Miniaturized hemoproteins

Catalysis and Electron Transfer in De Novo Designed Metalloproteins

One of the hallmark advances in our understanding of metalloprotein function is showcased in our ability to design new, non-native, catalytically active protein scaffolds. This review highlights progress and milestone achievements in the field of de novo metalloprotein design focused on reports from the past decade with special emphasis on de novo designs couched within common subfields of bioinorganic study: heme binding proteins, monometal- and dimetal-containing catalytic sites, and metal-containing electron transfer sites. Within each subfield, we highlight several of what we have identified as significant and important contributions to either our understanding of that subfield or de novo metalloprotein design as a discipline. These reports are placed in context both historically and scientifically. General suggestions for future directions that we feel will be important to advance our understanding or accelerate discovery are discussed.

De Novo-Designed β-Sheet Heme Proteins

The field of de novo protein design has met with considerable success over the past few decades. Heme, a cofactor, has often been introduced to impart a diverse array of functions to a protein, ranging from electron transport to respiration. In nature, heme is found to occur predominantly in α-helical structures over β-sheets, which has resulted in significant designs of heme proteins utilizing coiled-coil helices. By contrast, there are only a few known β-sheet proteins that bind heme and designs of β-sheets frequently result in amyloid-like aggregates. This review reflects on our success in designing a series of multistranded β-sheet heme binding peptides that are well folded in both aqueous and membrane-like environments. Initially, we designed a β-hairpin peptide that self-assembles to bind heme and performs peroxidase activity in membrane. The β-hairpin was optimized further to accommodate a heme binding pocket within multistranded β-sheets for catalysis and electron transfer in membranes. Furthermore, we de novo designed and characterized β-sheet peptides and miniproteins that are soluble in an aqueous environment capable of binding single and multiple hemes with high affinity and stability. Collectively, these studies highlight the substantial progress made toward the design of functional β-sheets.

Mn-Mimochrome VI*a: An Artificial Metalloenzyme With Peroxygenase Activity

Manganese-porphyrins are important tools in catalysis, due to their capability to promote a wide variety of synthetically valuable transformations. Despite their great reactivity, the difficulties to control the reaction selectivity and to protect the catalyst from self-degradation hamper their practical application. Compared to small-molecule porphyrin complexes, metalloenzymes display remarkable features, because the reactivity of the metal center is finely modulated by a complex interplay of interactions within the protein matrix. In the effort to combine the catalytic potential of manganese porphyrins with the unique properties of biological catalysts, artificial metalloenzymes have been reported, mainly by incorporation of manganese-porphyrins into native protein scaffolds. Here we describe the spectroscopic and catalytic properties of Mn-Mimochrome VI*a (Mn-MC6*a), a mini-protein with a manganese deuteroporphyrin active site within a scaffold of two synthetic peptides covalently bound to the porphyrin. Mn-MC6*a is an efficient catalyst endowed with peroxygenase activity. The UV-vis absorption spectrum of Mn-MC6*a resembles that of Mn-reconstituted horseradish peroxidase (Mn-HRP), both in the resting and high-valent oxidized states. Remarkably, Mn-MC6*a shows a higher reactivity compared to Mn-HRP, because higher yields and chemoselectivity were observed in thioether oxidation. Experimental evidences also provided indications on the nature of the high-valent reactive intermediate and on the sulfoxidation mechanism.

Design and engineering of artificial oxygen-activating metalloenzymes

Many efforts are being made in the design and engineering of metalloenzymes with catalytic properties fulfilling the needs of practical applications. Progress in this field has recently been accelerated by advances in computational, molecular and structural biology. This review article focuses on the recent examples of oxygen-activating metalloenzymes, developed through the strategies of de novo design, miniaturization processes and protein redesign. Considerable progress in these diverse design approaches has produced many metal-containing biocatalysts able to adopt the functions of native enzymes or even novel functions beyond those found in Nature.

An artificial heme-enzyme with enhanced catalytic activity: evolution, functional screening and structural characterization

The rational refinement of function into the heme-protein model Mimochrome VI (MC6) resulted in a new analogue, Fe^III-E²L(TD)-MC6, with an improved peroxidase activity.

Artificial heme-proteins: determination of axial ligand orientations through paramagnetic NMR shifts

An empirical equation, describing the relationship between paramagnetic shifts and axial ligand orientations has been applied to an artificial bis-histidine ferriheme-protein, in order to determine the geometry of the active site.

De novo design, synthesis and characterisation of MP3, a new catalytic four-helix bundle hemeprotein

A new artificial metalloenzyme, MP3 (MiniPeroxidase 3), designed by combining the excellent structural properties of four-helix bundle protein scaffolds with the activity of natural peroxidases, was synthesised and characterised. This new hemeprotein model was developed by covalently linking the deuteroporphyrin to two peptide chains of different compositions to obtain an asymmetric helix-loop-helix/heme/helix-loop-helix sandwich arrangement, characterised by 1) a His residue on one chain that acts as an axial ligand to the iron ion; 2) a vacant distal site that is able to accommodate exogenous ligands or substrates; and 3) an Arg residue in the distal site that should assist in hydrogen peroxide activation to give an HRP-like catalytic process. MP3 was synthesised and characterised as its iron complex. CD measurements revealed the high helix-forming propensity of the peptide, confirming the appropriateness of the model procedure; UV/Vis, MCD and EPR experiments gave insights into the coordination geometry and the spin state of the metal. Kinetic experiments showed that Fe(III)-MP3 possesses peroxidase-like activity comparable to R38A-hHRP, highlighting the possibility of mimicking the functional features of natural enzymes. The synergistic application of de novo design methods, synthetic procedures, and spectroscopic characterisation, described herein, demonstrates a method by which to implement and optimise catalytic activity for an enzyme mimetic.

Controlling and fine tuning the physical properties of two identical metal coordination sites in de novo designed three stranded coiled coil peptides

Herein we report how de novo designed peptides can be used to investigate whether the position of a metal site along a linear sequence that folds into a three-stranded α-helical coiled coil defines the physical properties of Cd(II) ions in either CdS(3) or CdS(3)O (O-being an exogenous water molecule) coordination environments. Peptides are presented that bind Cd(II) into two identical coordination sites that are located at different topological positions at the interior of these constructs. The peptide GRANDL16PenL19IL23PenL26I binds two Cd(II) as trigonal planar 3-coordinate CdS(3) structures whereas GRANDL12AL16CL26AL30C sequesters two Cd(II) as pseudotetrahedral 4-coordinate CdS(3)O structures. We demonstrate how for the first peptide, having a more rigid structure, the location of the identical binding sites along the linear sequence does not affect the physical properties of the two bound Cd(II). However, the sites are not completely independent as Cd(II) bound to one of the sites ((113)Cd NMR chemical shift of 681 ppm) is perturbed by the metalation state (apo or [Cd(pep)(Hpep)(2)](+) or [Cd(pep)(3)](-)) of the second center ((113)Cd NMR chemical shift of 686 ppm). GRANDL12AL16CL26AL30C shows a completely different behavior. The physical properties of the two bound Cd(II) ions indeed depend on the position of the metal center, having pK(a2) values for the equilibrium [Cd(pep)(Hpep)(2)](+) → [Cd(pep)(3)](-) + 2H(+) (corresponding to deprotonation and coordination of cysteine thiols) that range from 9.9 to 13.9. In addition, the L26AL30C site shows dynamic behavior, which is not observed for the L12AL16C site. These results indicate that for these systems one cannot simply assign a "4-coordinate structure" and assume certain physical properties for that site since important factors such as packing of the adjacent Leu, size of the intended cavity (endo vs exo) and location of the metal site play crucial roles in determining the final properties of the bound Cd(II).

Heme Binding by the N-Terminal Fragment 1−44 of Human Growth Hormone

Fragment 1-44 of human growth hormone (hGH), prepared in vitro by limited proteolysis of the hormone with pepsin at low pH, encompasses in full the N-terminal helix of this four-helix bundle protein [Spolaore, B., Polverino de Laureto, P., Zambonin, M., and Fontana, A. (2004) Biochemistry 40, 9460-9468]. Here, we report the new and interesting observation that fragment 1-44 can bind heme. The binding property is specific for the N-terminal helix of hGH, since heme binding does not occur with fragment 45-191 or the entire protein. The spectral characteristics of Fe-protoporphyrin IX are those of a low-spin, hexacoordinated iron ligated by two imidazole rings of His residues or His and Met residues. Far-UV circular dichroism (CD) measurements revealed that fragment 1-44 acquires a helical secondary structure upon heme binding. Heme appears to be bound to the fragment in a stereospecific way, since an induced dichroic signal is observed in the Soret region of the CD spectrum. The heme-fragment complex occurs in a 1:1 molar ratio, as determined by spectrophotometric titration, as well as by electrospray-ionization mass spectrometric analysis of the complex. The fragment alone is much more susceptible to tryptic digestion than the heme complex, implying a more folded and rigid structure of this last species. It is proposed that the molecular features of fragment 1-44 determining its heme-binding property reside in the amphipathic character of the helix adopted by the fragment, as well as in the presence in its polypeptide chain of His18, His21, and Met14. These residues can act as specific ligands for the heme-iron, as observed with cytochromes.

Conformational and Electronic Properties of a Microperoxidase in Aqueous Solution: A Computational Study

A theoretical study of the conformational properties of a small heme peptide in aqueous solution is carried out by classical, long-timescale molecular dynamics simulations. The electronic properties of this species, that is, the relative energies of its excited electronic states and the redox potential, are reproduced and related to the conformational behavior using the perturbed matrix method and basic statistical mechanics. Our results show an interesting coupling between the conformational transitions and the electronic properties. These investigations, beyond the biophysically relevant results addressing the long-standing question of the actual role of the enzyme structure on the enzyme activity, are also of some methodological interest since they offer a further computational perspective for including the electronic degrees of freedom into the modeling of rather complex molecular systems.

Miniaturized heme proteins: crystal structure of Co(III)-mimochrome IV

Protein design provides an attractive approach to test the essential features required for folding and function. Previously, we described the design and structural characterization in solution of mimochromes, a series of miniaturized metalloproteins, patterned after the F-helix of the hemoglobin beta-chain. Mimochromes consist of two medium-sized helical peptides, covalently linked to the deuteroporphyrin. CD and NMR characterization of the prototype, mimochrome I, revealed that the overall structure conforms well to the design. However, formation of Delta and Lambda diastereomers was observed. To overcome the problem of diastereomer formation, we re-designed mimochrome I, by engineering intramolecular, interchain interactions. The resulting model was mimochrome IV: the solution structural characterization showed the presence of the Lambda isomer as a unique form. To examine the extent to which the stereochemical stability and uniqueness of mimochrome IV was retained in the solid state, the crystal structure of Co(III)-mimochrome IV was solved by X-ray diffraction, and compared to the solution structure of the same derivative. Co(III)-mimochrome IV structures, both in solution and in the solid state, are characterized by the following common features: a bis-His axial coordination, a Lambda configuration around the metal ion, and a predominant helical conformation of the peptide chains. However, in the crystal structure, intrachain Glu1-Arg9 ion pairs are preferred over the designed, and experimentally found in solution, interchain interactions. This ion pairing switch may be related to strong packing interactions.

A Possible Role for the Covalent Heme−Protein Linkage in Cytochrome c Revealed via Comparison of N-Acetylmicroperoxidase-8 and a Synthetic, Monohistidine-Coordinated Heme Peptide

N-Acetylmicroperoxidase-8 (1) contains heme and residues 14-21 of horse mitochondrial cytochrome c (cyt c). The two thioether bonds linking protein to heme in cyt c are present in 1, and the native axial ligand His-18 remains coordinated to iron. As an approach to probing structural or functional roles played by the double covalent heme-protein linkage in cyt c, we have initiated a study in which the properties of 1 are compared with those of a synthetic mono-His coordinated heme peptide containing a single covalent linkage (2). One consequence of the greater conformational restriction imposed on peptide conformation in 1 is that His-Fe(III) coordination is approximately 1.4 kcal/mol more favorable in 1 than in 2. This highlights a clear advantage conferred to cyt c by having two covalent heme-protein linkages rather than one: greater thermodynamic stability of the protein fold. EPR (11 K) and resonance Raman (298 K) studies reveal that 1 and 2 exhibit a thermal high-spin/low-spin ferric equilibrium but that low-spin character is considerably more pronounced in 1. In addition, the thioether 2-(methylthio)ethanol (MTE) coordinates 0.5 kcal/mol more strongly to 1 than to 2 in 60:40 H(2)O/CH(3)OH and only triggers the expected conversion of iron to the low-spin state characteristic of ferric cyt c in the case of 1. This demonstrates that the axial ligand field provided by an imidazole and a thioether is too weak to induce a high-spin to low-spin conversion in a ferric porphyrin. Our results suggest that a conformationally constrained double covalent heme-protein linkage, as exists in 1 and its parent protein cyt c, is an effective solution that nature has evolved to circumvent this limitation. We propose that the stronger His-Fe(III) coordination enabled by such a linkage serves to markedly enhance the effective ligand field strength of His-18. Our studies with 1 and 2 suggest that a double covalent linkage in cyt c may also enable energetically more favorable trans ligation of Met-80 than would be possible if only a single linkage were present. This would serve to further increase the stability of the protein fold and perhaps to increase the effective ligand field strength of Met-80 as well.

In vitro selection of hematoporphyrin binding DNA aptamers

DNA aptamers that bind to hematoporphyrin IX (HPIX) were isolated using an in vitro selection technique. Most aptamers obtained after the 7th and 10th rounds contained guanine-rich sequences. Binding assay using fluorescence polarization technique and structural analysis by CD spectra revealed that the parallel guanine-quartet structure of the aptamer participates in the recognition of HPIX.

De novo design of helical bundles as models for understanding protein folding and function

De novo protein design has proven to be a powerful tool for understanding protein folding, structure, and function. In this Account, we highlight aspects of our research on the design of dimeric, four-helix bundles. Dimeric, four-helix bundles are found throughout nature, and the history of their design in our laboratory illustrates our hierarchic approach to protein design. This approach has been successfully applied to create a completely native-like protein. Structural and mutational analysis allowed us to explore the determinants of native protein structure. These determinants were then applied to the design of a dinuclear metal-binding protein that can now serve as a model for this important class of proteins.

Miniaturized metalloproteins: application to iron-sulfur proteins

The miniaturization process applied to rubredoxins generated a class of peptide-based metalloprotein models, named METP (miniaturized electron transfer protein). The crystal structure of Desulfovibrio vulgaris rubredoxin was selected as a template for the construction of a tetrahedral (S(gamma)-Cys)(4) iron-binding site. Analysis of the structure showed that a sphere of 17 A in diameter, centered on the metal, circumscribes two unconnected approximately C(2) symmetry related beta-hairpins, each containing the -Cys-(Aaa)(2)-Cys- sequence. These observations provided a starting point for the design of an undecapeptide, which self assembles in the presence of tetrahedrally coordinating metal ions. The METP peptide was synthesized in good yield by standard methodologies. Successful assembly of the METP peptide with Co(II), Zn(II), Fe(II/III), in the expected 2:1 stoichiometry, was proven by UV-visible and circular dichroism spectroscopies. UV-visible analysis of the metal complexes indicated the four Cys ligands tetrahedrally arrange around the metal ion, as designed. Circular dichroism measurements on both the free and metal-bound forms revealed that the metal coordination drives the peptide chain to fold into a turned conformation. NMR characterization of the Zn(II)-METP complex fully supported the structure of the designed model. These results prove that METP reproduces the main features of rubredoxin.

De novo design and structural characterization of proteins and metalloproteins

De novo protein design has recently emerged as an attractive approach for studying the structure and function of proteins. This approach critically tests our understanding of the principles of protein folding; only in de novo design must one truly confront the issue of how to specify a protein's fold and function. If we truly understand proteins, it should be possible to design receptors, enzymes, and ion channels from scratch. Further, as this understanding evolves and is further refined, it should be possible to design proteins and biomimetic polymers with properties unprecedented in nature.

Retrostructural analysis of metalloproteins: application to the design of a minimal model for diiron proteins

De novo protein design provides an attractive approach for the construction of models to probe the features required for function of complex metalloproteins. The metal-binding sites of many metalloproteins lie between multiple elements of secondary structure, inviting a retrostructural approach to constructing minimal models of their active sites. The backbone geometries comprising the metal-binding sites of zinc fingers, diiron proteins, and rubredoxins may be described to within approximately 1 A rms deviation by using a simple geometric model with only six adjustable parameters. These geometric models provide excellent starting points for the design of metalloproteins, as illustrated in the construction of Due Ferro 1 (DF1), a minimal model for the Glu-Xxx-Xxx-His class of dinuclear metalloproteins. This protein was synthesized and structurally characterized as the di-Zn(II) complex by x-ray crystallography, by using data that extend to 2.5 A. This four-helix bundle protein is comprised of two noncovalently associated helix-loop-helix motifs. The dinuclear center is formed by two bridging Glu and two chelating Glu side chains, as well as two monodentate His ligands. The primary ligands are mostly buried in the protein interior, and their geometries are stabilized by a network of hydrogen bonds to second-shell ligands. In particular, a Tyr residue forms a hydrogen bond to a chelating Glu ligand, similar to a motif found in the diiron-containing R2 subunit of Escherichia coli ribonucleotide reductase and the ferritins. DF1 also binds cobalt and iron ions and should provide an attractive model for a variety of diiron proteins that use oxygen for processes including iron storage, radical formation, and hydrocarbon oxidation.

De novo proteins as models of radical enzymes

Catalytically essential side-chain radicals have been recognized in a growing number of redox enzymes. Here we present a novel approach to study this class of redox cofactors. Our aim is to construct a de novo protein, a radical maquette, that will provide a protein framework in which to investigate how side-chain radicals are generated, controlled, and directed toward catalysis. A tryptophan and a tyrosine radical maquette, denoted alpha(3)W(1) and alpha(3)Y(1), respectively, have been synthesized. alpha(3)W(1) and alpha(3)Y(1) contain 65 residues each and have molecular masses of 7.4 kDa. The proteins differ only in residue 32, which is the position of their single aromatic side chain. Structural characterization reveals that the proteins fold in water solution into thermodynamically stable, alpha-helical conformations with well-defined tertiary structures. The proteins are resistant to pH changes and remain stable through the physiological pH range. The aromatic residues are shown to be located within the protein interior and shielded from the bulk phase, as designed. Differential pulse voltammetry was used to examine the reduction potentials of the aromatic side chains in alpha(3)W(1) and alpha(3)Y(1) and compare them to the potentials of tryptophan and tyrosine when dissolved in water. The tryptophan and tyrosine potentials were raised considerably when moved from a solution environment to a well-ordered protein milieu. We propose that the increase in reduction potential of the aromatic residues buried within the protein, relative to the solution potentials, is due to a lack of an effective protonic contact between the aromatic residues and the bulk solution.