Exchange of histidine spacing between Sp1 and GLI zinc fingers: distinct effect of histidine spacing-linker region on DNA binding

In the DNA recognition mode of C(2)H(2)-type zinc fingers, the finger-finger connection region, consisting of the histidine spacing (HX(3-5)H) and linker, would be important for determining the orientation of the zinc finger domains. To clarify the influence of spacing between two ligand histidines in the DNA binding, we exchanged the histidine spacing between Sp1 and GLI zinc fingers, which have an HX(3)H-TGEKK linker (typical) and an HX(4)H-SNEKP linker (atypical), respectively. A significant decrease in the DNA binding affinity and specificity is found in Sp1-type peptides, whereas GLI-type peptides show a mild reduction. To evaluate the effect of the linker characteristics, we further designed Sp1-type mutants with an SNEKP linker. As a result, the significant effect of the histidine spacing in Sp1-type peptides was reduced. These results demonstrate that (1) the histidine spacing significantly affects the DNA binding of zinc finger proteins and (2) the histidine spacing and the following linker regions are one effective target for regulating the DNA recognition mode of zinc finger proteins.     

Effects of DNA binding of the zinc finger and linkers for domain fusion on the catalytic activity of sequence-specific chimeric recombinases determined by a facile fluorescent system

Artificial zinc finger proteins (ZFPs) consist of Cys(2)-His(2)-type modules composed of ～30 amino acids with a ββα structure that coordinates a zinc ion. ZFPs that recognize specific DNA target sequences can substitute for the binding domains of enzymes that act on DNA to create designer enzymes with programmable sequence specificity. The most studied of these engineered enzymes are zinc finger nucleases (ZFNs). ZFNs have been widely used to model organisms and are currently in human clinical trials with an aim of therapeutic gene editing. Difficulties with ZFNs arise from unpredictable mutations caused by nonhomologous end joining and off-target DNA cleavage and mutagenesis. A more recent strategy that aims to address the shortcomings of ZFNs involves zinc finger recombinases (ZFRs). A thorough understanding of ZFRs and methods for their modification promises powerful new tools for gene manipulation in model organisms as well as in gene therapy. In an effort to design efficient and specific ZFRs, the effects of the DNA binding affinity of the zinc finger domains and the linker sequence between ZFPs and recombinase catalytic domains have been assessed. A plasmid system containing ZFR target sites was constructed for evaluation of catalytic activities of ZFRs with variable linker lengths and numbers of zinc finger modules. Recombination efficiencies were evaluated by restriction enzyme analysis of isolated plasmids after reaction in Escherichia coli and changes in EGFP fluorescence in mammalian cells. The results provide information relevant to the design of ZFRs that will be useful for sequence-specific genome modification.     

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.     

Multiconnection of identical zinc finger: implication for DNA binding affinity and unit modulation of the three zinc finger domain

Cys(2)-His(2)-type zinc finger proteins have a tandemly repeated array structure consisting of independent finger modules. They are expected to elevate the DNA binding affinity and specificity by increasing the number of finger modules. To investigate the relation between the number and the DNA binding affinity of the zinc finger, we have designed the two- to four-finger peptides by connecting the central zinc finger (finger 2) of Sp1 with the canonical linker sequence, Thr-Gly-Glu-Lys-Pro. Gel mobility shift assays reveal that the cognate three- and four-finger peptides, Sp1(zf222) and Sp1(zf2222), strongly bind to the predicted target sequences, but the two-finger peptide, Sp1(zf22), does not. Of special interest is the fact that the dissociation constant for Sp1(zf2222) binding to the target DNA is comparable to that for Sp1(zf222). The methylation interference, DNase I and hydroxyl radical footprintings, and circular permutation analyses demonstrate that Sp1(zf2222) binds to its target site with three successive zinc fingers and the binding of the fourth zinc finger is inhibited by DNA bending induced by the binding of the three-finger domain. The present results strongly indicate that the zinc finger protein binds to DNA by the three-finger domain as one binding unit. In addition, this information provides the basis for the design of a novel multifinger protein with high affinity and specificity for long DNA sequences, such as chromosomal DNAs.     

锌指蛋白的核酸识别特异性研究进展

锌指蛋白是最大的DNA结合蛋白,它能和DNA进行特异性识别,是研究蛋白—DNA相互作用的理想对象。改变锌指元件上的几个保守的氨基酸位点可设计筛选出序列特异的全新锌指蛋白,计算机在锌指蛋白设计方面的应用,使得全新的锌指蛋白识别特异性明显增强。这在基因治疗等方面,具有广阔的应用前景。     

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.     

DNA-Binding ability of GAGA zinc finger depends on the nature of amino acids present in the beta-hairpin

The GAGA factor of Drosophila melanogaster uses a single Cys2-His2-type zinc finger for specific DNA binding. Comparative sequence alignment of the GAGA zinc finger core with other structurally characterized zinc fingers reveals that the beta-hairpin of the GAGA zinc finger prefers amino acids with an aliphatic side-chain different from those of other zinc fingers. To probe the substitution effect of aromatic amino acids in the beta-hairpin on the DNA binding, three mutant peptides were designed by substituting consensus phenylalanine, an aromatic amino acid, at key positions in the beta-hairpin region. The metal-binding and the overall fold of the mutant peptides are very similar to those of the wild-type as shown by UV-vis absorption spectroscopy and circular dichroism spectroscopy. However, the gel mobility shift assay and isothermal calorimetric studies demonstrated that none of the mutants are able to bind the cognate DNA substrate, although the mutation is confined only to the beta-hairpin region. The present results suggest that the nature of the amino acids in the beta-hairpin plays an important role in the DNA-binding of the GAGA factor protein.     

A novel DNA-binding motif abuts the zinc finger domain of insect nuclear hormone receptor FTZ-F1 and mouse embryonal long terminal repeat-binding protein.

Fruit fly FTZ-F1, silkworm BmFTZ-F1, and mouse embryonal long terminal repeat-binding protein are members of the nuclear hormone receptor superfamily, which recognizes the same sequence, 5'-PyCAAGGPyCPu-3'. Among these proteins, a 30-amino-acid basic region abutting the C-terminal end of the zinc finger motif, designated the FTZ-F1 box, is conserved. Gel mobility shift competition by various mutant peptides of the DNA-binding region revealed that the FTZ-F1 box as well as the zinc finger motif is involved in the high-affinity binding of FTZ-F1 to its target site. Using a gel mobility shift matrix competition assay, we demonstrated that the FTZ-F1 box governs the recognition of the first three bases, while the zinc finger region recognizes the remaining part of the binding sequence. We also showed that the DNA-binding region of FTZ-F1 recognizes and binds to DNA as a monomer. Occurrence of the FTZ-F1 box sequence in other members of the nuclear hormone receptor superfamily raises the possibility that these receptors constitute a unique subfamily which binds to DNA as a monomer.     

DNA-induced alpha-helix capping in conserved linker sequences is a determinant of binding affinity in Cys(2)-His(2) zinc fingers

High-affinity, sequence-specific DNA binding by Cys(2)-His(2) zinc finger proteins is mediated by both specific protein-base interactions and non-specific contacts between charged side-chains and the phosphate backbone. In addition, in DNA complexes of multiple zinc fingers, protein-protein interactions between the finger units contribute to the binding affinity. We present NMR evidence for another contribution to high- affinity binding, a highly specific DNA-induced helix capping involving residues in the linker sequence between fingers. Capping at the C terminus of the alpha-helix in each zinc finger, incorporating a consensus TGEKP linker sequence that follows each finger, provides substantial binding energy to the DNA complexes of zinc fingers 1-3 of TFIIIA (zf1-3) and the four zinc fingers of the Wilms' tumor suppressor protein (wt1-4). The same alpha-helix C-capping motif is observed in the X-ray structures of four other protein-DNA complexes. The structures of each of the TGEKP linkers in these complexes can be superimposed on the linker sequences in the zf1-3 complex, revealing a remarkable similarity in both backbone and side-chain conformations. The canonical linker structures from the zinc-finger-DNA complexes have been compared to the NMR structure of the TGEKP linker connecting fingers 1 and 2 in zf1-3 in the absence of DNA. This comparison reveals that additional stabilization likely arises in the DNA complexes from hydrogen bonding between the backbone amide of E3 and the side-chain O(gamma) of T1 in the linker. We suggest that these DNA-induced C-capping interactions provide a means whereby the multiple-finger complex, which must necessarily be domain-flexible in the unbound state as it searches for the correct DNA sequence, can be "snap-locked" in place once the correct DNA sequence is encountered. These observations provide a rationale for the high conservation of the TGEKP linker sequences in Cys(2)-His(2) zinc finger proteins.     

Evaluation of a modular strategy for the construction of novel polydactyl zinc finger DNA-binding proteins

In previous studies, we have developed a technology for the rapid construction of novel DNA-binding proteins with the potential to recognize any unique site in a given genome. This technology relies on the modular assembly of modified zinc finger DNA-binding domains, each of which recognizes a three bp subsite of DNA. A complete set of 64 domains would provide comprehensive recognition of any desired DNA sequence, and new proteins could be assembled by any laboratory in a matter of hours. However, a critical parameter for this approach is the extent to which each domain functions as an independent, modular unit, without influence or dependence on its neighboring domains. We therefore examined the detailed binding behavior of several modularly assembled polydactyl zinc finger proteins. We first demonstrated that 80 modularly assembled 3-finger proteins can recognize their DNA target with very high specificity using a multitarget ELISA-based specificity assay. A more detailed analysis of DNA binding specificity for eight 3-finger proteins and two 6-finger proteins was performed using a target site selection assay. Results showed that the specificity of these proteins was as good or better than that of zinc finger proteins constructed using methods that allow for interdependency. In some cases, near perfect specificity was achieved. Complications due to target site overlap were found to be restricted to only one particular amino acid interaction (involving an aspartate in position 2 of the alpha-helix) that occurs in a minority of cases. As this is the first report of target site selection for designed, well characterized 6-finger proteins, unique insights are discussed concerning the relationship of protein length and specificity. These results have important implications for the design of proteins that can recognize extended DNA sequences, as well as provide insights into the general rules of recognition for naturally occurring zinc finger proteins.     

Arsenite interacts selectively with zinc finger proteins containing C3H1 or C4 motifs

Arsenic inhibits DNA repair and enhances the genotoxicity of DNA-damaging agents such as benzo[a]pyrene and ultraviolet radiation. Arsenic interaction with DNA repair proteins containing functional zinc finger motifs is one proposed mechanism to account for these observations. Here, we report that arsenite binds to both CCHC DNA-binding zinc fingers of the DNA repair protein PARP-1 (poly(ADP-ribose) polymerase-1). Furthermore, trivalent arsenite coordinated with all three cysteine residues as demonstrated by MS/MS. MALDI-TOF-MS analysis of peptides harboring site-directed substitutions of cysteine with histidine residues within the PARP-1 zinc finger revealed that arsenite bound to peptides containing three or four cysteine residues, but not to peptides with two cysteines, demonstrating arsenite binding selectivity. This finding was not unique to PARP-1; arsenite did not bind to a peptide representing the CCHH zinc finger of the DNA repair protein aprataxin, but did bind to an aprataxin peptide mutated to a CCHC zinc finger. To investigate the impact of arsenite on PARP-1 zinc finger function, we measured the zinc content and DNA-binding capacity of PARP-1 immunoprecipitated from arsenite-exposed cells. PARP-1 zinc content and DNA binding were decreased by 76 and 80%, respectively, compared with protein isolated from untreated cells. We observed comparable decreases in zinc content for XPA (xeroderma pigmentosum group A) protein (CCCC zinc finger), but not SP-1 (specificity protein-1) or aprataxin (CCHH zinc finger). These findings demonstrate that PARP-1 is a direct molecular target of arsenite and that arsenite interacts selectively with zinc finger motifs containing three or more cysteine residues.     

Rational design of DNA sequence-specific zinc fingers

We developed a rational scheme for designing DNA binding proteins. The scheme was applied for a zinc finger protein and the designed sequences were experimentally characterized with high DNA sequence specificity. Starting with the backbone of a known finger structure, we initially calculated amino acid sequences compatible with the expected structure and the secondary structures of the designed fingers were then experimentally confirmed. The DNA-binding function was added to the designed finger by reconsidering a section of the amino acid sequence and computationally selecting amino acids to have the lowest protein-DNA interaction energy for the target DNA sequences. Among the designed proteins, one had a gap between the lowest and second lowest protein-DNA interaction energies that was sufficient to give DNA sequence-specificity.