Greater binding affinity of trivalent antimony to a CCCH zinc finger domain compared to a CCHC domain of kinetoplastid proteins

It has been reported recently that Sb(III) competes with Zn(II) for its binding to the CCHC zinc finger domain of the HIV-1 NCp7 protein, suggesting that zinc finger proteins may be molecular targets for antimony-based drugs. Here, the interaction of Sb(III) with a CCCH zinc finger domain, which is considered to play a crucial role in the biology of kinetoplastid protozoa, has been characterized for the first time. The binding characteristics of Sb(III) were compared between a CCCH-type peptide derived from a kinetoplastid protein and two different CCHC-type zinc finger peptides. The formation of 1 : 1 Zn-peptide and Sb-peptide complexes from the different peptides was demonstrated using circular dichroism, UV absorption, fluorescence spectroscopies and ESI-MS. Titration of the Zn-peptide complexes with SbCl(3) was performed at pH 6 and 7, exploiting the intrinsic fluorescence of the peptides. The differential spectral characteristics of the peptides allowed for competition experiments between the different peptides for binding of Zn(II). The present study establishes that Sb(III) more effectively displaces Zn(II) from the CCCH peptide than CCHC ones, as a result of both the greater stability of the Sb-CCCH complex (compared to Sb-CCHC complexes) and the lower stability of the Zn-CCCH complex (compared to Zn-CCHC complexes). Comparison of the binding characteristics of Sb(III) or Zn(II) between the CCHC-type peptides with different amino acid sequences supports the model that not only the conserved zinc finger motif, but also the sequence of non-conserved amino acids determines the binding affinity of Sb(III) and Zn(II). These data suggest that the interaction of Sb(III) with CCCH-type zinc finger proteins may modulate, or even mediate, the pharmacological action of antimonial drugs.     

Specific DNA binding to a major histocompatibility complex enhancer sequence by a synthetic 57-residue double zinc finger peptide from a human enhancer binding protein

Two 57-residue peptides containing one pair of "zinc fingers" from a human enhancer binding protein were prepared by solid-phase peptide synthesis. One peptide (MBP-DF) contained the native sequence, while the second peptide ([Abu11]MBP-DF) has an alpha-aminobutyric acid residue substituted for a nonconserved cysteine residue at position 11. The peptides were characterized by several chemical and physical methods, and their DNA binding properties were evaluated using gel retardation experiments. Spectroscopic studies demonstrated that addition of metal ions such as zinc and cobalt resulted in specific conformational changes in both peptides, indicating that cysteine-11 does not appear to be involved in metal chelation. One-dimensional 1H NMR studies indicate that a stable folded structure is formed upon addition of zinc, and the chemical shift pattern is consistent with that previously observed for one constituent single finger (Omichinski, J., Clore, G. M., Appella, E., Sakaguchi, K., and Gronenborn, A. M. (1990) Biochemistry 29, 9324-9334). Gel retardation experiments demonstrate that the peptides are capable of interacting with a 15-mer oligonucleotide comprising a portion of the major histocompatibility complex enhancer sequence and that the interaction is zinc-dependent. The dissociation constant for the [Abu11]MBP-DF peptide is 1.4 x 10(-7) M with maximal binding occurring at a zinc-to-peptide ratio of 2 to 1. The binding specificity observed with respect to related enhancer sequences exhibits the same relative order as noted previously for the whole protein. Studies with point mutants of the major histocompatibility complex enhancer binding sequence indicate that the last GC base pair in a four-guanine stretch plays a pivotal role in the interaction between the peptide and DNA.     

Physiological levels of glutathione enhance Zn(II) binding by a Cys4 zinc finger

Using fluorescence and UV-vis spectroscopies and mass spectrometry, we demonstrated that the presence of physiological levels of reduced glutathione enhances the binding of Zn(II) to XPAzf, a Cys4 zinc finger peptide derived from the XPA protein, by means of formation of a ternary complex of a general formula ZnXPAzf[GSH]. Similar complexes were also indicated by ESI-MS for isostructural Co(II)- and Cd(II)-substituted XPAzf. The observed enhancement of the Zn(II) binding to XPAzf by a factor of 50 over the physiological range of GSH concentrations of 1-20 mM corresponds to a dissociation constant of GSH from the ZnXPAzf[GSH] complex of 0.05 μM. This effect may account for an apparent discrepancy between relatively low Zn(II) binding constants measured in vitro for many zinc fingers, and the requirement of tight Zn(II) binding enforced by intracellular zinc buffering by the thionein/metallothionein couple.     

Mechanism of DNA binding by the ADR1 zinc finger transcription factor as determined by SPR

The ADR1 protein recognizes a six base-pair consensus DNA sequence using two zinc fingers and an adjacent accessory motif. Kinetic measurements were performed on the DNA-binding domain of ADR1 using surface plasmon resonance. Binding by ADR1 was characterized to two known native binding sequences from the ADH2 and CTA1 promoter regions, which differ in two of the six consensus positions. In addition, non-specific binding by ADR1 to a random DNA sequence was measured. ADR1 binds the native sites with nanomolar affinities. Remarkably, ADR1 binds non-specific DNA with affinities only approximately tenfold lower than the native sequences. The specific and non-specific binding affinities are conferred mainly by differences in the association phase of DNA binding. The association rate for the complex is strongly influenced by the proximal accessory region, while the dissociation reaction and specificity of binding are controlled by the two zinc fingers. Binding kinetics of two ADR1 mutants was also examined. ADR1 containing an R91K mutation in the accessory region bound with similar affinity to wild-type, but with slightly less sequence specificity. The R91K mutation was observed to increase binding affinity to a suboptimal sequence by decreasing the complex dissociation rate. L146H, a change-of-specificity mutation at the +3 position of the second zinc finger, bound its preferred sequence with a slightly higher affinity than wild-type. The L146H mutant indicates that beneficial protein-DNA contacts provide similar levels of stabilization to the complex, whether they are hydrogen-bonding or van der Waals interactions.     

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.     

A family of acyclic brevinin-1 peptides from the skin of the Ryukyu brown frog Rana okinavana

The 24 amino-acid residue antimicrobial peptide, brevinin-1 is synthesized in the skins of a wide range of species of Eurasian and North American frogs belonging to the genus Rana. All previously characterized brevinin-1 peptides contain the cyclic heptapeptide domain Cys18-(Xaa)4-Lys-Cys24 at the COOH-terminus of the molecule. Four structurally related peptides were isolated from an extract of the skin of the Ryukyu brown frog Rana okinavana. The amino acid sequences of the peptides [Phe-(Xaa)4-Ile-(Xaa)2-Leu-Ala-Lys-Gly-Leu-Pro-Ser-Leu-Ile-Xaa-Leu-Xaa-Lys-Lys.NH2] identified them as members of the brevinin-1 family that lacked the COOH-terminal cyclic domain but contained a C-terminally alpha-amidated residue. It is suggested, as one possibility, that the Cys18 in the brevinin-1 consensus sequence has been deleted and the Cys24 residue has mutated to a glycine that acts as substrate for peptidyl-glycine alpha-amidating monooxygenase. The peptides potently inhibited the growth of Escherichia coli and Staphylococcus aureus confirming that a cyclic domain is not necessary for antimicrobial activity. A fifth peptide (SFLNFFKGAA10KNLLAAGLDK20LKCKISGTQC30), that also displayed broad-spectrum antimicrobial activity, was isolated from the skin extract and showed structural similarity with members of the ranatuerin-2 family previously isolated from the skin of North American ranid frogs.     

A synthetic peptide encompassing the binding site of the second zinc atom (the 'structural' zinc) of alcohol dehydrogenase.

A 23-residue peptide was synthesized that incorporates the loop which binds the structural zinc atom of mammalian alcohol dehydrogenases and contributes, in part, to subunit interactions in the native enzyme. Neither the amino acid composition nor the sequence of the peptide resemble those of zinc fingers. The reduced peptide stoichiometrically binds zinc or cobalt to form stable complexes with a dissociation constant of the peptide/CO2+ complex of 2.1 microM at pH 7.5. EDTA disrupts the complex. The absorption and magnetic circular dichroic spectra of the cobalt-peptide are indicative of a tetrahedral coordination geometry, and are similar to those of the cobalt-substituted structural site of horse and human (beta 1 beta 1) liver alcohol dehydrogenases. Consequently, the synthetic peptide can serve as a model for the metal-binding segment of alcohol dehydrogenase and for studies of fundamental problems concerning protein/metal interactions.     

Structure of the His44 --> Ala single point mutant of the distal finger motif of HIV-1 nucleocapsid protein: a combined NMR, molecular dynamics simulation, and fluorescence study

The nucleocapsid protein (NCp7) of human immunodeficiency virus type 1 (HIV-1) contains two highly conserved CCHC zinc fingers that strongly bind Zn(2+) through coordination of one His and three Cys residues. It has been suggested that NCp7 function is conformation specific since substitution of any of the zinc coordinating residues in the zinc finger motifs leads to subsequent loss of viral infectivity. To further determine the structural requirements necessary for this specific conformation, we investigated by (1)H 2D NMR and molecular dynamics simulations the structure of the distal finger motif of NCp7 in which the zinc coordinating amino acid, His 44, was substituted by a noncoordinating Ala residue. While the fold of the N-terminal part of this mutated peptide was similar to that of the native peptide, an increased lability and significant conformational changes were observed in the vicinity of the His-to-Ala mutation. Moreover, molecular dynamics simulations suggested a mechanism by which the variant peptide can bind zinc ion even though one zinc-coordinating amino acid was lacking. Using the fluorescence of the naturally occurring Trp37 residue, the binding affinity of the variant peptide to the (TG)(3) model oligonucleotide was found to be decreased by about 2 orders of magnitude with respect with the native peptide. Modeling of the DNA:NCp7 complex using structures of the variant peptide suggests that the residues forming a hydrophobic cleft in the native protein are improperly oriented for efficient DNA binding by the variant peptide.     

Spectroscopic characterization of Co(II)-, Ni(II)-, and Cd(II)-substituted wild-type and non-native retroviral-type zinc finger peptides

The nucleocapsid protein (NCP) from Mason-Pfizer monkey virus (MPMV) contains two evolutionary invariant Cys-X₂-Cys-X₄-His-X₄-Cys retroviral-type zinc finger structures, where the Cys and His residues provide ligands to a tetrahedrally coordinated Zn(II) ion. The N-terminal zinc finger (F1) of NCP from MPMV contains an immediately contiguous Cys in the -1 position relative to the start of this conserved motif: Cys-Cys-X₂-Cys-X₄-His-X₄-Cys. Metal complexes of 18-amino acid peptides which model the native zinc finger sequence, SER-Cys-X₂-Cys-X₄-His-X₄-Cys (F1_SC), and non-native Cys-SER-X₂-Cys-X₄-His-X₄-Cys (F1_CS) and SER-SER-X₂-Cys-X₄-His-X₄-Cys (F1_SS) sequences have been spectroscopically characterized and compared to the native two-zinc-finger protein fragment, MPMV NCP 21-80. All Co(II)-substituted peptide complexes adopt tetrahedral ligand geometries and have S^-MCo(II) ligand-to-metal charge-transfer (LMCT) transition intensities consistent with three Co(II)-S bonds for F1_SC and F1_CS. The non-native F1_CS peptide binds Co(II) with K_Co=1.5᎒⁶ M^-1, comparable to that of the native complex, and 걄-fold tighter than F1_SS. Like the Co(II) derivative, the absorption spectrum of Ni(II)-substituted NCP 21-80 is most consistent with tetrahedral Ni(II) complexes with multiple thiolate donors. In contrast, Ni(II) complexes of F1_SC and F1_CS exhibit a single absorption band in the 400-550 nm region ()겨-300 M^-1 cm^-1), distinct in the two complexes, assignable to a degenerate d-d transition envelope characteristic of non-native square-planar coordination geometry, and an intense LMCT transition in the UV ()₂₅₅ᄾ,000 M^-1 cm^-1). Cd(II) complexes have intense absorption in the UV (5_max=233 nm), with absolute intensities consistent with 񬩈 M^-1 cm^-1 per Cd(II)-S bond. ¹¹³Cd NMR spectroscopy of ¹¹³Cd MPMV NCP gives '=649 ppm, consistent with S₃N coordination. Co(II) and Cd(II) complexes of non-native F1_CS peptides are more sensitive to oxidation by O₂, relative to F1_SC, suggestive of a higher lability in the non-native chelate. The implications of these findings for the evolutionary conservation of this motif are discussed.     

Solution structure of a CCHHC domain of neural zinc finger factor-1 and its implications for DNA binding

The structure of a CCHHC zinc-binding domain from neural zinc finger factor-1 (NZF-1) has been determined in solution though the use of NMR methods. This domain is a member of a family of domains that have the Cys-X(4)-Cys-X(4)-His-X(7)-His-X(5)-Cys consensus sequence. The structure determination reveals a novel fold based around a zinc(II) ion coordinated to three Cys residues and the second of the two conserved His residues. The other His residue is stacked between the metal-coordinated His residue and a relatively conserved aromatic residue. Analysis of His to Gln sequence variants reveals that both His residues are required for the formation of a well-defined structure, but neither is required for high-affinity metal binding at a tetrahedral site. The structure suggests that a two-domain protein fragment and a double-stranded DNA binding site may interact with a common two-fold axis relating the two domains and the two half-sites of the DNA-inverted repeat.     

Evidence for the expression of three genes encoding homologous atrial gland peptides that cause egg laying in Aplysia

Three peptide complexes which can induce egg laying in Aplysia were isolated from the atrial gland of the marine mollusc Aplysia californica and chemically characterized. Amino acid sequence analyses established the covalent structures, including disulfide assignments, of all three dimeric complexes. Each complex consisted of an identical 18-residue peptide (A-AP) which was disulfide-bonded to a 36-residue peptide that was homologous to bag cell egg-laying hormone (ELH). The primary structure of A-AP was determined to be: NH2-Asp-Ser-Asp-Val-Ser-Leu-Phe-Asn-Gly-Asp-Leu-Leu-Pro-Asn-Gly-Arg-Cys- Ser-COOH. The primary structure of one of the three ELH-related peptides (A-ELH) was determined to be NH2-Ile-Ser-Ile-Asn-Gln-Asp-Leu-Lys-Ala-Ile-Thr-Asp-Met-Leu-Leu-Thr-Glu- Gln-Ile-Gln-Ala-Arg-Arg-Arg-Cys-Leu-Asp-Ala-Leu-Arg-Gln-Arg-Leu-Leu-Asp- -Leu-COOH. The two other ELH-related peptides, [Ala27]A-ELH and [Gln23, Ala27]A-ELH, differed from A-ELH at 1 and 2 residues, respectively. Both [Ala27] A-ELH and [Gln23, Ala27]A-ELH were novel peptide sequences representing products of as yet uncharacterized genes within the ELH family. These structural studies provide the first direct chemical evidence that an 18-residue peptide (A-AP) derived from a polypeptide precursor encoded by the A gene, as predicted from nucleotide sequence analysis, occurs in the atrial gland; the Cys17 residue of A-AP is disulfide-bonded to Cys25 of A-ELH; and A-AP also occurs disulfide-bonded to two additional, previously undescribed ELH-related peptides, [Ala27]A-ELH and [Gln23, Ala27]A-ELH.     

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.