Evaluating the roles of the heme a side chains in cytochrome c oxidase using designed heme proteins

Heme a is a redox cofactor unique to cytochrome c oxidases and vital to aerobic respiration. Heme a differs from the more common heme b by two chemical modifications, the C-8 formyl group and the C-2 hydroxyethylfarnesyl group. The effects of these porphyrin substituents on ferric and ferrous heme binding and electrochemistry were evaluated in a designed heme protein maquette. The maquette scaffold chosen, [Delta7-H3m](2), is a four-alpha-helix bundle that contains two bis(3-methyl-l-histidine) heme binding sites with known absolute ferric and ferrous heme b affinities. Hemes b, o, o+16, and heme a, those involved in the biosynthesis of heme a, were incorporated into the bis(3-methyl-l-histidine) heme binding sites in [Delta7-H3m](2). Spectroscopic analyses indicate that 2 equiv of each heme binds to [Delta7-H3m](2), as designed. Equilibrium binding studies of the hemes with the maquette demonstrate the tight affinity for hemes containing the C-2 hydroxyethylfarnesyl group in both the ferric and ferrous forms. Coupled with the measured equilibrium midpoint potentials, the data indicate that the hydroxyethylfarnesyl group stabilizes the binding of both ferrous and ferric heme by at least 6.3 kcal/mol via hydrophobic interactions. The data also demonstrate that the incorporation of the C-8 formyl substituent in heme a results in a 179 mV, or 4.1 kcal/mol, positive shift in the heme reduction potential relative to heme o due to the destabilization of ferric heme binding relative to ferrous heme binding. The two substituents appear to counterbalance each other to provide for tighter heme a affinity relative to heme b in both the ferrous and ferric forms by at least 6.3 and 2.1 kcal/mol, respectively. These results also provide a rationale for the reaction sequence observed in the biosynthesis of heme a.     

Determination of nonligand amino acids critical to [4Fe-4S]2+/+ assembly in ferredoxin maquettes.

The prototype ferredoxin maquette, FdM, is a 16-amino acid peptide which efficiently incorporates a single [4Fe-4S]2+/+ cluster with spectroscopic and electrochemical properties that are typical of natural bacterial ferredoxins. Using this synthetic protein scaffold, we have investigated the role of the nonliganding amino acids in the assembly of the iron-sulfur cluster. In a stepwise fashion, we truncated FdM to a seven-amino acid peptide, FdM-7, which incorporates a cluster spectroscopically identical to FdM but in lower yield, 29% relative to FdM. FdM-7 consists solely of the. CIACGAC. consensus ferredoxin core motif observed in natural protein sequences. Initially, all of the nonliganding amino acids were substituted for either glycine, FdM-7-PolyGly (.CGGCGGC.), or alanine, FdM-7-PolyAla (.CAACAAC.), on the basis of analysis of natural ferredoxin sequences. Both FdM-7-PolyGly and FdM-7-PolyAla incorporated little [4Fe-4S]2+/+ cluster, 6 and 7%, respectively. A systematic study of the incorporation of a single isoleucine into each of the four nonliganding positions indicated that placement either in the second or in the sixth core motif positions,.CIGCGGC. or.CGGCGIC., restored the iron-sulfur cluster binding capacity of the peptides to the level of FdM-7. Incorporation of an isoleucine into the fifth position,.CGGCIGC., which in natural ferredoxins is predominantly occupied by a glycine, resulted in a loss of [4Fe-4S] affinity. The substitution of leucine, tryptophan, and arginine into the second core motif position illustrated the stabilization of the [4Fe-4S] cluster by bulky hydrophobic amino acids. Furthermore, the incorporation of a single isoleucine into the second core motif position in a 16-amino acid ferredoxin maquette resulted in a 5-fold increase in the level of [4Fe-4S] cluster binding relative to that of the glycine variant. The protein design rules derived from this study are fully consistent with those derived from natural ferredoxin sequence analysis, suggesting they are applicable to both the de novo design and structure-based redesign of natural proteins.     

Complete primary structure of the chicken alpha1(V) collagen chain.

Chicken alpha1(V) collagen cDNAs have been cloned by a variety of methods and positively identified. We present here the entire translated sequence of the chick polypeptide and compare selected regions to other collagen chains in the type V/XI family.     

Click and Cut: a click chemistry approach to developing oxidative DNA damaging agents

Metallodrugs provide important first-line treatment against various forms of human cancer. To overcome chemotherapeutic resistance and widen treatment possibilities, new agents with improved or alternative modes of action are highly sought after. Here, we present a click chemistry strategy for developing DNA damaging metallodrugs. The approach involves the development of a series of polyamine ligands where three primary, secondary or tertiary alkyne-amines were selected and ‘clicked’ using the copper-catalysed azide-alkyne cycloaddition reaction to a 1,3,5-azide mesitylene core to produce a family of compounds we call the ‘Tri-Click’ (TC) series. From the isolated library, one dominant ligand (TC1) emerged as a high-affinity copper(II) binding agent with potent DNA recognition and damaging properties. Using a range of in vitro biophysical and molecular techniques—including free radical scavengers, spin trapping antioxidants and base excision repair (BER) enzymes—the oxidative DNA damaging mechanism of copper-bound TC1 was elucidated. This activity was then compared to intracellular results obtained from peripheral blood mononuclear cells exposed to Cu(II)–TC1 where use of BER enzymes and fluorescently modified dNTPs enabled the characterisation and quantification of genomic DNA lesions produced by the complex. The approach can serve as a new avenue for the design of DNA damaging agents with unique activity profiles.     

Loss of major nutrient sensing and signaling pathways suppresses starvation lethality in electron transport chain mutants

The electron transport chain (ETC) is a well-studied and highly conserved metabolic pathway that produces ATP through generation of a proton gradient across the inner mitochondrial membrane coupled to oxidative phosphorylation. ETC mutations are associated with a wide array of human disease conditions and to aging-related phenotypes in a number of different organisms. In this study, we sought to better understand the role of the ETC in aging using a yeast model. A panel of ETC mutant strains that fail to survive starvation was used to isolate suppressor mutants that survive. These suppressors tend to fall into major nutrient sensing and signaling pathways, suggesting that the ETC is involved in proper starvation signaling to these pathways in yeast. These suppressors also partially restore ETC-associated gene expression and pH homeostasis defects, though it remains unclear whether these phenotypes directly cause the suppression or are simply effects. This work further highlights the complex cellular network connections between metabolic pathways and signaling events in the cell and their potential roles in aging and age-related diseases.     

Metalloprotein and redox protein design

Metalloprotein and redox protein design are rapidly advancing toward the chemical synthesis of novel proteins that have predictable structures and functions. Current data demonstrate a breadth of successful approaches to metallopeptide and metalloprotein design based on de novo, rational and combinatorial strategies. These sophisticated synthetic analogs of natural proteins constructively test our comprehension of metalloprotein structure/function relationships. Additionally, designed redox proteins provide novel constructs for examining the thermodynamics and kinetics of biological electron transfer.