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<StructureSection load='3TGN' size='350' side='right' caption='3TGN' scene='' /> | <StructureSection load='3TGN' size='350' side='right' caption='3TGN' scene='' /> | ||
== '''Zinc-Dependent Transcriptional Regulator AdcR''' == | == '''Zinc-Dependent Transcriptional Regulator AdcR''' == | ||
===Introduction=== | ===Introduction=== | ||
AdcR is a zinc-dependent transcriptional regulator that controls the activation of over seventy genes within the bacteria [https://en.wikipedia.org/wiki/Streptococcus_pneumoniae''Streptococcus pneumoniae'']<ref>DOI:10.1093/nar/gku1304 </ref>. Zinc plays a vital role in organism homeostasis acting as a [https://en.wikipedia.org/wiki/Cofactor_(biochemistry) co-factor] and a regulator of enzymatic activity, however zinc can lead to cell toxicity and deficiency of other vital metals that are also necessary for protein function<ref> Fraústo da Silva J, Williams R. The Biological Chemistry of Elements: The Inorganic Chemistry of Life. Second ed. Oxford University Press; Oxford: 2001.</ref><ref> DOI: 10.1021/cr900077w</ref>. Given the importance of zinc in general homeostasis the vital role of AdcR in ''Streptococcus pneumoniae'' can be understood given its ability to regulate zinc transfer proteins within the bacteria. | AdcR is a zinc-dependent transcriptional regulator that controls the activation of over seventy genes within the bacteria [https://en.wikipedia.org/wiki/Streptococcus_pneumoniae''Streptococcus pneumoniae'']<ref>DOI:10.1093/nar/gku1304 </ref>. Zinc plays a vital role in organism homeostasis acting as a [https://en.wikipedia.org/wiki/Cofactor_(biochemistry) co-factor] and a regulator of enzymatic activity, however zinc can lead to cell toxicity and deficiency of other vital metals that are also necessary for protein function<ref> Fraústo da Silva J, Williams R. The Biological Chemistry of Elements: The Inorganic Chemistry of Life. Second ed. Oxford University Press; Oxford: 2001.</ref><ref> DOI: 10.1021/cr900077w</ref>. Given the importance of zinc in general homeostasis the vital role of AdcR in ''Streptococcus pneumoniae'' can be understood given its ability to regulate zinc transfer proteins within the bacteria. | ||
[[Image:Image1.jpg | 300 px|left|thumb| Members of the MarR protein family conserve a number of features including a general triangular shape, a two fold pseudosymmetric homo dimer, and a wingled helix-turn-helix pattern. Proteins 3BPX, 2FBK, 3KP5, and 2PFB (members of the MarR family) are pictured above.]] | [[Image:Image1.jpg | 300 px|left|thumb| Members of the MarR protein family conserve a number of features including a general triangular shape, a two fold pseudosymmetric homo dimer, and a wingled helix-turn-helix pattern. Proteins 3BPX, 2FBK, 3KP5, and 2PFB (members of the MarR family) are pictured above.]] | ||
Consistent with AdcR's identity as a member of the MarR protein family, AdcR exhibits a triangular shape consisting of a two fold pseudosymetric homo dimer with its own unique winged helix-turn-helix [https://en.wikipedia.org/wiki/Helix-turn-helix (wHTH)] binding domain. This structure calls for multiple zinc binding sites that facilitate protein conformational change allowing for DNA binding and regulation through the wHTH domain. | Consistent with AdcR's identity as a member of the MarR protein family, AdcR exhibits a triangular shape consisting of a two fold pseudosymetric homo dimer with its own unique winged helix-turn-helix [https://en.wikipedia.org/wiki/Helix-turn-helix (wHTH)] binding domain. This structure calls for multiple zinc binding sites that facilitate protein conformational change allowing for DNA binding and regulation through the wHTH domain. | ||
== '''Zn(II) Binding''' == | == '''Zn(II) Binding''' == | ||
Zinc-Dependent Transcriptional Regulator AdcR has <scene name='69/694230/Two_binding_sites/1'>two binding sites</scene> on each of its two protomers and can bind a total of four Zn(II) per dimer. <scene name='69/694230/Dimerization_domain/1'>The dimerization domain</scene> is made up of the <font color='blue'>alpha helix 1</font>, <font color='gold'>alpha helix 5</font>, and the <font color='orange'>alpha helix 6</font>. This domain is connected to the HTH winged domain with the long <font color='gold'>alpha helix 5</font>. This dimerization domain connects to the DNA binding domain and together with the <font color='blue'>alpha 1</font> <font color='turquoise'>alpha 2</font> loop make up the <scene name='69/694230/Alpha_1_alpha_2/1'>metal binding sites</scene><ref>PMID:22085181</ref>. Each protomer has one high affinity site (KZn1 = 10^12 M; pH 8) and one low affinity binding site (KZn2 = 10^7 M; pH 8). The metal binding pockets of the AdcR MarR transcriptional regulator are made up of the DNA binding domain with the extended alpha 1 and alpha 2 loop. The two different Zn(II) binding sites are connected via hydrogen bonding of the Nd1 atom of H108 and then liganding Oe1 atom of E41. | Zinc-Dependent Transcriptional Regulator AdcR has <scene name='69/694230/Two_binding_sites/1'>two binding sites</scene> on each of its two protomers and can bind a total of four Zn(II) per dimer. <scene name='69/694230/Dimerization_domain/1'>The dimerization domain</scene> is made up of the <font color='blue'>alpha helix 1</font>, <font color='gold'>alpha helix 5</font>, and the <font color='orange'>alpha helix 6</font>. This domain is connected to the HTH winged domain with the long <font color='gold'>alpha helix 5</font>. This dimerization domain connects to the DNA binding domain and together with the <font color='blue'>alpha 1</font> <font color='turquoise'>alpha 2</font> loop make up the <scene name='69/694230/Alpha_1_alpha_2/1'>metal binding sites</scene><ref>PMID:22085181</ref>. Each protomer has one high affinity site (KZn1 = 10^12 M; pH 8) and one low affinity binding site (KZn2 = 10^7 M; pH 8). The metal binding pockets of the AdcR MarR transcriptional regulator are made up of the DNA binding domain with the extended alpha 1 and alpha 2 loop. The two different Zn(II) binding sites are connected via hydrogen bonding of the Nd1 atom of H108 and then liganding Oe1 atom of E41. | ||
=== Binding Site 1 === | === Binding Site 1 === | ||
<scene name='69/694230/Binding_site_1/1'>Binding site 1</scene> consists of a distorted tetrahedral geometry around Zn(II). The four amino acids involved in zinc binding are E24 Oe1, H42 Nd1, H108 Ne2, and H112 Ne2. Binding site 1 is the only binding site that plays a significant role in the protein's regulatory function. The ability of binding site 1 to coordinate to the Zn(II) ion is pH dependent. At pH 6 the binding affinity for the Zn(II) ion is 10^9 - 10^10 M^-1, but at pH 8 the binding affinity increases to 10^12 M^-1. This is due to the charges on the histidines of the binding site. At pH 8, the histidines are positively charged and can interact with the negatively charged Zn(II) ion. However, at pH 6 the histidines are neutrally charged and will not coordinate as well with Zn(II). | <scene name='69/694230/Binding_site_1/1'>Binding site 1</scene> consists of a distorted tetrahedral geometry around Zn(II). The four amino acids involved in zinc binding are E24 Oe1, H42 Nd1, H108 Ne2, and H112 Ne2. Binding site 1 is the only binding site that plays a significant role in the protein's regulatory function. The ability of binding site 1 to coordinate to the Zn(II) ion is pH dependent. At pH 6 the binding affinity for the Zn(II) ion is 10^9 - 10^10 M^-1, but at pH 8 the binding affinity increases to 10^12 M^-1. This is due to the charges on the histidines of the binding site. At pH 8, the histidines are positively charged and can interact with the negatively charged Zn(II) ion. However, at pH 6 the histidines are neutrally charged and will not coordinate as well with Zn(II). | ||
=== Binding Site 2 === | === Binding Site 2 === | ||
<scene name='69/694230/Binding_site_2/1'>Binding site 2</scene> consists of a highly distorted tetrahedral geometry around the zinc ion. There are three amino acids involved in the binding of the zinc ion (C30, E41, and E107) as well as a water molecule. If a C30A AdcR missense is present in binding site 2, it will have no effect on the ability of the protein to bind DNA. Therefore, binding site 2 has no significant role in DNA binding. | <scene name='69/694230/Binding_site_2/1'>Binding site 2</scene> consists of a highly distorted tetrahedral geometry around the zinc ion. There are three amino acids involved in the binding of the zinc ion (C30, E41, and E107) as well as a water molecule. If a C30A AdcR missense is present in binding site 2, it will have no effect on the ability of the protein to bind DNA. Therefore, binding site 2 has no significant role in DNA binding. | ||
== '''Other Ligands''' == | == '''Other Ligands''' == | ||
The AdcR MarR transcriptional regulator is able to bind Co(II) in binding site 1 in a way that induces similar conformational changes to Zn(II) binding. Co(II) coordination in binding site 1 is able to allosterically activate DNA binding similarly to Zn(II) binding. | The AdcR MarR transcriptional regulator is able to bind Co(II) in binding site 1 in a way that induces similar conformational changes to Zn(II) binding. Co(II) coordination in binding site 1 is able to allosterically activate DNA binding similarly to Zn(II) binding. | ||
== '''DNA Binding''' == | == '''DNA Binding''' == | ||
=== Hydrogen Bond Network === | === Hydrogen Bond Network === | ||
[[Image:H Bonding of DNA.png|300 px|left|thumb|The Hydrogen Bonding Network is shown with dotted green lines approximately 2.8 angstroms between residues. The network consists of 4 major residues as follows from right to left: E24, N38, Q40, S74. ]] | [[Image:H Bonding of DNA.png|300 px|left|thumb|The Hydrogen Bonding Network is shown with dotted green lines approximately 2.8 angstroms between residues. The network consists of 4 major residues as follows from right to left: E24, N38, Q40, S74. ]] | ||
The binding of Zinc allows for the conformational change that induces the binding of DNA in order to activate genes. The binding of Zinc metals creates a hydrogen bond network within the protein that connects the metal binding sites and the [https://en.wikipedia.org/wiki/DNA-binding_domain DNA binding domain]. Most importantly, the hydrogen bonding network connects the metal binding pockets to the alpha 4 helix. Alpha 4 helix plays a crucial role in binding DNA because it acts as the recognition helix. The specific sequence of DNA that is recognized by alpha helix 4 is unknown at the moment; however, scientists believe that the hydrogen bond network acts as an allosteric activator for the protein to bind DNA. The hydrogen bond network connects the alpha 2 and alpha 4 helix via hydrogen bonding between specific residues. After zinc is bound, a glutamate (<font color='blue'>E24</font>) residue from a random coil accepts a hydrogen bond from the carboxamide end of an asparagine (<font color='green'>N38</font>) residue from the alpha 2 helix. Then, a glutamine (<font color='gold'>Q40</font>) residue from alpha 2 helix accepts a hydrogen bond from a serine (<font color='red'>S74</font>) residue from the alpha 4 helix. The color coding in the previous sentence represents the <scene name='69/694230/Hydrogen_bonding_1/1'>Hydrogen Bonding Network</scene>, which is seen across the MarR family as a whole. Now the protein is ready to bind DNA. | The binding of Zinc allows for the conformational change that induces the binding of DNA in order to activate genes. The binding of Zinc metals creates a hydrogen bond network within the protein that connects the metal binding sites and the [https://en.wikipedia.org/wiki/DNA-binding_domain DNA binding domain]. Most importantly, the hydrogen bonding network connects the metal binding pockets to the alpha 4 helix. Alpha 4 helix plays a crucial role in binding DNA because it acts as the recognition helix. The specific sequence of DNA that is recognized by alpha helix 4 is unknown at the moment; however, scientists believe that the hydrogen bond network acts as an allosteric activator for the protein to bind DNA. The hydrogen bond network connects the alpha 2 and alpha 4 helix via hydrogen bonding between specific residues. After zinc is bound, a glutamate (<font color='blue'>E24</font>) residue from a random coil accepts a hydrogen bond from the carboxamide end of an asparagine (<font color='green'>N38</font>) residue from the alpha 2 helix. Then, a glutamine (<font color='gold'>Q40</font>) residue from alpha 2 helix accepts a hydrogen bond from a serine (<font color='red'>S74</font>) residue from the alpha 4 helix. The color coding in the previous sentence represents the <scene name='69/694230/Hydrogen_bonding_1/1'>Hydrogen Bonding Network</scene>, which is seen across the MarR family as a whole. Now the protein is ready to bind DNA. | ||
[[Image:Charge_map.jpg |300 px|right|thumb| A charge map of AdcR shows the general triangular shape and the positive charged (blue) area on HTH domains]] | [[Image:Charge_map.jpg |300 px|right|thumb| A charge map of AdcR shows the general triangular shape and the positive charged (blue) area on HTH domains]] | ||
=== Helix-Turn-Helix Domain === | === Helix-Turn-Helix Domain === | ||
The AdcR MarR transcriptional regulator's structure resembles the other proteins in the same family as mentioned before; however, the most notable differences are found in the winged helix-turn-helix (wHTH) motif that assists in binding DNA. Although AdcR is a highly alpha helical protein, the "wings" of the DNA binding domain consist of two anti parallel beta strands that are made up of several positively charged residues such as Arg. The major groove of DNA is bound to the recognition helix while the wings grip onto the minor grooves. The charge map on the right highlights the <font color='blue'>positively</font> charged areas, which stabilize the negatively charged backbone of the major and minor grooves of DNA. There is one on each domain of the protein. | The AdcR MarR transcriptional regulator's structure resembles the other proteins in the same family as mentioned before; however, the most notable differences are found in the winged helix-turn-helix (wHTH) motif that assists in binding DNA. Although AdcR is a highly alpha helical protein, the "wings" of the DNA binding domain consist of two anti parallel beta strands that are made up of several positively charged residues such as Arg. The major groove of DNA is bound to the recognition helix while the wings grip onto the minor grooves. The charge map on the right highlights the <font color='blue'>positively</font> charged areas, which stabilize the negatively charged backbone of the major and minor grooves of DNA. There is one on each domain of the protein. | ||
The <scene name='69/694230/Whth/1'>wHTH</scene> domain is made up of the alpha 2 and alpha 4 helices along with anti-parallel beta sheets on each side. These structures can been seen in the java applet as all green structures in the rainbow scheme for clarity purposes. Only one monomer is shown. The recognition helix, or the alpha 4 helix, binds the major groove of DNA through hydrogen bonding and Van der Waals interactions between exposed bases. The wings of the helix bind the minor groove of DNA while the other helices stabilize the DNA and Protein upon binding. The two anti parallel beta sheets contain several Arginine residues and other positive amino acids that stabilize this interaction between DNA. | |||
The <scene name='69/694230/Whth/1'>wHTH</scene> domain is made up of the alpha 2 and alpha 4 helices along with anti-parallel beta sheets on each side. These structures can been seen in the java applet as all green structures in the rainbow scheme for clarity purposes. Only one monomer is shown. The recognition helix, or the alpha 4 helix, binds the major groove of DNA through hydrogen bonding and Van der Waals interactions between exposed bases. The wings of the helix bind the minor groove of DNA while the other helices stabilize the DNA and Protein upon binding. The two anti parallel beta sheets contain several Arginine residues and other positive amino acids that stabilize this interaction between DNA. | |||
</StructureSection> | </StructureSection> | ||