Zinc-dependent structure of a single-finger domain of yeast ADR1

Lessons from zinc-binding peptides

Zinc-finger domains are small metal-binding modules that are found in a wide range of gene regulatory proteins. Peptides corresponding to these domains have provided valuable model systems for examining a number of biophysical parameters entirely unrelated to their nucleic acid binding properties. These include the chemical basis for metal-ion affinity and selectivity, thermodynamic properties related to hydrophobic packing and beta-sheet propensities, and constraints on the generation of ligand-binding and potential catalytic sites. These studies have laid the foundation for applications such as the generation of optically detected zinc probes and the design of metal-binding peptides and proteins with desired spectroscopic and chemical properties.

Interaction of wild-type and truncated forms of transcription factor IIIA from Saccharomyces cerevisiae with the 5 S RNA gene

Transcription factor (TF) IIIA, which contains nine zinc finger motifs, binds to the internal control region of the 5S RNA gene as the first step in the assembly of a multifactor complex that promotes accurate initiation of transcription by RNA polymerase III. We have monitored the interaction of wild-type and truncated forms of yeast TFIIIA with the 5 S RNA gene. The DNase I footprints obtained with full-length TFIIIA and a polypeptide containing the amino-terminal five zinc fingers (TF5) were indistinguishable, extending from nucleotides +64 to +99 of the 5 S RNA gene. This suggests that fingers 6 through 9 of yeast TFIIIA are not in tight association with DNA. The DNase I footprint obtained with a polypeptide containing the amino-terminal four zinc fingers (TF4) was 14 base pairs shorter than that of TF5, extending from nucleotides +78 to +99 on the nontranscribed strand and from nucleotides +79 to +98 on the transcribed strand of the 5 S RNA gene. Protection provided by a polypeptide containing the first three zinc fingers (TF3) was similar to that provided by TF4, with the exception that protection on the nontranscribed strand ended at nucleotide +80, rather than nucleotide +78. Methylation protection analysis indicated that finger 5 makes major groove contacts with guanines +73 and +74. The amino-terminal four zinc fingers make contacts that span the internal control region, which extends from nucleotides +81 to +94 of the 5 S RNA gene, with finger 4 appearing to contact guanine +82. Measurements of the apparent Kd values of the TFIIIA.DNA complexes indicated that the amino-terminal three zinc fingers of TFIIIA have a binding energy that is similar to that of the full-length protein.

The solution structure of the first zinc finger domain of SWI5: a novel structural extension to a common fold

BACKGROUND

The 2Cys-2His (C2-H2) zinc finger is a protein domain commonly used for sequence-specific DNA recognition. The zinc fingers of the yeast transcription factors SWI5 and ACE2 share strong sequence homology, which extends into a region N-terminal to the first finger, suggesting that the DNA-binding domains of these two proteins include additional structural elements.

RESULTS

Structural analysis of the zinc fingers of SWI5 reveals that a 15 residue region N-terminal to the finger motifs forms part of the structure of the first finger domain, adding a beta strand and a helix not previously observed in other zinc finger structures. Sequence analysis suggests that other zinc finger proteins may also have this structure. Biochemical studies show that this additional structure increases DNA-binding affinity.

CONCLUSIONS

The structural analysis presented reveals a novel zinc finger structure in which additional structural elements have been added to the C2-H2 zinc finger fold. This additional structure may enhance stability and has implications for DNA recognition by extending the potential DNA-binding surface of a single zinc finger domain.

A new Cys2/His2 zinc finger gene, rKr1, expressed in oligodendrocytes and neurons

The myelination of nerve fibers is essential for the function of the vertebrate nervous system as a prerequisite for fast saltatory conduction of action potentials. In the central nervous system (CNS), myelin is produced by oligodendrocytes. In order to identify gene regulatory proteins involved in the differentiation of this glial cell type or in the expression of myelin-specific genes, we have constructed a cDNA library from a highly enriched population of rat oligodendrocytes and screened this library for members of the Krüppel family of Cys2/His2 zinc finger proteins. One of the identified clones, named rKr1, encodes a novel protein of 650 amino acids which contains 12 carboxy-terminal zinc finger domains and an amino-terminal acidic domain. On Northern blots, a single rKr1 mRNA of 4.3 kb is detected. This message is present in all adult rat tissues tested, with the highest levels found in the CNS and testis. In situ hybridization on the P15 brain revealed that the transcript is expressed in differentiated oligodendrocytes and in subtypes of neurons. Particularly high message levels are found in motor neurons of the brainstem and the spinal cord. The modular structure of the rKr1 protein, in which a potential DNA binding region (the zinc fingers) is combined with a putative activation domain (the acidic region), suggests a function as sequence-specific transcriptional activator.

The galvanization of biology: a growing appreciation for the roles of zinc

Zinc ions are key structural components of a large number of proteins. The binding of zinc stabilizes the folded conformations of domains so that they may facilitate interactions between the proteins and other macromolecules such as DNA. The modular nature of some of these zinc-containing proteins has allowed the rational design of site-specific DNA binding proteins. The ability of zinc to be bound specifically within a range of tetrahedral sites appears to be responsible for the evolution of the side range of zinc-stabilized structural domains now known to exist. The lack of redox activity for the zinc ion and its binding and exchange kinetics also may be important in the use of zinc for specific functional roles.

Design of a monomeric 23-residue polypeptide with defined tertiary structure

Small proteins or protein domains generally require disulfide bridges or metal sites for their stabilization. Here it is shown that the beta beta alpha architecture of zinc fingers can be reproduced in a 23-residue polypeptide in the absence of metal ions. The sequence was obtained through an iterative design process. A key feature of the final design is the incorporation of a type II' beta turn to aid in beta-hairpin formation. Nuclear magnetic resonance analysis reveals that the alpha helix and beta hairpin are held together by a defined hydrophobic core. The availability of this structural template has implications for the development of functional polypeptides.

Characterization of metal binding by a designed protein: single ligand substitutions at a tetrahedral Cys2His2 site

The tetrahedral Cys2His2 Zn(II)-binding site in the de novo designed protein Z alpha 4 [Regan, L., & Clarke, N. D. (1990) Biochemistry 29, 10878] has been studied by independently mutating each of the metal-binding ligands to alanine. The contribution of each ligand to the geometry and affinity of metal binding has been characterized using Co(II), Zn(II), and Cd(II). The results indicate that all four ligands contribute to high-affinity metal binding in Z alpha 4. Two of the four metal-site mutants retain the tetrahedral Zn(II)-binding geometry of Z alpha 4, with one water molecule presumed to bind in the vacant ligand position. These mutants provide the first examples of a demonstrated de novo tetrahedral three-coordinate site designed into a protein and as such are a first step toward the design of catalytic rather than structural Zn(II) sites. One of the metal-site mutants binds Zn(II) with either tetrahedral four-coordinate or five-coordinate geometry, while the last ligand-to-alanine substitution abolishes tetrahedral binding. The importance of ligand type for metal-binding in Z alpha 4 was investigated by characterizing two ligand-swap mutants in which a cysteine residue was replaced with a histidine. In both cases, tetrahedral metal binding was lost. Collectively, these results affirm the strategy used to design Z alpha 4 by showing that all designed liganding residues are participating in metal binding, and by suggesting that the tetrahedral geometry of the binding site is perturbed when the designed side chain ligands are replaced with alternate ligands.

Novel metal-binding proteins by design

We describe the successful design of a tetrahedral His3Cys Zn(II)-binding site in a small protein of known structure: the B1 domain of Streptococcal protein G. The B1 variants containing the novel metal-binding site were characterized using a combination of optical absorption, circular dichroism and NMR spectroscopies. The results indicate that the designed proteins bind Zn(II) with high affinity and tetrahedral coordination geometry, and that the overall secondary and tertiary structure of the B1 domain is maintained.

Designing zinc-finger ADR1 mutants with altered specificity of DNA binding to T in UAS1 sequences

Yeast ADR1 contains two Cys2,His2 zinc fingers needed for DNA binding to the upstream activation sequence UAS1, with bases T5T6G7-G8A9G10 in the ADH2 promoter. Potential DNA-contacting amino acid residues at -1, +3, and +6 in the alpha-helical domains of ADR1's fingers one and two include RHR-RLR; however, the latter finger two residues Leu146 and Arg149 had not proved to be crucial for ADR1 binding, even though Leu146-T6 and Arg149-T5 interactions with UAS1 DNA were predicted. We altered Leu146 or Arg149 by PCR cassette mutagenesis, to study ADR1 mutant binding to 16 UAS1 variants of thymine bases T5 and T6. Mutation of Leu146 to His, making finger two (RLR) like finger one (RHR), decreased binding to wild type UAS1 having T6, but enhanced its binding strength to sequences having purines G6 or A6, similar to binding seen between finger one's His118 and base A9 of UAS1. Mutating Leu146 to Lys caused this finger two RKR mutant to bind strongly to both G6 and T6, possibly by lysine's amine H-bonding to the carbonyl of guanine or thymine. Specificity of ADR1 for UAS1 with T6 may thus be due to hydrophobic interaction between Leu146 and the T6 methyl group. ADR1 mutants with either His or Lys in the central +3 residue (146) of zinc finger two, which have Arg149 in the +6 alpha-helical position, bind with UAS1 mutant sequences having G5 very strongly, T5 strongly, A5 intermediately, and C5 weakly.(ABSTRACT TRUNCATED AT 250 WORDS)

The positively acting amdA gene of Aspergillus nidulans encodes a protein with two C2H2 zinc-finger motifs

Semi-dominant mutations in the amdA gene lead to elevated expression of the gene encoding acetamidase, amdS. These mutations also cause constitutive expression of the acetate-inducible gene, aciA. In the amdS 5' regulatory region, two cis-acting mutations, amdl66 and amdl666, have been isolated which specifically affect amdA activation of amdS. These mutations are a duplication and a triplication of an 18 bp GA-rich sequence, thought to define the amdA site of action within the amdS promoter region. Similar GA-rich sequences have also been found in the 5' region of aciA. This paper describes the cloning and initial functional characterization of the amdA gene and two of its mutant alleles. The wild-type amdA gene has been cloned by a chromosome walk from genes gatA and alcC on linkage group VII and localized by complementation of an amdA loss-of-function mutation. Transcriptional analysis reveals that the gene is expressed constitutively at low levels under growth conditions which affect expression of amdS and aciA. The gene is predicted to encode an 880-amino-acid protein which contains two C2H2 zinc fingers, a nuclear localization sequence and two transcriptional activation domains. The amdA7 semi-dominant gain-of-function mutation results in a glycine to aspartate substitution which would increase the acidity of one of these regions. Analysis of in vitro generated mutations in the 5' region of amdS using an amdS::lacZ reporter has been used to localize the site of action of AmdA. The C2H2 zinc-finger motifs identified in the protein are similar to those found in the carbon catabolite repressor protein, CreA, which also regulates amdS and recognizes sequences which overlap with the proposed site of action for AmdA.

Cooperative, non-specific binding of a zinc finger peptide to DNA

The DNA binding and structural properties of Xfin-31 (Lee, M.S., Gippert, G.P., Soman, K.V., Case, D.A. and Wright, P.E., 1989, Science 245, 635-637), a twenty five amino acid zinc finger peptide, in the reduced, oxidized and zinc complex forms, as well as the fourteen residue helical segment of the zinc finger (residues 12-25) have been compared using affinity coelectrophoresis (ACE) and circular dichroism (CD) spectroscopy. The zinc complex and oxidized peptides bind cooperatively to DNA although the cooperativity factor, omega, is more than 15-fold greater for the zinc complex. The reduced peptide in the absence of zinc and the helical segment do not bind cooperatively (omega = 1). Hence, the binding constant for singly contiguous sites (K omega) ranges over 100-fold for the various peptides even though the intrinsic binding constants (K) are similar. An increase in binding order and affinity for the other forms of Xfin-31 is correlated with an increasing similarity of the CD spectrum to that of the Xfin-31 zinc complex. The surprising DNA binding activity of the oxidized peptide may result from hydrophobic interactions between the amino-terminal loop formed by the Cys3-Cys6 disulfide bond and conserved hydrophobic residues in the carboxyl-terminal segment. Xfin-31 may be a particularly useful model for studying several poorly understood aspects of cooperative, non-specific DNA binding since it is small, has a stable, well-defined structure, and structures of zinc fingers bound to DNA have been determined.

Characterization of the zinc-metalloprotein nature of rat spermatidal protein TP2

Spermatidal transition protein, TP2, was purified from rat testes by Hg-affinity chromatography. The present study reports the details of the zinc-metalloprotein nature of TP2 by employing the 65 Zn-blotting technique. Chemical modification of cysteine by iodoacetic acid, and histidine by diethylpyrocarbonate, resulted in a near complete inhibition of 65Zn-binding to TP2. The 65Zinc-binding was localized to the V8 protease-derived N-terminal two-third polypeptide fragment. Circular dichroism spectroscopy studies of TP2 (zinc pre-incubated) and its V8 protease-derived polypeptide fragments revealed that the N-terminal fragment has a Type I-beta-turn spectrum, while the C-terminal fragment has a small but significant alpha-helical structure. EDTA altered the circular dichroism spectrum of TP2 and the N-terminal fragment (zinc binding domain) but not that of the C-terminal fragment.

Repression of transcriptional activity at a distance by the evolutionarily conserved KRAB domain present in a subfamily of zinc finger proteins

Sub-families of related zinc finger protein genes have been defined on the basis of evolutionarily conserved structural features found outside the C2-H2 finger repeats. Such elements include the FAX domain found in a large number of Xenopus ZFPs, the evolutionarily conserved KRAB (Krüppel-associated box) and the ZiN (zinc finger N-terminal) domains. Here we describe a new evolutionarily conserved motif within zinc finger proteins which we have named the leucine rich region (LeR). Since conserved modules in regulatory proteins may specify properties relevant to their action we have determined the functional capabilities of LeR and the KRAB domains in the regulation of gene transcription by fusing relevant regions to a heterologous DNA-binding domain (GAL4 DNA-binding domain). We found that the KRAB-A domain tethered to RNA polymerase II promoters by a GAL4 DNA-binding domain actively represses transcription in a distance-independent manner. KRAB-mediated repression is dependent on the dose of the GAL4-KRAB-A fusion protein and on the presence of GAL4 binding sites on the DNA. Conversely, the LeR domain did not modulate significantly the transcription. Our results indicate that the KRAB domain present in the non-finger region of many ZFP genes quenches transcription possibly due to specific protein-protein interactions between the KRAB-A domain and components of the proximal transcriptional apparatus.

Structure of a histidine-X4-histidine zinc finger domain: insights into ADR1-UAS1 protein-DNA recognition

The solution structure for a mutant zinc finger peptide based on the sequence of the C-terminal ADR1 finger has been determined by two-dimensional NMR spectroscopy. The mutant peptide, called PAPA, has both proline residues from the wild-type sequence replaced with alanines. A nonessential cysteine was also replaced with alanine. The behavior of PAPA in solution implicates the prolines in the conformational heterogeneity reported earlier for the wild-type peptide [Xu, R. X., Horvath, S. J., & Klevit, R. E. (1991) Biochemistry 30, 3365-3371]. The solution structure of PAPA reveals several interesting features of the zinc finger motif. The residue immediately following the second cysteine ligand adopts a positive phi angle, which we propose is a common feature of this class of zinc fingers, regardless of whether this residue is a glycine. The NMR spectrum and resulting solution structure of PAPA suggest that a side-chain to side-chain hydrogen bond involving an arginine and an aspartic acid analogous to one observed in the Zif268 protein-DNA cocrystal structure exists in solution in the absence of DNA [Pavletich, N. P., & Pabo, C. O. (1991) Science 252, 809-817]. A model for the interaction between the two ADR1 zinc fingers and their DNA binding sites was built by superpositioning the refined solution structures of PAPA and ADR1b onto the Zif268 structure. This model offers structural explanations for a variety of mutations to the ADR1 zinc finger domains that have been shown to affect DNA-binding affinity or specificity.

Zinc fingers: conserved properties that can distinguish between spurious and actual DNA-binding motifs

The zinc finger, one of the major structural motifs used for sequence specific DNA binding, has been identified in many regulatory proteins. By analogy, involvement in nucleic acid recognition has been implied for proteins that contain two cysteines and two histidines, spaced in accordance with the zinc finger motif. In this study we identify sequence dependent characteristics that are conserved in the DNA-binding zinc fingers and are probably required for a functional DNA-binding zinc finger. Examination of the conserved properties in view of the solved three dimensional structure of a zinc finger, confirms the importance of most of these properties. The absence of the identified physical-chemical characteristics from CCHH containing sequences of non-DNA binding proteins suggest that they can be used to distinguish between spurious and actual DNA binding zinc fingers.

The putative zinc-finger protein WZF1 interacts with a cis-acting element of wheat histone genes

A nonamer motif (CATCCAACG) that is one of the cis-acting elements identified in the proximal promoter region of some wheat histone genes is included in the region that interacts with the wheat DNA-binding protein, HBP (histone gene-binding protein)-2. To obtain structural and functional information about this DNA-binding protein, we attempted to isolate a cDNA clone encoding HBP-2 on the basis of its ability to bind to a nonamer-containing 38-bp DNA fragment. Southwestern screening of a wheat cDNA library with concatenated 38-residue oligonucleotides as the probe produced one candidate clone. Nucleotide sequence analyses of this cDNA clone and the corresponding genomic clone showed that the protein deduced from the nucleotide sequence consisted of 261 amino acids and contained a set of zinc-finger motifs similar to those found in many eukaryotic transcription factors. The protein, named WZF1 (wheat zinc-finger protein 1), which was expressed from the cDNA in Escherichia coli cells, bound specifically and metal-ion-dependently to the nonamer-containing oligonucleotide. The WZF1 mRNA was highly expressed in the root apexes of wheat seedlings, but less so in the proximal portion of young leaves; whereas, histone H3 mRNA was highly expressed in both tissues. The expression patterns of the WZF1 and histone H3 genes in the early stages of germination differed, expression of the WZF1 gene being almost constant but not that of the H3 gene. The relationship of WZF1 and HBP-2 and the possible role of WZF1 in the histone gene expression were discussed.

Nuclease properties of two putative zinc finger peptides

We studied the interaction of wheat germ 5S rRNA with synthetic polypeptides whose amino acid sequences were similar to that of the second zinc finger of Xenopus laevis transcriptional factor IIIA (TFIIIA). The results clearly show that in addition to weak 5S rRNA binding activity (data not shown), these two 30 amino acid long polypeptides hydrolyse some phosphodiester bonds of wheat germ 5S rRNA. The cleavage pattern of plant 5S rRNA is very specific and the cuts occur only after the pyrimidine residues. The same properties of these peptides were furthermore observed for E. coli tRNA(Phe). We found that the digestion specificity of both the zinc finger peptides is very similar to that of a pancreatic ribonuclease (RNase A).

Crystal structure of a five-finger GLI-DNA complex: new perspectives on zinc fingers

Zinc finger proteins, of the type first discovered in transcription factor IIIA (TFIIIA), are one of the largest and most important families of DNA-binding proteins. The crystal structure of a complex containing the five Zn fingers from the human GLI oncogene and a high-affinity DNA binding site has been determined at 2.6 A resolution. Finger one does not contact the DNA. Fingers two through five bind in the major groove and wrap around the DNA, but lack the simple, strictly periodic arrangement observed in the Zif268 complex. Fingers four and five of GLI make extensive base contacts in a conserved nine base-pair region, and this section of the DNA has a conformation intermediate between B-DNA and A-DNA. Analyzing the GLI complex and comparing it with Zif268 offers new perspectives on Zn finger-DNA recognition.

Time-resolved energy transfer measurements of donor-acceptor distance distributions and intramolecular flexibility of a CCHH zinc finger peptide

Time-resolved frequency-domain fluorescence energy transfer measurements have been used to investigate the solution structure of a single-domain CCHH-type zinc finger peptide. These measurements reveal not only the range of accessible distances for a given donor-acceptor pair within the molecule but also the degree of conformational flexibility that occurs in solution. Two donor-acceptor (D-A)-pair zinc finger peptides have been synthesized. A single tryptophan residue located at the midpoint of the sequence was the energy donor for two different acceptors. One acceptor, attached at the amino terminus was a 5-(dimethylamino)-1-naphthalenesulfonyl (DNS) group; the second acceptor was a 7-amino-4-methyl-coumarin-3-acetyl (AMCA) group, attached to the epsilon-amino function of a carboxy-terminal lysine residue. Distance distributions and the mutual site-to-site diffusion coefficients were determined for these two D-A-labeled peptides under zinc-bound, metal-free, and denatured conditions. The D-A distance distributions determined for these two peptides under metal-free and zinc-bound conditions indicated a shorter distance and a unique conformation (narrow distribution) when metal was bound and a longer distance with greater conformational flexibility when metal ion was absent. No site-to-site diffusion was detected for the zinc-bound peptide, whereas an appreciable amount of diffusion was measured for both metal-free and denatured peptide. Anisotropy measurements on the peptides indicated increased flexibility of all regions of the peptide chain in the absence of zinc and a more compact, less flexible structure when zinc was bound. It was concluded from these results that the metal-bound conformation represents a unique, well-defined structure. Comparison of distance distributions measured for metal-free and denatured peptide indicated that there is some residual structure present in the metal-free peptide.

Independence of metal binding between tandem Cys2His2 zinc finger domains

Most Cys2His2 zinc finger proteins contain tandem arrays of metal binding domains. The tandem nature of these arrays suggests that metal binding by these domains may not be independent but rather that metal binding may occur in a cooperative manner. This is especially true in light of the crystal structure of a three zinc finger array bound to DNA that revealed several types of interactions between domains. To address this question, peptides containing two tandem domains have been prepared. While metal binding studies do show that the two finger peptide has a metal ion affinity about threefold higher than that for a single domain peptide with the same sequence, additional studies reveal that this behavior is due to increased single site affinities in the context of the two domain peptide rather than to cooperativity. These studies indicate that domains of this type are independent of one another with regard to metal binding, at least in the absence of DNA. This observation has implications with regard to the question of whether the activities of proteins of this class might be modulated by available zinc concentrations.

Structures of DNA-binding mutant zinc finger domains: implications for DNA binding

Studies of Cys2-His2 zinc finger domains have revealed that the structures of individual finger domains in solution determined by NMR spectroscopy are strikingly similar to the structure of fingers bound to DNA determined by X-ray diffraction. Therefore, detailed structural analyses of single finger domains that contain amino acid substitutions known to affect DNA binding in the whole protein can yield information concerning the structural ramifications of such mutations. We have used this approach to study two mutants in the N-terminal finger domain of ADR1, a yeast transcription factor that contains two Cys2-His2 zinc finger sequences spanning residues 102-159. Two point mutants at position 118 in the N-terminal zinc finger (ADR1b: 102-130) that adversely affect the DNA-binding activity of ADR1 have previously been identified: H118A and H118Y. The structures of wild-type ADR1b and the two mutant zinc finger domains were determined using two-dimensional nuclear magnetic resonance spectroscopy and distance geometry and were refined using a complete relaxation matrix method approach (REPENT) to improve agreement between the models and the nuclear Overhauser effect spectroscopy data from which they were generated. The molecular architecture of the refined wild-type ADR1b domain is presented in detail. Comparisons of wild-type ADR1b and the two mutants revealed that neither mutation causes a significant structural perturbation. The structures indicate that the DNA binding properties of the His 118 mutants are dependent on the identity of the side chain at position 118, which has been postulated to make a direct DNA contact in the wild-type ADR1 protein. The results suggest that the identity of the side chain at the middle DNA contact position in Cys2-His2 zinc fingers may be changed with impunity regarding the domain structure and can affect the affinity of the protein-DNA interaction.

Thermodynamic beta-sheet propensities measured using a zinc-finger host peptide

The three-dimensional structures of proteins reveal that the distribution of amino acids within the major classes of secondary structure is not random but that each amino acid has its own preferred secondary structural arrangements. Propensity scales for residues in alpha-helices have been generated through the use of various host-guest systems. Here we measure the thermodynamic beta-sheet propensities of each of the twenty commonly occurring amino acids. A previously studied zinc-finger peptide was used as the host system in which amino acids were substituted into a guest site, a solvent-exposed position in an antiparallel beta-sheet. As these peptides are unfolded in the absence of bound metal but are folded in their presence, it is assumed that the thermodynamics of metal binding fully reflect peptide-folding energy. A competitive cobalt(II)-binding assay was used to determine these energies with high precision. The relative free energies correlate well with previously derived potential values based on statistical analysis of protein structures. We are therefore able to present a thermodynamic beta-sheet propensity scale for all the commonly occurring amino acids in aqueous solution.

Metal binding properties of single amino acid deletion mutants of zinc finger peptides: studies using cobalt(II) as a spectroscopic probe

Peptides corresponding to Cys2His2 zinc finger domains from which one amino acid has been deleted have been synthesized and their metal-binding properties characterized. In contrast to earlier reports (Párraga, G., S. Horvath, L. Hood, E. T. Young, and R. E. Klevit. 1990. Proc. Natl. Acad. Sci. USA. 87:137-141.), such peptides do bind metal ions such as cobalt(II). A peptide with the sequence ProTyrLysCysProGluCysLysSerPheSerGlnLysSerAspLeuValLysHisGlnArgThrHis ThrGly (which corresponds to a previously characterized consensus zinc finger sequence from which a Gly residue immediately following the second Cys residue has been deleted) was found to form a 1:1 peptide to cobalt(II) complex with an absorption spectrum quite similar to those previously observed for zinc finger peptide-cobalt(II) complexes. The dissociation constant for this complex is 6 x 10(-6)M, a factor of 100 times higher than that for the parent peptide. A peptide with the sequence LysProTyrProCysGlyLeuCysArgCysPheThrArgArgAspLeuLeulleArgHisAlaGln - LyslleHisSerGlyAsnLeu corresponding to a similar mutation of the peptide ADR1 was also characterized. Spectroscopic studies with cobalt(II) revealed that this peptide forms both 1:1 and 2:1 peptide to cobalt(II) complexes. The absorption spectra of the two forms and the dissociation constants were determined via deconvolution methods. In contrast, the parent peptide ADR1a was found to form only a 1:1 complex under comparable conditions and this 1:1 complex was found to be more stable than that for the mutant. These results reveal that deletion mutations do adversely affect the stability of zinc finger peptide-metal complexes but that the effects are not as drastic as had been previously described.

Chemical assay for cyst(e)ine-rich peptides detects a novel intestinal peptide ZF-1, homologous to a single zinc-finger motif

Cysteine is a relatively infrequent constituent of proteins, which in its thiol or half-cystine form contributes in a special manner to their three-dimensional structure. We show that in small cystine-containing peptides, the Cys content is always higher than the average in proteins in general. This observation makes it possible to search for new peptides by monitoring only their Cys content. We have developed a chemical assay for the detection of cyst(e)ine-rich peptides in tissue extracts. Using this assay we have isolated from porcine intestine a novel cysteine-rich peptide, which we denote ZF-1. ZF-1 is homologous to a single zinc-finger motif and has an acetylated N-terminus. This is the first demonstration of the existence of a processed single zinc-finger-like structure. The structural homology of ZF-1 to the zinc-finger motif, present in several metal-binding and DNA-binding proteins, suggests an important role of this peptide in metal transport and/or modulation of gene expression.

A mutation outside the two zinc fingers of ADR1 can suppress defects in either finger

A second-site mutation that restored DNA binding to ADR1 mutants altered at different positions in the two zinc fingers was identified. This mutation (called IS1) was a conservative change of arginine 91 to lysine in a region amino terminal to the two zinc fingers and known from previous experiments to be necessary for DNA binding. IS1 increased binding to the UAS1 sequence two- to sevenfold for various ADR1 mutants and twofold for wild-type ADR1. The change of arginine 91 to glycine decreased binding twofold, suggesting that this arginine is involved in DNA binding in the wild-type protein. The increase in binding by IS1 did not involve protein-protein interactions between the two ADR1 monomers, nor did it require the presence of the sequences flanking UAS1. However, the effect of IS1 was influenced by the sequence of the first finger, suggesting that interactions between the region amino terminal to the fingers and the fingers themselves could exist. A model for the role of the amino-terminal region based on these results and sequence homologies with other DNA-binding motifs is proposed.

Novel member of the zinc finger superfamily: A C2-HC finger that recognizes a glia-specific gene

A novel member of the zinc finger superfamily was cloned by virtue of its binding to cis-regulatory elements of a glia-specific gene, the myelin proteolipid protein (PLP) gene. Named MyTI (myelin transcription factor I), this gene is most highly transcribed in the developing nervous system, where expression precedes induction of its presumptive target, PLP. Low levels of MyTI transcripts can be detected in nonneural tissues only by polymerase chain reaction analysis. Zinc is a necessary cofactor for DNA binding of MyTI, as the zinc-chelating agent 1,10-orthophenanthroline eliminates binding activity. Zinc may stabilize the DNA-binding domain of MyTI by coordinating three cysteine and one histidine residue in a Cys-X5-Cys-X12-His-X4-Cys (C2-HC) arrangement. The MyTI protein has six fingers of the C2-HC class arranged in two widely separated clusters. These two domains of DNA binding can function independently and recognize the same DNA sequence, suggesting that MyTI may contribute to the higher-order structure of a target promoter by simultaneously binding both proximal and distal sites. The six fingers are highly conserved, suggesting that they arose from successive duplication events, while the linker regions diverge in size and sequence. Both amino acid sequence comparisons and secondary-structure predictions indicate that the C2-HC fingers of MyTI do not resemble the zinc-mediated loops of C2-H2 fingers, C2-C2 fingers, or Cx clusters. MyTI may therefore be the prototype of a new structural family of zinc-stabilized DNA binding proteins.

A mutation outside the two zinc fingers of ADR1 can suppress defects in either finger

A second-site mutation that restored DNA binding to ADR1 mutants altered at different positions in the two zinc fingers was identified. This mutation (called IS1) was a conservative change of arginine 91 to lysine in a region amino terminal to the two zinc fingers and known from previous experiments to be necessary for DNA binding. IS1 increased binding to the UAS1 sequence two- to sevenfold for various ADR1 mutants and twofold for wild-type ADR1. The change of arginine 91 to glycine decreased binding twofold, suggesting that this arginine is involved in DNA binding in the wild-type protein. The increase in binding by IS1 did not involve protein-protein interactions between the two ADR1 monomers, nor did it require the presence of the sequences flanking UAS1. However, the effect of IS1 was influenced by the sequence of the first finger, suggesting that interactions between the region amino terminal to the fingers and the fingers themselves could exist. A model for the role of the amino-terminal region based on these results and sequence homologies with other DNA-binding motifs is proposed.

Novel member of the zinc finger superfamily: A C2-HC finger that recognizes a glia-specific gene

A novel member of the zinc finger superfamily was cloned by virtue of its binding to cis-regulatory elements of a glia-specific gene, the myelin proteolipid protein (PLP) gene. Named MyTI (myelin transcription factor I), this gene is most highly transcribed in the developing nervous system, where expression precedes induction of its presumptive target, PLP. Low levels of MyTI transcripts can be detected in nonneural tissues only by polymerase chain reaction analysis. Zinc is a necessary cofactor for DNA binding of MyTI, as the zinc-chelating agent 1,10-orthophenanthroline eliminates binding activity. Zinc may stabilize the DNA-binding domain of MyTI by coordinating three cysteine and one histidine residue in a Cys-X5-Cys-X12-His-X4-Cys (C2-HC) arrangement. The MyTI protein has six fingers of the C2-HC class arranged in two widely separated clusters. These two domains of DNA binding can function independently and recognize the same DNA sequence, suggesting that MyTI may contribute to the higher-order structure of a target promoter by simultaneously binding both proximal and distal sites. The six fingers are highly conserved, suggesting that they arose from successive duplication events, while the linker regions diverge in size and sequence. Both amino acid sequence comparisons and secondary-structure predictions indicate that the C2-HC fingers of MyTI do not resemble the zinc-mediated loops of C2-H2 fingers, C2-C2 fingers, or Cx clusters. MyTI may therefore be the prototype of a new structural family of zinc-stabilized DNA binding proteins.

Regulation of transcription in eukaryotes by DNA-binding proteins

1. The recognition of DNA by gene regulatory proteins is often mediated by structural motifs that comprise a protein DNA-binding domain. 2. Although binding of these proteins to DNA is not itself sufficient to affect transcription it is a necessary prerequisite. 3. This review summarizes recent studies that define structural motifs for DNA binding function of eukaryotic transcription factors.

The ubiquitous transactivator Zfp-38 is upregulated during spermatogenesis with differential transcription

We describe the complete nucleotide sequence of a full length cDNA clone encoding a new mouse zinc finger protein gene, Zfp-38 and localize it on chromosome 5 by the interspecific backcross analysis. The N-terminal domain of the Zfp-38 protein (64 kDa) contains 358 amino acids and the C-terminal domain of 197 residues encodes 7 zinc fingers. We also present evidence that Zfp-38 is a strong transcriptional activator. The transactivation domain was localized in the non finger region and a fusion protein containing 112 amino acid residues from this region of the Zfp-38 and the DNA binding domain of the yeast Gal 4 protein, very efficiently transactivated the expression of a reporter CAT plasmid, harboring the Gal4 target site. By in situ hybridization and northern blotting technique, the Zfp-38 transcript can be detected at a highly elevated level during spermatogenesis. Its expression accompanies the progression from pachytene spermatocytes to round spermatids. The undifferentiated spermatogonia or the haploid elongated spermatid and the spermatozoa do not show any detectable level of the transcript. Interestingly, other tissues express low levels of a slightly shorter transcript with a different 5' end as determined by RNase protection. The presence of both a transcriptional activating domain and 7 DNA binding zinc fingers, coupled with the cell type(s) specific expression pattern, suggests that Zfp-38 has the potential to regulate transcription during spermatogenesis.

Structure of the TFIIIA-5 S DNA complex

The missing-nucleoside experiment, a recently developed approach for determining the positions along a DNA molecule that make energetically important contacts with protein, has been used to investigate the structure of the complex of transcription factor IIIA with a somatic 5 S RNA gene from Xenopus borealis. We detect three distinct regions of the 5 S promoter that are contacted by TFIIIA, corresponding to the A-box, intermediate element and C-box regions previously identified by mutagenesis experiments. The advantage of the missing-nucleoside experiment over mutagenesis is that additional information, directly related to the structure of the complex, is obtained. Of most importance is that contacts to each strand of DNA are determined independently, and can be assigned unambiguously as interactions with TFIIIA. Throughout the binding site the strongest contacts are made with the non-coding strand of the 5 S gene. The two groups of contacts at either end of the binding site (boxes A and C) are comprised of sets of approximately ten contiguous nucleosides for which the contacts are reflected, without stagger, from one strand to the other. In contrast, contacts in the center of the promoter (the intermediate element) are staggered about five base-pairs in the 5' direction with respect to each strand. These results, when analyzed in conjunction with the hydroxyl-radical footprint of the complex, support a model in which TFIIIA wraps around the DNA in the major groove of the helix for one turn at the two ends of the complex in boxes A and C, and lies on one side of the DNA helix in the center of the complex at the intermediate element.

Mutations in the zinc fingers of ADR1 that change the specificity of DNA binding and transactivation

ADR1 is a yeast transcription factor that contains two zinc fingers of the Cys-2-His-2 (C2H2) class. Mutations that change the specificity of DNA binding of ADR1 to its target site, upstream activation sequence 1 (UAS1), have been identified at three positions in the first zinc finger. Mutations Arg-115 to Gln, His-118 to Thr, and Arg-121 to Asn led to new specificities of DNA binding at adjacent positions 10, 9, and 8 (3'-GAG-5') in UAS1. Arg-115 is at the finger tip, and His-118 and Arg-121 are at positions 3 and 6, respectively, in the alpha helix of finger 1. One double mutant displayed the binding specificity expected from the properties of its constituent new-specificity mutations. Mutations in the second finger that allowed its binding site to be identified through loss-of-contact phenotypes were made. These mutations imply a tail-to-tail orientation of the two ADR1 monomers on their adjacent binding sites. Finger 1 is aligned on UAS1 in an amino-to-carboxyl-terminal orientation along the guanine-rich strand in a 3'-to-5' direction. One of the ADR1 mutants was functional in vivo with both its cognate binding site and wild-type UAS1, but the other two mutants were defective in transactivation despite their ability to bind with high affinity to their cognate binding sites.

Aromatic-aromatic interactions in the zinc finger motif. Analysis of the two-dimensional nuclear magnetic resonance structure of a mutant domain

The folding and stability of globular proteins are determined by a variety of chemical mechanisms, including hydrogen bonds, salt bridges and the hydrophobic effect. Of particular interest are weakly polar interactions involving aromatic rings, which are proposed to regulate the geometry of closely packed protein interiors. Such interactions reflect the electrostatic contribution of pi-electrons and, unlike van der Waals' interactions and the hydrophobic effect, may, in principle, introduce a directional force in a protein's hydrophobic core. Although the weakly polar hypothesis is supported by a statistical analysis of protein structures, the general importance of such contributions to protein folding and stability is unclear. Here, we show the presence of alternative aromatic-aromatic interactions in the two-dimensional nuclear magnetic resonance structure of a mutant Zn finger. Changes in aromatic packing lead in turn to local and non-local differences between the structures of a wild-type and mutant domain. The results provide insight into the evolution of Zn finger sequences and have implications for understanding how geometric relationships may be chemically encoded in a simple sequence template.

Metal binding and folding properties of a minimalist Cys2His2 zinc finger peptide

A minimalist Cys2His2 zinc finger peptide, Lys-Tyr-Ala-Cys-Ala-Ala-Cys-Ala-Ala-Ala-Phe-Ala-Ala-Lys-Ala-Ala-Leu-Ala- Ala-His-Ala-Ala-Ala-His-Ala-Lys, has been synthesized. Metal binding studies using Co2+ as a probe indicated that this peptide forms a 1:1 peptide/metal complex with a dissociation constant comparable to that observed for other zinc finger peptides. At high peptide concentrations, a 2:1 peptide/metal complex also forms, with four cysteinates coordinated to Co2+. Additional studies with sequence variants in which the canonical hydrophobic residues were changed to alanine, or in which one of the residues between the cysteines and the histidines was deleted, revealed an even more pronounced formation of the 2:1 complex over the 1:1 complex. In addition, the absorption spectra of the 1:1 peptide/Co2+ complexes of the variant peptides are significantly different from those seen for complexes of the parent peptide or those of more typical zinc finger peptides. NMR studies revealed that the parent peptide folds in the presence of Zn2+ to a structure very similar to that observed for other zinc finger peptides of this class. Taken together, these results suggest that the metal-binding and canonical hydrophobic residues are necessary and sufficient to determine the structure of this class of zinc finger peptides.

Mutations in the zinc fingers of ADR1 that change the specificity of DNA binding and transactivation

ADR1 is a yeast transcription factor that contains two zinc fingers of the Cys-2-His-2 (C2H2) class. Mutations that change the specificity of DNA binding of ADR1 to its target site, upstream activation sequence 1 (UAS1), have been identified at three positions in the first zinc finger. Mutations Arg-115 to Gln, His-118 to Thr, and Arg-121 to Asn led to new specificities of DNA binding at adjacent positions 10, 9, and 8 (3'-GAG-5') in UAS1. Arg-115 is at the finger tip, and His-118 and Arg-121 are at positions 3 and 6, respectively, in the alpha helix of finger 1. One double mutant displayed the binding specificity expected from the properties of its constituent new-specificity mutations. Mutations in the second finger that allowed its binding site to be identified through loss-of-contact phenotypes were made. These mutations imply a tail-to-tail orientation of the two ADR1 monomers on their adjacent binding sites. Finger 1 is aligned on UAS1 in an amino-to-carboxyl-terminal orientation along the guanine-rich strand in a 3'-to-5' direction. One of the ADR1 mutants was functional in vivo with both its cognate binding site and wild-type UAS1, but the other two mutants were defective in transactivation despite their ability to bind with high affinity to their cognate binding sites.

Only two of the five zinc fingers of the eukaryotic transcriptional repressor PRDI-BF1 are required for sequence-specific DNA binding

The eukaryotic transcriptional repressor PRDI-BF1 contains five zinc fingers of the C2H2 type, and the protein binds specifically to PRDI, a 14-bp regulatory element of the beta interferon gene promoter. We have investigated the amino acid sequence requirements for specific binding to PRDI and found that the five zinc fingers and a short stretch of amino acids N terminal to the first finger are necessary and sufficient for PRDI-specific binding. The contribution of individual zinc fingers to DNA binding was investigated by inserting them in various combinations into another zinc finger-containing DNA-binding protein whose own fingers had been removed. We found that insertion of PRDI-BF1 zinc fingers 1 and 2 confer PRDI-binding activity on the recipient protein. In contrast, the insertion of PRDI-BF1 zinc fingers 2 through 5, the insertion of zinc finger 1 or 2 alone, and the insertion of zinc fingers 1 and 2 in reverse order did not confer PRDI-binding activity. We conclude that the first two PRDI-BF1 zinc fingers together are sufficient for the sequence-specific recognition of PRDI.

A metal-binding motif implicated in RNA recognition by an aminoacyl-tRNA synthetase and by a retroviral gene product

A randomly generated mutation in Escherichia coli alanine tRNA synthetase compensates for a mutation in its cognate tRNA. The enzyme's mutation occurs next to a Cys-X2-Cys-X6-His-X2-His metal-binding motif that is distinct from the zinc finger motif found in some DNA-binding proteins. Instead, the synthetase's metal binding domain resembles the Cys-X2-Cys-X4-His-X4-Cys metal-binding domain of the gag gene product of retroviruses. For Ala-tRNA synthetase, the metal bound at the Cys-His motif is important specifically for the tRNA-dependent step of catalysis, and the enzyme-tRNA interaction is dependent on the geometry of metal co-ordination to the enzyme. These data, and the demonstrated sensitivity of RNA packaging to mutations in the metal-binding domain of the gag gene product of retroviruses, suggest that an aminoacyl-tRNA synthetase and retroviruses have adopted a related metal-binding motif for RNA recognition.

Nucleocapsid zinc fingers detected in retroviruses: EXAFS studies of intact viruses and the solution-state structure of the nucleocapsid protein from HIV-1

All retroviral nucleocapsid (NC) proteins contain one or two copies of an invariant 3Cys-1His array (CCHC = C-X2-C-X4-H-X4-C; C = Cys, H = His, X = variable amino acid) that are essential for RNA genome packaging and infectivity and have been proposed to function as zinc-binding domains. Although the arrays are capable of binding zinc in vitro, the physiological relevance of zinc coordination has not been firmly established. We have obtained zinc-edge extended X-ray absorption fine structure (EXAFS) spectra for intact retroviruses in order to determine if virus-bound zinc, which is present in quantities nearly stoichiometric with the CCHC arrays (Bess, J.W., Jr., Powell, P.J., Issaq, H.J., Schumack, L.J., Grimes, M.K., Henderson, L.E., & Arthur, L.O., 1992, J. Virol. 66, 840-847), exists in a unique coordination environment. The viral EXAFS spectra obtained are remarkably similar to the spectrum of a model CCHC zinc finger peptide with known 3Cys-1His zinc coordination structure. This finding, combined with other biochemical results, indicates that the majority of the viral zinc is coordinated to the NC CCHC arrays in mature retroviruses. Based on these findings, we have extended our NMR studies of the HIV-1 NC protein and have determined its three-dimensional solution-state structure. The CCHC arrays of HIV-1 NC exist as independently folded, noninteracting domains on a flexible polypeptide chain, with conservatively substituted aromatic residues forming hydrophobic patches on the zinc finger surfaces. These residues are essential for RNA genome recognition, and fluorescence measurements indicate that at least one residue (Trp37) participates directly in binding to nucleic acids in vitro. The NC is only the third HIV-1 protein to be structurally characterized, and the combined EXAFS, structural, and nucleic acid-binding results provide a basis for the rational design of new NC-targeted antiviral agents and vaccines for the control of AIDS.

Only two of the five zinc fingers of the eukaryotic transcriptional repressor PRDI-BF1 are required for sequence-specific DNA binding

The eukaryotic transcriptional repressor PRDI-BF1 contains five zinc fingers of the C2H2 type, and the protein binds specifically to PRDI, a 14-bp regulatory element of the beta interferon gene promoter. We have investigated the amino acid sequence requirements for specific binding to PRDI and found that the five zinc fingers and a short stretch of amino acids N terminal to the first finger are necessary and sufficient for PRDI-specific binding. The contribution of individual zinc fingers to DNA binding was investigated by inserting them in various combinations into another zinc finger-containing DNA-binding protein whose own fingers had been removed. We found that insertion of PRDI-BF1 zinc fingers 1 and 2 confer PRDI-binding activity on the recipient protein. In contrast, the insertion of PRDI-BF1 zinc fingers 2 through 5, the insertion of zinc finger 1 or 2 alone, and the insertion of zinc fingers 1 and 2 in reverse order did not confer PRDI-binding activity. We conclude that the first two PRDI-BF1 zinc fingers together are sufficient for the sequence-specific recognition of PRDI.

Genes encoding transcription factor IIIA and the RNA polymerase common subunit RPB6 are divergently transcribed in Saccharomyces cerevisiae

The gene encoding Saccharomyces cerevisiae transcription factor TFIIIA has been found adjacent to RPB6, a gene that specifies a subunit shared by nuclear RNA polymerases. Analysis of DNA upstream of the RPB6 gene revealed an open reading frame that predicts a protein, designated PZF1, with nine C2H2 zinc fingers. The presence of nine C2H2 zinc fingers in PZF1 protein, a hallmark of amphibian TFIIIA proteins, suggested that PZF1 might be a TFIIIA homologue. We found that purified recombinant PZF1 specifically binds the internal control region (ICR) of the 5S rRNA gene in S. cerevisiae. The presence of nine C2H2 zinc fingers, the specific binding to ICR DNA, and the similarity of the predicted molecular mass of PZF1 with that determined for purified yeast TFIIIA, together indicate that PZF1 is TFIIIA. The yeast and amphibian TFIIIA proteins share only a limited number of residues outside of those normally conserved in C2H2 zinc fingers; these conserved residues may provide clues to the sequence specificity of these proteins. The PZF1 gene was found to be single copy, transcribed into a 1.5-kilobase mRNA, and essential for yeast cell viability. Interestingly, the yeast RPB6 and TFIIIA coding sequences are divergently transcribed and are separated by only 233 base pairs, providing the potential for coregulated expression of components of RNA polymerases and the 5S rRNA component of ribosomes.