The rational design and construction of a cuboidal iron-sulfur protein.

Rational protein design is an emerging approach for testing general theories of protein chemistry through the creation of new structures and functions. Here we present the first successful introduction by rational design of a [Fe4S4] cuboidal cluster into the hydrophobic core of Escherichia coli thioredoxin, a protein normally devoid of metal centers. Cuboidal [Fe4S4] is one of the stable forms of self-assembled iron-sulfur clusters that are thought to represent some of the earliest evolved biological redox centers. [Fe4S4] clusters have been recruited for use in a variety of proteins whose functions are central to many of the major biochemical processes ranging from simple soluble electron-transfer agents, to membrane-bound components of electron-transfer chains, to electron reservoirs in complex metalloenzymes such as nitrogenase. By situating an [Fe4S4] cluster into a protein environment not previously adapted by evolution we can explore the factors by which their activity is modulated by the protein matrix.

Construction of a catalytically active iron superoxide dismutase by rational protein design.

The rational protein design algorithm DEZYMER was used to introduce the active site of nonheme iron superoxide dismutase (SOD) into the hydrophobic interior of the host protein, Escherichia coli thioredoxin (Trx), a protein that does not naturally contain a transition metal-binding site. Reconstitution of the designed protein, Trx-SOD, showed the incorporation of one high-affinity metal-binding site. The electronic spectra of the holoprotein and its N3- and F- adducts are analogous to those previously reported for native {Fe3+}SOD. Activity assays showed that {Fe3+}Trx-SOD is capable of catalyzing the dismutation of the superoxide anion; comparative studies with the unrelated wild-type E. coli iron SOD indicated that {Fe3+}Trx-SOD catalyzes the dismutation reaction at a rate on the order of 10(5) M-1s -1. The ability to design catalytically competent metalloenzymes allows for the systematic investigation of fundamental mechanistic questions concerning catalysis at transition metal centers.

Structures of zinc finger domains from transcription factor Sp1. Insights into sequence-specific protein-DNA recognition.

The carboxyl terminus of transcription factor Sp1 contains three contiguous Cys2-His2 zinc finger domains with the consensus sequence Cys-X2-4-Cys-X12-His-X3-His. We have used standard homonuclear two-dimensional NMR techniques to solve the solution structures of synthetic peptides corresponding to the last two zinc finger domains (Sp1f2 and Sp1f3, respectively) of Sp1. Our studies indicate a classical Cys2-His2 type fold for both the domains differing from each other primarily in the conformation of Cys-X2-Cys (beta-type I turn) and Cys-X4-Cys (beta-type II turn) elements. There are, however, no significant differences in the metal binding properties between the Cys-X4-Cys (Sp1f2) and Cys-X2-Cys (Sp1f3) subclasses of zinc fingers. The free solution structures of Sp1f2 and Sp1f3 are very similar to those of the analogous fingers of Zif268 bound to DNA. There is NMR spectral evidence suggesting that the Arg-Asp buttressing interaction observed in the Zif-268.DNA complex is also preserved in unbound Sp1f2 and Sp1f3. Modeling Sp1-DNA complex by overlaying the Sp1f2 and Sp1f3 structures on Zif268 fingers 1 and 2, respectively, predicts the role of key amino acid residues, the interference/protection data, and supports the model of Sp1-DNA interaction proposed earlier.

Spectroscopic and kinetic properties of unphosphorylated rat hepatic phenylalanine hydroxylase expressed in Escherichia coli. Comparison of resting and activated states.

The non-heme iron-dependent metalloenzyme, rat hepatic phenylalanine hydroxylase (EC 1.14.16.1; phenylalanine 4-monooxygenase (PAH) was overexpressed in Escherichia coli and purified to homogeneity, allowing a detailed comparison of the kinetic, hydrodynamic, and spectroscopic properties of its allosteric states. The homotetrameric recombinant enzyme, which is highly active and contains 0.7-0.8 iron atoms per subunit, is identical to the native enzyme in several properties: Km, 6-methyltetrahydropterin = 61 microM and L-Phe = 170 microM; Vmax = 9 s-1 (compared to 45 microM, 180 microM, and 13 s-1 for the rat hepatic enzyme). L-Phe and lysolecithin treatment induce the rPAHT-->rPAHR (where r is recombinant) allosteric transformation necessary for rPAH activity. Characteristic changes in the fluorescence spectra, increased hydrophobicity, a large activation energy barrier, and a 10% volume increase of the tetrameric structure are consistent with a significant reorganization of the protein following allosteric activation. However, optical and EPR spectroscopic data suggest that only minor changes occur in the primary coordination sphere (carboxylate/histidine/water) of the catalytic iron center. Detailed steady state kinetic investigations, using 6-methyltetrahydropterin as cofactor and lysolecithin as activator, indicate rPAH follows a sequential mechanism. A catalytic Arrhenius Eact of 14.6 +/- 0.3 kcal/mol subunit was determined from temperature-dependent stopped-flow kinetics data. rPAH inactivates during L-Phe hydroxylation with a half-life of 4.3 min at 25 degrees C, corresponding to an Arrhenius Eact of 10 +/- 1 kcal/mol subunit for the inactivation process. Catechol binding (2.4 x 10(6) M-1) is shown to occur only at catalytically competent iron sites. Ferrous rPAH binds NO, giving rise to an ST = 3/2 spin system.

Sequence-specific recognition of DNA by zinc-finger peptides derived from the transcription factor Sp1.

We have overexpressed and purified two peptide fragments of Sp1 that contain the three "zinc-finger" domains necessary for specific Sp1 DNA binding. These peptides assume a stable, folded conformation in solution in the presence of Zn2+ as shown by DNA binding assays and NMR spectroscopy. Mobility-shift assays demonstrate that the Sp1 peptides recognize a number of different Sp1 DNA binding sites (GC boxes, with the core sequence GGGCGG). The dissociation constant for a 92-amino acid peptide binding to the GGGGCGGGGC sequence (Kd approximately 10 nM) and the relative affinities for several other DNA sequences definitively demonstrate Sp1-like binding properties. The thermodynamic binding site for Sp1-Zn92 has been mapped using the primer-extension/mobility-shift assay revealing that the 5' portion of the GC box DNA sequence (GGG GCG) contributes more strongly to the total binding energy than the 3' portion (GGGC). These findings are interpreted in the context of the Sp1 amino acid sequence in comparison with the structurally characterized Zif-268/DNA complex. A model is proposed that offers a structural explanation for the ability of Sp1 to recognize a diverse array of DNA sequences in terms of the individual (and different) DNA binding properties of each of the three zinc-finger domains.

Construction of new ligand binding sites in proteins of known structure. II. Grafting of a buried transition metal binding site into Escherichia coli thioredoxin.

In an accompanying paper a computational procedure is described, which introduces new ligand-binding sites into proteins of known structure. Here we describe the experimental implementation of one of the designs, which is intended to introduce a copper-binding site into Escherichia coli thioredoxin. The new binding site can be introduced with a minimum of four amino acid changes. The binding site is buried so that structural rules for making mutations in the hydrophobic core of a protein, as well as for the introduction of new functions, are being tested in this experiment. The mutant protein is folded even in the absence of metals, and variants that retain the original activity of thioredoxin can be isolated. The protein has gained a metal-binding site specific for transition metals. The metal co-ordination chemistry at the binding site varies depending on the metal that is introduced into it. Mercury(II) is co-ordinated in the expected manner. Copper(II) binds in a way that was not anticipated in the original design. It appears to use two of the four residues intended to form the co-ordination sphere, and two other residues that were not part of the original set of mutations. It is therefore necessary not only to introduce new functional groups to form a new site, but also to consider and remove alternative modes of binding.

Binding of [(dien)PtCl] Cl to poly(dG-dC)-poly(dG-dC) facilitates the B goes to Z conformational transition.

Chlorodiethylenetriamineplatinum(II) chloride, [(dien)PtCl]Cl, bound to less than or equal to 10% of the nucleotide bases of poly(dG-dC) . poly(dG-dC) reduces the amount of ethanol necessary to bring about the B goes to Z conformational transition in proportion to the amount of platinum complex bound as monitored by CD spectroscopy. The transition may be effected by 25% ethanol with 9.3% of the bases modified polymer an ethanol with 5.4% of the bases modified. With an unmodified polymer an ethanol concentration of 55-60% is necessary to bring about the transition. The assignment of the Z conformation was supported by 31P NMR spectroscopy. This covalent modification of the DNA is reversed by treatment with cyanide ion after which the normal amount of ethanol is necessary to achieve the transition. The platinum complex shows no enhanced binding to DNA in the Z versus the B conformation. Between 20 and 33% (saturation binding) modification, [(dien)PtCl]Cl binds cooperatively to the heterocopolymer as judged by CD spectroscopy. At this high level of modification it is no longer possible to induce the Z DNA structure with ethanol. When [(dien)PtCl]Cl is bound to preformed (with ethanol) Z DNA at saturating levels the CD spectrum is altered but reverts to the spectrum of highly modified DNA upon removal of ethanol. The antitumor drug cis-diaminedichloroplatinum(II), cis-DDP, binds to poly(dG-dC) . poly(dG-dC) and alters the CD spectrum. It does not facilitate the B goes to Z conformational change, however, and actually prevents it from happening even at very high ethanol concentrations.