Expanding the DNA-recognition repertoire for zinc finger proteins beyond 20 amino acids

The design of DNA binding domains based on the Cys2His2 zinc finger motif has proven to be a successful strategy for the specific recognition of novel DNA sequences. Although considerable effort has been devoted to the generation of zinc finger proteins with widely varying DNA-binding preferences, only a limited number of potential DNA binding sites have been targeted with a high degree of specificity. These restrictions on zinc finger design appear to be a consequence of the limited repertoire of side-chain lengths and functionalities available with the 20 proteinogenic amino acids. To demonstrate that these limitations can be overcome through the use of "unnatural" amino acids, expressed protein ligation was employed to incorporate the amino acid citrulline into a single position within a three-zinc finger protein. As anticipated, the resulting semisynthetic protein specifically recognizes adenine in the appropriate position of its binding site.     

Coordination properties of zinc finger peptides revisited: ligand competition studies reveal higher affinities for zinc and cobalt

Zinc fingers are ubiquitous small protein domains which have a Zn(Cys)(4-x)(His)(x) site. They possess great diversity in their structure and amino acid composition. Using a family of six peptides, it was possible to assess the influence of hydrophobic amino acids on the metal-peptide affinities and on the rates of metal association and dissociation. A model of a treble-clef zinc finger, a model of the zinc finger site of a redox-switch protein, and four variants of the classical ββα zinc finger were used. They differ in their coordination set, their sequence length, and their hydrophobic amino acid content. The speciation, metal binding constants, and structure of these peptides have been investigated as a function of pH. The zinc binding constants of peptides, which adopt a well-defined structure, were found to be around 10(15) at pH 7.0. The rates of zinc exchange between EDTA and the peptides were also assessed. We evidenced that the packing of hydrophobic amino acids into a well-defined hydrophobic core can have a drastic influence on both the binding constant and the kinetics of metal exchange. Notably, well-packed hydrophobic amino acids can increase the stability constant by 4 orders of magnitude. The half-life of zinc exchange was also seen to vary significantly depending on the sequence of the zinc finger. The possible causes for this behavior are discussed. This work will help in understanding the dynamics of zinc exchange in zinc-containing proteins.     

Total chemical synthesis of crambin

Crambin is a small (46 amino acids) protein isolated from the seeds of the plant Crambe abyssinica. Crambin has been extensively used as a model protein for the development of advanced crystallography and NMR techniques and for computational folding studies. We set out to establish synthetic access to crambin. Initially, we synthesized the 46 amino acid polypeptide by native chemical ligation of two distinct sets of peptide segments (15 + 31 and 31 + 15 residues). The synthetic polypeptide chain folded in good yield to give native crambin containing three disulfide bonds. The chemically synthesized crambin was characterized by LC-MS and by 2D-NMR. However, the 31-residue peptide segments were difficult to purify, and this caused an overall low yield for the synthesis. To overcome this problem, we synthesized crambin by the native chemical ligation of three segments (15 + 16 + 15 residues). Total synthesis using the ligation of three segments gave more than a 10-fold increase in yield and a protein product of exceptionally high purity. This work demonstrates the efficacy of chemical protein synthesis by the native chemical ligation of three segments and establishes efficient synthetic access to the important model protein crambin for experimental studies of protein folding and stability.     

Contribution of individual zinc ligands to metal binding and peptide folding of zinc finger peptides

Little is known about the contribution of individual zinc-ligating amino acid residues for coupling between zinc binding and protein folding in zinc finger domains. To understand such roles of each zinc ligand, four zinc finger mutant peptides corresponding to the second zinc finger domain of Sp1 were synthesized. In the mutant peptides, glycine was substituted for one of four zinc ligands. Their metal binding and folding properties were spectroscopically characterized and compared to those of the native zinc finger peptide. In particular, the electronic charge-transfer and d-d bands of the Co(II)-substituted peptide complexes were used to examine the metal coordination number and geometry. Fluorescence emission studies revealed that the mutant peptides are capable of binding zinc despite removing one ligand. Circular dichroism results clearly showed the induction of an alpha-helix by zinc binding. In addition, the structures of certain mutant zinc finger peptides were simulated by molecular dynamics calculation. The information indicates that His23 and the hydrophobic core formed between the alpha-helix and the beta-sheet play an essential role in alpha-helix induction. This report demonstrates that each ligand does not contribute equally to alpha-helix formation and coordination geometry in the zinc finger peptide.     

Design of thiol-containing amino acids for native chemical ligation at non-Cys sites

<正>Protein chemical synthesis usually relies on the use of native chemical ligation that couples peptide thioester with a Cys-peptide.A limitation of this method is the difficulty of finding an appropriate Cys ligation site in many synthetic targets.To overcome this problem,the ligation-desulfurization approach has been developed.This approach involves the use of a thiol-containing amino acid as the ligation partner.After the sequence assembly is completed,the thiol group is removed through a desulfurization reaction to generate the standard amino acids.Currently this strategy has been applied to the ligations at a number of amino acids including Ala,Phe,Val,Lys,Thr,Leu,Pro and Gln.The present article reviews the design and synthesis of these thiol-containing amino acids for native chemical ligation at non-Cys sites.     

Recent developments in peptide ligation independent of amino acid side-chain functional group

Chemical synthesis of peptides and proteins has evolved into an indispensable tool for chemical biology. Peptide ligation is a straightforward technique for joining two short peptide fragments together via a native peptide bond to afford a larger natural peptide or protein. However, the junction sites are limited to several specific amino acids because most peptide ligations involve participation of the side-chain functional groups of the junction-site amino acids. To overcome such intrinsic limitations, “general” peptide ligations which do not rely on the side-chain functional group have been developed. This review summarized the recent developments in peptide ligations that are independent of side-chain functional group of ligation-junction-site amino acid.     

Sequence-selective and hydrolytic cleavage of DNA by zinc finger mutants

We have reported the successful conversion of the structural zinc site in zinc finger peptides to a functional zinc site. A series of resulting zinc finger mutants exhibit the hydrolytic ability of the activated ester depending on the coordination geometry and acidity of the zinc ions. In this study, we explored the hydrolytic ability of DNA by the H4 mutant since the mutant showed the highest hydrolytic ability of the activated ester among the series of mutant peptides. The zinc-bound form of the H4 mutant peptide exhibited the hydrolytic ability of activated phosphoesters and even converted the supercoiled plasmid to the nicked circular form. An increasing ionic strength leads to a loss in the nuclease ability of the zinc finger mutants due to the nonspecific interaction between the zinc finger peptide and DNA. In sharp contrast, the three-tandem H4-type zinc finger protein performed the specific DNA hydrolysis at the GC box even at a high ionic strength. Thus, the present study demonstrated that converting the native zinc site to the hydrolytic zinc site in the zinc finger protein is a novel approach for creating artificial nucleases with sequence selectivity.     

Extending synthetic access to proteins with a removable acyl transfer auxiliary

A chemo- and regioselective auxiliary-mediated peptide ligation has been developed that is effective under nonidealized conditions for the synthesis of proteins. This general amide bond ligation utilizes a removable auxiliary that is analogous to the role of cysteine in native chemical ligation, combining chemoselective thioester exchange with efficient regioselective intramolecular acyl transfer. Acid lability and improved ligation efficiency were introduced into the 2-mercaptobenzyl auxiliary by increasing the electron density of the aromatic ring. The 62 amino acid SH3 domain from alpha-spectrin was synthesized using the auxiliary-mediated ligation at a Lys-Gly sequence. The auxiliary was removed with TFA and scavengers from the ligated product. This methodology enables unprotected peptides to be coupled at noncysteine ligation sites expanding the scope of protein synthesis and semisynthesis.     

蛋白质的化学全合成

含有非天然氨基酸的蛋白质（如翻译后修饰蛋白质、修饰有探针分子的蛋白质等）是化学生物学中重要的生理活性分子。这些分子难以通过生物表达来获取，而必须使用化学方法来合成。半胱氨酸肽片段连接方法是目前应用于蛋白质化学全合成中的一种重要方法，该方法能够在温和的水溶液中高效地实现肽片段的连接，从而生成天然或者非天然的蛋白质。本文系统地综述了半胱氨酸肽片段连接方法的基本原理，详细讨论了近年来人们对该方法的一些重要改进。最后又介绍了该方法在几类重要的蛋白质分子合成中的代表性应用。     

Role of protein structure and the role of individual fingers in zinc finger protein–DNA recognition: a molecular dynamics simulation study and free energy calculations

Molecular dynamics and MM_GBSA energy calculations on various zinc finger proteins containing three and four fingers bound to their target DNA gave insights into the role of each finger in the DNA binding process as part of the protein structure. The wild type Zif 268 (PDB code: 1AAY) gave a ΔG value of ??76.1 (14) kcal/mol. Zinc fingers ZF1, ZF2 and ZF3 were mutated in one experiment and in another experiment one finger was cut and the rest of the protein was studied for binding. The ΔΔG values for the Zinc Finger protein with both ZF1 and ZF2 mutated was +?80 kcal/mol, while mutating only ZF1 the ΔΔG value was +?52 kcal/mol (relative to the wild type). Cutting ZF3 and studying the protein consisting only of ZF1 linked to ZF2 gave a ΔΔG value of +?68 kcal/mol. Upon cutting ZF1, the resulting ZF2 linked to ZF3 protein gave a ΔΔG value of +?41 kcal/mol. The above results shed light on the importance of each finger in the binding process, especially the role of ZF1 as the anchoring finger followed in importance by ZF2 and ZF3. The energy difference between the binding of the wild type protein Zif268 (1AAY) and that for individual finger binding to DNA according to the formula: ΔΔG_{linkers, otherstructuralfactors}?=?ΔG_zif268???(ΔG_F1+F2+F3) gave a value?=???44.5 kcal/mol. This stabilization can be attributed to the contribution of linkers and other structural factors in the intact protein in the DNA binding process. DNA binding energies of variant proteins of the wild type Zif268 which differ in their ZF1 amino acid sequence gave evidence of a good relationship between binding energy and recognition and specificity, this finding confirms the reported vital role of ZF1 in the ZF protein scanning and anchoring to the target DNA sequence. The role of hydrogen bonds in both specific and nonspecific amino acid-DNA contacts is discussed in relation to mutations. The binding energies of variant Zinc Finger proteins confirmed the role of ZF1 in the recognition, specificity and anchoring of the zinc finger protein to DNA.     

DNA sequence-enabled reassembly of the green fluorescent protein

We describe a general methodology for the direct detection of DNA by the design of a split-protein system that reassembles to form an active complex only in the presence of a targeted DNA sequence. This approach, called SEquence Enabled Reassembly (SEER) of proteins, combines the ability to rationally dissect proteins to construct oligomerization-dependent protein reassembly systems and the availability of DNA binding Cys2-His2 zinc-finger motifs for the recognition of specific DNA sequences. We demonstrate the feasibility of the SEER approach utilizing the split green fluorescent protein appended to appropriate zinc fingers, such that chromophore formation is only catalyzed in the presence of DNA sequences that incorporate binding sites for both zinc fingers.     

Chemical synthesis of a cyclotide via intramolecular cyclization of peptide O-esters

Cyclotides constitute a fascinating family of circular proteins containing ca.30 amino acid residues.They have a unique cyclic cysteine knot topology and exhibit remarkable thermal,chemical and enzymatic stabilities.These characteristics enable them to have a range of biological activities and promising pharmaceutical and agricultural applications.Here,we present a practical strategy for the chemical synthesis of cyclotides through the intramolecular ligation of fully unprotected peptide O-esters.This strategy involves the mild Fmoc solid-phase peptide synthesis of the peptide O-ester backbone,the head-to-tail cyclization of the cyclotide backbone by native chemical ligation,and the oxidative refolding to yield the natural knot protein.The simplicity and high efficiency of the strategy can be employed in the synthesis of artificial cyclotides for pharmaceutical applications.     

Effect of arginine on stability of GST-ZNF191（243-368）

For better understanding the chemical or biological information of ZNF191(243-368), we expressed the fusion protein of GST and ZNF191(243-368), and used it to obtain the binding DNA sequence of this zinc finger protein. But in the process of expression and purification, we found this fusion protein slowly degradated. For resolving this problem, we simultaneously added charged amino acids L-Arg and L-Glu to the solution of fusion protein, and demonstrated that this method can dramatically increase the stability of this fusion protein. This method can make the fusion protein suitable for the continuous works, especially for situations where high protein concentration and long-term stability without precipitate and degradation of protein are required.     

Biosynthetic phage display: a novel protein engineering tool combining chemical and genetic diversity

BACKGROUND: Molecular diversity in nature is developed through a combination of genetic and chemical elements. We have developed a method that permits selective manipulation of both these elements in one protein engineering tool. It combines the ability to introduce non-natural amino acids into a protein using native chemical ligation with exhaustive targeted mutagenesis of the protein via phage-display mutagenesis. RESULTS: A fully functional biosynthetic version of the protease inhibitor eglin c was constructed. The amino-terminal fragment (residues 8-40) was chemically synthesized with a non-natural amino acid at position 25. The remaining carboxy-terminal fragment was expressed as a 30-residue peptide extension of gIIIp or gVIIIp on filamentous phage in a phage-display mutagenesis format. Native chemical ligation was used to couple the two fragments and produced a protein that refolded to its active form. To facilitate the packing of the introduced non-natural amino acid, residues 52 and 54 in the carboxy-terminal fragment were fully randomized by phage-display mutagenesis. Although the majority of the observed solutions for residues 52 and 54 were hydrophobic - complementing the stereochemistry of the introduced non-natural amino acid - a significant number of residues (unexpected because of stereochemical and charge criteria) were observed in these positions. CONCLUSIONS: Peptide synthesis and phage-display mutagenesis can be combined to produce a very powerful protein engineering tool. The physical properties of the environment surrounding the introduced non-natural residue can be selected for by evaluating all possible combinations of amino acid types at a targeted set of sites using phage-display mutagenesis.     

Mirror image forms of snow flea antifreeze protein prepared by total chemical synthesis have identical antifreeze activities

The recently discovered glycine-rich snow flea antifreeze protein (sfAFP) has no sequence homology with any known proteins. No experimental structure has been reported for this interesting protein molecule. Here we report the total chemical synthesis of the mirror image forms of sfAFP (i.e., L-sfAFP, the native protein, and D-sfAFP, the native protein's enantiomer). The predicted 81 amino acid residue polypeptide chain of sfAFP contains Cys residues at positions 1, 13, 28, and 43 and was prepared from four synthetic peptide segments by sequential native chemical ligation. After purification, the full-length synthetic polypeptide was folded at 4 degrees C to form the sfAFP protein containing two disulfides. Chemically synthesized sfAFP had the expected antifreeze activity in an ice recrystallization inhibition assay. Mirror image D-sfAFP protein was prepared by the same synthetic strategy, using peptide segments made from d-amino acids, and had an identical but opposite-sign CD spectrum. As expected, D-sfAFP displays the same antifreeze properties as L-sfAFP, because ice presents an achiral surface for sfAFP binding. Facile synthetic access to sfAFP will enable determination of its molecular structure and systematic elucidation of the molecular basis of the antifreeze properties of this unique protein.     

Single-nucleotide-specific PNA-peptide ligation on synthetic and PCR DNA templates

DNA-directed chemical synthesis has matured into a useful tool with applications such as fabrication of defined (nano)molecular architectures, evolution of amplifiable small-molecule libraries, and nucleic acid detection. Most commonly, chemical methods were used to join oligonucleotides under the control of a DNA or RNA template. The full potential of chemical ligation reactions can be uncovered when nonnatural oligonucleotide analogues that can provide new opportunities such as increased stability, DNA affinity, hybridization selectivity, and/or ease and accuracy of detection are employed. It is shown that peptide nucleic acid (PNA) conjugates, nonionic biostable DNA analogues, allowed the fashioning of highly chemoselective and sequence-selective peptide ligation methods. In particular, PNA-mediated native chemical ligations proceed with sequence selectivities and ligation rates that reach those of ligase-catalyzed oligodeoxynucleotide reactions. Usually, sequence-specific ligations can only be achieved by employing short-length probes, which show DNA affinities that are too low to allow stable binding to target segments in large, double-stranded DNA. It is demonstrated that the PNA-based ligation chemistry allowed the development of a homogeneous system in which rapid single-base mutation analyses can be performed even on double-stranded PCR DNA templates.     

Alternative heterocycles for DNA recognition: the benzimidazole/imidazole pair

Boc-protected benzimidazole-pyrrole, benzimidazole-imidazole, and benzimidazole-methoxypyrrole amino acids were synthesized and incorporated into DNA binding polyamides, comprised of N-methyl pyrrole and N-methyl imidazole amino acids, by means of solid-phase synthesis on an oxime resin. These hairpin polyamides were designed to determine the DNA recognition profile of a side-by-side benzimidazole/imidazole pair for the designated six base pair recognition sequence. Equilibrium association constants of the polyamide-DNA complexes were determined at two of the six base pair positions of the recognition sequence by quantitative DNase I footprinting titrations on DNA fragments each containing matched and single base pair mismatched binding sites. The results indicate that the benzimidazole-heterocycle building blocks can replace pyrrole-pyrrole, pyrrole-imidazole, and pyrrole-hydroxypyrrole constructs while retaining relative site specifities and subnanomolar match site affinities. The benzimidazole-containing hairpin polyamides represent a novel class of DNA binding ligands featuring tunable target recognition sequences combined with the favorable properties of the benzimidazole type DNA minor groove binders.     

DNA-directed formation of peptide bond: a model study toward DNA-programmed peptide ligation

A model study of DNA-directed peptide ligation has been developed by transferring fluorescent reporting group from small molecule thioester to a DNA strand (template DNA) in the presence of a thiol-functionalized DNA strand (auxiliary DNA), mimicking the Native Chemical Ligation (NCL) reaction. This DNA-directed transfer shows dependence on the sequence complementarity of the two DNA strands, with in situ generated 4-thiolphenylmethyl functionalized oligonucleotide as the auxiliary DNA strand, under mild basic condition (pH=8.5), and with tris(2-carboxyethyl) phosphine hydrochloride (TCEP) as a reducing agent. Reactions with different amino acid α-thioesters resulted in varied transfer efficiencies from glycine to α-substituted amino acids. This study has provided the basic foundation to use DNA-programmed chemistry toward the chemical synthesis or unnatural modification of protein molecules.