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.     

一种特异识别SV40启动子的人工转录因子的构建

转录因子是真核表达调控中非常重要的一类反式作用因子,通常由DNA结合域与效应域两部分组成,而锌指结构是DNA结合域的常见组成单元。人工转录因子就是基于转录因子的这种结构特点,人为地选择针对特定序列的DNA结合域与具有特定作用的效应域组合而成。利用噬菌体展示技术,筛选到与SV40启动子上9bp序列特异结合的锌指结构,再连接KOX1的KRAB域构建了一种人工转录因子。转染实验表明它对SV40下游的报告基因的表达有很显著的抑制作用。     

Pentaprobe: a comprehensive sequence for the one-step detection of DNA-binding activities

The rapid increase in the number of novel proteins identified in genome projects necessitates simple and rapid methods for assigning function. We describe a strategy for determining whether novel proteins possess typical sequence-specific DNA-binding activity. Many proteins bind recognition sequences of 5 bp or less. Given that there are 4⁵ possible 5 bp sites, one might expect the length of sequence required to cover all possibilities would be 4⁵ × 5 or 5120 nt. But by allowing overlaps, utilising both strands and using a computer algorithm to generate the minimum sequence, we find the length required is only 516 base pairs. We generated this sequence as six overlapping double-stranded oligonucleotides, termed pentaprobe, and used it in gel retardation experiments to assess DNA binding by both known and putative DNA-binding proteins from several protein families. We have confirmed binding by the zinc finger proteins BKLF, Eos and Pegasus, the Ets domain protein PU.1 and the treble clef N- and C-terminal fingers of GATA-1. We also showed that the N-terminal zinc finger domain of FOG-1 does not behave as a typical DNA-binding domain. Our results suggest that pentaprobe, and related sequences such as hexaprobe, represent useful tools for probing protein function.     

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

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

人工转录因子研究进展

转录因子是真核表达调控中非常重要的一类反式作用因子,通常由DNA结合结构域与效应结构域两部分组成,研究发现这两个结构域可以各自独立发生作用。基于转录因子的这种结构特点,可以人为地选择针对特定序列的DNA结合结构域与具有特定作用的效应结构域构建人工转录因子。目前人工转录因子的DNA结合结构域多为C₂H₂ 型锌指结构,每一个锌指单元由大约30个氨基酸组成,识别DNA双螺旋大沟中相连的3bp序列,并可通过氢键作用与相应的碱基结合;多个锌指可以串联成簇,从而识别并结合较长的DNA序列区域。常见的人工转录因子的效应结构域有激活结构域以及抑制结构域,不同的效应结构域赋予人工转录因子不同的功能。目前人工转录因子已经在基础研究、药物设计以及基因治疗等领域得到了广泛的应用。     

Prediction of DNA-binding specificity in zinc finger proteins

Zinc finger proteins interact via their individual fingers to three base pair subsites on the target DNA. The four key residue positions -1, 2, 3 and 6 on the alpha-helix of the zinc fingers have hydrogen bond interactions with the DNA. Mutating these key residues enables generation of a plethora of combinatorial possibilities that can bind to any DNA stretch of interest. Exploiting the binding specificity and affinity of the interaction between the zinc fingers and the respective DNA can help to generate engineered zinc fingers for therapeutic purposes involving genome targeting. Exploring the structure-function relationships of the existing zinc finger-DNA complexes can aid in predicting the probable zinc fingers that could bind to any target DNA. Computational tools ease the prediction of such engineered zinc fingers by effectively utilizing information from the available experimental data. A study of literature reveals many approaches for predicting DNA-binding specificity in zinc finger proteins. However, an alternative approach that looks into the physico-chemical properties of these complexes would do away with the difficulties of designing unbiased zinc fingers with the desired affinity and specificity. We present a physico-chemical approach that exploits the relative strengths of hydrogen bonding between the target DNA and all combinatorially possible zinc fingers to select the most optimum zinc finger protein candidate.     

真核生物中锌指蛋白的结构与功能

真核生物中的许多蛋白质分子包含锌指结构区,这类蛋白称为锌指蛋白.锌指蛋白因其包含特殊的指状结构,在对DNA、蛋白质和RNA的识别和结合中起重要作用.许多锌指蛋白的锌指结构域包含能与DNA特异结合的区域,并与某些效应结构域（如KRAB、SCAN、BTB/POZ、SNAG、SANT和PLAG等）相连,这类锌指蛋白常作为转录因子起作用,可调控靶基因的转录.一些锌指蛋白包含蛋白质识别结构域（如LIM锌指、MYND锌指、PHD锌指和RING锌指等）,它们能够特异地介导蛋白质之间的相互作用,因此被称作蛋白适配器.此外,某些锌指蛋白还可以结合RNA,起转录后调控作用.本文就锌指蛋白与DNA、RNA以及蛋白质分子间的相互作用作一综述.     

Solution structure of the N-terminal zinc fingers of the Xenopus laevis double-stranded RNA-binding protein ZFa

Several zinc finger proteins have been discovered recently that bind specifically to double-stranded RNA. These include the mammalian JAZ and wig proteins, and the seven-zinc finger protein ZFa from Xenopus laevis. We have determined the solution structure of a 127 residue fragment of ZFa, which consists of two zinc finger domains connected by a linker that remains unstructured in the free protein in solution. The first zinc finger consists of a three-stranded beta-sheet and three helices, while the second finger contains only a two-stranded sheet and two helices. The common structures of the core regions of the two fingers are superimposable. Each finger has a highly electropositive surface that maps to a helix-kink-helix motif. There is no evidence for interactions between the two fingers, consistent with the length (24 residues) and unstructured nature of the intervening linker. Comparison with a number of other proteins shows similarities in the topology and arrangement of secondary structure elements with canonical DNA-binding zinc fingers, with protein interaction motifs such as FOG zinc fingers, and with other DNA-binding and RNA-binding proteins that do not contain zinc. However, in none of these cases does the alignment of these structures with the ZFa zinc fingers produce a consistent picture of a plausible RNA-binding interface. We conclude that the ZFa zinc fingers represent a new motif for the binding of double-stranded RNA.