Sandbox Reserved 1053: Difference between revisions

18177-18182.</ref>. The Czr operon contains genes for the proteins Czr A and [http://proteopedia.org/wiki/index.php/3byr Czr B]. Czr B is a Zinc transport protein which moves Zn²⁺ out of a cell while Czr A regulates this process by controlling expression level of Czr B. When relatively low amounts of zinc are present in the cell Czr A will bind to DNA, preventing the progression of RNA polymerase and thus inhibiting expression of Czr B. Decreased expression of Czr B results in the ability of the cell to retain Zn²⁺ more readily. Because Czr A and Czr B are transcribed as part of the same operon, an inhibitor of Czr A must be readily available to allow full transcription of Czr B when necessary. Czr A is noncompetitively inhibited by the binding of two Zn²⁺ ions, which is ideal in that this allows for expression of Czr B, a Zn²⁺ transporter to be dependent on the relative amount of Zn²⁺ in the cell.  Czr A displays two different conformations; the first typically binds DNA and has relatively low affinity for Zn²⁺, in this conformation the <scene name='69/694220/A5_helices__dna_binding/1'>a5 helices are open</scene>. The <scene name='69/694220/A5_helices_dna_binding/1'>a5 helices swing down</scene> to achieve the other conformation which binds two Zn²⁺ ions and has relatively low affinity for DNA.   

The <scene name='69/694219/Serandhisresidues/2'>main DNA interactions</scene> have been found to occur at the Ser 54 and 57 along with His 58 residues. These residues are likely to interact with the 5'-TGAA sequence found in the half-site of the DNA. These residues are found in the N terminal of the R helix. The residues involved in the <scene name='69/694219/Dna_binding_pocket/1'>DNA binding pocket</scene> are Val 42 and Gln 53. This was experimentally determined by mutating the Gln and Val with Ala residues and measuring the binding capacity; In a previously published article <ref name="critical"/>, the DNA bound state of CzrA was tested by using the known critical residues for DNA interactions. Critical residues, Gln53, Val42, Ser54, Ser57, and His58, were replaced with Ala and then compared to the kinetics of the wild type protein. Replacing only the Q53 and V42 residues resulted in an 11-fold and 160-fold decrease in K_a, respectively. Other residues such as S54, S57, and H58 were also replaced with Ala residues, and it was found that these mutations caused binding similar to the fully inhibited Zn²⁺ bound state. Table 1 in this same article shows the different K_observed, and the measured decrease in K_observed for each mutation. The bind between the DNA and the protein can be attributed to losing certain intermolecular forces such as possible hydrogen bonding when changing from Gln and Ala, and a loss of London Dispersion forces in the Val to Ala change.

Many zinc-dependent proteins are transcriptional regulators<ref>DOI: 10.1128/MMBR.00015-06</ref>. CzrA fits into this category as an [https://en.wikipedia.org/wiki/Allosteric_regulation allosteric inhibitor] of the czr operon. Two [https://en.wikipedia.org/wiki/Zinc Zn⁺²] ions may bind to the dimer<ref name="critical"/>, at the location of the <scene name='69/694218/Alpha_5_helices/2'> alpha 5 </scene> helix from each monomer. As zinc binds, the alpha 5 helices <scene name='69/694218/2kjc_zinc_bound/1'>swing down</scene> to inhibit the DNA binding residues. Furthermore, CzrA must be in its dimer form for zinc to bind. The <scene name='69/694218/Spacefill_with_zinc_pockets/1'>zinc binding pocket</scene> is formed by two residues from each monomer, so Zn⁺² cannot bind to the monomer. The <scene name='69/694218/Zinc_residues/1'>zinc binding site</scene> is formed by Asp84 and His86 from one monomer, and His97 and His100 from the other monomer. Histidines are a repetitive and commonly found residue in zinc-binding proteins <ref>Miller J, McLachlan AD, Klug A. Repetitive zinc-binding domains in the protein transcription factor IIIA from Xenopus oocytes. EMBO J. 1985 Jun 4;4(6):1609-1614.</ref>.