CD spectra show the relational style between Zic-, Gli-, Glis-zinc finger protein and DNA

Zic family proteins have five C2H2-type zinc finger motifs. The Zic-zinc finger domains show high homology to the corresponding domains of the Gli and Glis families, which also contain five C2H2-type zinc finger motifs. The zinc finger motifs of the proteins of these three protein families form an alpha-helix conformation in solution. The addition of oligo DNA that included a Gli-binding sequence increased the alpha-helix content estimated by using circular dichroism spectroscopy. Comparison of the Zic-, Gli-, and Glis-zinc fingers indicated that the alpha-helix content after the addition of oligo DNA correlated well with the affinity of each zinc finger for the oligo DNA (correlation coefficient, 0.85). The importance of the zinc ion for protein folding was reflected in a reduction in the alpha-helix content upon removal of the zinc ion. Owing to the compact globular structure, the alpha-helix structure of the proteins of these three protein families is extremely thermally stable. These results suggest that the alpha-helix structure is important for DNA binding and profoundly related to functional and structural diversity among the three families.     

Structure and DNA binding characteristics of the three‐Cys2His2 domain of mouse testis zinc finger protein

The C‐terminal three‐Cys₂His₂ zinc‐finger domain (TZD) of mouse testis zinc‐finger protein binds to the 5′‐TGTACAGTGT‐3′ at the Aie1 (aurora‐C) promoter with high specificity. Interestingly, the primary sequence of TZD is unique, possessing two distinct linkers, TGEKP and GAAP, and distinct residues at presumed DNA binding sites at each finger, especially finger 3. A K_d value of ～10^?8 M was obtained from surface plasmon resonance analysis for the TZD‐DNA complex. NMR structure of the free TZD showed that each zinc finger forms a typical ββα fold. On binding to DNA, chemical shift perturbations and the R₂ transverse relaxation rate in finger 3 are significantly smaller than those in fingers 1 and 2, which indicates that the DNA binding affinity in finger 3 is weaker. Furthermore, the shift perturbations between TZD in complex with the cognate DNA and its serial mutants revealed that both ADE7 and CYT8, underlined in 5′‐ATATGTACAGTGTTAT‐3′, are critical in specific binding, and the DNA binding in finger 3 is sequence independent. Remarkably, the shift perturbations in finger 3 on the linker mutation of TZD (GAAP mutated to TGEKP) were barely detected, which further indicates that finger 3 does not play a critical role in DNA sequence‐specific recognition. The complex model showed that residues important for DNA binding are mainly located on positions ?1, 2, 3, and 6 of α‐helices in fingers 1 and 2. The DNA sequence and nonsequence‐specific bindings occurring simultaneously in TZD provide valuable information for better understanding of protein–DNA recognition. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Keep Your Fingers Off My DNA: Protein–Protein Interactions Mediated by C2H2 Zinc Finger Domains

Cys2-His2 (C2H2) zinc finger domains (ZFs) were originally identified as DNA-binding domains, and uncharacterized domains are typically assumed to function in DNA binding. However, a growing body of evidence suggests an important and widespread role for these domains in protein binding. There are even examples of zinc fingers that support both DNA and protein interactions, which can be found in well-known DNA-binding proteins such as Sp1, Zif268, and Ying Yang 1 (YY1). C2H2 protein–protein interactions (PPIs) are proving to be more abundant than previously appreciated, more plastic than their DNA-binding counterparts, and more variable and complex in their interactions surfaces. Here we review the current knowledge of over 100 C2H2 zinc finger-mediated PPIs, focusing on what is known about the binding surface, contributions of individual fingers to the interaction, and function. An accurate understanding of zinc finger biology will likely require greater insights into the potential protein interaction capabilities of C2H2 ZFs.     

C2H2型锌指蛋白结合的DNA序列预测方法的研究进展

C2H2型锌指蛋白是哺乳动物中数量最多的一类转录调控因子.C2H2型锌指蛋白中含有的C2H2型锌指基序多是不相同的,表明它们很可能结合不同的DNA序列,从而调控不同的基因,行使多样化的调控功能.然而,目前大多数C2H2型锌指蛋白结合的DNA序列仍不明确,这阻碍了C2H2型锌指蛋白的功能研究.目前,针对C2H2型锌指蛋白的靶序列预测已有一些初步的研究.本文介绍了C2H2型锌指基序与DNA结合的经典模式,并对C2H2型锌指蛋白靶序列预测方法中所用到的算法、训练集、金标准数据集及相应工具进行了全面系统的总结归纳,旨在丰富对C2H2型锌指蛋白靶序列预测原理和工具的认识,为C2H2型锌指蛋白靶序列的精确预测和更深入的功能研究打下基础.     

A structural approach reveals how neighbouring C2H2 zinc fingers influence DNA binding specificity

Development of an accurate protein–DNA recognition code that can predict DNA specificity from protein sequence is a central problem in biology. C₂H₂ zinc fingers constitute by far the largest family of DNA binding domains and their binding specificity has been studied intensively. However, despite decades of research, accurate prediction of DNA specificity remains elusive. A major obstacle is thought to be the inability of current methods to account for the influence of neighbouring domains. Here we show that this problem can be addressed using a structural approach: we build structural models for all C₂H₂-ZF–DNA complexes with known binding motifs and find six distinct binding modes. Each mode changes the orientation of specificity residues with respect to the DNA, thereby modulating base preference. Most importantly, the structural analysis shows that residues at the domain interface strongly and predictably influence the binding mode, and hence specificity. Accounting for predicted binding mode significantly improves prediction accuracy of predicted motifs. This new insight into the fundamental behaviour of C₂H₂-ZFs has implications for both improving the prediction of natural zinc finger-binding sites, and for prioritizing further experiments to complete the code. It also provides a new design feature for zinc finger engineering.     

Swapping of the beta-hairpin region between Sp1 and GLI zinc fingers: significant role of the beta-hairpin region in DNA binding properties of C2H2-type zinc finger peptides

The recent design strategy of zinc finger peptides has mainly focused on the alpha-helix region, which plays a direct role in DNA recognition. On the other hand, the study of non-DNA-contacting regions is extremely scarce. By swapping the beta-hairpin regions between the Sp1 and GLI zinc fingers, in this study, we investigated how the beta-hairpin region of the C(2)H(2)-type zinc finger peptides contributes to the DNA binding properties. Surprisingly, the Sp1 mutant with the GLI-type beta-hairpin had a higher DNA binding affinity than that of the wild-type Sp1. The result of the DNase I footprinting analyses also showed the change in the DNA binding pattern. In contrast, the GLI zinc finger completely lost DNA binding ability as a result of exchanging the beta-hairpin region. These results strongly indicate that the beta-hairpin region appears to function as a scaffold and has an important effect on the DNA binding properties of the C(2)H(2)-type zinc finger peptides.     

Characterization of a new RNase HII and its essential amino acid residues in the archaeon <Emphasis Type="Italic">Sulfolobus tokodaii</Emphasis> reveals a regulatory C-terminus

The archaea possess RNase H proteins that share features of both prokaryotic and eukaryotic forms. Although the Sulfolobus RNase HI has been reported to have unique structural and biochemical properties, its RNase HII has not yet been investigated and its biochemical properties remain unknown. In the present study, we have characterized the ST0519 RNase HII from S. tokodaii as a new form. The enzyme utilized hybrid RNA/DNA as a substrate and had an optimal temperature between 37 and 50°C. The activity of wild-type protein was stimulated by Mn²⁺, whereas this cation significantly inhibited the activity of C-terminal truncated mutant proteins. A series of mutation assays revealed a regulatory C-terminal tail in the S. tokodaii RNase HII. One mutant, ST0519 (residues 1–195), retained only partial activity, while ST0519 (residues 1–196) completely lost its activity. Based on the presumed structure, the C-terminus might form a short α-helix in which two residues, I195 and L196, are essential for the cleavage activity. Our data suggest that the C-terminal α-helix is likely involved in the Mn²⁺-dependent substrate cleavage activity through stabilization of a flexible loop structure. Our findings offer important clues for further understanding the structure and function of both archaeal and eukaryotic RNase HII.     

Identifying a Folding Nucleus for the Lysozyme/α-Lactalbumin Family from Sequence Conservation Clusters

Four subfamilies of c-type lysozyme and one subfamily of α-lactalbumin are defined from 78 sequences, and their folding nucleus is identified with a method based on conserved residues and native structural contacts between pairs of conserved residues. One large cluster of 19 conserved residues is found which is mostly nonpolar, buried, and nonfunctional. It can be subdivided into three subclusters: (1) conserved residues in four helices; (2) conserved residues that stabilize the connector between the α and the β domains; and (3) a β-turn, sitting in the middle of a bowl of α-helix residues. It is proposed that this folding nucleus initiates four helices, A, B, C, and D, three β sheets, and the connector, which corresponds closely to the nucleation of the so-called fast folding track pathway. As the secondary structures propagate, nonconserved residues and functionally conserved residues would form additional contacts. The conserved residues are selected with a phylogenetic scheme in which single members of subfamilies are selected. Subfamilies are then equally weighted to obtain the consensus conservation. Received: 11 June 2001 / Accepted: 28 August 2001     

JAZ requires the double-stranded RNA-binding zinc finger motifs for nuclear localization.

We have cloned and characterized a novel zinc finger protein, termed JAZ. JAZ contains four C(2)H(2)-type zinc finger motifs that are connected by long (28-38) amino acid linker sequences. JAZ is expressed in all tissues tested and localizes in the nucleus, primarily the nucleolus. JAZ preferentially binds to double-stranded (ds) RNA or RNA/DNA hybrids rather than DNA. Mutation of individual zinc finger motifs reveals that the zinc finger domains are not only essential for dsRNA binding but are also required for its nucleolar localization, which demonstrates a complex trafficking mechanism dependent on the nucleic acid-binding capability of the protein. Furthermore, forced expression of JAZ potently induces apoptosis in murine fibroblast cells. Thus, JAZ may belong to a class of zinc finger proteins that features dsRNA binding and may regulate cell growth via the unique dsRNA binding properties.     

Rice <Emphasis Type="BoldItalic">ZFP15</Emphasis> Gene Encoding for a Novel C2H2-type Zinc Finger Protein Lacking DLN box,is Regulated by Spike Development but not by Abiotic Stresses

A novel C2H2-type zinc finger protein gene, ZFP15, was cloned from rice by RT-PCR approach. The ZFP15 gene encodes a protein of 144 amino acid residues with a predicted molecular mass of 15 kDa. The ZFP15 protein comprises two C2H2-type zinc finger domains, a putative nuclear localization signal (NLS) at its N-terminus but the DLN-box identified in all reported plant C2H2-type zinc finger proteins was not found. A homology search revealed that ZFP15 gene was localized within a cluster of C2H2-type zinc finger genes in BAC clone OJ1754_E06 mapped on chromosome 3. All three members in the cluster encoded proteins showed high identities in amino acids and might contribute to a co-regulation. The RT-PCR assay revealed that ZFP15 mRNA was not regulated by cold, salt, drought and ABA stresses, though CRT/DRE and ABRE elements were found in the promoter region of ZFP15 gene. The expression profiling also showed that ZFP15 mRNA was expressed with a lower level in leaves and roots, but not detected in stems. Besides, ZFP15 was shown to accumulate much more in flowering spike than in immature spike. Thus, ZFP15, as the first characterized C2H2-type zinc finger protein in rice, might play a regulatory role on rice spike development.     

Exchange of histidine spacing between Sp1 and GLI zinc fingers: distinct effect of histidine spacing-linker region on DNA binding

In the DNA recognition mode of C(2)H(2)-type zinc fingers, the finger-finger connection region, consisting of the histidine spacing (HX(3-5)H) and linker, would be important for determining the orientation of the zinc finger domains. To clarify the influence of spacing between two ligand histidines in the DNA binding, we exchanged the histidine spacing between Sp1 and GLI zinc fingers, which have an HX(3)H-TGEKK linker (typical) and an HX(4)H-SNEKP linker (atypical), respectively. A significant decrease in the DNA binding affinity and specificity is found in Sp1-type peptides, whereas GLI-type peptides show a mild reduction. To evaluate the effect of the linker characteristics, we further designed Sp1-type mutants with an SNEKP linker. As a result, the significant effect of the histidine spacing in Sp1-type peptides was reduced. These results demonstrate that (1) the histidine spacing significantly affects the DNA binding of zinc finger proteins and (2) the histidine spacing and the following linker regions are one effective target for regulating the DNA recognition mode of zinc finger proteins.     

The maize ID1 flowering time regulator is a zinc finger protein with novel DNA binding properties

The INDETERMINATE protein, ID1, plays a key role in regulating the transition to flowering in maize. ID1 is the founding member of a plant-specific zinc finger protein family that is defined by a highly conserved amino sequence called the ID domain. The ID domain includes a cluster of three different types of zinc fingers separated from a fourth C2H2 finger by a long spacer; ID1 is distinct from other ID domain proteins by having a much longer spacer. In vitro DNA selection and amplification binding assays and DNA binding experiments showed that ID1 binds selectively to an 11 bp consensus motif via the ID domain. Unexpectedly, site-directed mutagenesis of the ID1 protein showed that zinc fingers located at each end of the ID domain are not required for binding to the consensus motif despite the fact that one of these zinc fingers is a canonical C2H2 DNA binding domain. In addition, an ID1 in vitro deletion mutant that lacks the extra spacer between zinc fingers binds the same 11 bp motif as normal ID1, suggesting that all ID domain-containing proteins recognize the same DNA target sequence. Our results demonstrate that maize ID1 and ID domain proteins have novel zinc finger configurations with unique DNA binding properties.     

Identification of peptide epitopes of MAGE-1, -2, -3 that demonstrate HLA-A3-specific binding

 The MAGE gene family of tumour antigens are expressed in a wide variety of human cancers. We have identified 43 nonamer peptide sequences, from MAGE-1, -2 and -3 proteins that contain binding motifs for HLA-A3 MHC class I molecules. The T2 cell line, transfected with the cDNA for the HLA-A3 gene, was used in a MHC class I stabilisation assay performed at 37°C and 26°C. At 37°C, 2 peptides were identified that stabilised HLA-A3 with high affinity (fluorescence ratio, FR >1.5), 4 peptides with low affinity (FR 1.11 – 1.49) and 31 peptides that did not stabilise this HLA haplotype (FR <1.1). At 26°C, 12 peptides were identified that stabilised HLA-A3 with high affinity, 8 peptides with low affinity and 17 peptides that did not stabilise this HLA haplotype. Two peptides stabilised HLA-A3 at both temperatures. Small changes in one to three amino acids at positions distinct from the anchor residues altered peptide affinity. Data were compared to a similar study in which a peptide competition assay was used to investigate MAGE-1 peptide binding to several HLA haplotypes. This study demonstrates that anchor residues do not accurately predict peptide binding to specific HLA haplotypes, changes in one to three amino acids at positions distinct from anchor residues influence peptide binding and alternative methods of determining peptide binding yield different results. We are currently investigating the ability of these peptides to induce antitumour cytotoxic T lymphocyte activity as they may be of potential therapeutic value. Received: 4 January 1996 / Accepted: 20 March 1996     

Structural organization of Staf-DNA complexes

The transactivator Staf, which contains seven contiguous zinc fingers of the C₂-H₂ type, exerts its effects on gene expression by binding to specific targets in vertebrate small nuclear RNA (snRNA) and snRNA-type gene promoters. Here, we have investigated the interaction of the Staf zinc finger domain with the optimal Xenopus selenocysteine tRNA (xtRNA^Sec) and human U6 snRNA (hU6) Staf motifs. Generation of a series of polypeptides containing increasing numbers of Staf zinc fingers tested in binding assays, by interference techniques and by binding site selection served to elucidate the mode of interaction between the zinc fingers and the Staf motifs. Our results provide strong evidence that zinc fingers 3–6 represent the minimal zinc finger region for high affinity binding to Staf motifs. Furthermore, we show that the binding of Staf is achieved through a broad spectrum of close contacts between zinc fingers 1–6 and xtRNA^Sec or optimal sites or between zinc fingers 3–6 and the hU6 site. Extensive DNA major groove contacts contribute to the interaction with Staf that associates more closely with the non-template than with the template strand. Based on these findings and the structural information provided by the solved structures of other zinc finger–DNA complexes, we propose a model for the interaction between Staf zinc fingers and the xtRNA^Sec, optimal and hU6 sites.     

Multifaceted SlyD from <Emphasis Type="Italic">Helicobacter pylori</Emphasis>: implication in [NiFe] hydrogenase maturation

SlyD belongs to the FK506-binding protein (FKBP) family with both peptidylprolyl isomerase (PPIase) and chaperone activities, and is considered to be a ubiquitous cytosolic protein-folding facilitator in bacteria. It possesses a histidine- and cysteine-rich C-terminus binding to selected divalent metal ions (e.g., Ni²⁺, Zn²⁺), which is important for its involvement in the maturation processes of metalloenzymes. We have determined the solution structure of C-terminus-truncated SlyD from Helicobacter pylori (HpSlyDΔC). HpSlyDΔC folds into two well-separated, orientation-independent domains: the PPIase-active FKBP domain and the chaperone-active insert-in-flap (IF) domain. The FKBP domain consists of a four-stranded antiparallel β-sheet with an α-helix on one side, whereas the IF domain folds into a four-stranded antiparallel β-sheet accompanied by a short α-helix. Intact H. pylori SlyD binds both Ni²⁺ and Zn²⁺, with dissociation constants of 2.74 and 3.79 μM respectively. Intriguingly, binding of Ni²⁺ instead of Zn²⁺ induces protein conformational changes around the active sites of the FKBP domain, implicating a regulatory role of nickel. The twin-arginine translocation (Tat) signal peptide from the small subunit of [NiFe] hydrogenase (HydA) binds the protein at the IF domain. Nickel binding and the recognition of the Tat signal peptide by the protein suggest that SlyD participates in [NiFe] hydrogenase maturation processes.