Functional analyses of the Dof domain, a zinc finger DNA-binding domain, in a pumpkin DNA-binding protein AOBP

AOBP, a DNA-binding protein in pumpkin, contains a Dof domain that is composed of 52 amino acid residues and is highly conserved in several DNA-binding proteins of higher plants. The Dof domain has a significant resemblance to Cys2/Cys2 zinc finger DNA-binding domains of steroid hormone receptors and GATA1, but has a longer putative loop where an extra Cys residue is conserved. We show that the Dof domain in AOBP functions as a zinc finger DNA-binding domain and suggest that the Cys residue uniquely conserved in the putative loop might negatively regulate the binding to DNA.     

Preferential oxidation of zinc finger 2 in estrogen receptor DNA-binding domain prevents dimerization and, hence, DNA binding

For approximately one-third of estrogen receptor (ER)-positive breast cancer patients, extracted tumor ER is unable to bind to its cognate DNA estrogen response element (ERE), an effect that is partly reversible by the thiol-reducing agent dithiothreitol (DTT). Full-length (67 kDa) ER or its 11 kDa recombinant DNA-binding domain (ER-DBD) is also susceptible to loss of structure and function by the action of oxidants such as diamide and hydrogen peroxide; however, prior DNA binding by ER or ER-DBD protects against this oxidant induced loss of function. The ER-DBD contains two (Cys)(4)-liganded zinc finger motifs that cooperate to stabilize a rigid DNA-binding recognition helix and a flexible helix-supported dimerization loop, respectively. Comparisons between synthetic peptide analogues of each zinc finger and recombinant ER-DBD in the presence of zinc by electrophoretic mobility shift assay, circular dichroism, and mass spectrometry confirm that cooperativity between these zinc fingers is required for both ER-DBD structure (alpha-helicity) and function (dimeric DNA binding). Rapid proteolytic digestion of monomeric, non-DNA-bound ER-DBD followed by HPLC-MS analysis of the resulting peptides demonstrates that zinc inhibits thiol oxidation of the DNA-binding finger, but not the finger supporting the flexible dimerization loop, which remains sensitive to internal disulfide formation. These findings indicate that the loss of ER DNA-binding function in extracts from some primary breast tumors and in ER or ER-DBD exposed to thiol-reacting oxidants results from this asymmetric zinc finger susceptibility to disulfide formation that prevents dimerization. Although ER-DBD contains several strategically located methionine residues, they are less susceptible to oxidation than the thiol groups and, thus, afford no protection against cysteine oxidation and consequent loss of ER DNA-binding function.     

Combining structure-based design with phage display to create new Cys(2)His(2) zinc finger dimers

BACKGROUND: Several strategies have been reported for the design and selection of novel DNA-binding proteins. Most of these studies have used Cys(2)His(2) zinc finger proteins as a framework, and have focused on constructs that bind DNA in a manner similar to Zif268, with neighboring fingers connected by a canonical (Krüppel-type) linker. This linker does not seem ideal for larger constructs because only modest improvements in affinity are observed when more than three fingers are connected in this manner. Two strategies have been described that allow the productive assembly of more than three canonically linked fingers on a DNA site: connecting sets of fingers using linkers (covalent), or assembling sets of fingers using dimerization domains (non-covalent). RESULTS: Using a combination of structure-based design and phage display, we have developed a new dimerization system for Cys(2)His(2) zinc fingers that allows the assembly of more than three fingers on a desired target site. Zinc finger constructs employing this new dimerization system have high affinity and good specificity for their target sites both in vitro and in vivo. Constructs that recognize an asymmetric binding site as heterodimers can be obtained through substitutions in the zinc finger and dimerization regions. CONCLUSIONS: Our modular zinc finger dimerization system allows more than three Cys(2)His(2) zinc fingers to be productively assembled on a DNA-binding site. Dimerization may offer certain advantages over covalent linkage for the recognition of large DNA sequences. Our results also illustrate the power of combining structure-based design with phage display in a strategy that assimilates the best features of each method.     

植物Dof转录因子及其生物学功能

Dof(DNA binding with one finger)蛋白是植物特有的一类转录因子,包含一个C2-C2锌指,其N-末端保守的Dof结构域是既与DNA又和蛋白相互作用的双重功能域。在过去10多年的研究中,Dof蛋白在多种单子叶和双子叶植物中被分离。Dof蛋白作为转录的激活子或抑制子在植物的生长和发育中发挥重要作用。就Dof转录因子及其生物学功能的进展进行了综述。     

An arginine residue instead of a conserved leucine residue in the recognition helix of the finger 3 of Zif268 stabilizes the domain structure and mediates DNA binding

The Cys(2)His(2)-type zinc finger is a common DNA binding motif that is widely used in the design of artificial zinc finger proteins. In almost all Cys(2)His(2)-type zinc fingers, position 4 of the α-helical DNA-recognition site is occupied by a Leu residue involved in formation of the minimal hydrophobic core. However, the third zinc finger domain of native Zif268 contains an Arg residue instead of the conserved Leu. Our aim in the present study was to clarify the role of this Arg in the formation of a stable domain structure and in DNA binding by substituting it with a Lys, Leu, or Hgn, which have different terminal side-chain structures. Assessed were the metal binding properties, peptide conformations, and DNA-binding abilities of the mutants. All three mutant finger 3 peptides exhibited conformations and thermal stabilities similar to the wild-type peptide. In DNA-binding assays, the Lys mutant bound to target DNA, though its affinity was lower than that of the wild-type peptide. On the other hand, the Leu and Hgn mutants had no ability to bind DNA, despite the similarity in their secondary structures to the wild-type. Our results demonstrate that, as with the Leu residue, the aliphatic carbon side chain of this Arg residue plays a key role in the formation of a stable zinc finger domain, and its terminal guanidinium group appears to be essential for DNA binding mediated through both electrostatic interaction and hydrogen bonding with DNA phosphate backbone.     

Solution structure of a CCHHC domain of neural zinc finger factor-1 and its implications for DNA binding

The structure of a CCHHC zinc-binding domain from neural zinc finger factor-1 (NZF-1) has been determined in solution though the use of NMR methods. This domain is a member of a family of domains that have the Cys-X(4)-Cys-X(4)-His-X(7)-His-X(5)-Cys consensus sequence. The structure determination reveals a novel fold based around a zinc(II) ion coordinated to three Cys residues and the second of the two conserved His residues. The other His residue is stacked between the metal-coordinated His residue and a relatively conserved aromatic residue. Analysis of His to Gln sequence variants reveals that both His residues are required for the formation of a well-defined structure, but neither is required for high-affinity metal binding at a tetrahedral site. The structure suggests that a two-domain protein fragment and a double-stranded DNA binding site may interact with a common two-fold axis relating the two domains and the two half-sites of the DNA-inverted repeat.