A zinc finger directory for high-affinity DNA recognition

Unleashing the potential: type I CRISPR-Cas systems in actinomycetes for genome editing

Covering: up to the end of 2023Type I CRISPR-Cas systems are widely distributed, found in over 40% of bacteria and 80% of archaea. Among genome-sequenced actinomycetes (particularly Streptomyces spp.), 45.54% possess type I CRISPR-Cas systems. In comparison to widely used CRISPR systems like Cas9 or Cas12a, these endogenous CRISPR-Cas systems have significant advantages, including better compatibility, wide distribution, and ease of operation (since no exogenous Cas gene delivery is needed). Furthermore, type I CRISPR-Cas systems can simultaneously edit and regulate genes by adjusting the crRNA spacer length. Meanwhile, most actinomycetes are recalcitrant to genetic manipulation, hindering the discovery and engineering of natural products (NPs). The endogenous type I CRISPR-Cas systems in actinomycetes may offer a promising alternative to overcome these barriers. This review summarizes the challenges and recent advances in CRISPR-based genome engineering technologies for actinomycetes. It also presents and discusses how to establish and develop genome editing tools based on type I CRISPR-Cas systems in actinomycetes, with the aim of their future application in gene editing and the discovery of NPs in actinomycetes.

Binding to the Other Side: The AT-Hook DNA-Binding Domain Allows Nuclear Factors to Exploit the DNA Minor Groove

The "AT-hook" is a peculiar DNA-binding domain that interacts with DNA in the minor groove in correspondence to AT-rich sequences. This domain has been first described in the HMGA protein family of architectural factors and later in various transcription factors and chromatin proteins, often in association with major groove DNA-binding domains. In this review, using a literature search, we identified about one hundred AT-hook-containing proteins, mainly chromatin proteins and transcription factors. After considering the prototypes of AT-hook-containing proteins, the HMGA family, we review those that have been studied in more detail and that have been involved in various pathologies with a particular focus on cancer. This review shows that the AT-hook is a domain that gives proteins not only the ability to interact with DNA but also with RNA and proteins. This domain can have enzymatic activity and can influence the activity of the major groove DNA-binding domain and chromatin docking modules when present, and its activity can be modulated by post-translational modifications. Future research on the function of AT-hook-containing proteins will allow us to better decipher their function and contribution to the different pathologies and to eventually uncover their mutual influences.

UltraFast PhotoInduced double duplex DNA invasion into a 400-mer dsDNA target

BACKGROUND

Natural DNA restriction enzymes bind duplex DNA with high affinity at multiple sites; however, for some of the artificial chemical-based restriction moieties, invasion of the double-strand for efficient cleavage is an obstacle. We have previously reported photo-induced double-duplex invasion (pDDI) using 3-cyanovinylcarbazole (K)-containing probes for both the target strands that photo-crosslink with pyrimidine bases in a sequence-specific manner on both the strands, stabilizing the opened double-strand for cleavage. The drawback of the pDDI was low efficiency due to inter-probe cross-linking, solved by the inclusion of 5-cyano-uridine at -1 position on the complimentary strand with respect to K in both probes. Although this led to reduced inter-probe cross-linking, the pDDI efficiency was still low.

RESULTS

Here, we report that inter-probe cross-linking and intra-probe cross-linking of a single probe is also leading to reduced pDDI efficiency. We addressed this problem by designing DDI probes to inhibit both inter-probe and intra-probe cross-linking.

CONCLUSION

Based on the new design of pDDI probe with 5-cyano uridine led to a drastic increase in the efficiency of pDDI in (400-mer) double-stranded DNA with only 1 s of photo-irradiation.

A deterministic code for transcription factor-DNA recognition through computation of binding interfaces

The recognition code between transcription factor (TF) amino acids and DNA bases remains poorly understood. Here, the determinants of TF amino acid-DNA base binding selectivity were identified through the analysis of crystals of TF-DNA complexes. Selective, high-frequency interactions were identified for the vast majority of amino acid side chains (‘structural code’). DNA binding specificities were then independently assessed by meta-analysis of random-mutagenesis studies of Zn finger-target DNA sequences. Selective, high-frequency interactions were identified for the majority of mutagenized residues (‘mutagenesis code’). The structural code and the mutagenesis code were shown to match to a striking level of accuracy (P = 3.1 × 10−33), suggesting the identification of fundamental rules of TF binding to DNA bases. Additional insight was gained by showing a geometry-dictated choice among DNA-binding TF residues with overlapping specificity. These findings indicate the existence of a DNA recognition mode whereby the physical-chemical characteristics of the interacting residues play a deterministic role. The discovery of this DNA recognition code advances our knowledge on fundamental features of regulation of gene expression and is expected to pave the way for integration with higher-order complexity approaches.

Harnessing the power of directed evolution to improve genome editing systems

The recent development of genome editing systems, such as zinc-finger nucleases, transcription activator-like effectors, CRISPR-Cas nucleases, and base editors has enabled the unprecedented capability to engineer the genomes of living cells. The ever-increasing demand for genome editors with improved accuracy, activity, and functionality has stimulated significant efforts to further engineer the genome editing systems. Directed evolution represents a promising strategy to improve the existing genome editing systems and enable new editing functions. Here, we review recent representative strategies to harness the power of directed evolution to improve genome editing systems, which have led to state-of-the-art genome editors that have significant implications for diverse applications in both laboratories and clinics.

PATZ1 (MAZR) Co-occupies Genomic Sites With p53 and Inhibits Liver Cancer Cell Proliferation via Regulating p27

Liver cancer is the third most common cause of cancer death in the world. POZ/BTB and AT-hook-containing zinc finger protein 1 (PATZ1/MAZR) is a transcription factor associated with various cancers. However, the role of PATZ1 in cancer progression remains controversial largely due to lack of genome-wide studies. Here we report that PATZ1 regulates cell proliferation by directly regulating CDKN1B (p27) in hepatocellular carcinoma cells. Our PATZ1 ChIP-seq and gene expression microarray analyses revealed that PATZ1 is strongly related to cancer signatures and cellular proliferation. We further discovered that PATZ1 depletion led to an increased rate of colony formation, elevated Ki-67 expression and greater S phase entry. Importantly, the increased cancer cell proliferation was accompanied with suppressed expression of the cyclin-dependent kinase inhibitor CDKN1B. Consistently, we found that PATZ1 binds to the genomic loci flanking the transcriptional start site of CDKN1B and positively regulates its transcription. Notably, we demonstrated that PATZ1 is a p53 partner and p53 is essential for CDKN1B regulation. In conclusion, our study provides novel mechanistic insights into the inhibitory role of PATZ1 in liver cancer progression, thereby yielding a promising therapeutic intervention to alleviate tumor burden.

Functionalized gold nanoparticles with zinc finger-fused proteins as a colorimetric immunoassay platform

The quest for highly sensitive and specific detection of disease biomarkers is high, despite many advances in analysis system. Here, we present a sensitive immunoassay platform using DNA-tethered gold nanoparticles and DNA-binding zinc fingers (ZFs). Monomeric alkaline phosphatase (mAP) and human TNF-α were employed as a signal generator and a disease biomarker, respectively. Gold nanoparticles (AuNPs) were first grafted with double-stranded DNAs having specific sequences for two different types of ZFs (QNK and zif268). The alkaline phosphatase and TNF-α-specific protein binder were genetically fused to each of two different types of ZFs, respectively, followed by conjugation with the DNA-tethered AuNPs in a sequence-specific manner. The use of the functionalized AuNPs as a signal generator in a colorimetric immunoassay of TNF-α led to LOD of 120 pg/ml, showing about 161-fold higher sensitivity than a protein binder-fused mAP. The present immunoassay platform could be applied to other analytes by simply replacing a targeting moiety, allowing a versatile and reproducible colorimetric immunoassay.

Development of Toolboxes for Precision Genome/Epigenome Editing and Imaging of Epigenetics

Zinc finger (ZF) proteins are composed of repeated ββα modules and coordinate a zinc ion. ZF domains recognizing specific DNA target sequences can be substituted for the binding domains of various DNA-modifying enzymes to create designer nucleases, recombinases, and methyltransferases with programmable sequence specificity. Enzymatic genome editing and modification can be applied to many fields of basic research and medicine. The recent development of new platforms using transcription activator-like effector (TALE) proteins or the CRISPR-Cas9 system has expanded the range of possibilities for genome-editing technologies. In addition, these DNA binding domains can also be utilized to build a toolbox for epigenetic controls by fusing them with protein- or DNA-modifying enzymes. Here, our research on epigenome editing including the development of artificial zinc finger recombinase (ZFR), split DNA methyltransferase, and fluorescence imaging of histone proteins by ZIP tag-probe system is introduced. Advances in the ZF, TALE, and CRISPR-Cas9 platforms have paved the way for the next generation of genome/epigenome engineering approaches.

Breaching Self-Tolerance to Alu Duplex RNA Underlies MDA5-Mediated Inflammation

Aberrant activation of innate immune receptors can cause a spectrum of immune disorders, such as Aicardi-Goutières syndrome (AGS). One such receptor is MDA5, a viral dsRNA sensor that induces antiviral immune response. Using a newly developed RNase-protection/RNA-seq approach, we demonstrate here that constitutive activation of MDA5 in AGS results from the loss of tolerance to cellular dsRNAs formed by Alu retroelements. While wild-type MDA5 cannot efficiently recognize Alu-dsRNAs because of its limited filament formation on imperfect duplexes, AGS variants of MDA5 display reduced sensitivity to duplex structural irregularities, assembling signaling-competent filaments on Alu-dsRNAs. Moreover, we identified an unexpected role of an RNA-rich cellular environment in suppressing aberrant MDA5 oligomerization, highlighting context dependence of self versus non-self discrimination. Overall, our work demonstrates that the increased efficiency of MDA5 in recognizing dsRNA comes at a cost of self-recognition and implicates a unique role of Alu-dsRNAs as virus-like elements that shape the primate immune system.

Zinc Fingers, TALEs, and CRISPR Systems: A Comparison of Tools for Epigenome Editing

The completion of genome, epigenome, and transcriptome mapping in multiple cell types has created a demand for precision biomolecular tools that allow researchers to functionally manipulate DNA, reconfigure chromatin structure, and ultimately reshape gene expression patterns. Epigenetic editing tools provide the ability to interrogate the relationship between epigenetic modifications and gene expression. Importantly, this information can be exploited to reprogram cell fate for both basic research and therapeutic applications. Three different molecular platforms for epigenetic editing have been developed: zinc finger proteins (ZFs), transcription activator-like effectors (TALEs), and the system of Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) and CRISPR-associated (Cas) proteins. These platforms serve as custom DNA-binding domains (DBDs), which are fused to epigenetic modifying domains to manipulate epigenetic marks at specific sites in the genome. The addition and/or removal of epigenetic modifications reconfigures local chromatin structure, with the potential to provoke long-lasting changes in gene transcription. Here we summarize the molecular structure and mechanism of action of ZF, TALE, and CRISPR platforms and describe their applications for the locus-specific manipulation of the epigenome. The advantages and disadvantages of each platform will be discussed with regard to genomic specificity, potency in regulating gene expression, and reprogramming cell phenotypes, as well as ease of design, construction, and delivery. Finally, we outline potential applications for these tools in molecular biology and biomedicine and identify possible barriers to their future clinical implementation.

An ensemble micro neural network approach for elucidating interactions between zinc finger proteins and their target DNA

BACKGROUND

The ability to engineer zinc finger proteins binding to a DNA sequence of choice is essential for targeted genome editing to be possible. Experimental techniques and molecular docking have been successful in predicting protein-DNA interactions, however, they are highly time and resource intensive. Here, we present a novel algorithm designed for high throughput prediction of optimal zinc finger protein for 9 bp DNA sequences of choice. In accordance with the principles of information theory, a subset identified by using K-means clustering was used as a representative for the space of all possible 9 bp DNA sequences. The modeling and simulation results assuming synergistic mode of binding obtained from this subset were used to train an ensemble micro neural network. Synergistic mode of binding is the closest to the DNA-protein binding seen in nature, and gives much higher quality predictions, while the time and resources increase exponentially in the trade off. Our algorithm is inspired from an ensemble machine learning approach, and incorporates the predictions made by 100 parallel neural networks, each with a different hidden layer architecture designed to pick up different features from the training dataset to predict optimal zinc finger proteins for any 9 bp target DNA.

RESULTS

The model gave an accuracy of an average 83% sequence identity for the testing dataset. The BLAST e-value are well within the statistical confidence interval of E-05 for 100% of the testing samples. The geometric mean and median value for the BLAST e-values were found to be 1.70E-12 and 7.00E-12 respectively. For final validation of approach, we compared our predictions against optimal ZFPs reported in literature for a set of experimentally studied DNA sequences. The accuracy, as measured by the average string identity between our predictions and the optimal zinc finger protein reported in literature for a 9 bp DNA target was found to be as high as 81% for DNA targets with a consensus sequence GCNGNNGCN reported in literature. Moreover, the average string identity of our predictions for a catalogue of over 100 9 bp DNA for which the optimal zinc finger protein has been reported in literature was found to be 71%.

CONCLUSIONS

Validation with experimental data shows that our tool is capable of domain adaptation and thus scales well to datasets other than the training set with high accuracy. As synergistic binding comes the closest to the ideal mode of binding, our algorithm predicts biologically relevant results in sync with the experimental data present in the literature. While there have been disjointed attempts to approach this problem synergistically reported in literature, there is no work covering the whole sample space. Our algorithm allows designing zinc finger proteins for DNA targets of the user's choice, opening up new frontiers in the field of targeted genome editing. This algorithm is also available as an easy to use web server, ZifNN, at http://web.iitd.ac.in/~sundar/ZifNN/ .

Exploiting the recognition code for elucidating the mechanism of zinc finger protein-DNA interactions

Background

Engineering zinc finger protein motifs for specific binding to double-stranded DNA is critical for targeted genome editing. Most existing tools for predicting DNA-binding specificity in zinc fingers are trained on data obtained from naturally occurring proteins, thereby skewing the predictions. Moreover, these mostly neglect the cooperativity exhibited by zinc fingers.

Methods

Here, we present an ab-initio method that is based on mutation of the key α-helical residues of individual fingers of the parent template for Zif-268 and its consensus sequence (PDB ID: 1AAY). In an attempt to elucidate the mechanism of zinc finger protein-DNA interactions, we evaluated and compared three approaches, differing in the amino acid mutations introduced in the Zif-268 parent template, and the mode of binding they try to mimic, i.e., modular and synergistic mode of binding.

Results

Comparative evaluation of the three strategies reveals that the synergistic mode of binding appears to mimic the ideal mechanism of DNA-zinc finger protein binding. Analysis of the predictions made by all three strategies indicate strong dependence of zinc finger binding specificity on the amino acid propensity and the position of a 3-bp DNA sub-site in the target DNA sequence. Moreover, the binding affinity of the individual zinc fingers was found to increase in the order Finger 1 < Finger 2 < Finger 3, thus confirming the cooperative effect.

Conclusions

Our analysis offers novel insights into the prediction of ZFPs for target DNA sequences and the approaches have been made available as an easy to use web server at http://web.iitd.ac.in/~sundar/zifpredict_ihbe

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-016-3324-8) contains supplementary material, which is available to authorized users.

Streptococcus pneumoniae Genome-wide Identification and Characterization of BOX Element-binding Domains

The BOX elements are short repetitive DNA sequences that distribute randomly in intergenic regions of the Streptococcus pneumoniae genome. The function and origin of such elements are still unknown, but they were found to modulate expression of neighboring genes. Evidences suggested that the modulation's mechanism can be fulfilled by sequence-specific interaction of BOX elements with transcription factor family proteins. However, the type and function of these BOX-binding proteins still remain largely unexplored to date. In the current study we described a synthetic protocol to investigate the recognition and interaction between a highly conserved site of BOX elements and the DNA-binding domains of a variety of putative transcription factors in the pneumococcal genome. With the protocol we were able to predict those high-affinity domain binders of the conserved BOX DNA site (BOX DNA) in a high-throughput manner, and analyzed sequence-specific interaction in the domainDNA recognition at molecular level. Consequently, a number of putative transcription factor domains with both high affinity and specificity for the BOX DNA were identified, from which the helix-turn-helix (HTH) motif of a small heat shock factor was selected as a case study and tested for its binding capability toward the double-stranded BOX DNA using fluorescence anisotropy analysis. As might be expected, a relatively high affinity was detected for the interaction of HTH motif with BOX DNA with dissociation constant at nanomolar level. Molecular dynamics simulation, atomic structure examination and binding energy analysis revealed a complicated network of intensive nonbonded interactions across the complex interface, which confers both stability and specificity for the complex architecture.

Nuclease Target Site Selection for Maximizing On-target Activity and Minimizing Off-target Effects in Genome Editing

The rapid advancement in targeted genome editing using engineered nucleases such as ZFNs, TALENs, and CRISPR/Cas9 systems has resulted in a suite of powerful methods that allows researchers to target any genomic locus of interest. A complementary set of design tools has been developed to aid researchers with nuclease design, target site selection, and experimental validation. Here, we review the various tools available for target selection in designing engineered nucleases, and for quantifying nuclease activity and specificity, including web-based search tools and experimental methods. We also elucidate challenges in target selection, especially in predicting off-target effects, and discuss future directions in precision genome editing and its applications.

Controlling gene networks and cell fate with precision-targeted DNA-binding proteins and small-molecule-based genome readers

Transcription factors control the fate of a cell by regulating the expression of genes and regulatory networks. Recent successes in inducing pluripotency in terminally differentiated cells as well as directing differentiation with natural transcription factors has lent credence to the efforts that aim to direct cell fate with rationally designed transcription factors. Because DNA-binding factors are modular in design, they can be engineered to target specific genomic sequences and perform pre-programmed regulatory functions upon binding. Such precision-tailored factors can serve as molecular tools to reprogramme or differentiate cells in a targeted manner. Using different types of engineered DNA binders, both regulatory transcriptional controls of gene networks, as well as permanent alteration of genomic content, can be implemented to study cell fate decisions. In the present review, we describe the current state of the art in artificial transcription factor design and the exciting prospect of employing artificial DNA-binding factors to manipulate the transcriptional networks as well as epigenetic landscapes that govern cell fate.

Engineering bacterial transcription regulation to create a synthetic in vitro two-hybrid system for protein interaction assays

Transcriptional activation of σ(54)-RNA polymerase holoenzyme (σ(54)-RNAP) in bacteria is dependent on a cis-acting DNA element (bacterial enhancer), which recruits the bacterial enhancer-binding protein to contact the holoenzyme via DNA looping. Using a constructive synthetic biology approach, we recapitulated such process of transcriptional activation by recruitment in a reconstituted cell-free system, assembled entirely from a defined number of purified components. We further engineered the bacterial enhancer-binding protein PspF to create an in vitro two-hybrid system (IVT2H), capable of carrying out gene regulation in response to expressed protein interactions. Compared with genetic systems and other in vitro methods, IVT2H not only allows detection of different types of protein interactions in just a few hours without involving cells but also provides a general correlation of the relative binding strength of the protein interaction with the IVT2H signal. Due to its reconstituted nature, IVT2H provides a biochemical assay platform with a clean and defined background. We demonstrated the proof-of-concept of using IVT2H as an alternative assay for high throughput screening of small-molecule inhibitors of protein-protein interaction.

Role of stem cells in large animal genetic engineering in the TALENs-CRISPR era

The establishment of embryonic stem cells (ESCs) and gene targeting technologies in mice has revolutionised the field of genetics. The relative ease with which genes can be knocked out, and exogenous sequences introduced, has allowed the mouse to become the prime model for deciphering the genetic code. Not surprisingly, the lack of authentic ESCs has hampered the livestock genetics field and has forced animal scientists into adapting alternative technologies for genetic engineering. The recent discovery of the creation of induced pluripotent stem cells (iPSCs) by upregulation of a handful of reprogramming genes has offered renewed enthusiasm to animal geneticists. However, much like ESCs, establishing authentic iPSCs from the domestic animals is still beset with problems, including (but not limited to) the persistent expression of reprogramming genes and the lack of proven potential for differentiation into target cell types both in vitro and in vivo. Site-specific nucleases comprised of zinc finger nucleases (ZFNs), transcription activator-like effector nucleases (TALENs) and clustered regulated interspaced short palindromic repeats (CRISPRs) emerged as powerful genetic tools for precisely editing the genome, usurping the need for ESC-based genetic modifications even in the mouse. In this article, in the aftermath of these powerful genome editing technologies, the role of pluripotent stem cells in livestock genetics is discussed.

Expression, signaling and function of Egr transcription factors in pancreatic β-cells and insulin-responsive tissues

Egr-1 and the related zinc finger transcription factors Egr-2, Egr-3, and Egr-4 are stimulated by many extracellular signaling molecules and represent a convergence point for intracellular signaling cascades. Egr-1 expression is induced in insulinoma cells and pancreatic β-cells following stimulation with either glucose, or pregnenolone sulfate. Moreover, stimulation of Gαq and Gαs-coupled receptors enhances EGR-1 gene transcription. Functional studies revealed that Egr transcription factors control insulin biosynthesis via regulation of Pdx-1 expression. Glucose homeostasis and pancreatic islet size are regulated by Egr transcription factors, indicating that these proteins control central physiological parameters regulated by pancreatic β-cells. In addition, Egr-1 is an integral part of the insulin receptor signaling cascade in insulin-responsive tissues and influences insulin resistance.

RIG-I forms signaling-competent filaments in an ATP-dependent, ubiquitin-independent manner

Retinoic acid-inducible gene 1 (RIG-I) and melanoma differentiation-associated protein 5 (MDA5) are paralogous receptors for viral double-stranded RNA (dsRNA) with divergent specificity. We have previously shown that MDA5 forms filaments upon viral dsRNA recognition and that this filament formation is essential for interferon signal activation. Here, we show that while RIG-I binds to a dsRNA end as a monomer in the absence of ATP, it assembles in the presence of ATP into a filament that propagates from the dsRNA end to the interior. Furthermore, RIG-I filaments directly stimulate mitochondrial antiviral signaling (MAVS) filament formation without any cofactor, such as polyubiquitin chains, and forced juxtaposition of the isolated signaling domain of RIG-I, as it would be in the filament, is sufficient to activate interferon signaling. Our findings thus define filamentous architecture as a common yet versatile molecular platform for divergent viral RNA detection and proximity-induced signal activation by RIG-I and MDA5.

Precision editing of large animal genomes

Transgenic animals are an important source of protein and nutrition for most humans and will play key roles in satisfying the increasing demand for food in an ever-increasing world population. The past decade has experienced a revolution in the development of methods that permit the introduction of specific alterations to complex genomes. This precision will enhance genome-based improvement of farm animals for food production. Precision genetics also will enhance the development of therapeutic biomaterials and models of human disease as resources for the development of advanced patient therapies.

Towards artificial metallonucleases for gene therapy: recent advances and new perspectives

The process of DNA targeting or repair of mutated genes within the cell, induced by specifically positioned double-strand cleavage of DNA near the mutated sequence, can be applied for gene therapy of monogenic diseases. For this purpose, highly specific artificial metallonucleases are developed. They are expected to be important future tools of modern genetics. The present state of art and strategies of research are summarized, including protein engineering and artificial ‘chemical’ nucleases. From the results, we learn about the basic role of the metal ions and the various ligands, and about the DNA binding and cleavage mechanism. The results collected provide useful guidance for engineering highly controlled enzymes for use in gene therapy.

Theoretical design of a specific DNA-Zinc-finger protein interaction with semi-empirical quantum chemical methods

The interactions of a zinc-finger (ZF) protein with DNA containing the specific recognition site of the ZF and with a non-specific DNA were studied with the semi-empirical quantum chemical method of PM6/Mozyme. The ZF protein (1MEY)-DNA complex structures were generated by docking calculations. The complex structures were reoptimized with the PM6/Mozyme method with implicit solvation in water. The structures were also calculated in the gas phase. The interaction enthalpies between the protein and DNA within the complexes obtained in the PM6/Mozyme with solvation optimized structures were calculated with the single-point PM6-DH2/Mozyme method (PM6 with dispersion, H-bond correction and Mozyme) with solvation. The results supported the specific and non-specific interactions in the complexes obtained from the docking experiments. The binding enthalpies of the specific and non-specific DNA binding to the protein differed significantly. The interactions between the nucleic acid strands in duplexes were also evaluated; these interactions between the base pairs were different because of the different "G…C:A…T" ratios in the DNA molecules studied. The stacking interactions between the nucleic bases were also characterized in the DNA duplexes.

Beyond DNA: zinc finger domains as RNA-binding modules

Over the last 25 years, we have learned that many structural classes of zinc-binding domains (zinc fingers, ZFs) exist and it has become clear that the molecular functions of these domains are by no means limited to the sequence-specific recognition of double-stranded DNA. For example, ZFs can act as protein recognition or RNA-binding modules, and some domains can exhibit more than one function. In this chapter we describe the progress that has been made in understanding the role of ZF domains as RNA-recognition modules, and we speculate about both the prevalence of such functions and the prospects for creating designer ZFs that target RNA.

An affinity-based scoring scheme for predicting DNA-binding activities of modularly assembled zinc-finger proteins

Zinc-finger proteins (ZFPs) have long been recognized for their potential to manipulate genetic information because they can be engineered to bind novel DNA targets. Individual zinc-finger domains (ZFDs) bind specific DNA triplet sequences; their apparent modularity has led some groups to propose methods that allow virtually any desired DNA motif to be targeted in vitro. In practice, however, ZFPs engineered using this 'modular assembly' approach do not always function well in vivo. Here we report a modular assembly scoring strategy that both identifies combinations of modules least likely to function efficiently in vivo and provides accurate estimates of their relative binding affinities in vitro. Predicted binding affinities for 53 'three-finger' ZFPs, computed based on energy contributions of the constituent modules, were highly correlated (r = 0.80) with activity levels measured in bacterial two-hybrid assays. Moreover, K(d) values for seven modularly assembled ZFPs and their intended targets, measured using fluorescence anisotropy, were also highly correlated with predictions (r = 0.91). We propose that success rates for ZFP modular assembly can be significantly improved by exploiting the score-based strategy described here.

Generation and functional analysis of zinc finger nucleases

The recent development of artificial endonucleases with tailored specificities has opened the door for a wide range of new applications, including the correction of mutated genes directly in the chromosome. This kind of gene therapy is based on homologous recombination, which can be stimulated by the creation of a targeted DNA double-strand break (DSB) near the site of the desired recombination event. Artificial nucleases containing zinc finger DNA-binding domains have provided important proofs of concept, showing that inserting a DSB in the target locus leads to gene correction frequencies of 1-18% in human cells. In this paper, we describe how zinc finger nucleases are assembled by polymerase chain reaction (PCR) and present two methods to assess these custom nucleases quickly in vitro and in a cell-based recombination assay.

Energy-based prediction of amino acid-nucleotide base recognition

Despite decades of investigations, it is not yet clear whether there are rules dictating the specificity of the interaction between amino acids and nucleotide bases. This issue was addressed by determining, in a dataset consisting of 100 high-resolution protein-DNA structures, the frequency and energy of interaction between each amino acid and base, and the energetics of water-mediated interactions. The analysis was carried out using HINT, a non-Newtonian force field encoding both enthalpic and entropic contributions, and Rank, a geometry-based tool for evaluating hydrogen bond interactions. A frequency- and energy-based preferential interaction of Arg and Lys with G, Asp and Glu with C, and Asn and Gln with A was found. Not only favorable, but also unfavorable contacts were found to be conserved. Water-mediated interactions strongly increase the probability of Thr-A, Lys-A, and Lys-C contacts. The frequency, interaction energy, and water enhancement factors associated with each amino acid-base pair were used to predict the base triplet recognized by the helix motif in 45 zinc fingers, which represents an ideal case study for the analysis of one-to-one amino acid-base pair contacts. The model correctly predicted 70.4% of 135 amino acid-base pairs, and, by weighting the energetic relevance of each amino acid-base pair to the overall recognition energy, it yielded a prediction rate of 89.7%.

Zinc-finger nucleases: the next generation emerges

Methods of modifying the human genome precisely and efficiently hold great promise for revolutionizing the gene therapy arena. One particularly promising technology is based on the homologous recombination (HR) pathway and is known as gene targeting. Until recently, the low frequency of HR in mammalian cells, and the resulting dependence on selection to identify these rare events, has prevented gene targeting from being applied in a therapeutic context. However, recent advances in generating customized zinc-finger nucleases (ZFNs) that can create a DNA double-strand break (DSB) at preselected sites in the human genome have paved the way for HR-based strategies in gene therapy. By introducing a DSB into a target locus of interest, ZFNs stimulate gene targeting by several orders of magnitude through activation of cellular DNA repair pathways. The capability of this technology to achieve gene conversion frequencies of up to 29% in the absence of selection demonstrates its potential power. In this paper we review recent advances in, and upcoming challenges for, this emerging technology and discuss future experimental work that will be needed to bring ZFNs safely into a clinical setting.

ZIFIBI: Prediction of DNA binding sites for zinc finger proteins

The cis-regulatory region of target genes is key elements in the transcriptional regulation of gene expression. Many of these cis-regulatory regions have not been identified by either biological experiments or computational methods. Recently, a few additional C(2)H(2) zinc finger transcription factor binding sites have been discovered. The majority of the zinc finger binding sites, however, are still unknown. In this study, we used publically available data to evaluate possible interaction patterns between nucleotides and the amino acids of zinc finger domains. We calculated the most probable state path of three nucleotides sequences using a Hidden Markov Model (HMM). We used these computations to predict C(2)H(2) zinc finger transcription factor binding sites in cis-regulatory regions of their target genes (http://bioinfo.hanyang.ac.kr/ZIFIBI/frameset.php).

DNA-binding specificity is a major determinant of the activity and toxicity of zinc-finger nucleases

The engineering of proteins to manipulate cellular genomes has developed into a promising technology for biomedical research, including gene therapy. In particular, zinc-finger nucleases (ZFNs), which consist of a nonspecific endonuclease domain tethered to a tailored zinc-finger (ZF) DNA-binding domain, have proven invaluable for stimulating homology-directed gene repair in a variety of cell types. However, previous studies demonstrated that ZFNs could be associated with significant cytotoxicity due to cleavage at off-target sites. Here, we compared the in vitro affinities and specificities of nine ZF DNA-binding domains with their performance as ZFNs in human cells. The results of our cell-based assays reveal that the DNA-binding specificity--in addition to the affinity--is a major determinant of ZFN activity and is inversely correlated with ZFN-associated toxicity. In addition, our data provide the first evidence that engineering strategies, which account for context-dependent DNA-binding effects, yield ZFs that function as highly efficient ZFNs in human cells.

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.

Structural modeling of sequence specificity by an autoantibody against single-stranded DNA

11F8 is a sequence-specific pathogenic anti-single-stranded (ss)DNA autoantibody isolated from a lupus prone mouse. Site-directed mutagenesis of 11F8 has shown that six binding site residues (R31VH, W33VH, L97VH, R98VH, Y100VH, and Y32VL) contribute 80% of the free energy for complex formation. Mutagenesis results along with intermolecular distances obtained from fluorescence resonance energy transfer were implemented here as restraints to model docking between 11F8 and the sequence-specific ssDNA. The model of the complex suggests that aromatic stacking and two sets of bidentate hydrogen bonds between binding site arginine residues (R31VH and R96VH) and loop nucleotides provide the molecular basis for high affinity and specificity. In part, 11F8 utilizes the same ssDNA binding motif of Y32VL, H91VL, and an aromatic residue in the third complementarity-determining region to recognize thymine-rich sequences as do two anti-ssDNA autoantibodies crystallized in complex with thymine. R31SVH is a dominant somatic mutation found in the J558 germline sequence that is implicated in 11F8 sequence specificity. A model of the mutant R31S11F8.ssDNA complex suggests that different interface contacts occur when serine replaces arginine 31 at the binding site. The modeled contacts between the R31S11F8 mutant and thymine are closely related to those observed in other anti-ssDNA binding antibodies, while we find additional contacts between 11F8 and ssDNA that involve amino acids not utilized by the other antibodies. These data-driven 11F8.ssDNA models provide testable hypotheses concerning interactions that mediate sequence specificity in 11F8 and the effects of somatic mutation on ssDNA recognition.

In vitro characterization of the Mig1 repressor from Saccharomyces cerevisiae reveals evidence for monomeric and higher molecular weight forms

The Mig1 DNA-binding protein of Saccharomyces cerevisiae was expressed and purified from yeast and the physical properties were characterized by several methods, including gel filtration, sucrose gradient sedimentation and native gel electrophoresis. Purified Mig1 exists as a monomer with a Stokes' radius of 48 A and a sedimentation coefficient of 3.55 S. Mig1 has an elongated shape with a frictional coefficient of 1.83. The K(d) of purified Mig1 for the SUC2 A site is 2.8 nM and for SUC2 B site 25.8 nM; these values were similar for Mig1 purified from repressed and derepressed cells. Full-length Mig1 expressed in yeast binds more tightly to SUC2 B than bacterially expressed GST-Mig1. Sucrose gradient sedimentation resolved a larger molecular weight form of Mig1 in whole-cell extracts that was not seen in purified samples and may represent a complex with another protein. This complex is found within the nucleus and is seen only in repressed cells. Mig1 exists in multiple phosphorylation states and only less phosphorylated forms of Mig1 are associated with this complex.

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.

Designer zinc-finger proteins and their applications

The Cys(2)His(2) zinc finger is one of the most common DNA-binding motifs in Eukaryota. A simple mode of DNA recognition by the Cys(2)His(2) zinc finger domain provides an ideal scaffold for designing proteins with novel sequence specificities. The ability to bind specifically to virtually any DNA sequence combined with the potential of fusing them with effector domains has led to the technology of engineering of chimeric DNA-modifying enzymes and transcription factors. This in turn has opened the possibility of using the engineered zinc finger-based factors as novel human therapeutics. One such synthetic factor-designer zinc finger transcription activator of the vascular endothelial growth factor A gene-has recently entered clinical trials to evaluate the ability of stimulating the growth of blood vessels in treating the peripheral arterial obstructive disease. This review concentrates on the aspects of natural Cys(2)His(2) zinc fingers evolution and fundamental steps in design of engineered zinc finger proteins. The applications of engineered zinc finger proteins are discussed in a context of the mechanism mediating their effect on the targeted DNA. Furthermore, the regulation of the expression of zinc finger proteins and their targeting to various cellular compartments and to chromatin and non-chromatin target templates are described. Also possible future applications of designer zinc finger proteins are discussed.

Calcium Ion Responsive DNA Binding in a Zinc Finger Fusion Protein

Zinc finger fusion proteins, having a Ca-binding site from troponin C, were created to develop Ca-responsive regulation of DNA binding. The typical zinc finger folding of a novel fusion protein with a single finger, F2-Tn, was investigated using UV-vis spectroscopy of the Co-substituted form and CD experiments. Detailed structural analyses of F2-Tn/Zn2+ using NMR experiments and structural calculations clarify that our fusion protein gives a native zinc finger folding with the artificial Ca-binding domain intervening two helices. The Ca-responsive DNA-binding affinity of troponin-fused protein with two fingers (using F1F2-Tn) was investigated by electrophoretic mobility shift assay (EMSA). EMSA analyses of F1F2-Tn were performed under the conditions of various concentrations of the Ca ion. F1F2-Tn has a Kd value of 5.8 nM in the absence of Ca ion and shows a higher Kd value of 13 nM in the presence of 100 equiv of Ca ion. The artificially designed fusion zinc finger protein with a Ca-binding domain has Ca-responsive DNA-binding affinity. It is leading to a better understanding of the construction of zinc finger-based artificial transcriptional factors with a Ca switch.

Binding of two zinc finger nuclease monomers to two specific sites is required for effective double-strand DNA cleavage

Custom-designed zinc finger nucleases (ZFNs) are becoming powerful tools in gene targeting-the process of replacing a gene within a genome by homologous recombination. Here, we have studied the DNA cleavage by one such ZFN, DeltaQNK-FN, in order to gain insight into how ZFNs cleave DNA and how two inverted sites promote double-strand cleavage. DNA cleavage by DeltaQNK-FN is greatly facilitated when two DeltaQNK-binding sites are close together in an inverted orientation. Substrate cleavage was not first order with respect to the concentration of DeltaQNK-FN, indicating that double-strand cleavage requires dimerization of the FokI cleavage domain. Rates of DNA cleavage decrease as the substrate concentrations increase, suggesting that the DeltaQNK-FN molecules are effectively "trapped" in a 1:1 complex on DNA when the DNA is in excess. The physical association of two ZFN monomers on DNA was monitored by using the biotin-pull-down assay, which showed that the formation of DeltaQNK-FN active complex required both binding of the two DeltaQNK-FN molecules to specific DNA sites and divalent metal ions.

Combining SELEX with quantitative assays to rapidly obtain accurate models of protein-DNA interactions

Models for the specificity of DNA-binding transcription factors are often based on small amounts of qualitative data and therefore have limited accuracy. In this study we demonstrate a simple and efficient method of affinity chromatography-SELEX followed by a quantitative binding (QuMFRA) assay to rapidly collect the data necessary for more accurate models. Using the zinc finger protein EGR as an e.g. we show that many bindings sites can be obtained efficiently with affinity chromatography-SELEX, but those sequences alone provide a weight matrix model with limited accuracy. Using a QuMFRA assay to determine the quantitative relative affinity for only a subset of the sequences obtained by SELEX leads to a much more accurate model. Application of this method to variants of a transcription factor would allow us to generate a large collection of quantitative data for modeling protein-DNA interactions that could facilitate the determination of recognition codes for different transcription factor families.

An artificial six-zinc finger peptide with polyarginine linker: Selective binding to the discontinuous DNA sequences

Artificial DNA binding peptides recognizing separated sequences would expand varieties of the target genes for desirable transcriptional control. Here we demonstrated that polyarginine linker between two 3-zinc finger domains gives DNA binding selectivity to the separated target sequences. We created a six-zinc finger peptide, Sp1ZF6(Arg)8, by connecting two DNA binding domains of transcription factor Sp1 with a bulky and cationic polyarginine linker. The DNA binding properties to continuous and discontinuous target sequences were examined and compared to those of Sp1ZF6(Gly)10 containing a flexible and neutral polyglycine linker. The dissociation constants indicate that Sp1ZF6(Arg)8 has an obvious DNA binding preference to discontinuous target sequences but not Sp1ZF6(Gly)10. Footprinting analyses also showed that Sp1ZF6(Arg)8 binds properly only to the discontinuous target sites, while Sp1ZF6(Gly)10 does not distinguish them. The results provide helpful information for linker design of future zinc finger peptides to various states of DNA as gene expression regulators.

Saccharomyces cerevisiae Hop1 zinc finger motif is the minimal region required for its function in vitro

Saccharomyces cerevisiae meiosis-specific HOP1, which encodes a core component of synaptonemal complex, plays a key role in proper pairing of homologous chromosomes and processing of meiotic DNA double strand breaks. Isolation and analysis of hop1 mutants indicated that these functions require Cys(371) of Hop1 embedded in a region (residues 343-378) sharing homology to a zinc finger motif (ZnF). However, the precise biochemical function of Hop1, or its putative ZnF, in these processes is poorly understood. Our previous studies revealed that Hop1 is a DNA-binding protein, showed substantially higher binding affinity for G4 DNA, and enhances its formation. We report herein that ZnF appears to be sufficient for both zinc as well as DNA-binding activities. Molecular modeling studies suggested that Hop1 ZnF differs from the previously characterized natural ZnFs. The zinc-binding assay showed that the affinity for zinc is weaker for C371S ZnF mutant compared with the wild type (WT) ZnF. Analysis of CD spectra indicated that zinc and DNA induce substantial conformational changes in WT ZnF, but not in C371S ZnF mutant. The results from a number of different experimental approaches suggested that the DNA-binding properties of ZnF are similar to those of full-length Hop1 and that interaction with DNA rich in G residues is particularly robust. Significantly, WT ZnF by itself, but not C371S mutant, was able to bind duplex DNA and promote interstitial pairing of DNA double helices via the formation of guanine quartets. Together, these results implicate a direct role for Hop1 in pairing of homologous chromosomes during meiosis.

Site-selective in vivo targeting of cytosine-5 DNA methylation by zinc-finger proteins

Cytosine-5 DNA methylation is a critical signal defining heritable epigenetic states of transcription. As aberrant methylation patterns often accompany disease states, the ability to target cytosine methylation to preselected regions could prove valuable in re-establishing proper gene regulation. We employ the strategy of targeted gene methylation in yeast, which has a naturally unmethylated genome, selectively directing de novo DNA methylation via the fusion of C5 DNA methyltransferases to heterologous DNA-binding proteins. The zinc-finger proteins Zif268 and Zip53 can target DNA methylation by M.CviPI or M.SssI 5-52 nt from single zinc-factor binding sites. Modification at specific GC (M.CviPI) or CG (M.SssI) sites is enhanced as much as 20-fold compared with strains expressing either the free enzyme or a fusion protein with the zinc-finger protein moiety unable to bind to DNA. Interestingly, methylation is also selectively targeted as far as 353 nt from the zinc-finger protein binding sites, possibly indicative of looping, nucleosomes or higher-order chromatin structure. These data demonstrate that methylation can be targeted in vivo to a potentially broad range of sequences using specifically engineered zinc-finger proteins. Further more, the selective targeting of methylation by zinc-finger proteins demonstrates that binding of distinct classes of factors can be monitored in living cells.

Drug discovery with engineered zinc-finger proteins

Zinc-finger proteins (ZFPs) that recognize novel DNA sequences are the basis of a powerful technology platform with many uses in drug discovery and therapeutics. These proteins have been used as the DNA-binding domains of novel transcription factors (ZFP TFs), which are useful for validating genes as drug targets and for engineering cell lines for small-molecule screening and protein production. Recently, they have also been used as a basis for novel human therapeutics. Most of our advances in the design and application of these ZFP TFs rely on our ability to engineer ZFPs that bind short stretches of DNA (typically 9-18 base pairs) located within the promoters of target genes. Here, we summarize the methods used to design these DNA-binding domains, explain how they are incorporated into novel transcription factors (and other useful molecules) and describe some key applications in drug discovery.

Assessment by molecular dynamics simulations of the structural determinants of DNA-binding specificity for transcription factor Sp1

The DNA-binding domain (DBD) of the ubiquituous transcription factor Sp1 consists of three consecutive zinc fingers that recognize a number of nucleotide sequences different from, but related to and sometimes overlapping, those recognized by the structurally better characterized early growth response protein 1 (EGR1, also known as Zif268, Krox-24, and NGFI-A). The accepted consensus binding sequence for Sp1 is usually defined by the asymmetric hexanucleotide core GGGCGG but this sequence does not include, among others, the GAG (=CTC) repeat that constitutes a high-affinity site for Sp1 binding to the wt1 promoter. Since no 3D structure of the whole DBD of Sp1 is available, either alone or in complex with DNA, a homology-based model was built and its interaction with two DNA 14-mers was studied using nanosecond molecular dynamics simulations in the presence of explicit water molecules. These oligonucleotides represent Sp1 target sites that are present in the promoters of the mdr1 and wt1 genes. For comparative purposes and validation of the protocol, the complex between the DBD of EGR1 and its DNA target site within the proximal mdr1 promoter was simulated under the same conditions. Some water molecules were seen to play an important role in recognition and stabilization of the protein-DNA complexes. Our results, which are supported by the available experimental evidence, suggest that the accuracy in the prediction of putative Sp1-binding sites can be improved by interpreting a set of rules, which are a blend of both stringency and tolerance, for the juxtaposed triplet subsites to which each zinc finger binds. Our approach can be extrapolated to WT1 and other related natural or artificial zinc-finger-containing DNA-binding proteins and may aid in the assignment of particular DNA stretches as allowed or disallowed-binding sites.

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.

Binding of the priming nucleotide in the initiation of transcription by T7 RNA polymerase

Unlike DNA polymerases, an RNA polymerase must initiate transcription de novo, that is binding of the initiating (+1) nucleoside triphosphate must be achieved without benefit of the cooperative binding energetics of an associated primer. Since a single Watson-Crick base pair is not stable in solution, RNA polymerases might be expected to provide additional stabilizing interactions to facilitate binding and positioning of the initiating (priming) nucleoside triphosphate at position +1. Consistent with base-specific stabilizing interactions, of the 17 T7 RNA polymerase promoters in the phage genome, 15 begin with guanine. In this work, we demonstrate that the purine N-7 is important in the utilization of the initial substrate GTP. The fact that on a template encoding AG as the first two bases in the transcript (as in the remaining two of the T7 genome) transcription starts predominantly (but not exclusively) at the G at position +2 additionally implicates the purine O-6 as an important recognition element in the major groove. Finally, results suggest that these interactions serve primarily to position the initiating base in the active site. It is proposed that T7 RNA polymerase interacts directly with the Hoogsteen side of the initial priming GTP (most likely via an interaction with an arginine side chain in the protein) to provide the extra stability required at this unique step in transcription.