Soluble expression and purification of tumor suppressor WT1 and its zinc finger domain

Full length murine WT1 and its zinc finger domain were separately inserted into Escherichia coli expression vectors with various fusion tags on either terminus by Gateway technology (Invitrogen) and expression of soluble protein was assessed. Fusion proteins including the four zinc finger domains of WT1 were used to optimize expression and purification conditions and to characterize WT1:DNA interactions in the absence of WT1:WT1 interactions. Zinc finger protein for in vitro characterization was prepared by IMAC purification of WT1 residues 321-443 with a thioredoxin-hexahistidine N-terminal fusion, followed by 3C protease cleavage to liberate the zinc fingers and cation exchange chromatography to isolate the zinc fingers and reduce the level of the truncated forms. Titration of zinc finger domain with a binding site from the PDGFA promoter gave a K(d) of 100±30nM for the -KTS isoform and 130±40nM for the +KTS isoform. The zinc finger domain was also co-crystallized with a double-stranded DNA oligonucleotide, yielding crystals that diffract to 5.5?. Using protocols established for the zinc finger domain, we expressed soluble full-length WT1 with an N-terminal thioredoxin domain and purified the fusion protein by IMAC. In electro-mobility shift assays, purified full-length WT1 bound double-stranded oligonucleotides containing known WT1 binding sites, but not control oligonucleotides. Two molecules of WT1 bind an oligonucleotide presenting the full PDGFA promoter, demonstrating that active full-length WT1 can be produced in E. coli and used to investigate WT1 dimerization in complex with DNA in vitro.     

Differential binding of zinc fingers from Xenopus TFIIIA and p43 to 5S RNA and the 5S RNA gene.

Zinc fingers are usually associated with proteins that interact with DNA. Yet in two oocyte-specific Xenopus proteins, TFIIA and p43, zinc fingers are used to bind 5S RNA. One of these, TFIIIA, also binds the 5S RNA gene. Both proteins have nine zinc fingers that are nearly identical with respect to size and spacing. We have determined the relative affinities of groups of zinc fingers from TFIIIA for both 5S RNA and the 5S RNA gene. We have also determined the relative affinities of groups of zinc fingers from p43 for 5S RNA. The primary protein regions for RNA and DNA interaction in TFIIIA are located at opposite ends of the molecule. All zinc fingers from TFIIIA participate in binding 5S RNA, but zinc fingers from the C terminus have the highest affinity. N-terminal zinc fingers are essential for binding the 5S RNA gene. In contrast, zinc fingers at the amino terminus of p43 are essential for binding 5S RNA.     

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.     

Structure of the Wilms tumor suppressor protein zinc finger domain bound to DNA

The zinc finger domain of the Wilms tumor suppressor protein (WT1) contains four canonical Cys(2)His(2) zinc fingers. WT1 binds preferentially to DNA sequences that are closely related to the EGR-1 consensus site. We report the structure determination by both X-ray crystallography and NMR spectroscopy of the WT1 zinc finger domain in complex with DNA. The X-ray structure was determined for the complex with a cognate 14 base-pair oligonucleotide, and composite X-ray/NMR structures were determined for complexes with both the 14 base-pair and an extended 17 base-pair DNA. This combined approach allowed unambiguous determination of the position of the first zinc finger, which is influenced by lattice contacts in the crystal structure. The crystal structure shows the second, third and fourth zinc finger domains inserted deep into the major groove of the DNA where they make base-specific interactions. The DNA duplex is distorted in the vicinity of the first zinc finger, with a cytidine twisted and tilted out of the base stack to pack against finger 1 and the tip of finger 2. By contrast, the composite X-ray/NMR structures show that finger 1 continues to follow the major groove in the solution complexes. However, the orientation of the helix is non-canonical, and the fingertip and the N terminus of the helix project out of the major groove; as a consequence, the zinc finger side-chains that are commonly involved in base recognition make no contact with the DNA. We conclude that finger 1 helps to anchor WT1 to the DNA by amplifying the binding affinity although it does not contribute significantly to binding specificity. The structures provide molecular level insights into the potential consequences of mutations in zinc fingers 2 and 3 that are associated with Denys-Drash syndrome and nephritic syndrome. The mutations are of two types, and either destabilize the zinc finger structure or replace key base contact residues.     

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.     

Functional analysis of the two zinc fingers of SRE, a GATA-type factor that negatively regulates siderophore synthesis in Neurospora crassa

Multiple GATA factors, zinc finger DNA binding proteins that recognize consensus GATA elements, exist in Neurospora crassa. One of them, SRE, is involved in controlling the iron metabolic pathway of N. crassa. In N. crassa, iron transport is mediated by a number of small cyclic peptides, known as siderophores. The siderophore synthesis pathway is negatively regulated by SRE; a loss-of-function sre mutant strain showed partial constitutive synthesis of siderophore. In the research presented here, the negative function of SRE was further confirmed by a heterokaryon test and by gene complementation. SRE was expressed as a GST fusion protein. In vitro EMSA revealed that SRE binds specifically to DNA molecules containing GATA sequence elements. Autoregulation of sre gene expression appears possible because the sre gene promoter itself contains GATA sequences. Mutations were introduced into sre that lead to amino acid substitutions in each of the zinc fingers that will disrupt their function. In vitro EMSA revealed that both N-terminal and C-terminal zinc fingers of SRE are involved in DNA binding. This feature is different from that found with the vertebrate two zinc finger GATA factors. Invivo tests, accomplished by transforming the mutant sre genes into sre rip mutant, showed that SRE with mutations in either or both zinc fingers still maintained its function under low-iron conditions. In contrast, these mutant SRE proteins fail to function under high-iron conditions. Our results predict the presence of other positive or negative regulators of the siderophore synthetic pathway.     

NMR Structure of the Amino-Terminal Domain of the Lambda Integrase Protein in Complex with DNA: Immobilization of a Flexible Tail Facilitates Beta-Sheet Recognition of the Major Groove

The integrase protein (Int) from bacteriophage lambda is the archetypal member of the tyrosine recombinase family, a large group of enzymes that rearrange DNA in all domains of life. Int catalyzes the insertion and excision of the viral genome into and out of the Escherichia coli chromosome. Recombination transpires within higher-order nucleoprotein complexes that form when its amino-terminal domain binds to arm-type DNA sequences that are located distal to the site of strand exchange. Arm-site binding by Int is essential for catalysis, as it promotes Int-mediated bridge structures that stabilize the recombination machinery. We have elucidated how Int is able to sequence specifically recognize the arm-type site sequence by determining the solution structure of its amino-terminal domain (Int^N, residues Met1 to Leu64) in complex with its P′2 DNA binding site. Previous studies have shown that Int^N adopts a rare monomeric DNA binding fold that consists of a three-stranded antiparallel beta-sheet that is packed against a carboxy-terminal alpha helix. A low-resolution crystal structure of the full-length protein also revealed that the sheet is inserted into the major groove of the arm-type site. The solution structure presented here reveals how Int^N specifically recognizes the arm-type site sequence. A novel feature of the new solution structure is the use of an 11-residue tail that is located at the amino terminus. DNA binding induces the folding of a 3₁₀ helix in the tail that projects the amino terminus of the protein deep into the minor groove for stabilizing DNA contacts. This finding reveals the structural basis for the observation that the “unstructured” amino terminus is required for recombination.     

DNA-induced alpha-helix capping in conserved linker sequences is a determinant of binding affinity in Cys(2)-His(2) zinc fingers

High-affinity, sequence-specific DNA binding by Cys(2)-His(2) zinc finger proteins is mediated by both specific protein-base interactions and non-specific contacts between charged side-chains and the phosphate backbone. In addition, in DNA complexes of multiple zinc fingers, protein-protein interactions between the finger units contribute to the binding affinity. We present NMR evidence for another contribution to high- affinity binding, a highly specific DNA-induced helix capping involving residues in the linker sequence between fingers. Capping at the C terminus of the alpha-helix in each zinc finger, incorporating a consensus TGEKP linker sequence that follows each finger, provides substantial binding energy to the DNA complexes of zinc fingers 1-3 of TFIIIA (zf1-3) and the four zinc fingers of the Wilms' tumor suppressor protein (wt1-4). The same alpha-helix C-capping motif is observed in the X-ray structures of four other protein-DNA complexes. The structures of each of the TGEKP linkers in these complexes can be superimposed on the linker sequences in the zf1-3 complex, revealing a remarkable similarity in both backbone and side-chain conformations. The canonical linker structures from the zinc-finger-DNA complexes have been compared to the NMR structure of the TGEKP linker connecting fingers 1 and 2 in zf1-3 in the absence of DNA. This comparison reveals that additional stabilization likely arises in the DNA complexes from hydrogen bonding between the backbone amide of E3 and the side-chain O(gamma) of T1 in the linker. We suggest that these DNA-induced C-capping interactions provide a means whereby the multiple-finger complex, which must necessarily be domain-flexible in the unbound state as it searches for the correct DNA sequence, can be "snap-locked" in place once the correct DNA sequence is encountered. These observations provide a rationale for the high conservation of the TGEKP linker sequences in Cys(2)-His(2) zinc finger proteins.     

The zinc fingers of human poly(ADP-ribose) polymerase are differentially required for the recognition of DNA breaks and nicks and the consequent enzyme activation. Other structures recognize intact DNA

The recognition of double-stranded DNA breaks and single-stranded nicks by human poly(ADP-ribose) polymerase and the consequent enzymic activation were examined using derivatives of the enzyme expressed in Escherichia coli. The N-terminal 162 residues encompass two zinc fingers. Deletion or mutation of the first finger results in a loss of activation by DNA with either single-stranded or double-stranded damage. Destruction of the second finger reduces activation by double-stranded DNA breaks only slightly, but eliminates activation by single-stranded DNA nicks. These data suggest that activation by single-stranded DNA nicks requires two zinc fingers, but activation by double-stranded DNA breaks requires only the finger closer to the N terminus. Variant proteins that lack both zinc fingers are enzymically inactive but still exhibit weak DNA binding, which is independent of DNA damage. Thus, other regions are also capable of binding intact DNA, but the recognition of a strand nick or break which occasions the synthesis of poly(ADP-ribose) specifically requires the zinc fingers.