Structure of Aart, a designed six-finger zinc finger peptide, bound to DNA

Cys2-His2 zinc fingers are one of the most common types of DNA-binding domains. Modifications to zinc-finger binding specificity have recently enabled custom DNA-binding proteins to be designed to a wide array of target sequences. We present here a 1.96 A structure of Aart, a designed six-zinc finger protein, bound to a consensus DNA target site. This is the first structure of a designed protein with six fingers, and was intended to provide insights into the unusual affinity and specificity characteristics of this protein. Most protein-DNA contacts were found to be consistent with expectations, while others were unanticipated or insufficient to explain specificity. Several were unexpectedly mediated by glycerol, water molecules or amino acid-base stacking interactions. These results challenge some conventional concepts of recognition, particularly the finding that triplets containing 5'A, C, or T are typically not specified by direct interaction with the amino acid in position 6 of the recognition helix.     

Zinc is required for folding and binding of a single zinc finger to DNA

A synthetic peptide corresponding to zinc finger 31 of the Xenopus protein Xfin adopts a folded conformation in the presence of zinc. The same peptide in the absence of zinc is not folded in a stable tertiary conformation, as determined by NMR. Binding experiments have shown that the peptide binds non-specifically to DNA only in the presence of zinc. Moreover, competitive DNA binding experiments indicate interaction with 3.9 +/- 0.4 base pairs.     

Specific DNA binding to a major histocompatibility complex enhancer sequence by a synthetic 57-residue double zinc finger peptide from a human enhancer binding protein

Two 57-residue peptides containing one pair of "zinc fingers" from a human enhancer binding protein were prepared by solid-phase peptide synthesis. One peptide (MBP-DF) contained the native sequence, while the second peptide ([Abu11]MBP-DF) has an alpha-aminobutyric acid residue substituted for a nonconserved cysteine residue at position 11. The peptides were characterized by several chemical and physical methods, and their DNA binding properties were evaluated using gel retardation experiments. Spectroscopic studies demonstrated that addition of metal ions such as zinc and cobalt resulted in specific conformational changes in both peptides, indicating that cysteine-11 does not appear to be involved in metal chelation. One-dimensional 1H NMR studies indicate that a stable folded structure is formed upon addition of zinc, and the chemical shift pattern is consistent with that previously observed for one constituent single finger (Omichinski, J., Clore, G. M., Appella, E., Sakaguchi, K., and Gronenborn, A. M. (1990) Biochemistry 29, 9324-9334). Gel retardation experiments demonstrate that the peptides are capable of interacting with a 15-mer oligonucleotide comprising a portion of the major histocompatibility complex enhancer sequence and that the interaction is zinc-dependent. The dissociation constant for the [Abu11]MBP-DF peptide is 1.4 x 10(-7) M with maximal binding occurring at a zinc-to-peptide ratio of 2 to 1. The binding specificity observed with respect to related enhancer sequences exhibits the same relative order as noted previously for the whole protein. Studies with point mutants of the major histocompatibility complex enhancer binding sequence indicate that the last GC base pair in a four-guanine stretch plays a pivotal role in the interaction between the peptide and DNA.     

Looking into DNA recognition: zinc finger binding specificity

We present a quantitative, theoretical analysis of the recognition mechanisms used by two zinc finger proteins: Zif268, which selectively binds to GC-rich sequences, and a Zif268 mutant, which binds to a TATA box site. This analysis is based on a recently developed method (ADAPT), which allows binding specificity to be analyzed via the calculation of complexation energies for all possible DNA target sequences. The results obtained with the zinc finger proteins show that, although both mainly select their targets using direct, pairwise protein–DNA interactions, they also use sequence-dependent DNA deformation to enhance their selectivity. A new extension of our methodology enables us to determine the quantitative contribution of these two components and also to measure the contributions of individual residues to overall specificity. The results show that indirect recognition is particularly important in the case of the TATA box binding mutant, accounting for 30% of the total selectivity. The residue-by-residue analysis of the protein–DNA interaction energy indicates that the existence of amino acid–base contacts does not necessarily imply sequence selectivity, and that side chains without contacts can nevertheless contribute to defining the protein's target sequence.     

DNA binding properties of the vitamin D3 receptor zinc finger region.

The DNA binding domains of the nuclear receptor superfamily are highly conserved and consist of residues that fold into two zinc finger-like motifs, suggesting that the structures of this region among the members of the superfamily are likely to be very similar. Furthermore, the response elements that these receptors bind to are similar in sequence and organization. Nevertheless, these receptors selectively recognize target response elements and differentially regulate linked genes. In order to study the details of receptor:DNA binding, we have overexpressed and purified the vitamin D3 receptor DNA binding domain (VDRF) and have begun characterizing its DNA binding properties. We find that the VDRF protein binds strongly and specifically to direct repeats constituting a vitamin D response element from the mouse osteopontin (Spp-1) promoter region but weakly to the human osteocalcin vitamin D response element. Unlike receptors that recognize hormone response elements oriented as inverted repeats, such as the glucocorticoid receptor (GR) and estrogen receptor, VDRF appears to bind half-sites noncooperatively, without the free energy contribution of dimerization seen when the glucocorticoid receptor DNA binding domain associates with a glucocorticoid response element. By comparing and contrasting the DNA binding properties of the vitamin D and glucocorticoid receptors, we suggest a model for how receptors that prefer direct repeats differ in their binding strategy from those that recognize inverted repeats.     

Role of the DNA ligase III zinc finger in polynucleotide binding and ligation.

Mammalian DNA ligase III exists as two distinct isoforms denoted alpha and beta. Both forms possess a motif that is homologous to the putative zinc finger present in poly(ADP-ribose) polymerase. Here, the role of this motif in the binding and ligation of nicked DNA and RNA substrates in vitro has been examined in both isoforms. Disruption of the putative zinc finger did not affect DNA ligase III activity on nicked DNA duplex, nor did it abolish DNA ligase III-alpha activity during DNA base excision repair in a cell-free assay. In contrast, disruption of this motif reduced 3-fold the activity of both DNA ligase III isoforms on nicked RNA present in RNA/DNA homopolymers. Furthermore, whereas disruption of the motif did not prevent binding of DNA ligase III to nicked DNA duplex, binding to nicked RNA homopolymers was reduced approximately 10-fold. These results suggest that the putative zinc finger does not stimulate DNA ligase III activity on simple nicked DNA substrates, but indicate that this motif can target the binding and activity of DNA ligase III to nicked RNA homopolymer. The implications of these results to the cellular role of the putative zinc finger are discussed.     

The DNA ligase III zinc finger stimulates binding to DNA secondary structure and promotes end joining

The ability to rejoin broken chromosomes is fundamental to the maintenance of genetic integrity. Mammalian cells possess at least five DNA ligases, including three isoforms of DNA ligase III (Lig-3). Lig-3 proteins differ from other DNA ligases in the presence of an N-terminal zinc finger (Zn-f) motif that exhibits extensive homology with two zinc fingers in poly(ADP-ribose) polymerase (PARP). Here we report that the Zn-f confers upon Lig-3 the ability to bind DNA duplexes harbouring a variety of DNA secondary structures, including single-strand gaps and single-strand flaps. Moreover, the Zn-f stimulates intermolecular end joining of duplexes that harbour these structures up to 16-fold. The Zn-f also stimulates end joining between duplexes lacking secondary structure, but to a lesser extent (up to 4-fold). We conclude that the Zn-f may enable Lig-3 to rejoin chromosomal DNA strand breaks located at sites of clustered damage induced by ionising radiation or near to secondary structure intermediates of DNA metabolism.     

Structure of a designed dimeric zinc finger protein bound to DNA

Proteins that employ dimerization domains to bind cooperatively to DNA have a number of potential advantages over monomers with regards to gene regulation. Using a combination of structure-based design and phage display, a dimeric Cys(2)His(2) zinc finger protein has been created that binds cooperatively to DNA via an attached leucine zipper dimerization domain. This chimera, derived from components of Zif268 and GCN4, displayed excellent DNA-binding specificity, and we now report the 1.5 A resolution cocrystal structure of the Zif268-GCN4 homodimer bound to DNA. This structure shows how phage display has annealed the DNA binding and dimerization domains into a single functional unit. Moreover, this chimera provides a potential platform for the creation heterodimeric zinc finger proteins that can regulate a desired target gene through cooperative DNA recognition.     

Kin17, a mouse nuclear zinc finger protein that binds preferentially to curved DNA.

Kin17 is a 45 kDa protein encoded by the KIN17 gene located on mouse chromosome 2, band A. The kin17 amino acid sequence predicts two domains, which were shown to be functional: (i) a bipartite nuclear localization signal (NLS) that can drive the protein to the cell nucleus, (ii) a bona fide zinc finger of the C2H2 type. The zinc finger is involved in kin17 binding to double-stranded DNA since a mutant deleted of the zinc finger, kin17 delta 1, showed reduced binding. Single-stranded DNA was bound poorly by kin17. Interestingly, we found that kin17 protein showed preferential binding to curved DNA from either pBR322 or synthetic oligonucleotides. Binding of kin17 to a non-curved DNA segment increased after we had inserted into it a short curved synthetic oligonucleotide. Kin17 delta 2, a mutant deleted of 110 amino acids at the C-terminal end, still exhibited preferential binding to curved DNA and so did kin17 delta 1, suggesting that a domain recognizing curved DNA is located in the protein core.     

Alpha-helical linker of an artificial 6-zinc finger peptide contributes to selective DNA binding to a discontinuous recognition sequence

Although many zinc finger motifs have been developed to recognize specific DNA triplets, a rational way to selectively skip a particular non-recognized gap in the DNA sequence has never been established. We have now created a 6-zinc finger peptide with an alpha-helix linker, Sp1ZF6(EAAAR)4, which selectively binds to the discontinuous recognition sites in the same phase (10 bp gap) against the opposite phase (5 bp gap) of the DNA helix. The linker peptide (EAAAR)4 forms an alpha-helix structure stabilized by salt bridges, and the helical length is estimated to be about 30 A, corresponding to that of the 10 bp DNA. The gel shift assays demonstrate that Sp1ZF6(EAAAR)4 preferably binds to the 10 bp-gapped target rather than the 5 bp-gapped target. The CD spectra show that the alpha-helical content of the (EAAAR)4 linker is higher in the complex with the 10 bp-gapped target than in the complex with the 5 bp-gapped target. The present results indicate that the alpha-helical linker is suitable for binding to the recognition sites in the same phase and that the linker induces the loss of binding affinity to the recognition sites with the opposite phase. The engineering of a helix-structured linker in the 6-zinc finger peptides should be one of the most promising approaches for selectively targeting discontinuous recognition sites depending on their phase situations.     

Selected peptide extension contacts hydrophobic patch on neighboring zinc finger and mediates dimerization on DNA.

Protein-protein interactions often play a crucial role in stabilizing protein-DNA complexes and thus facilitate site-specific DNA recognition. We have worked to incorporate such protein-protein contacts into our design and selection strategies for short peptide extensions that promote cooperative binding of zinc finger proteins to DNA. We have determined the crystal structure of one of these fusion protein-DNA complexes. The selected peptide extension was found to mediate dimerization by reaching across the dyad axis and contacting a hydrophobic patch on the surface of the zinc finger bound to the adjacent DNA site. The peptide-zinc finger protein interactions observed in this structure are similar to those of some homeodomain heterodimers. We also find that the region of the zinc finger surface contacted by the selected peptide extension corresponds to surfaces that also make key interactions in the zinc finger proteins GLI and SWI5.     

Redox state regulates binding of p53 to sequence-specific DNA, but not to non-specific or mismatched DNA.

Redox modulation of wild-type p53 plays a role in sequence-specific DNA binding in vitro . Reduction produces a DNA-binding form of the protein while oxidation produces a non-DNA-binding form. Primer extension analysis reveals that increasing concentrations of reduced p53 result in enhanced protection of the consensus sequence, while increasing concentrations of oxidized p53 confer minimal protection of the consensus sequence. DNA binding by oxidized p53 is, therefore, not sequence-specific. In contrast, there is no observable difference in the binding of oxidized p53 and reduced p53 to double-stranded non-specific or mismatched DNA in gel mobility shift assays. Both forms of p53 bind equally well, suggesting that redox modulation of p53 does not play a role in its binding to non-specific or mismatched DNA. In view of the in vitro evidence that redox state influences the sequence-specific DNA-binding of p53, we have examined the effect of oxidative stress on the in vivo ability of p53 to bind to and transactivate PG13-CAT, a reporter construct containing multiple copies of the p53 consensus binding site linked to the chloramphenicol acetyltransferase gene. Hydrogen peroxide treatment of cells cotransfected with p53 results in a marked decrease in CAT activity, suggesting that oxidation of p53 decreases the ability of the protein to bind to consensus DNA and transactivate target genes in vivo.