Exploring the recognition of quadruplex DNA by an engineered Cys2-His2 zinc finger protein

We have recently described an engineered zinc finger protein (Gq1) that binds with high specificity to the intramolecular G-quadruplex formed by the human telomeric sequence 5'-(GGTTAG)(5)-3', and that inhibits the activity of the enzyme telomerase in vitro. Here we report site-directed mutagenesis, biophysical, and molecular modeling studies that provide new insights into quadruplex recognition by the zinc finger scaffold. We show that any one finger of Gq1 can be replaced with the corresponding finger of Zif268, without significant loss of quadruplex affinity or quadruplex versus duplex discrimination. Replacement of two fingers, with one being finger 2, of Gq1 by Zif268 results in significant impairment of quadruplex recognition and loss of discrimination. Molecular modeling suggests that the zinc fingers of Gq1 can bind to the human parallel-stranded quadruplex structure in a stable arrangement, whereas Zif268-quadruplex models show significantly weaker binding energy. Modeling also suggests that an important role of the key protein finger residues in the Gq1-quadruplex complex is to maintain Gq1 in an optimum conformation for quadruplex recognition.     

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.     

序列特异的三锌指多肽的构建及其在大肠杆菌中的表达

在获得单一锌指突变体的基础上,以小鼠转录因子Zif268的三锌指DNA结合区为模板,利用重叠(Over-lap)PCR技术,获得了关键氨基酸位点同时突变的三锌指突变体ZF123、2ZF123。ZF123、2ZF123分别克隆进pUC-18质粒,序列测定正确后,以pGEX-2T为表达质粒,在大肠杆菌JM109中实现了功能性的表达。经SDS-PAGE分析,表达出了分子量34.0kD的融合蛋白,扫描分析其含量在20%左右。菌体经超声波破碎后,对可溶性融合蛋白进行了纯化得到了游离的目的蛋白,为进一步的DNA结合特性分析、杂交转录因子的构建等奠定了基础。     

Zn finger-based direct detection system for PCR products of <Emphasis Type="Italic">Salmonella</Emphasis> spp. and the Influenza A virus

We have detected PCR products from Salmonella spp. and Influenza A virus using Zn finger protein Zif268 and Sp1, respectively. Previously, we demonstrated a novel method of rapid and specific detection of PCR products from Legionella pneumophila genome using Zn finger protein Sp1. In principle, this methodology might be applied to the detection of most bacteria and viruses using various Zn finger proteins. Here, to demonstrate the wider applicability of our method, we detected PCR products from Salmonella spp. and the Influenza A virus. BLAST data indicated the Zif268 and Sp1 recognition sequence were located on the gyrB gene of Salmonella spp. and the nucleoprotein gene of Influenza A virus, respectively. The PCR products from the oligonucleotide corresponding to the gyrB gene of Salmonella spp. or the nucleoprotein gene of the Influenza A virus could be specifically detected by ELISA or fluorescence depolarization measurement using Zif268 or Sp1. These results indicate the wide applicability of our novel methodology.     

Signatures of Protein-DNA Recognition in Free DNA Binding Sites

One obstacle to achieving complete understanding of the principles underlying sequence-dependent recognition of DNA is the paucity of structural data for DNA recognition sequences in their free (unbound) state. Here, we carried out crystallization screening of 50 DNA duplexes containing cognate protein binding sites and obtained new crystal structures of free DNA binding sites for three distinct modes of DNA recognition: anti-parallel β strands (MetR), helix-turn-helix motif + hinge helices (PurR), and zinc fingers (Zif268). Structural changes between free and protein-bound DNA are manifested differently in each case. The new DNA structures reveal that distinctive sequence-dependent DNA geometry dominates recognition by MetR, protein-induced bending of DNA dictates recognition by PurR, and deformability of DNA along the A-B continuum is important in recognition by Zif268. Together, our findings show that crystal structures of free DNA binding sites provide new information about the nature of protein-DNA interactions and thus lend insights towards a structural code for DNA recognition.     

Zn finger-based direct detection system for PCR products of<Emphasis Type="Italic"> Salmonella</Emphasis> spp. and the Influenza A virus

We have detected PCR products from Salmonella spp. and Influenza A virus using Zn finger protein Zif268 and Sp1, respectively. Previously, we demonstrated a novel method of rapid and specific detection of PCR products from Legionella pneumophila genome using Zn finger protein Sp1. In principle, this methodology might be applied to the detection of most bacteria and viruses using various Zn finger proteins. Here, to demonstrate the wider applicability of our method, we detected PCR products from Salmonella spp. and the Influenza A virus. BLAST data indicated the Zif268 and Sp1 recognition sequence were located on the gyrB gene of Salmonella spp. and the nucleoprotein gene of Influenza A virus, respectively. The PCR products from the oligonucleotide corresponding to the gyrB gene of Salmonella spp. or the nucleoprotein gene of the Influenza A virus could be specifically detected by ELISA or fluorescence depolarization measurement using Zif268 or Sp1. These results indicate the wide applicability of our novel methodology. An erratum to this article can be found at     

Binding studies with mutants of Zif268. Contribution of individual side chains to binding affinity and specificity in the Zif268 zinc finger-DNA complex.

The Zif268 zinc finger-DNA complex has served as a model system for understanding how Cys2His2 type zinc fingers recognize DNA. Structural studies of the Zif268-DNA complex revealed that residues at four positions in the alpha helix of each zinc finger play key roles in recognition, but there has been no information about the precise contributions of individual residues. Here we report the results of binding studies involving five mutants of Zif268 that have changes in the base-contacting residues of finger one. These studies let us evaluate the contributions that Arg18 (position -1 of the alpha helix), Asp20 (position 2), Glu21 (position 3), and Arg24 (position 6) make to the overall energy of DNA binding. Our results confirm the important role played by these arginines. By comparing the affinities of the wild type and mutant peptides for various sites, we also prove that Asp20 and Glu21 play important roles in determining binding site specificity.     

Disrupting reconsolidation of drug memories reduces cocaine-seeking behavior

Maladaptive memories that associate environmental stimuli with the effects of drugs of abuse are known to be a major cause of relapse to, and persistence of, a drug addictive habit. However, memories may be disrupted after their acquisition and consolidation by impairing their reconsolidation. Here, we show that infusion of Zif268 antisense oligodeoxynucleotides into the basolateral amygdala, prior to the reactivation of a well-learned memory for a conditioned stimulus (CS)-cocaine association, abolishes the acquired conditioned reinforcing properties of the drug-associated stimulus and thus its impact on the learning of a new cocaine-seeking response. Furthermore, we show that reconsolidation of CS-fear memories also requires Zif268 in the amygdala. These results demonstrate that appetitive CS-drug memories undergo reconsolidation in a manner similar to aversive memories and that this amygdala-dependent reconsolidation can be disrupted to reduce the impact of drug cues on drug seeking.     

Hsmar1 Transposition Is Sensitive to the Topology of the Transposon Donor and the Target

Hsmar1 is a member of the Tc1-mariner superfamily of DNA transposons. These elements mobilize within the genome of their host by a cut-and-paste mechanism. We have exploited the in vitro reaction provided by Hsmar1 to investigate the effect of DNA supercoiling on transposon integration. We found that the topology of both the transposon and the target affect integration. Relaxed transposons have an integration defect that can be partially restored in the presence of elevated levels of negatively supercoiled target DNA. Negatively supercoiled DNA is a better target than nicked or positively supercoiled DNA, suggesting that underwinding of the DNA helix promotes target interactions. Like other Tc1-mariner elements, Hsmar1 integrates into 5′-TA dinucleotides. The direct vicinity of the target TA provides little sequence specificity for target interactions. However, transposition within a plasmid substrate was not random and some TA dinucleotides were targeted preferentially. The distribution of intramolecular target sites was not affected by DNA topology.     

Analysis of DNA and Zinc finger interactions using mechanical force spectroscopy

The unbinding force of Zif268-DNA complex has been studied by atomic force microscopy (AFM). DNA and Zif268 were covalently immobilized on the surfaces of an AFM tip and glass substrate, respectively. Confocal microscopy was used to confirm the successful immobilization of DNA. Because of the complexity of the protein-DNA interaction, parallel experiments were designed to discriminate specific interactions. For such experiments, a typical unbinding force of a single Zif268-DNA complex (approx 550 pN at 40 nN/s force loading rate) was evaluated.