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<sub><sub></sub></sub>{{Sandbox_Reserved_CH462_Biochemistry_II}}<!-- PLEASE ADD YOUR CONTENT BELOW HERE -->
{{Sandbox_Reserved_CH462_Biochemistry_II}}<!-- PLEASE ADD YOUR CONTENT BELOW HERE -->
= Cytochrome ''bd''-1 oxidase in ''Escherichia coli'' =
= Cytochrome ''bd''-1 oxidase in ''Escherichia coli'' =
<StructureSection  load='6rx4'  size='350'  frame='true' side='right' caption='Cartoon representation of E. coli cytochrome bd-1 oxidase designed from [https://www.rcsb.org/structure/6RX4 PDB: 6RX4]. Blue= CydA; green= CydB; yellow= CydX; pink= CydS; gray = hemes and UQ-8.' scene='83/832931/Full/3'>
==Introduction==
==Introduction==
<StructureSection  load='6rx4size='350' frame='true' side='right' caption='E. coli cytochrome bd-1 oxidase. Blue= CydA; green= CydB; yellow= CydX; pink= CydS; gray = hemes and UQ-8.'
<scene name='83/832931/Full/4'>Cytochrome bd oxidase</scene> is a type of quinol-dependent [https://en.wikipedia.org/wiki/Transmembrane_protein transmembrane] (Fig. 1) terminal [https://en.wikipedia.org/wiki/Oxidase oxidase] found exclusively in [https://en.wikipedia.org/wiki/Prokaryote prokaryotes].<ref name="Safarian">PMID: 27126043</ref> With a very high oxygen affinity, bd oxidases play a vital role in the [https://en.wikipedia.org/wiki/Oxidative_phosphorylation oxidative phosphorylation] pathway in both gram-positive and gram-negative bacteria. Cytochrome ''bd'' oxidase's responsibility in the oxidative phosphorylation pathway also allows it to act as a key survival factor in the bacterial stress response against antibacterial drugs <ref name="Safarian">PMID: 31604309</ref>, hypoxia, cyanide, [https://en.wikipedia.org/wiki/Nitric_oxide nitric oxide], and H<sub>2</sub>O<sub>2</sub><ref name="Harikishore">PMID: 31939065</ref>. Given this knowledge, ''bd'' oxidases have become an area of scientific research worth pursuing as they could serve as an ideal target for antimicrobial drug development. <ref name="Boot">PMID: 28878275</ref>
[[Image:Pp_and_cp_of_oxdiase.png|550 px|center|thumb|''Figure 1''. Cartoon model of cytochrome bd-oxidase in ''E. coli''. Dashed lines represent borders of [https://en.wikipedia.org/wiki/Cytoplasm cytoplasmic] and [https://en.wikipedia.org/wiki/Periplasm periplasmic] regions.  A quinol bound in the periplasmic <scene name='83/832924/Q_loop/3'>Q-loop</scene> is [https://en.wikipedia.org/wiki/Redox oxidized] and releases protons into the periplasmic space, generating a [https://en.wikipedia.org/wiki/Electrochemical_gradient proton gradient].  Protons and oxygen atoms from the cytoplasmic side enter cytochrome ''bd'' oxidase through specific channels.  Oxygen is [https://en.wikipedia.org/wiki/Redox reduced] to water, which is released into the cytoplasmic space.  Blue = CydA; green = CydB; yellow = CydX; pink = CydS.  [[https://www.rcsb.org/structure/6RX4 PDB: 6RX4]]]]
The overall mechanism of ''bd'' oxidases involves an exergonic [https://en.wikipedia.org/wiki/Dioxygen_in_biological_reactions reduction of molecular oxygen] into water (Fig. 2). During this reaction, a proton gradient is generated in order to assist in the conservation of energy. <ref name="Belevich">PMID: 17690093</ref> Unlike other terminal oxidases, bd oxidases do not use a proton pump. Instead, bd oxidases use a form of vectorial chemistry that releases protons from the quinol oxidation into the positive, periplasmic side of the membrane. Protons that are required for the water formation are then consumed from the negative, cytoplasmic side of the membrane, thus creating the previously mentioned proton gradient.
[[Image:proton graadient.jpg|300 px|left|thumb|Figure 2: Overall schematic representation of cytochrome bd oxidase. <ref name= "Giuffre">PMID: 24486503</ref>; General display of the reduction of molecular oxygen into water using the quinol as a reducing substrate. The three hemes are located near the periplasmic space, meaning that the membrane potential is generated mainly from proton transfer from the cytoplasm towards the active site on the opposite site of the membrane. Heme b<sub>558</sub> is involved in quinol oxidation and heme d serves as the site where O2 binds and becomes reduced to H2O.]]


This page will be specifically focusing on the structure and overall function of the 6RX4 ''bd'' oxidase in [https://en.wikipedia.org/wiki/Escherichia_coli ''E. coli'']. 6RX4 is a part of the long(L) quinol-binding domain subfamily that terminal oxidases are classified into. The L-subfamily of ''bd'' oxidases are responsible for the survival of acute infectious diseases such as ''E. coli'' and [http://www.example.com salmonella]. The 6RX4's three <scene name='83/832931/Heme/4'>heme</scene> groups, its periplasmically exposed <scene name='83/832924/Q_loop/3'>Q-loop</scene>, and <scene name='83/832942/Four_subunits_labelled_6rx4/2'>four protein subunits</scene> will be of primary focus when identifying the relationship between structure and function.
==Structure==
=== Subunits ===


== Function ==
Cytochrome ''bd'' oxidase is made up of four individual subunits.<ref name="Alexander">PMID:31723136</ref> The two major subunits, CydA and CydB, are each composed of one peripheral [https://en.wikipedia.org/wiki/Alpha_helix helix] and two bundles of four [https://en.wikipedia.org/wiki/Transmembrane_protein transmembrane] helices. The <scene name='83/832924/Cyda_subunit/6'>CydA subunit</scene> plays the most important role in the oxygen [https://en.wikipedia.org/wiki/Redox reduction reaction] as it contains the Q-loop as well as all three [https://en.wikipedia.org/wiki/Heme heme] groups. The <scene name='83/832924/Cydb_subunit/2'>CydB subunit</scene> harbors the <scene name='83/832924/Ubiquinone/3'>ubiquinone</scene> molecule which provides structural support to the subunit that mimics the three hemes found in CydA.<ref name="Safarian">PMID: 31604309</ref><ref name="Safarian2">PMID: 27126043</ref> The remaining two subunits, CydS and CydX, are both single helix structures that assist in the oxygen reduction reaction. Unique to ''E. coli'', the <scene name='83/832924/Cyds_subunit/4'>CydS subunit</scene> binds to CydA to block oxygen from directly binding to heme b<sub>595</sub>. The <scene name='83/832924/Cydx_subunit/4'>CydX subunit</scene> promotes the assembly and stability of the oxidase complex. CydX is composed of 37 mostly hydrophilic [https://en.wikipedia.org/wiki/Amino_acid amino acid] residues, including <scene name='83/832924/Glu25/2'>Glu25</scene> that is exposed to the cytoplasm and prevents the helix from fully entering the membrane. <ref name="Alexander">PMID:31723136</ref>
The <scene name='83/832931/Full/4'>cytochrome ''bd'' oxidase</scene> allows bacteria to be resistant to hypoxia, cyanide, nitric oxide, and H<sub>2</sub>O<sub>2</sub><ref name="Harikishore">PMID: 31939065</ref>
== Disease ==


== Relevance ==
===Q-Loop===
 
Another significant structural feature of bd oxidase is the <scene name='83/832924/Q_loop/3'>Q-loop</scene> which is located between TM helices 6 and 7 of the CydA subunit.<ref name="Alexander">PMID:31723136</ref> The periplasmic Q-loop in ''E. coli'' stretches over a length of 136 amino acid residues, making it much longer than the Q-loop in [https://en.wikipedia.org/wiki/Geobacillus_thermoglucosidasius ''Geobacillus Thermodenitrificans''].<ref name="Safarian">PMID: 27126043</ref> The Q-loop is likely involved in [https://en.wikipedia.org/wiki/Hydroquinone quinol] binding and oxidation. The [https://en.wikipedia.org/wiki/N-terminus N-terminal end] of this Q-loop is very flexible and likely functions as the hinge that allows for quinone binding while the [https://en.wikipedia.org/wiki/C-terminus C-terminal end] is much more rigid which provides stabilization for the enzyme.<ref name="Alexander">PMID:31723136</ref>


== Molecular Function ==
== Molecular Function ==
=== H and O channels ===
=== H and O channels ===
[[Image:O_AND_H_CHANNEL.png|300 px|right|thumb|'''Figure 3'''. H and o-channels of cytochrome bd-oxidase in ''E. coli''. Channels are outlined in gray, water is shown as spheres, and various amino acids are labeled above.  [[https://www.rcsb.org/structure/6RX4 PDB:6RX4]]]]
[[Image:O_AND_H_CHANNEL.png|300 px|right|thumb|'''Figure 3'''. H and O-channels of cytochrome bd-oxidase in ''E. coli''. Channels are outlined in gray, water is shown as spheres, and relevant amino acids are labeled above.  [[https://www.rcsb.org/structure/6RX4 PDB:6RX4]]]]
The hydrogen and oxygen channels (Fig. 3) are essential for H<sup>+</sup> and O<sub>2</sub> molecules to reach the active site of cytochrome ''bd'' oxidase. A proton motive force generated by the oxidase<ref name= "Safarian">PMID:31604309</ref> allows protons from the cytoplasm to flow through a hydrophilic <scene name='83/832931/Overall_h_channel/2'>H-channel</scene> full of water (pink dots), entering at <scene name='83/832931/Start_of_h_channel/2'>Asp119<sup>A</sup></scene> and moving past <scene name='83/832931/Start_of_h_channel/2'>Lys57<sup>A</sup>, Lys109<sup>B</sup>, Asp105<sup>B</sup>, Tyr379<sup>B</sup>, and Asp58<sup>B</sup></scene><ref name="Alexander">PMID:31723136</ref> where they can be transferred to the active site with the help of the conserved residues <scene name='83/832931/End_of_h_channel/4'>Ser108<sup>A</sup>, Glu107<sup>A</sup>, and Ser140<sup>A</sup></scene><ref name= "Safarian">PMID:31604309</ref>.  A smaller <scene name='83/832931/O_channel_overall/3'>O-channel</scene> also exists that transitions from hydrophobic to hydrophilic as it gets closer to the active site. This channel allows oxygen to reach the active site, starting near <scene name='83/832931/Ochannel/2'>Trp63</scene> in CydB and passing by <scene name='83/832931/Ochannel/2'>Ile144<sup>A</sup>, Leu101<sup>A</sup>, and Glu99<sup>A</sup></scene><ref name= "Safarian">PMID:31604309</ref>, which assists with the binding of oxygen to the active site.  The o-channel channel is approximately 1.5 Å in diameter<ref name="Alexander">PMID:31723136</ref>, which may help with selectivity.  
The hydrogen and oxygen channels (Fig. 3) are essential for H<sup>+</sup> and O<sub>2</sub> molecules to reach the active site of cytochrome ''bd'' oxidase. A [https://en.wikipedia.org/wiki/Chemiosmosis#The_proton-motive_force proton motive force] generated by the oxidase<ref name= "Safarian">PMID:31604309</ref> allows protons from the cytoplasm to flow through a hydrophilic <scene name='83/832931/Overall_h_channel/2'>H-channel</scene> full of water (pink dots), entering at <scene name='83/832931/Start_of_h_channel/2'>Asp119<sup>A</sup></scene> and moving past <scene name='83/832931/Start_of_h_channel/2'>Lys57<sup>A</sup>, Lys109<sup>B</sup>, Asp105<sup>B</sup>, Tyr379<sup>B</sup>, and Asp58<sup>B</sup></scene><ref name="Alexander">PMID:31723136</ref> where they can be transferred to the active site with the help of the conserved residues <scene name='83/832931/End_of_h_channel/4'>Ser108<sup>A</sup>, Glu107<sup>A</sup>, and Ser140<sup>A</sup></scene><ref name= "Safarian">PMID:31604309</ref>.  A smaller <scene name='83/832931/O_channel_overall/3'>O-channel</scene> also exists that transitions from hydrophobic to hydrophilic as it gets closer to the active site. This channel allows oxygen to reach the active site, starting near <scene name='83/832931/Ochannel/2'>Trp63</scene> in CydB and passing by <scene name='83/832931/Ochannel/2'>Ile144<sup>A</sup>, Leu101<sup>A</sup>, and Glu99<sup>A</sup></scene><ref name= "Safarian">PMID:31604309</ref>, which assists with the binding of oxygen to the active site.  The O-channel channel is approximately 1.5 [https://en.wikipedia.org/wiki/Angstrom Å] in diameter<ref name="Alexander">PMID:31723136</ref>, which may help with [https://en.wikipedia.org/wiki/Chemical_specificity selectivity].  


Interestingly, the o-channel does not exist in the cytochrome''bd'' oxidase of [https://en.wikipedia.org/wiki/Geobacillus_thermoglucosidasius ''Geobacillus thermodenitrificans'']; instead, oxygen binds directly to the active site<ref name="Safarian2">PMID: 27126043</ref>.  The <scene name='83/832931/Cyds/1'>CydS</scene> subunit found in E. coli blocks this alternate oxygen entry site, which allows oxygen to travel through the o-channel<ref name="Safarian">PMID:31604309</ref><ref name="Alexander">PMID:31723136</ref>.  The presence of an o-channel affects oxidase activity, as the ''E. coli'' oxidase acts as a "true" oxidase, while the ''G. thermodenitrificans'' bd oxidase contributes more to detoxification<ref name="Alexander">PMID:31723136</ref>.
Interestingly, the O-channel does not exist in the cytochrome ''bd'' oxidase of [https://www.rcsb.org/structure/5DOQ ''Geobacillus thermodenitrificans'']; instead, oxygen binds directly to the active site<ref name="Safarian2">PMID: 27126043</ref>.  The <scene name='83/832931/Cyds/1'>CydS</scene> subunit found in ''E. coli'' blocks this alternate oxygen entry site, which allows oxygen to travel through the O-channel<ref name="Safarian">PMID:31604309</ref><ref name="Alexander">PMID:31723136</ref>.  The presence of an O-channel affects oxidase activity, as the ''E. coli'' oxidase acts as a "true" oxidase, while the ''G. thermodenitrificans'' bd oxidase contributes more to [https://en.wikipedia.org/wiki/Detoxification#Metabolic_detoxification detoxification]<ref name="Alexander">PMID:31723136</ref>.
=== Hemes ===
=== Hemes ===
Three <scene name='83/832931/Heme/6'>hemes</scene> are present in the CydA subunit. These three hemes form a triangle to maximize subunit stability<ref name="Safarian">PMID:31604309</ref><ref name="Alexander">PMID:31723136</ref><ref name="Safarian2">PMID:27126043</ref>, which is an evolutionary conserved feature across bd oxidases<ref name="Safarian">PMID:31604309</ref>.  Heme b<sub>558</sub> acts as the primary electron acceptor by catalyzing the oxidation of quinol<ref name="Alexander">PMID:31723136</ref>. Conserved <scene name='83/832931/Met393/1'>His186 and Met393</scene> help to stabilize heme b558<ref name="Alexander">PMID:31723136</ref>. Heme b<sub>558</sub> transfers the electrons to heme b595, which transfers them to the active site heme d<ref name= "Safarian">PMID:31604309</ref>.  A conserved <scene name='83/832931/Trp441/5'>Trp441</scene> assists heme b<sub>595</sub> in transferring electrons to heme d<ref name="Safarian2">PMID:27126043</ref>.  A conserved <scene name='83/832931/Hemeb595/2'>Glu445</scene> is essential for charge stabilization of heme b<sub>595</sub><ref name="Alexander">PMID:31723136</ref>, while <scene name='83/832931/Hemeh19/2'>His19</scene> stabilizes heme d<ref name="Safarian2">PMID:27126043</ref>. As heme d collects the electrons from heme b<sub>595</sub>, <scene name='83/832931/Heme_d/2'>Glu99</scene> in the o-channel facilities the binding of oxygen to heme d, and <scene name='83/832931/Heme_d/2'>Ser109, Glu107, and Ser140</scene> in the h-channel facilitate proton transfer to heme d<ref name="Safarian">PMID:31604309</ref>. Similar to the three hemes, the <scene name='83/832931/Uq8/3'>ubiquinone-8</scene> (UQ-8) molecule found in CydB mimics the triangular formation to stabilize the subunit<ref name="Safarian">PMID:31604309</ref>.  
Three <scene name='83/832931/Heme/6'>hemes</scene> are present in the <scene name='83/832924/Cyda_subunit/6'>CydA subunit</scene>. These three hemes form a triangle to maximize subunit stability<ref name="Safarian">PMID:31604309</ref><ref name="Alexander">PMID:31723136</ref><ref name="Safarian2">PMID:27126043</ref>, which is an evolutionary conserved feature across bd oxidases<ref name="Safarian">PMID:31604309</ref>.  Heme b<sub>558</sub> acts as the primary [https://en.wikipedia.org/wiki/Electron_acceptor electron acceptor] by [https://en.wikipedia.org/wiki/Catalysis catalyzing] the [https://en.wikipedia.org/wiki/Hydroquinone#Redox oxidation of quinol]<ref name="Alexander">PMID:31723136</ref>. Conserved <scene name='83/832931/Met393/1'>His186 and Met393</scene> help to stabilize heme b558<ref name="Alexander">PMID:31723136</ref>. Heme b<sub>558</sub> [https://en.wikipedia.org/wiki/Electron_transfer transfers] the electrons to heme b595, which transfers them to the active site heme d<ref name= "Safarian">PMID:31604309</ref>.  Multiple residues help stabilzie this electron trasnfer including a conserved <scene name='83/832931/Trp441/6'>Trp441</scene> that assists heme b<sub>595</sub> in transferring electrons to heme d<ref name="Safarian2">PMID:27126043</ref>.  A conserved <scene name='83/832931/Hemeb595/2'>Glu445</scene> is also essential for charge stabilization of heme b<sub>595</sub><ref name="Alexander">PMID:31723136</ref>, while <scene name='83/832931/Hemeh19/3'>His19</scene> stabilizes heme d<ref name="Safarian2">PMID:27126043</ref>. As heme d collects the electrons from heme b<sub>595</sub>, <scene name='83/832931/Heme_d/3'>Glu99</scene> in the O-channel facilities the binding of oxygen to heme d, and <scene name='83/832931/Heme_d/3'>Ser108, Glu107, and Ser140</scene> in the H-channel facilitate proton transfer to heme d<ref name="Safarian">PMID:31604309</ref>. Similar to the three hemes, the <scene name='83/832931/Uq8/3'>ubiquinone-8</scene> (UQ-8) molecule found in the <scene name='83/832924/Cydb_subunit/2'>CydB subunit</scene> mimics the triangular formation to stabilize the subunit<ref name="Safarian">PMID:31604309</ref>.  
===Mechanism===
===Mechanism===
Quinol is used as the initial electron donor  and heme b<sub>558</sub> is the initial electron acceptor.  <scene name='83/832931/Heme/6'>Heme b<sub>558</sub></scene> transfers the electrons to <scene name='83/832931/Heme/6'>heme b<sub>595</sub></scene>, which transfers the electrons to <scene name='83/832931/Heme/6'>heme d</scene>.  Concurrently, the <scene name='83/832931/Overall_h_channel/1'>H-channel</scene> will collect protons and <scene name='83/832931/O_channel_overall/2'>o-channel</scene> will collect oxygen atoms that will flow to heme d (Fig. 3).  With electrons, oxygen, and protons available, heme d can successfully reduce dioxygen to water (Fig. 4).
Quinol transfers two electrons to heme b<sub>558</sub> and releases two protons into the periplasmic space as the initial [https://en.wikipedia.org/wiki/Electron_donor electron donor].  <scene name='83/832931/Heme/6'>Heme b558</scene> transfers the electrons to <scene name='83/832931/Heme/6'>heme b595</scene>, which transfers the electrons to <scene name='83/832931/Heme/6'>heme d</scene>.  Concurrently, the <scene name='83/832931/Overall_h_channel/2'>H-channel</scene> collects protons from the cytoplasmic side using the proton gradient and the <scene name='83/832931/O_channel_overall/3'>O-channel</scene> collects oxygen atoms.  The protons and oxygen flow to the active site heme d (Fig. 3).  With electrons, oxygen, and protons available, heme d can successfully reduce dioxygen to water (Fig. 2, 4). [[Image:mech4.png|500 px|center|thumb|''Figure 4''. General mechanism of cytochrome bd-oxidase in ''E. coli''. Electrons are passed from quinol to heme b<sub>558</sub> to heme b<sub>595</sub> to heme d. Protons and oxygen atoms flow into the H-channel and O-channel to heme d. Heme d catalzyes the reduction of oxygen to water.]]
== Relevance ==
== Relevance ==
The cytochrome ''bd'' oxidase is essential for bacteria to thrive in the human body by enhancing bacterial growth and colonization.  Any alteration of the bd oxdiase Cyd subunits will most likely produce a nonfunctional mutant cytochrome ''bd'' oxidase<ref name="Moosa">PMID: 28760899</ref>, which inhibits bacterial growth.  If ''E. coli'' were missing or possessed ineffective CydA and B subunits, bacterial growth ceased.<ref name="Hughes">PMID: 28182951</ref>.  With [https://en.wikipedia.org/wiki/Colitis colitis], ''E. coli'' mutants that were missing CydAB colonized poorly in comparison to the wild type levels of colonization<ref name="Hughes">PMID: 28182951</ref>.  The cytochrome ''bd'' oxidase is the main component in nitric oxide (NO) tolerance in bacteria, which is released by neutrophils and macrophages when the host is infected<ref name="Shepherd">PMID: 27767067</ref>. ''E. coli'' growth seen in urinary tract infections is mainly due to the NO resistant bd oxidase. Without the CydA  and CydB subunits, bacteria could not colonize in high NO conditions<ref name="Shepherd">PMID: 27767067</ref>.  Cytochrome ''bd'' oxidases are essential in other pathogenic bacteria such as [https://en.wikipedia.org/wiki/Mycobacterium_tuberculosis ''M. tuberculosis''].  Deletion of the CydA and CydB subunits dramatically decreased the growth of ''M. tb'' compared to the wild type when exposed to imidazo[1,2-α]pyridine, a known inhibitor of respiratory enzymes<ref name="Arora">PMID:25155596</ref>.  Upregulation of the cytochrome ''bd'' oxidase Cyd genes resulted in a mutant strain of ''M. tb'' that was resistant to imidazo[1,2-α]pyridine<ref name="Arora">PMID:25155596</ref>.
The cytochrome ''bd'' oxidase is essential for [https://en.wikipedia.org/wiki/Pathogenic_bacteria pathogenic bacteria] to thrive in the human body because it enhances bacterial growth and [https://en.wikipedia.org/wiki/Bacterial_growth colonization].  Any alteration of the ''bd'' oxidase Cyd subunits will most likely produce a nonfunctional [https://en.wikipedia.org/wiki/Mutant mutant] cytochrome ''bd'' oxidase<ref name="Moosa">PMID: 28760899</ref>, which inhibits bacterial growth.  If ''E. coli'' are missing or possess ineffective CydA and B subunits, bacterial growth ceases.<ref name="Hughes">PMID: 28182951</ref>.  With [https://en.wikipedia.org/wiki/Colitis colitis], ''E. coli'' mutants that were missing CydAB colonized poorly in comparison to the [https://en.wikipedia.org/wiki/Wild_type wild type] levels of colonization<ref name="Hughes">PMID: 28182951</ref>.  The cytochrome ''bd'' oxidase is the main component in [https://en.wikipedia.org/wiki/Biological_functions_of_nitric_oxide#Effects_in_bacteria nitric oxide] (NO) tolerance in bacteria, which is released by [https://en.wikipedia.org/wiki/Neutrophil neutrophils] and [https://en.wikipedia.org/wiki/Macrophage macrophages] when the [https://en.wikipedia.org/wiki/Host_(biology) host] is infected<ref name="Shepherd">PMID: 27767067</ref>. ''E. coli'' growth seen in [https://en.wikipedia.org/wiki/Urinary_tract_infection urinary tract infections] is mainly due to the NO resistant ''bd'' oxidase. Without the CydA  and CydB subunits, bacteria could not colonize in high NO conditions<ref name="Shepherd">PMID: 27767067</ref>.  Cytochrome ''bd'' oxidases are essential for life in other pathogenic bacteria such as [https://en.wikipedia.org/wiki/Mycobacterium_tuberculosis ''M. tuberculosis''].  Deletion of the CydA and CydB subunits dramatically decreased the growth of ''M. tb'' compared to the wild type when exposed to [https://en.wikipedia.org/wiki/Imidazopyridine imidazo[1,2-]][https://en.wikipedia.org/wiki/Imidazopyridine pyridine], a known [https://en.wikipedia.org/wiki/Enzyme_inhibitor inhibitor] of respiratory enzymes<ref name="Arora">PMID:25155596</ref>.  [https://en.wikipedia.org/wiki/Downregulation_and_upregulation Upregulation] of the cytochrome ''bd'' oxidase Cyd genes resulted in a mutant strain of ''M. tb'' that was [https://en.wikipedia.org/wiki/Antimicrobial_resistance resistant] to imidazo[1,2-α]pyridine<ref name="Arora">PMID:25155596</ref>.


Since cytochrome ''bd'' oxidases are only found in prokaryotes and are required for pathogenic bacterial infections, inhibitors that target cytochrome ''bd'' oxidase are promising antibacterial agents.  Compounds that target heme b<sub>558</sub><ref name="Harikishore">PMID: 31939065</ref>, create unusable forms of oxygen<ref name="Galván">PMID: 30790617</ref>, and target the o-channel <ref name="Lu">PMID: 26015371 </ref> have shown potential in halting bacterial growth.
Since cytochrome ''bd'' oxidases are only found in prokaryotes and are required for [https://en.wikipedia.org/wiki/Infection#Bacterial_or_viral pathogenic bacterial infections], inhibitors that target cytochrome ''bd'' oxidase are promising [https://en.wikipedia.org/wiki/Antibiotic antibacterial] agents.  Compounds that target heme b<sub>558</sub><ref name="Harikishore">PMID: 31939065</ref>, create [https://en.wikipedia.org/wiki/Allotropes_of_oxygen unusable forms of oxygen]<ref name="Galván">PMID: 30790617</ref>, and target the o-channel <ref name="Lu">PMID: 26015371 </ref> have shown potential in halting bacterial growth.




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Cytochrome bd-1 oxidase in Escherichia coliCytochrome bd-1 oxidase in Escherichia coli

Introduction

is a type of quinol-dependent transmembrane (Fig. 1) terminal oxidase found exclusively in prokaryotes.[1] With a very high oxygen affinity, bd oxidases play a vital role in the oxidative phosphorylation pathway in both gram-positive and gram-negative bacteria. Cytochrome bd oxidase's responsibility in the oxidative phosphorylation pathway also allows it to act as a key survival factor in the bacterial stress response against antibacterial drugs [1], hypoxia, cyanide, nitric oxide, and H2O2[2]. Given this knowledge, bd oxidases have become an area of scientific research worth pursuing as they could serve as an ideal target for antimicrobial drug development. [3]

Figure 1. Cartoon model of cytochrome bd-oxidase in E. coli. Dashed lines represent borders of cytoplasmic and periplasmic regions. A quinol bound in the periplasmic is oxidized and releases protons into the periplasmic space, generating a proton gradient. Protons and oxygen atoms from the cytoplasmic side enter cytochrome bd oxidase through specific channels. Oxygen is reduced to water, which is released into the cytoplasmic space. Blue = CydA; green = CydB; yellow = CydX; pink = CydS. [PDB: 6RX4]

The overall mechanism of bd oxidases involves an exergonic reduction of molecular oxygen into water (Fig. 2). During this reaction, a proton gradient is generated in order to assist in the conservation of energy. [4] Unlike other terminal oxidases, bd oxidases do not use a proton pump. Instead, bd oxidases use a form of vectorial chemistry that releases protons from the quinol oxidation into the positive, periplasmic side of the membrane. Protons that are required for the water formation are then consumed from the negative, cytoplasmic side of the membrane, thus creating the previously mentioned proton gradient.

Figure 2: Overall schematic representation of cytochrome bd oxidase. [5]; General display of the reduction of molecular oxygen into water using the quinol as a reducing substrate. The three hemes are located near the periplasmic space, meaning that the membrane potential is generated mainly from proton transfer from the cytoplasm towards the active site on the opposite site of the membrane. Heme b558 is involved in quinol oxidation and heme d serves as the site where O2 binds and becomes reduced to H2O.

This page will be specifically focusing on the structure and overall function of the 6RX4 bd oxidase in E. coli. 6RX4 is a part of the long(L) quinol-binding domain subfamily that terminal oxidases are classified into. The L-subfamily of bd oxidases are responsible for the survival of acute infectious diseases such as E. coli and salmonella. The 6RX4's three groups, its periplasmically exposed , and will be of primary focus when identifying the relationship between structure and function.

Structure

Subunits

Cytochrome bd oxidase is made up of four individual subunits.[6] The two major subunits, CydA and CydB, are each composed of one peripheral helix and two bundles of four transmembrane helices. The plays the most important role in the oxygen reduction reaction as it contains the Q-loop as well as all three heme groups. The harbors the molecule which provides structural support to the subunit that mimics the three hemes found in CydA.[1][7] The remaining two subunits, CydS and CydX, are both single helix structures that assist in the oxygen reduction reaction. Unique to E. coli, the binds to CydA to block oxygen from directly binding to heme b595. The promotes the assembly and stability of the oxidase complex. CydX is composed of 37 mostly hydrophilic amino acid residues, including that is exposed to the cytoplasm and prevents the helix from fully entering the membrane. [6]

Q-Loop

Another significant structural feature of bd oxidase is the which is located between TM helices 6 and 7 of the CydA subunit.[6] The periplasmic Q-loop in E. coli stretches over a length of 136 amino acid residues, making it much longer than the Q-loop in Geobacillus Thermodenitrificans.[1] The Q-loop is likely involved in quinol binding and oxidation. The N-terminal end of this Q-loop is very flexible and likely functions as the hinge that allows for quinone binding while the C-terminal end is much more rigid which provides stabilization for the enzyme.[6]

Molecular Function

H and O channels

Figure 3. H and O-channels of cytochrome bd-oxidase in E. coli. Channels are outlined in gray, water is shown as spheres, and relevant amino acids are labeled above. [PDB:6RX4]

The hydrogen and oxygen channels (Fig. 3) are essential for H+ and O2 molecules to reach the active site of cytochrome bd oxidase. A proton motive force generated by the oxidase[1] allows protons from the cytoplasm to flow through a hydrophilic full of water (pink dots), entering at and moving past [6] where they can be transferred to the active site with the help of the conserved residues [1]. A smaller also exists that transitions from hydrophobic to hydrophilic as it gets closer to the active site. This channel allows oxygen to reach the active site, starting near in CydB and passing by [1], which assists with the binding of oxygen to the active site. The O-channel channel is approximately 1.5 Å in diameter[6], which may help with selectivity.

Interestingly, the O-channel does not exist in the cytochrome bd oxidase of Geobacillus thermodenitrificans; instead, oxygen binds directly to the active site[7]. The subunit found in E. coli blocks this alternate oxygen entry site, which allows oxygen to travel through the O-channel[1][6]. The presence of an O-channel affects oxidase activity, as the E. coli oxidase acts as a "true" oxidase, while the G. thermodenitrificans bd oxidase contributes more to detoxification[6].

Hemes

Three are present in the . These three hemes form a triangle to maximize subunit stability[1][6][7], which is an evolutionary conserved feature across bd oxidases[1]. Heme b558 acts as the primary electron acceptor by catalyzing the oxidation of quinol[6]. Conserved help to stabilize heme b558[6]. Heme b558 transfers the electrons to heme b595, which transfers them to the active site heme d[1]. Multiple residues help stabilzie this electron trasnfer including a conserved that assists heme b595 in transferring electrons to heme d[7]. A conserved is also essential for charge stabilization of heme b595[6], while stabilizes heme d[7]. As heme d collects the electrons from heme b595, in the O-channel facilities the binding of oxygen to heme d, and in the H-channel facilitate proton transfer to heme d[1]. Similar to the three hemes, the (UQ-8) molecule found in the mimics the triangular formation to stabilize the subunit[1].

Mechanism

Quinol transfers two electrons to heme b558 and releases two protons into the periplasmic space as the initial electron donor. transfers the electrons to , which transfers the electrons to . Concurrently, the collects protons from the cytoplasmic side using the proton gradient and the collects oxygen atoms. The protons and oxygen flow to the active site heme d (Fig. 3). With electrons, oxygen, and protons available, heme d can successfully reduce dioxygen to water (Fig. 2, 4).

Figure 4. General mechanism of cytochrome bd-oxidase in E. coli. Electrons are passed from quinol to heme b558 to heme b595 to heme d. Protons and oxygen atoms flow into the H-channel and O-channel to heme d. Heme d catalzyes the reduction of oxygen to water.

Relevance

The cytochrome bd oxidase is essential for pathogenic bacteria to thrive in the human body because it enhances bacterial growth and colonization. Any alteration of the bd oxidase Cyd subunits will most likely produce a nonfunctional mutant cytochrome bd oxidase[8], which inhibits bacterial growth. If E. coli are missing or possess ineffective CydA and B subunits, bacterial growth ceases.[9]. With colitis, E. coli mutants that were missing CydAB colonized poorly in comparison to the wild type levels of colonization[9]. The cytochrome bd oxidase is the main component in nitric oxide (NO) tolerance in bacteria, which is released by neutrophils and macrophages when the host is infected[10]. E. coli growth seen in urinary tract infections is mainly due to the NO resistant bd oxidase. Without the CydA and CydB subunits, bacteria could not colonize in high NO conditions[10]. Cytochrome bd oxidases are essential for life in other pathogenic bacteria such as M. tuberculosis. Deletion of the CydA and CydB subunits dramatically decreased the growth of M. tb compared to the wild type when exposed to imidazo[1,2-]pyridine, a known inhibitor of respiratory enzymes[11]. Upregulation of the cytochrome bd oxidase Cyd genes resulted in a mutant strain of M. tb that was resistant to imidazo[1,2-α]pyridine[11].

Since cytochrome bd oxidases are only found in prokaryotes and are required for pathogenic bacterial infections, inhibitors that target cytochrome bd oxidase are promising antibacterial agents. Compounds that target heme b558[2], create unusable forms of oxygen[12], and target the o-channel [13] have shown potential in halting bacterial growth.


Cartoon representation of E. coli cytochrome bd-1 oxidase designed from PDB: 6RX4. Blue= CydA; green= CydB; yellow= CydX; pink= CydS; gray = hemes and UQ-8.

Drag the structure with the mouse to rotate

ReferencesReferences

  1. 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 Safarian S, Rajendran C, Muller H, Preu J, Langer JD, Ovchinnikov S, Hirose T, Kusumoto T, Sakamoto J, Michel H. Structure of a bd oxidase indicates similar mechanisms for membrane-integrated oxygen reductases. Science. 2016 Apr 29;352(6285):583-6. doi: 10.1126/science.aaf2477. PMID:27126043 doi:http://dx.doi.org/10.1126/science.aaf2477 Cite error: Invalid <ref> tag; name "Safarian" defined multiple times with different content
  2. 2.0 2.1 Harikishore A, Chong SSM, Ragunathan P, Bates RW, Gruber G. Targeting the menaquinol binding loop of mycobacterial cytochrome bd oxidase. Mol Divers. 2020 Jan 14. pii: 10.1007/s11030-020-10034-0. doi:, 10.1007/s11030-020-10034-0. PMID:31939065 doi:http://dx.doi.org/10.1007/s11030-020-10034-0
  3. Boot M, Jim KK, Liu T, Commandeur S, Lu P, Verboom T, Lill H, Bitter W, Bald D. A fluorescence-based reporter for monitoring expression of mycobacterial cytochrome bd in response to antibacterials and during infection. Sci Rep. 2017 Sep 6;7(1):10665. doi: 10.1038/s41598-017-10944-4. PMID:28878275 doi:http://dx.doi.org/10.1038/s41598-017-10944-4
  4. Belevich I, Borisov VB, Verkhovsky MI. Discovery of the true peroxy intermediate in the catalytic cycle of terminal oxidases by real-time measurement. J Biol Chem. 2007 Sep 28;282(39):28514-9. doi: 10.1074/jbc.M705562200. Epub 2007 , Aug 9. PMID:17690093 doi:http://dx.doi.org/10.1074/jbc.M705562200
  5. Giuffre A, Borisov VB, Arese M, Sarti P, Forte E. Cytochrome bd oxidase and bacterial tolerance to oxidative and nitrosative stress. Biochim Biophys Acta. 2014 Jul;1837(7):1178-87. doi:, 10.1016/j.bbabio.2014.01.016. Epub 2014 Jan 31. PMID:24486503 doi:http://dx.doi.org/10.1016/j.bbabio.2014.01.016
  6. 6.00 6.01 6.02 6.03 6.04 6.05 6.06 6.07 6.08 6.09 6.10 6.11 Thesseling A, Rasmussen T, Burschel S, Wohlwend D, Kagi J, Muller R, Bottcher B, Friedrich T. Homologous bd oxidases share the same architecture but differ in mechanism. Nat Commun. 2019 Nov 13;10(1):5138. doi: 10.1038/s41467-019-13122-4. PMID:31723136 doi:http://dx.doi.org/10.1038/s41467-019-13122-4
  7. 7.0 7.1 7.2 7.3 7.4 Safarian S, Rajendran C, Muller H, Preu J, Langer JD, Ovchinnikov S, Hirose T, Kusumoto T, Sakamoto J, Michel H. Structure of a bd oxidase indicates similar mechanisms for membrane-integrated oxygen reductases. Science. 2016 Apr 29;352(6285):583-6. doi: 10.1126/science.aaf2477. PMID:27126043 doi:http://dx.doi.org/10.1126/science.aaf2477
  8. Moosa A, Lamprecht DA, Arora K, Barry CE 3rd, Boshoff HIM, Ioerger TR, Steyn AJC, Mizrahi V, Warner DF. Susceptibility of Mycobacterium tuberculosis Cytochrome bd Oxidase Mutants to Compounds Targeting the Terminal Respiratory Oxidase, Cytochrome c. Antimicrob Agents Chemother. 2017 Sep 22;61(10). pii: AAC.01338-17. doi:, 10.1128/AAC.01338-17. Print 2017 Oct. PMID:28760899 doi:http://dx.doi.org/10.1128/AAC.01338-17
  9. 9.0 9.1 Hughes ER, Winter MG, Duerkop BA, Spiga L, Furtado de Carvalho T, Zhu W, Gillis CC, Buttner L, Smoot MP, Behrendt CL, Cherry S, Santos RL, Hooper LV, Winter SE. Microbial Respiration and Formate Oxidation as Metabolic Signatures of Inflammation-Associated Dysbiosis. Cell Host Microbe. 2017 Feb 8;21(2):208-219. doi: 10.1016/j.chom.2017.01.005. PMID:28182951 doi:http://dx.doi.org/10.1016/j.chom.2017.01.005
  10. 10.0 10.1 Shepherd M, Achard ME, Idris A, Totsika M, Phan MD, Peters KM, Sarkar S, Ribeiro CA, Holyoake LV, Ladakis D, Ulett GC, Sweet MJ, Poole RK, McEwan AG, Schembri MA. The cytochrome bd-I respiratory oxidase augments survival of multidrug-resistant Escherichia coli during infection. Sci Rep. 2016 Oct 21;6:35285. doi: 10.1038/srep35285. PMID:27767067 doi:http://dx.doi.org/10.1038/srep35285
  11. 11.0 11.1 Arora K, Ochoa-Montano B, Tsang PS, Blundell TL, Dawes SS, Mizrahi V, Bayliss T, Mackenzie CJ, Cleghorn LA, Ray PC, Wyatt PG, Uh E, Lee J, Barry CE 3rd, Boshoff HI. Respiratory flexibility in response to inhibition of cytochrome C oxidase in Mycobacterium tuberculosis. Antimicrob Agents Chemother. 2014 Nov;58(11):6962-5. doi: 10.1128/AAC.03486-14., Epub 2014 Aug 25. PMID:25155596 doi:http://dx.doi.org/10.1128/AAC.03486-14
  12. Galvan AE, Chalon MC, Rios Colombo NS, Schurig-Briccio LA, Sosa-Padilla B, Gennis RB, Bellomio A. Microcin J25 inhibits ubiquinol oxidase activity of purified cytochrome bd-I from Escherichia coli. Biochimie. 2019 May;160:141-147. doi: 10.1016/j.biochi.2019.02.007. Epub 2019 Feb, 19. PMID:30790617 doi:http://dx.doi.org/10.1016/j.biochi.2019.02.007
  13. Lu P, Heineke MH, Koul A, Andries K, Cook GM, Lill H, van Spanning R, Bald D. The cytochrome bd-type quinol oxidase is important for survival of Mycobacterium smegmatis under peroxide and antibiotic-induced stress. Sci Rep. 2015 May 27;5:10333. doi: 10.1038/srep10333. PMID:26015371 doi:http://dx.doi.org/10.1038/srep10333

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