Solving the structure of human H ferritin by genetically engineering intermolecular crystal contacts

Lawson, David M.; Artymiuk, Peter J.; Yewdall, S J; Smith, John L.; Livingstone, John; Treffry, Amyra; Luzzago, Alessandra; Levi, Sonia; Arosio, Paolo; Cesareni, Gianni; Thomas, Christine; Shaw, William V.; Harrison, Pauline M.

doi:10.1038/349541a0

Cited by 732 publications

(702 citation statements)

References 28 publications

Supporting

Mentioning

678

Contrasting

Unclassified

Order By: Relevance

“…A second, functionally diverse class of carboxylate-bridged diiron proteins (2-4, 65) features a helical Glu-Xxx-Xxx-His (EXXH) motif, with two rather than three residues between the liganding side chains. We have conducted a retrostructural analysis (27) of six members of this class, including three ferroxidases [ferritin (66), bacterioferritin (67), and rubrerythrin (68, 69)], ribonucleotide reductase R2 subunit (R2) (70), ⌬ 9 ACP desaturase (71), and the catalytic subunit of methane monooxygenase (72). Although there is less than 5% sequence identity common to all members of this class, their active sites are housed within a very simple pseudo-222-symmetric four-helix bundle.…”

Section: Resultsmentioning

confidence: 99%

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

Lombardi

Summa

Geremia

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

232

279

View full text Add to dashboard Cite

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 Å 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 GluXxx-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 Å. 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. P roteins use a limited repertoire of metal ion cofactors to help catalyze a multitude of reactions. For example, diiron sites (1-4) mediate reversible oxygen binding in hemerythrins, whereas they function as hydrolytic centers in phosphatases. Structurally similar diiron sites also mediate a number of oxygendependent oxidative processes. Ferritins serve as ferroxidases, while other diiron proteins catalyze hydroxylation, epoxidation, and desaturation reactions. Further, a diiron site in Escherichia coli ribonucleotide reductase is responsible for the formation of a Tyr radical. How do the structures of these proteins tune the chemical properties of a common diiron center to obtain such a diversity of highly specific catalysts? This question is being addressed through the study of the natural proteins as well as the study of small-molecule diiron complexes (1-4). Although impressive progress has been made on both fronts, these approaches have inherent limitations. The study of large proteins is hampered by their extreme complexity, and it is difficult to synthesize small-molecule models capable of simultaneously binding diiron, oxygen, and various substrates. Recently, we and others have sought a molecular middle ground between these two extremes through the design of small proteins and peptid...

show abstract

Section: Resultsmentioning

confidence: 99%

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

Lombardi

Summa

Geremia

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

232

279

View full text Add to dashboard Cite

show abstract

“…These observations indicate that the trigonal TGF-83 crystals are rather stabilized by the attraction of complementary charged surfaces and hydrophobic interactions than by the effects of individual residues. In the trigonal crystal form, dioxane might be as important for keeping symmetry-related molecules together by hydrophobic interactions as, for example, Ca2+ ions are for the formation of ferritin crystals (Lawson et al, 1991) or phosphate ions are for bovine pancreatic trypsin inhibitor crystals (Wlodawer, 1984).…”

Section: Crystal Contactsmentioning

confidence: 99%

The crystal structure of TGF‐β3 and comparison to TGF‐β2: Implications for receptor binding

et al. 1996

View full text Add to dashboard Cite

Transforming growth factors /? belong to a group of cytokines that control cellular proliferation and differentiation. Five isoforms are known that share approximately 75% sequence identity, but exert different biological activities. The structure of TGF-/?3 was solved by X-ray crystallography and refined to a final R-factor of 17.5% at 2.0 A resolution. Comp~ison with the structure of TGF-02 (Schlunegger MP, Grutter MG, 1992, Nature 358430-434; Daopin S, Piez KA, Ogawa Y, Davies DR, 1992, Science 252369-373) reveals a virtually identical central core. Differences exist in the conformations of the N-terminal a-helix and in the P-sheet loops. In TGF-03, the N-terminal cu-helix has moved = 1 A away from the central core. This movement can be correlated with the mutation of Leu 17 to Val and Ala 47. to Pro in TGF-63. The /?-sheet loops rotate as a rigid body 9" around an axis that runs approximately parallel to the dimer axis. If these differences are recognized by the TGF-0 receptors, they might account for the individual cellular responses. A molecule of the precipitating agent dioxane is bound in a crystal contact, forming a hydrogen bond with Trp 32. This dioxane may occupy a carbohydrate-binding site, because dioxane possesses some structural similarity with a carbohydrate. The dioxane is in contact with two tryptophans, which are often involved in carbohydrate recognition.

show abstract

“…The ability of the protein to catalyse Fe(I1) oxidation is well established [4,5], but the catalytic mechanism and the subsequent stages leading to mineralisation are not clearly defined. The use of site-directed mutagenesis has implicated a number of residues in iron-binding [4-71, but one of the reasons for the lack of direct information on ironbinding positions is that crystallisation of mammalian ferritins has always involved metal ions, usually Cd2+ or Ca2' [1,8]. Such metals compete with binding of Fe2' or Fe3' ions and thus prevent the unequivocal assignment of their sites.…”

Section: Introductionmentioning

confidence: 99%

Direct observation of the iron binding sites in a ferritin

et al. 1994

Self Cite

View full text Add to dashboard Cite

X-Ray analysis of the ferritin of Escherichia coli (EC-FTN) and of EC-FTN crystals soaked in (NH,),Fe(SO,), has revealed the presence of three iron-binding sites per subunit. Two of these form a di-iron site in the centre of the subunit as has been proposed for the 'ferroxidase centres' of human ferritin H chains. This di-iron site, lying within the 4-alpha-helix bundle, resemble those of ribonucleotide reductase, methane monoxygenase and haemerythrin.The third iron is bound by ligands unique to EC-FTN on the inner surface of the protein shell. It is speculated that this state may represent the nucleation centre of a novel type of Fe(III) cluster, recently observed in EC-FTN.

show abstract

Solving the structure of human H ferritin by genetically engineering intermolecular crystal contacts

Cited by 732 publications

References 28 publications

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

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

The crystal structure of TGF‐β3 and comparison to TGF‐β2: Implications for receptor binding

Direct observation of the iron binding sites in a ferritin

Contact Info

Product

Resources

About