Sticky fingers: zinc-fingers as protein-recognition motifs

Zinc-fingers (ZnFs) are extremely abundant in higher eukaryotes. Once considered to function exclusively as sequence-specific DNA-binding motifs, ZnFs are now known to have additional activities such as the recognition of RNA and other proteins. Here we discuss recent advances in our understanding of ZnFs as specific modules for protein recognition. Structural studies of ZnF complexes reveal considerable diversity in terms of protein partners, binding modes and affinities, and highlight the often underestimated versatility of ZnF structure and function. An appreciation of the structural features of ZnF-protein interactions will contribute to our ability to engineer and to use ZnFs with tailored protein-binding properties.     

Deciphering metal ion preference and primary coordination sphere robustness of a designed zinc finger with high‐resolution mass spectrometry

Small zinc finger (ZnF) motifs are promising molecular scaffolds for protein design owing to their structural robustness and versatility. Moreover, their characterization provides important insights into protein folding in general. ZnF motifs usually possess an exceptional specificity and high affinity towards Zn(II) ion to drive folding. While the Zn(II) ion is canonically coordinated by two cysteine and two histidine residues, many other coordination spheres also exist in small ZnFs, all having four amino acid ligands. Here we used high‐resolution mass spectrometry to study metal ion binding specificity and primary coordination sphere robustness of a designed zinc finger, named MM1. Based on the results, MM1 possesses high specificity for zinc with sub‐micromolar binding affinity. Surprisingly, MM1 retains metal ion binding affinity even in the presence of selective alanine mutations of the primary zinc coordinating amino acid residues.     

Characterization of a family of RanBP2-type zinc fingers that can recognize single-stranded RNA

The recognition of single-stranded RNA (ssRNA) is an important aspect of gene regulation, and a number of different classes of protein domains that recognize ssRNA in a sequence-specific manner have been identified. Recently, we demonstrated that the RanBP2-type zinc finger (ZnF) domains from the human splicing factor ZnF Ran binding domain-containing protein 2 (ZRANB2) can bind to a sequence containing the consensus AGGUAA. Six other human proteins, namely, Ewing's sarcoma (EWS), translocated in liposarcoma (TLS)/FUS, RNA-binding protein 56 (RBP56), RNA-binding motif 5 (RBM5), RNA-binding motif 10 (RBM10) and testis-expressed sequence 13A (TEX13A), each contains a single ZnF with homology to the ZRANB2 ZnFs, and several of these proteins have been implicated in the regulation of mRNA processing. Here, we show that all of these ZnFs are able to bind with micromolar affinities to ssRNA containing a GGU motif. NMR titration data reveal that binding is mediated by the corresponding surfaces on each ZnF, and we also show that sequence selectivity is largely limited to the GGU core motif and that substitution of the three flanking adenines that were selected in our original selection experiment has a minimal effect on binding affinity. These data establish a subset of RanBP2-type ZnFs as a new family of ssRNA-binding motifs.     

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.     

Solution structures of two CCHC zinc fingers from the FOG family protein U-shaped that mediate protein-protein interactions

BACKGROUND: Zinc finger domains have traditionally been regarded as sequence-specific DNA binding motifs. However, recent evidence indicates that many zinc fingers mediate specific protein-protein interactions. For instance, several zinc fingers from FOG family proteins have been shown to interact with the N-terminal zinc finger of GATA-1. RESULTS: We have used NMR spectroscopy to determine the first structures of two FOG family zinc fingers that are involved in protein-protein interactions: fingers 1 and 9 from U-shaped. These fingers resemble classical TFIIIA-like zinc fingers, with the exception of an unusual extended portion of the polypeptide backbone prior to the fourth zinc ligand. [15N,(1)H]-HSQC titrations have been used to define the GATA binding surface of USH-F1, and comparison with other FOG family proteins indicates that the recognition mechanism is conserved across species. The surface of FOG-type fingers that interacts with GATA-1 overlaps substantially with the surface through which classical fingers typically recognize DNA. This suggests that these fingers could not contact both GATA and DNA simultaneously. In addition, results from NMR, gel filtration, and sedimentation equilibrium experiments suggest that the interactions are of moderate affinity. CONCLUSIONS: Our results demonstrate unequivocally that zinc fingers comprising the classical betabetaalpha fold are capable of mediating specific contacts between proteins. The existence of this alternative function has implications for the prediction of protein function from sequence data and for the evolution of protein function.     

GATA-1 bends DNA in a site-independent fashion

The DNA binding domain of GATA-1 consists of two adjacent homologous zinc fingers, of which only the C-terminal finger binds DNA independently. Solution structure studies have shown that the DNA is bent by about 15 degrees in the complex formed with the single C-terminal finger of GATA-1. The N-terminal finger stabilizes DNA binding at some sites. To determine whether it contributes to DNA bending, we have performed circular permutation DNA bending experiments with a variety of DNA-binding sites recognized by GATA-1. By using a series of full-length GATA-1, double zinc finger, and single C-terminal finger constructs, we show that GATA-1 bends DNA by about 24 degrees, irrespective of the DNA-binding site. We propose that the N- and C-terminal fingers of GATA-1 adopt different orientations when bound to different cognate DNA sites. Furthermore, we characterize circular permutation bending artifacts arising from the reduced gel mobility of the protein-DNA complexes.     

Use of altered specificity mutants to probe a specific protein-protein interaction in differentiation: the GATA-1:FOG complex

GATA-1 and FOG (Friend of GATA-1) are each essential for erythroid and megakaryocyte development. FOG, a zinc finger protein, interacts with the amino (N) finger of GATA-1 and cooperates with GATA-1 to promote differentiation. To determine whether this interaction is critical for GATA-1 action, we selected GATA-1 mutants in yeast that fail to interact with FOG but retain normal DNA binding, as well a compensatory FOG mutant that restores interaction. These novel GATA-1 mutants do not promote erythroid differentiation of GATA-1- erythroid cells. Differentiation is rescued by the second-site FOG mutant. Thus, interaction of FOG with GATA-1 is essential for the function of GATA-1 in erythroid differentiation. These findings provide a paradigm for dissecting protein-protein associations involved in mammalian development.     

Metal-dependent stabilization of an active HMG protein

Using a cloned single domain of the high mobility group protein 1 (HMGB1), we evaluated the effect of introducing metal binding site(s) on protein stability and function. An HMG domain is a conserved sequence of approximately 80 amino acids rich in basic, aromatic and proline residues that is active in binding DNA in a sequence- or structure-specific manner. The design strategy focuses on anchoring selected regions of the protein, specifically loops and turns in the molecule, using His-metal ligands. Changes in secondary structure, thermostability and DNA binding properties of a series of such mutants were evaluated. The two most stable mutant constructs contain three surface histidine replacements (two metal binding sites) in the regions encompassing both turns of the molecule. On ligation with the divalent nickel cation, the stability of these two triple histidine mutants (I38H/N51H/D55H and G39H/N51H/D55H) increases by 1.3 and 1.6 kcal/mol, respectively, relative to the wild-type protein, although the creation of binding sites per se destabilizes the protein. The DNA-binding properties of the modified proteins are not impaired by the introduction of the metal binding motifs. These results indicate that it is feasible to stabilize protein tertiary structure using appropriate placement of surface His-metal bonds without loss of function.     

水稻RNA结合蛋白C3H12与RNA结合位点的鉴定

CCH型锌指蛋白质C3H12是进化上保守的RNA结合蛋白质,它含有5个串联的CCCH锌指结构域ZnF1-5,形成2个紧密的锌指簇ZnF1-3和ZnF4-5。早期的研究发现,C3H12可能通过与mRNA结合的方式在转录后水平调控基因的表达。然而,与C3H12结合的mRNA类型和他们的结合模式,并未通过实验得到证明。本文表达纯化了一系列C3H12截短及全长蛋白质,并合成了一些潜在RNA底物ARE9、ARE19及对照Random21。通过等温滴定量热法 (isothermal titration calorimetry, ITC) 确定了C3H12与富含腺嘌呤尿嘧啶单元 (AU-rich element, ARE) mRNA底物的结合,并揭示了互作核心区域和热力学性质。通过荧光光谱分析和微型热泳动 (microscale thermophoresis, MST)技术对ITC的结果进一步佐证。结果表明：(1) C3H12与ARE底物的相互作用是焓驱动的能量有利的 (ΔG<0) 特异性结合,结合比为1:1。(2) C3H12与ARE19的亲和力较ARE9更高（约2倍）。(3) C3H12中ZnF1-3在与ARE类底物的结合活性中发挥主导作用。(4) C3H12结构中的141个氨基酸残基的接头不直接参与和ARE底物的相互作用。本研究揭示的CCCH型锌指蛋白质C3H12与ARE底物结合模式,将为进一步在分子结构水平阐明C3H12与ARE底物结合的机制奠定基础。     

水稻RNA结合蛋白C3H12与RNA结合位点的鉴定

CCH型锌指蛋白质C3H12是进化上保守的RNA结合蛋白质,它含有5个串联的CCCH锌指结构域ZnF1-5,形成2个紧密的锌指簇ZnF1-3和ZnF4-5。早期的研究发现,C3H12可能通过与mRNA结合的方式在转录后水平调控基因的表达。然而,与C3H12结合的mRNA类型和他们的结合模式,并未通过实验得到证明。本文表达纯化了一系列C3H12截短及全长蛋白质,并合成了一些潜在RNA底物ARE9、ARE19及对照Random21。通过等温滴定量热法 (isothermal titration calorimetry, ITC) 确定了C3H12与富含腺嘌呤尿嘧啶单元 (AU-rich element, ARE) mRNA底物的结合,并揭示了互作核心区域和热力学性质。通过荧光光谱分析和微型热泳动 (microscale thermophoresis, MST)技术对ITC的结果进一步佐证。结果表明：(1) C3H12与ARE底物的相互作用是焓驱动的能量有利的 (ΔG<0) 特异性结合,结合比为1:1。(2) C3H12与ARE19的亲和力较ARE9更高（约2倍）。(3) C3H12中ZnF1-3在与ARE类底物的结合活性中发挥主导作用。(4) C3H12结构中的141个氨基酸残基的接头不直接参与和ARE底物的相互作用。本研究揭示的CCCH型锌指蛋白质C3H12与ARE底物结合模式,将为进一步在分子结构水平阐明C3H12与ARE底物结合的机制奠定基础。