will
39:50 . A very negative value, an that's very anaerobic. OK? Or
39:55 be a range of values anywhere in here. Uh But the more negative
39:59 are the more anaerobic it is And you're gonna expect to find certain
40:03 in those environments where you wouldn't find here. OK. But any
40:08 so that translates also to different respirations using different terminal acceptor.
40:15 And so as we go down, deniro fires and it's all about really
40:20 reduction potential of the system. And we're going more negative Mehanna engines are
40:25 sensitive to oxygen. OK? Uh among the these metal reducers,
40:33 The one of the keys to their is or what's helpful to others in
40:38 ecosystems is they provide forms of these that uh are more easily assimilated.
40:47 metals can be very water and soluble certain forms. So they can provide
40:53 in forms that are uh more soluble can be taken up by others in
40:57 environment which, which are critical for , especially with iron, the need
41:01 iron. Um the um and but , so the point here is that
41:07 are all representatives of the aerobic restoration using different terminal acceptor. OK.
41:16 so um so dissimulators, remember like it's not hold on to that
41:23 , it's letting it go. So free for others to, to
41:27 OK. Um I think that's close out part one or any questions about
41:35 . OK. So uh let's look Lizzo Trophy 1st. OK. So
41:44 , um looking at the front right? Looking at this part,
41:50 been focusing kind of on here since started class. All right. So
41:55 we're focusing on this part, the . OK? And so specifically inorganic
42:02 , OK? Um So, uh you know, we're switching gears and
42:09 at, you know, trophy, ? It still will have electron transport
42:15 pump A T P A S. ? You can have those things.
42:19 so uh let's look at, so don't forget this here,
42:26 So the source is gonna be something gonna be more reduced, right?
42:29 becomes oxidative compared to opposite of, the acceptor. OK? Um So
42:37 a trophy, um nitro fire. we just mentioned these guys in the
42:42 of the nitrogen cycle. So, so ammonia to nitrite, that is
42:52 process is carried out by 11 group bacteria. Another group carries out this
42:58 , OK. One is nitros Simonis one is nitro bacter. Don't need
43:02 know that, but there are two groups. Actually, one carries out
43:06 carries out the other. Um now soil P H, right? So
43:12 , these are acidic, nitric right? Is acidic, obviously.
43:18 where these have, where this is issue is in agricultural areas that are
43:28 commercial fertilizers being dumped on the OK. So very often it's an
43:35 and it's not all used. And so you have excess fertilizer which
43:39 course contains ammonia, uh phosphorus uh the two primary elements and the excess
43:49 then is gobbled up by micro of course, OK. And they'll
43:54 an excess of acid. So that's , where you over fertilize or put
43:59 much fertilizer around. It's not Uh That's when you can um increase
44:05 soil p or decrease the soil P as a result. Of course,
44:09 are sensitive to soil P H and may have heard the term uh you
44:14 too much fertilizer on you, burn the land, so to
44:17 And that's kind of what this is to is this effect. OK.
44:23 now, sulfur oxidation uh that two can be an issue OK. So
44:29 you're producing its metabolism produces so pure , right? And so you often
44:36 these in um in areas where mining occurring. So uh iron mines,
44:45 they'll have water, water is always part of the mining operation and um
44:51 water will be rich in many of types of elements. And so uh
44:56 problem can occur is um the production hydrogen sulfide. So, iron not
45:03 get involved in biochemistry of an iron . OK. But one of the
45:07 is actually can be if FES OK. And this can then form
45:14 sulfide, don't even know this. regardless the production of hydrogen sulfide leads
45:18 a lot of acid production. And you can also see it here
45:24 where that's being oxidized as sulfuric And that's a, that's a
45:30 that's a lot of acid. And so this water from these
45:36 especially with this, with these sulfur can be in even below two.
45:41 could be like P zero, which super acidic. So you can
45:46 you know, in a mining operation this water is collected, this metabolism
45:49 going on, you don't want to dump it out anywhere, right?
45:52 if you dump it into a nearby water or even land and that's gonna
45:58 in the water, it's gonna dramatically affect the, the wildlife in those
46:02 . So, uh it's something that have to treat, somehow neutralize.
46:09 not another issue is uh iron oxidation the pres of sulfur as well,
46:17 so, we're all aware of, rust, right. That's just spontaneous
46:21 of iron from the air, right ox of anaerobically. This also
46:27 So, think of uh bridges, structures made of iron that are
46:34 right? Typically, especially if it's it's gonna be embedded in the
46:38 right. So the sediment will be and it will have these metabolisms where
46:44 will contribute to iron oxidation anaerobically. that could weaken the structure as it
46:51 where these structures have collapsed because of of the corrosion. So it can
46:57 a problem especially in different environments. ? Um OK. So this is
47:04 of just meant to show the whole of these nitrogen and sulfur compounds that
47:11 their roles relate to each other. . So we start here. So
47:18 , you're more reduced molecules will become , right? These these serve as
47:25 sources for lit atrophy. OK. then kind of the uh dividing line
47:32 in this case with nitrogen compounds is might trait, right? So then
47:37 get to molecules that are more forms become reduced. So these typically serve
47:44 acceptor for anaerobic respiration. OK. , of course, we can close
47:49 loop. Um natural fixation again, to me ammonia back into the
47:56 OK. So, in um cell , same thing, right. So
48:02 reduced compounds become oxidized. So it's . Then we kind of, These
48:10 become uh acceptor for respiration and OK. So it's kind of how
48:15 connect and of course, H2, started with that over here and then
48:20 end with it over here. That's kind of how these all fit
48:26 . Um Any, any questions about ? Yes. OK. So let's
48:35 at, so Hydrogen Trophy. This is um on, you
48:43 obviously, if you look at this right here, OK. That
48:48 there's a truth, there's a Somebody that's using that must be a
48:52 , my best thing doesn't have to OK. It's a, it's a
48:57 that's been exploited um by a number bacteria, very different bacteria.
49:03 E coli can do this. So uh the reason why it's so
49:11 , I guess is the amount of . So this equates to a very
49:16 high negative delta G, right? hydrogen is not a um it's fairly
49:25 found in the environment. It's a of fermentation and other metabolic processes.
49:31 it's, you know, it's not that's obscure, it's something that hydrogen
49:35 a byproduct that can, you be found uh rather readily. And
49:40 you have a way to use uh all, all the better if
49:43 can, OK. It'll give you a good shot of energy. And
49:48 uh so they call it Hydrogen Trophy you find it in different types of
49:53 types, not just lit. And it's used in different ways.
49:58 here is here is aerobic um oxidation hydrogen. Um Here it is like
50:05 combination of both a inorganic and You going to suite. OK.
50:13 combination again here of organic and organic both of these. So that's the
50:18 here about is it a proper Not just in but in other
50:24 OK. Really? For the, the versatility of it? OK.
50:30 Now, Genesis, OK. This one that uses CO2, OK as
50:37 acceptor. OK. And uh and uh by, by the oxidation of
50:45 . OK. So I put C , OK? And so this,
50:50 remember if you recall the C CO2 not a good acceptor. OK?
50:55 bad. It takes a lot of to use that as an acceptor.
50:58 because of the way it lives in environment in plentiful, plentiful co2,
51:04 can actually make it work. Plus with the fact that oxidizing hydrogen gets
51:09 lot of energy. If you combine with CO2, which is not
51:13 it'll work. OK? Um The about this one is a, it's
51:20 it's a greenhouse gas that's worse than . Um It's primarily the source is
51:29 cows, right? The cows have digestive chambers and one of those carries
51:35 metha, OK? And that is if you think about the cows on
51:42 and the amount of methane, You can imagine, uh fortunately there
51:48 um methanol, which can kind of it out because that those are bacteria
51:54 actually oxidize methane. So you can of have balance the production with the
52:00 of it. Um And so of , remember that the mets are only
52:07 Archaea. It's strictly a property of that domain. OK. Um
52:14 it can be also, it's also uh production and met methane can also
52:19 quite vigorous in land fields. Strangely , um It's not uncommon to see
52:25 big landfills particularly, they'll have um have a pipe uh in the
52:32 And so it, there's so much production, they wanna get rid of
52:36 and not be a hazard, Explode or something. So I have
52:39 , you see a, a pipe a flame coming on top, that's
52:41 methane being produced in these uh but people are smart and they can actually
52:47 that to do use for energy to um you know, do to
52:52 various operation in uh in the, the, in the land fill or
52:57 in uh some big cattle operations. use this as well as, as
53:02 , as a means to power different around the uh facility. So,
53:09 yeah, the uh so let's look this question. OK. So remember
53:14 Hydrogen a trophy is one of those that's very versatile. I guess if
53:19 wanna call it that OK? But different uh labels, I guess you
53:24 put on something that use it. ? So for bacterial species that can
53:31 and supplied an energy source and carbon consisting of H two. So energy
53:41 , carbon source and nitrate. The term acceptor. So you can
53:49 put a bunch of maybe put a of labels on this. OK?
53:58 , let me open. Sorry. . There we go. Yes.
54:40 OK. That's yeah, of All these all apply, right?
54:45 uh this give me this a You could call this certainly hydrogen a
54:50 . OK? Um That's Autotroph. right. This is anaerobic restoration.
54:57 . So you can to set that on all these, on that,
55:02 that particular bacteria, of course. . Um So they let's just do
55:09 little bit of phototropic. Are there questions? So let's look a little
55:16 at. So trophy. Um so the way we break this
55:24 So what we're gonna do, we're gonna start here with this one down
55:28 . So a couple of keys are photo hetro, OK. And it
55:35 pigment molecules. So I remember with photosynthesis or photo trophy, I should
55:42 um uh we're evolving light obviously, ? And so that means you need
55:48 have molecules that absorb light. So you're familiar, of course with
55:54 . So we have what are called systems, which includes bacterial chlorophyll,
55:58 similar molecule Um So that's one OK. The other type is one
56:07 uses a different type of picket right? This Rhodopsin molecule bacterial
56:15 adoption very similar, OK. But different, completely different in terms of
56:20 it operates. We compare it to based systems. OK. So the
56:26 between the chlorophyll based types, Your familiarity is likely mostly with this
56:31 . OK. Um water electron So remember again, photo you know
56:38 of switching gears here, terms of , it's still reduction reactions, it's
56:44 electron donor source. All that stuff still applied. OK. Um A
56:51 P A is just light driven. . So proton gradient, all that
56:56 still applies. Um So um so so how we differentiate between this type
57:05 photosynthesis appear versus this type. Both are chlorophyll based but the difference
57:13 the one process forms oxygen. One not OK? Because they use
57:19 water is a donor, we oxidize water. That's what we call it
57:24 photosynthesis. OK. The other type does not use water, uses things
57:31 uh H two S or these other , those are the electron donors,
57:36 ? So we have to form oxygen a result. So we call those
57:40 no oxygen formation. Um So you these are gonna there's gonna be similarities
57:47 all pro photo trucks. OK. what this question here is asking.
57:52 . So which over the following is not applicable to all underlying several
58:08 Ok. It has to be an or you can't do it.
58:37 Count down. All right. Uh . It's gonna be 98% 99%.
59:03 , ok. So it's, that's app. Ok. So, because
59:11 you just right. Photo Hitter photo auto trophy. Ok. You
59:18 two types and so, but certainly gonna be some kind of light
59:22 So once it absorbs light, it excited and that's translated into some into
59:26 kind of energy production. OK. um all right, we went through
59:33 and all right. So the other here to mention is this, so
59:38 , so these are the sources of that are gonna be given up.
59:45 . They're gonna be oxidized and so , that's the role for for
59:50 algae, et cetera. Uh It's one for other types. OK.
59:55 the first process we're talking about which a bacterial sy basis does not,
60:02 no donor of electrons, right? a completely different process. OK.
60:08 let's look at that here, So again, as with anaerobic respiration
60:14 respiration period, right? Involve the . So too phototropic, right?
60:19 part of membrane, you stuff up of these pigments and things. But
60:23 um the bacteria adoption based, these found in Archaea, Archaea that are
60:29 loving the halo archaea, but then found in bacteria that are in the
60:37 ecosystems with these types. OK. a process of what we call horizontal
60:44 transfer. We'll talk about that in three passage of genes between the
60:48 Uh And so the form you see bacteria is called prote adoption,
60:53 A little bit different but still very . OK. And the adoption is
60:58 you've taken human phys or A P you've gone through the, how the
61:04 works, right? You talk about very, very, some similarities
61:09 OK. So the bacteria that do and they're aquatic bacteria, um the
61:20 of water, you see these in water is kind of purplish, pinkish
61:24 water. OK? Because the pigments have absorb green light and that these
61:31 reflects um purplish colors. OK. um the uh and so this
61:42 the light absorbing part is the OK. And that's the little molecule
61:48 see here in the interior, The red is the protein,
61:54 So that retinal is the bonding, protein. OK. And so absorption
62:01 light occurs right here. And as absorbed, basically the orientation of the
62:14 along that bond are flipped, Cys, the trans rights trans.
62:22 because that right now it's bound to when it shifts. So does the
62:28 OK. And that shifting is what protons to be pumped out.
62:35 And so again, it doesn't evolve . We're not talking about, we're
62:41 talking about electron transport or electron doors . It's all photons of light
62:48 that's it. OK. And so no photos reaction, there's no molecules
62:54 up electrons here. It's just light hitting and causing this process to pump
63:00 out. OK. Of course, involves a T P synthesis.
63:05 It's part of this membrane. So could be sitting uh right here.
63:10 . And protons will come through and form a T P. OK.
63:16 that's, that's gonna be a OK? It's just, there's
63:20 it's not an electron based system if will, it's photons of light
63:24 OK. So very unusual, it to be kind of one of the
63:29 types of photos systemss to evolve on before the chlorophyll based system came
63:36 OK? Um And so, you , it's what it is. And
63:41 the other key thing here is, ? So, so it's not electrons
63:46 it, it's just photons of light two the property of photo hetero,
63:51 ones that do this are photo heros require still metabolize like metabolism, what
63:58 been talking about before. So um , but it's a way to produce
64:03 , right? Uh just absorb produce A T P S. It's
64:06 light driven proton up, up to A T P A to make
64:11 OK? But it still needs to carbon, right? And so there's
64:15 , that's why these things are OK. Um uh Any questions about
64:23 ? Yeah. So that's where I in. So, we'll, we'll
64:27 that photo trophy on Thursday. And , right. So,
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