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| {{STRUCTURE_2wch| PDB=2wch | SIZE=400| SCENE= |right|CAPTION=Silk moth odorant binding protein complex with sex pheromone and Mg+2 ions [[2wch]] }}
| | <Structure load='2wch' size='350' frame='true' align='right' caption='Silk moth odorant binding protein complex with sex pheromone and Mg+2 ions [[2wch]] ' scene='' /> |
| | Updated on {{REVISIONDAY2}}-{{MONTHNAME|{{REVISIONMONTH}}}}-{{REVISIONYEAR}} |
| | {{#tree:id=OrganizedByTopic|openlevels=0| |
| | *Odorant binding protein |
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| | **[[4run]] – OBP 2A - human<br /> |
| | **[[2hlv]] – bOBP (mutant) - bovine<br /> |
| | **[[1obp]] – bOBP<br /> |
| | **[[1a3y]], [[1hqp]] – pOBP – pig<br /> |
| | **[[5ngh]] – OBP – giant panda<br /> |
| | **[[8aeh]] – dOBP - dog<br /> |
| | **[[3fiq]] - rOBP 1 - rat<br /> |
| | **[[3zq3]] – rOBP 3<br /> |
| | **[[1ooi]] – DmGOBP LUSH – ''Drosophila melanogaster''<br /> |
| | **[[2qdi]] – DmGOBP LUSH (mutant) <br /> |
| | **[[6hhe]] – DmGOBP 9A<br /> |
| | **[[6qq4]] – DmGOBP 28A<br /> |
| | **[[2erb]], [[3l47]], [[3l4a]], [[3pm2]], [[3r1o]], [[3r1p]], [[3pji]], [[8bxu]], [[8c68]], [[8c6e]], [[8c6g]] – AmmOBP – African malaria mosquito<br /> |
| | **[[3k1e]], [[5v13]], [[6og0]] - ymOBP – yellowfever mosquito<br /> |
| | **[[2wc5]], [[2wck]] – smGOBP – silk moth<br /> |
| | **[[3s0a]], [[3s0f]] – hbOBP – honey bee<br /> |
| | **[[3s0g]] – hbOBP (mutant) <br /> |
| | **[[4pt1]] – OBP D1 - locust<br /> |
| | **[[4z39]] – OBP (mutant) – vetch aphid<br /> |
| | **[[4z45]] – OBP – lettuce aphid<br /> |
| | **[[5dic]] – OBP – blowfly<br /> |
| | **[[6jpm]] – OBP 4 – green lacewing<br /> |
| | **[[7nyj]], [[7nza]] – OBP 1 – mite<br /> |
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| '''Odorant binding protein''' (OBP) are soluble proteins secreted in the nasal mucus of animals and the sensillar lymph of insects.
| | *Odorant binding protein complex with odorants |
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| '''''Bovine Odorant Binding Protein'''''
| | **[[1pbo]] – bOBP + azoselenium derivative <br /> |
| ---- | | **[[1hn2]], [[1g85]], [[1gt1]], [[1gt3]], [[1gt4]], [[1gt5]] - bOBP + odorant<br /> |
| [[Image:1GT1.jpg|300px|right|thumb| Crystal structure of Bovine Odorant Binding Protein]] [[Image:cow.jpg|300px|right|thumb| Cow]] | | **[[1dzj]], [[1dzk]], [[1dzm]], [[1dzp]], [[1e00]], [[1e02]], [[1e06]] - pOBP + odorant<br /> |
| Imagine a world without smells: no fresh cookies, no Valentine’s Day roses, and no stinky gym socks. The sense of smell clearly plays a unique role in how humans and other organisms experience their environment. Unlike the physical objects we see and touch, scents travel invisibly through the air, enter our nose, and elicit a sensory perception. The transduction for this sensory mechanism is crucial in eliciting neuronal activity to stimulate the brain and register that you "stopped and smelled the roses." Before transduction starts, however, select smell molecules, called odorants, must cross a water mucosa layer to reach an extracellular receptor. In bovines, this feat is performed by '''Bovine Odorant Binding Protein (bOBP)''', a small homodimeric protein composed of two β-barrels that utilize a hydrophobic ‘trap’ to transport and release odorants at cellular receptors.
| | **[[8aei]], [[8aej]] – dOBP + odorant <br /> |
| | **[[1oof]], [[1oog]], [[1ooh]] – DmOBP LUSH + alcohol <br /> |
| | **[[3b6x]], [[3b7a]], [[3b86]], [[3b87]], [[3b88]] – DmOBP LUSH (mutant) + alcohol <br /> |
| | **[[2gte]] – DmOBP LUSH + pheromone <br /> |
| | **[[1tuj]] – hbOBP ASP2 + trimethylsilyl propionate – NMR<BR /> |
| | **[[3rzs]], [[3s0d]], [[3s0e]] - hbOBP + odorant<br /> |
| | **[[3s0b]] – hbOBP + fluorescent probe<br /> |
| | **[[2wc6]], [[2wch]], [[2wcj]], [[2wcl]], [[2wcm]] – smGPBP + sex pheromone<br /> |
| | **[[3ogn]] – hmOBP + pheromone – house mosquito<br /> |
| | **[[2l2c]] - hmOBP + pheromone – NMR<BR /> |
| | **[[3l4l]], [[3qme]], [[3q8i]], [[3r1v]], [[8bxv]], [[8bxw]] – AmmOBP + odorant<br /> |
| | **[[3n7h]] – AmmOBP + DEET<br /> |
| | **[[5el2]] – OBP + icaridin – anopheles<br /> |
| | **[[6p2e]], [[6otl]] – ymOBP + benzaldehyde<br /> |
| | **[[6nbn]], [[6oii]] – ymOBP + arachidonic acid<br /> |
| | **[[6ogh]], [[6opb]] – ymOBP + linoleic acid<br /> |
| | **[[6omw]] – ymOBP + palmitoleic acid<br /> |
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| =='''Background'''==
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| ===''Odorants''===
| | [[Category:Topic Page]] |
| To understand the importance of bOBP, an introduction to smell-inducing agents, called odorants, is necessary. Essentially, odorants are chemicals. Anything you smell is a small molecule that travels through the air and reaches your nose. Thus, odorant recognition is a chemosensory mechanism. Besides enriching our daily lives, smells and chemical sensory mechanisms play are important: whether its a yeast cell recognizing a mating factor or a human identifying a gas leak, being able to locate and interpet chemicals is a way for an organism to adapt to their environment. For humans, the definition of an odorant is vague: any small, [http://en.wikipedia.org/wiki/Volatile_organic_compound volatile] compound that can reach the nose and elicit a sensory response is technically an odorant<ref name="one">PMID: 8070277</ref>. Despite the ambiguous formal definition, odorants share many chemical characteristics. They have similar molecular weights, usually falling in the range of 200-400 g/mol<ref name="two">PMID: 11058764</ref>. They also tend to be organic and uncharged; charged species are generally odorless, and polar compounds are weaker odorants, meaning more hydrophobic molecules are better odorants. Interestingly, these trends reverse in water-bound organisms; fish sense water soluble compounds instead<ref name="one" />. Because of the different environments, chemical transportation in air and water is very different, and subsequently the efficiently transported chemicals have opposite characteristics. Air-based odorants utilize a variety of chemistries, including [http://en.wikipedia.org/wiki/Terpenoid terpenoids], [http://en.wikipedia.org/wiki/Ester esters], [http://en.wikipedia.org/wiki/Aldehydes aldehydes], [http://en.wikipedia.org/wiki/Aromatic aromatics], [http://en.wikipedia.org/wiki/Muscone musks], and jasmines<ref name="three">PMID: 2318850</ref>, as well as [http://en.wikipedia.org/wiki/Pyrazine pyrazines], [http://en.wikipedia.org/wiki/Menthol menthol]], [http://en.wikipedia.org/wiki/Thymol thymols], and aliphatic alcohols. Although many classes of organic compounds elicit sensory responses, their relative strengths differ; odorant strength has been classically measured as the lowest perceivable concentration sensed by a statistically significant sample of the human population<ref name="one" />.
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| ===''Odorant Transduction and Transportation''===
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| [[Image:Odorants.jpg|300px|left|thumb| Odorant Receptor Pathway]]
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| Odorants are recognized by odorant receptors linked to a G-protein, G<sub>olf</sub>. As is common with [http://en.wikipedia.org/wiki/G_protein-coupled_receptor G protein-coupled receptors], an activated receptor causes the α-subunit of the G<sub>olf</sub> to displace GDP for GTP. With GTP bound, the α-subunit is activated and stimulates an adenylyl cyclase to form cAMP from ATP. Subsequent IP<sub>3</sub> release triggers Ca<sup>2+</sup> liberation, inducing membrane depolarization, action potentials, and direct neuronal stimuli to the brain<ref name="one" /><ref name="three" />. Odorant receptors are incredibly specific for their respective odorants, with hundreds of receptor genes encoded by humans alone<ref name="one" />.
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| Before odorants can reach receptors, they must pass through the nasal mucosa layer. This water layer abounds with hundreds of proteins that potentially interact with the odorant, creating a dangerous barrier for volatile organics to cross<ref name="one" /><ref name="two" /><ref name="four">PMID: 8836103</ref>. Also, because the layer is water, a thermodynamically unfavorable barrier is imposed on the organic, aliphatic odorants: without polar groups, most odorants do not dissolve in water. Fortunately, bOBP counteracts these problems. Odorant binding proteins (OBPs) carry nonspecific odorant molecules to and from receptor proteins<ref name="one" /><ref name="three" /><ref name="four" /> safely through the water layer. In contrast to receptors, most mammals with OBPs have just one single protein to carry out this function. OBPs are initially secreted in high millimolar concentrations by tubular-acinar glands underlining the nasal respiratory epithelium<ref name="one" />, and are a prevalent protein in most mammals. Bovines are particularly well-characterized, and research on bOBP form the research base of OBPs<ref name="two" />. Humans, however, have significantly lower secreted concentrations compared to other mammals.
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| ===''History''===
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| Heavy research into odorants, smell signal transduction, and OBPs began in the 1970s when organic chemists, with financial backing from perfume and food industries, found relationships between chemical structure and odor perception. At a similar time, medical conditions known as anosmias (blindness to particular odors), as well as continued interest from the perfume industry to maximize odorant recognition understanding, sparked biochemical interest, leading to identification of G<sub>olf</sub>, olfactory receptor genes, and OBPs. Through advancements in [http://en.wikipedia.org/wiki/Chemotaxis chemotaxis] understanding, olfaction was finally defined as chemical communication<ref name="one" />. Much work remains: although OBP structures are well-understood, their function is not (see below). Similarly, few receptor proteins have been crystallized, and their structural affinity for odorants and relationship to OBPs is poorly defined.
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| =='''Structure'''==
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| <Structure load='1pbo' size='400' frame='true' align='right' caption='Bovine OBP complex with odorant [[1pbo]]' scene='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Homodimer/1'/>
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| ===''Basic Structural Parameters''===
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| bOBP is a 159 residue <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Homodimer/1'>homodimer</scene>, with monomers respectively labeled blue and green, of noncovalently bound, virtually identical monomeric subunits<ref name="one" /><ref name="five">PMID: 8901871</ref>. Monomers are synthesized by cell independently, but their assembly process is not well understood. The most significant difference between the two monomers arises at the <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/C-termini/2'>C-termini</scene>; the terminal amino acids 151-159, shown in red, form a short α-helix in one subunit and a disordered tail in the other. Although electron densities at the N-termini of each subunit also differ, the underlying structural chemistry is currently unexplained<ref name="four" />. Other than the aforementioned minor differences, subunits are identical. The total protein itself is small, weighing a mere 19 kDa<ref name="one" />. Each monomeric subunit consists of eight <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Monomer/1'> eight β-sheets, followed by an α-helix, ending in one final β-sheet</scene><ref name="one" /><ref name="four" /><ref name="five" />, with the illustration showing the protein in a progressive reverse [http://en.wikipedia.org/wiki/Color_spectrum color spectrum] (BGYOR), with the N-terminus as blue and the C-terminus as red. The β-sheets loop tightly to form a [http://en.wikipedia.org/wiki/Beta_barrel β barrel].
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| ===''β Barrel Active Sites''===
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| The β barrels merit further description. Traditionally, a barrel served as an isolated ‘holding cell’ for an odorant. Inside the safety of the barrel shape, the odorant is protected from harsh proteins in the nasal mucosa, as well as from unfavorable interactions with water. Because most odorants are [http://en.wikipedia.org/wiki/Hydrophobic hydrophobic], the two β barrels’ active sites primarily contain <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Beta_barrel/7'>hydrophobic residues</scene> to create a favorable containment environment. As the model shows, the majority of inner surface is aliphatic (grey), with limited polar surface areas (purple). These [http://en.wikipedia.org/wiki/Amino_acid amino acid] residues include <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Beta_barrel/6'>seven aromatic</scene> (sky blue), <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Beta_barrel/4'>seven aliphatic</scene> (purple), and <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Beta_barrel/5'>four semi-polar</scene> (blue) residues <ref name="four" />: Ile 22, Phe 36, Thr 38, Phe 40, Phe 54, Phe 56, Val 69, Ala 81, Tyr 83, Asn 87, Phe 89, Ile 99, Ala 101, Asn 103, Leu 115, and Phe 119. The last two amino acids, Thr 116 and Gly 117, use main chain amino groups to form hydrogen bonds with the rare semi-polar odorant. The high fraction of aromatic amino acids allows for “smooth inner walls” that are somewhat flexible and facilitate broad odorant affinity<ref name="five" />. The subsequent space inside each barrel has a volume of approximately 480 Å<sup>3</sup><ref name="three" />.
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| ===''Domain Swapping''===
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| The linkages between monomers play crucial roles in forming completed barrels. Each <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Domain/3'>β barrel</scene> consists of amino acid residues 15-121 from one monomer (red), which form eight antiparallel β-sheet strands, and residues 145-149 of the second monomer (green), which form the ninth beta sheet required to complete the barrel<ref name="four" />. Monomer residues 123-139 (with 126-139 forming an α-helix) <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Homodimer/3'>form the bulk</scene> of the linking bridge between the two monomers<ref name="two" />, as illustrated by the orange molecular surface. The final β-sheet of each monomer completes the β barrel of its complementary monomer. This technique is called domain swapping, in which “a swapped domain in a protein oligomer is a globular domain (or sometimes one or a few elements of secondary structure) that is intertwined with an identical protein chain, with the swapped domain having an environment essentially identical to that of the same domain in a protein monomer." This characteristic is allowed by the notable lack of any cysteine residues in bOBP: without cysteines, constraining disulfide bonds do not form and the linking α-helix can snake to its sister monomer’s β barrel to complete the fold<ref name="four" />.
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| Because of domain swapping, an evaluation of vocabulary is needed: <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Monomer/2'>“monomer”</scene> refers to the 1-159 residues of a single unit, whereas <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Domain/4'>“domain”</scene> refers to residues 1-123 (green) of the first monomer and residues 124-159 of the second monomer (blue)<ref name="five" />. Domain swapping plays a crucial role in regulation. First, by requiring the two monomers to come together to complete a domain, a change in the chemical environment (i.e., a pH change) could prevent the domain swapping and provide a simple regulatory mechanism<ref name="four" />. This has been confirmed experimentally, in which negatively charged <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Homodimer/4'> Glu 125, Asp 126, Glu 127, and Asp 128</scene> residues (in CPK coloring) of the linking area are titrated at low pH and cause the dimer to dissociate by forming a turn. Second, the connection between the two monomers is a source of negative cooperativity, in which conformational changes in the first domain prevent odorants from binding in the second domain. The entire protein is held together by domain swapping, which utilizes strong noncovalent interactions from the hydrophobic effect; 78% of the ninth β-sheet’s water accessible surface is buried after incorporation into the β barrel<ref name="five" />.
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| ===''Other Functional Motifs''===
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| In addition to the β barrel domains, several other residues have important functions. Residues 57-66 noticeably protrude, likely to aid in receptor recognition. One of the most notable residues is <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Phe89/2'>Phe 89</scene> (pink). Phe 89, a flexible residue that can freely rotate<ref name="five" />, may serve as a door for allowing odorants in or out of the β barrel. Note the <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Phe89/1'>hole</scene> on the protein's surface where the pink Phe 89 peaks through, implying it acts as a gatekeeper. The residue can rotate approximately 120 degrees around the χ1 bond to prevent clashes with odorants<ref name="two" />. Phe 89 has been implicated in the negative cooperativity relationship between each domain, in which internal changes caused by odorant binding to the first domain prevent the second domain from binding a second odorant<ref name="six">PMID: 15373829</ref>.
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| =='''Physical Properties'''==
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| ===''Binding Capabilities''===
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| Since the odorant binding domains have malleable positions, odorants bind with a wide range of dissociation constants, K<sub>d</sub>. Large, hydrophilic, and unsaturated compounds bind poorly to bOBP, a property consistent with those of strong odorants previously described<ref name="three" />. Spherical shaped molecules also bind poorly<ref name="one" />. From an evolution standpoint, OBPs do not bind “pleasant” or “unpleasant” smelling odorants preferentially; however, non-odorous compounds typically do not bind to OBPs<ref name="three" />, implying OBPs may factor prominently into determining whether a molecule qualifies as an odorant. Certain chemical motifs do appear to have lower K<sub>d</sub> values (stronger binding) than others. Pyrazines, thiazoles, terpenoids, menthols, thymols, aliphatic alcohols, and aldehydes have lower K<sub>d</sub> values than round terpenoids, camphors, and polar compounds (like fatty acids)<ref name="two" />. Despite the wide range of dissociation constants, most K<sub>d</sub> values of bOBP are relatively high, often in the micromolar range.
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| ===''Kinetics''===
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| bOBP kinetics studies have scrutinized the once-popular two-site hypothesis where one binding site had high odorant affinity, and the second had low affinity. Although partly true, the currently accepted hypothesis focuses on negative cooperativity: binding one odorant decreases the likelihood of binding a second odorant<ref name="three" />. Overall, odorant dissociation is fast; this could be advantageous for unloading odorants quickly to interact with receptors and avoid time lapse between odor perception and the chemical signal itself<ref name="seven">PMID: 20932975</ref>.
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| Because of the odorant sensitivity to pH, the dimer monomerizes at pH 4.5, and the protein as a whole has an isoelectric point of pH 4.7<ref name="four" />.
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| =='''Functions'''==
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| <Structure load='1hn2' size='200' frame='true' align='right' caption='Bovine OBP complex with insect attractant [[1hn2]]' scene='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Ligand/1' />
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| ===''Chemical Function''===
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| The exact function of bOBP is not well defined. Although OBP primarily transports hydrophobic odorants across the hydrophilic nasal mucosa, this may not be its only role. The first alternative role tributes bOBP with regulating the concentrations odorant concentrations through buffering capabilities<ref name="three" />. With high K<sub>d</sub> values, bOBP can trap odorants more efficiently at high concentration and subsequently narrow the wide range of possible stimuli intensities<ref name="one" /><ref name="two" />. A second theory expands on bOBPs transporter role, claiming it may mediate odorant signal transduction by interacting with the odorant receptor as an odorant-OBP complex<ref name="one" />.
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| ===''Evolutionary Roles''===
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| Other possible roles of bOBP garner an evolutionarily competitive edge. The ability of bOBP to bind broad molecular classes could have aided the sequestration of cytotoxic or genotoxic compounds for removal or purification<ref name="two" />. Another particularly interesting hypothesis investigates the <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Ligand/1'>natural bOBP ligand</scene>, 1-octen-3-ol. Cows secrete this volatile chemical in their breath following stressors like inflammation, temperature, pollutants, or biological parasites. Interestingly, insects utilize 1-octen-3-ol to locate hosts. A possible evolutionary mechanism for bOBP could be binding 1-octen-3-ol to prevent excess insect bites<ref name="eight">PMID: 11114310</ref>.
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| =='''Functional Relatives'''==
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| <Structure load='2hlv' size='300' frame='true' align='left' caption='Bovine Mutant OBP, [[2hlv]]' scene='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Mutant/1' />
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| ===''Mutants''===
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| To assess domain swapping capabilities, a <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Mutant/1'>mutant monomer</scene> was engineered with a <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Mutant/2'>glycine</scene> inserted after position 121. This position was deemed valuable so that negatively charged residues in positions 125-128 could chemically <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Mutant/3'>"turn" backwards</scene> on itself more easily, a crucial event in preventing dimerization. Trp64Cys and His155Cys mutations were also induced to address the importance of <scene name='User:Michael_Kerins/Bovine_Odorant_Binding_Protein/Mutant/4'>disulfide bonds </scene> in stabilizing the engineered monomer. With these additions, domain swapping was reversed and the ninth β-sheet inserted itself into the monomer’s own β barrel domain. The peptidyl backbones of these residues were superimposable on native bOBP with exception to the backwards ‘hinge’ area and ten final residues at the C-terminus. Through Kd measurements, the mutant bound all tested odorants comparably to the swapped dimer<ref name="nine">PMID: 18269920</ref>.
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| ===''Protein Relationships''===
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| In addition to mutants, bOBP shares some characteristics with other proteins. Notable chemical relatives include mouse urinary protein (MUP). This protein, found in kidneys, shares a similar structure, but does not utilize domain swapping for stability<ref name="five" />. Many analogous carrier proteins also exist. Most of these proteins are lipocalins, including serum retinol-binding protein and β-lactoglobulin.
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| When comparing bOBP to other OBPs, a striking sequence difference is discovered: often, less than 20% of the sequence is completely conserved from one OBP to another. bOBP appears to be particularly unique; most lipocalins and other OBPs have cysteines and the associated disulfide bonds, whereas bOBP has neither. In fact, of the four sequences common to almost every OBP, bOBP contains only two: GxW and Yxx-x-YxG<ref name="two" />. In a class of proteins with already limited conservation, bOBP remains notable.
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| =='''Summary'''==
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| Bovine odorant binding protein is a small homodimeric protein found in the nasal mucosa of cows; it has numerous possible functions, including odorant buffering, cellular transduction, insect repellant, and its most important function: odorant transport across the nasal mucosa for delivery to the receptor. bOBP is required for transport because common odorants are traditionally hydrophobic and thus repelled by the hydrophilic layer. To accomplish its many tasks, it binds odorants in a hydrophobic β barrel motif.
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| =='''3D structures of odorant binding protein'''==
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| [[1a3y]], [[1hqp]] – pOBP – pig<br />
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| [[1ooi]] – DmGOBP LUSH – Drosophila melanogaster<br />
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| [[2qdi]] – DmGOBP LUSH (mutant)<br />
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| [[2erb]], [[3l47]], [[3l4a]], [[3pm2]], [[3r1o]], [[3r1p]], [[3pji]] – AmmOBP – African malaria mosquito<br />
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| [[3k1e]] - OBP – yellowfever mosquito<br />
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| [[2wc5]], [[2wck]] – smGOBP – silk moth<br />
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| [[3s0a]], [[3s0f]] – hbOBP – honey bee<br />
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| [[3s0g]] – hbOBP (mutant)<br />
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| [[2hlv]] – bOBP (mutant) - bovine<br />
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| [[3fiq]] - OBP - rat
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| ===Odorant binding protein complex with odorants===
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| [[1pbo]] – OBP + azoselenium derivative <br />
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| [[1oof]], [[1oog]], [[1ooh]] – DmOBP LUSH + alcohol <br />
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| [[3b6x]], [[3b7a]], [[3b86]], [[3b87]], [[3b88]] – DmOBP LUSH (mutant) + alcohol <br />
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| [[2gte]] – DmOBP LUSH + pheromone <br />
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| [[1tuj]] – hbOBP ASP2 + trimethylsilyl propionate – NMR<br />
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| [[3rzs]], [[3s0d]], [[3s0e]] - hbOBP + odorant<br />
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| [[1dzj]], [[1dzk]], [[1dzm]], [[1dzp]], [[1e00]], [[1e02]], [[1e06]] - pOBP + odorant<br />
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| [[1hn2]], [[1g85]], [[1gt1]], [[1gt3]], [[1gt4]], [[1gt5]] - bOBP + odorant<br />
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| [[3s0b]] – hbOBP + fluorescent probe<br />
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| [[2wc6]], [[2wch]], [[2wcj]], [[2wcl]], [[2wcm]] – smGPBP + sex pheromone<br />
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| [[3ogn]] – hmOBP + pheromone – house mosquito<br />
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| [[2l2c]] - hmOBP + pheromone – NMR<br /> | |
| [[3l4l]], [[3qme]], [[3q8i]], [[3r1v]] – AmmOBP + odorant<br />
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| [[3n7h]] – AmmOBP + DEET
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| =='''References'''==
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| <references />
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| *Articles 1 and 2 are review articles
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| =='''Contributors'''==
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| Michael Kerins
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| Special thanks to [http://proteopedia.org/wiki/index.php/User:David_L._Nelson Professor David Nelson] and [http://proteopedia.org/wiki/index.php/User:Michael_Patrick Professor Michael Patrick] for their research guidance and technical expertise in putting these pages together.
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| ------------------------------------------------------------------------------------------------------------------------------
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