Semisynthetic Nanoreactor for Reversible Single-Molecule Covalent Chemistry.

Protein engineering has been used to remodel pores for applications in biotechnology. For example, the heptameric α-hemolysin pore (αHL) has been engineered to form a nanoreactor to study covalent chemistry at the single-molecule level. Previous work has been confined largely to the chemistry of cysteine side chains or, in one instance, to an irreversible reaction of an unnatural amino acid side chain bearing a terminal alkyne.

A pivotal heme-transfer reaction intermediate in cytochrome c biogenesis.

c-Type cytochromes are widespread proteins, fundamental for respiration or photosynthesis in most cells. They contain heme covalently bound to protein in a highly conserved, highly stereospecific post-translational modification. In many bacteria, mitochondria, and archaea this heme attachment is catalyzed by the cytochrome c maturation (Ccm) proteins.

Metal and redox selectivity of protoporphyrin binding to the heme chaperone CcmE.

The interaction of heme with the heme chaperone CcmE is central to our understanding of cytochrome c maturation, a complex post-translational process involving at least eight proteins in many Gram-negative bacteria and plant mitochondria. We have shown previously that Escherichia coli CcmE can interact with heme non-covalently in vitro, before forming a novel covalent histidine-heme bond, in a redox-sensitive manner. The function of CcmE is to bind heme in the periplasm before transferring it to apocytochromes c.

Tuning the formation of a covalent haem-protein link by selection of reductive or oxidative conditions as exemplified by ascorbate peroxidase.

Previous work [Metcalfe, Ott, Patel, Singh, Mistry, Goff and Raven (2004) J. Am. Chem.

Direct transfer of membrane proteins from bacteria to planar bilayers for rapid screening by single-channel recording.

Although the examination of membrane proteins in planar bilayers is a powerful methodology for evaluating their pharmacology and physiological roles, introducing membrane proteins into bilayers is often a difficult process. Here, we use a mechanical probe to transfer membrane proteins directly from Escherichia coli expression colonies to artificial lipid bilayers. In this way, single-channel electrical recordings can be made from both of the major classes of membrane proteins, alpha-helix bundles and beta barrels, which are represented respectively by a K(+) channel and a bacterial pore-forming toxin.

Dynamic ligation properties of the Escherichia coli heme chaperone CcmE to non-covalently bound heme.

The cytochrome c maturation protein CcmE is an essential membrane-anchored heme chaperone involved in the post-translational covalent attachment of heme to c-type cytochromes in Gram-negative bacteria such as Escherichia coli. Previous in vitro studies have shown that CcmE can bind heme both covalently (via a histidine residue) and non-covalently. In this work we present results on the latter form of heme binding to a soluble form of CcmE.

Why isn't 'standard' heme good enough for c-type and d1-type cytochromes?

This perspective seeks to discuss why biology often modifies the fundamental iron-protoporphyrin IX moiety that is the very versatile cofactor of many heme proteins. A very common modification is the attachment of this cofactor via covalent bonds to two (or rarely one) sulfur atoms of cysteine residue side chains. This modification results in c-type cytochromes, which have diverse structures and functions.

C-type cytochrome formation: chemical and biological enigmas.

C-type cytochromes are proteins that are essential for the life of virtually all organisms. They characteristically contain heme that is covalently attached via thioether bonds to two cysteines in the protein. In this Account, we describe the challenging chemistry of thioether bond formation and the surprising variety of biogenesis systems that exist in nature to perform the difficult posttranslational heme attachment process.

The interaction of covalently bound heme with the cytochrome c maturation protein CcmE.

The heme chaperone CcmE is a novel protein that binds heme covalently via a histidine residue as part of its essential function in the process of cytochrome c biogenesis in many bacteria as well as plant mitochondria. In the continued absence of a structure of the holoform of CcmE, identification of the heme ligands is an important step in understanding the molecular function of this protein and the role of covalent heme binding to CcmE during the maturation of c-type cytochromes. In this work, we present spectroscopic data that provide insight into the ligation of the heme iron in the soluble domain of CcmE from Escherichia coli.

In vitro studies on thioether bond formation between Hydrogenobacter thermophilus apocytochrome c(552) with metalloprotoporphyrin derivatives.

Previously, in vitro formation of thioether bonds between Hydrogenobacter thermophilus apocytochrome c(552) and Fe-protoporphyrin IX has been demonstrated. Now we report studies on the reaction between the metalloderivatives Zn-, Co-, and Mn-protoporphyrin IX and the cysteine thiols of H. thermophilus apocytochrome c(552).

Stereoselective in vitro formation of c-type cytochrome variants from Hydrogenobacter thermophilus containing only a single thioether bond.

In vitro formation of Hydrogenobacter thermophilus cytochrome c552 has previously been demonstrated (Daltrop, O., Allen, J. W.

Interaction of heme with variants of the heme chaperone CcmE carrying active site mutations and a cleavable N-terminal His tag.

Cytochrome c maturation in the periplasms of many bacteria requires the heme chaperone CcmE, which binds heme covalently both in vivo and in vitro via a histidine residue before transferring the heme to apocytochromes c. To investigate the mechanism and specificity of heme attachment to CcmE, we have mutated the conserved histidine 130 of a soluble C-terminally His-tagged version of CcmE (CcmEsol-C-His6) from Escherichia coli to alanine or cysteine. Remarkably, covalent bond formation with heme occurs with the protein carrying the cysteine mutation, and the process occurs both in vivo and in vitro.

C-type cytochromes: diverse structures and biogenesis systems pose evolutionary problems.

C-type cytochromes are a structurally diverse group of haemoproteins, which are related by the occurrence of haem covalently attached to a polypeptide via two thioether bonds formed by the vinyl groups of haem and cysteine side chains in a CXXCH peptide motif. Remarkably, three different post-translational systems for forming these cytochromes have been identified. The evolution of both the proteins themselves and the biogenesis systems poses many questions to which answers are currently being sought.

Cytochrome c maturation. The in vitro reactions of horse heart apocytochrome c and Paracoccus dentrificans apocytochrome c550 with heme.

C-type cytochromes are characterized by having the heme moiety covalently attached via thioether bonds between the heme vinyl groups and the thiols of conserved cysteine residues of the polypeptide chain. Previously, we have shown the in vitro formation of Hydrogenobacter thermophilus cytochrome c(552) (Daltrop, O., Allen, J.

The CcmE protein of the c-type cytochrome biogenesis system: unusual in vitro heme incorporation into apo-CcmE and transfer from holo-CcmE to apocytochrome.

Three key steps of cytochrome c biogenesis in many Gram-negative bacteria, the uptake of heme by the heme chaperone CcmE, the covalent attachment of heme to CcmE, and its subsequent release from CcmE to an apocytochrome c, have been achieved in vitro. apo-CcmE from Escherichia coli preferentially bound to ferric, with high affinity (K(d), 200 nM), rather than ferrous heme. The preference for ferric heme was confirmed by competition with 8-anilino-1-naphthalenesulfonate, which bound to a hydrophobic pocket in apo-CcmE.

In vitro formation of a c-type cytochrome.

C-type cytochromes are essential for almost all organisms; they are characterized by the covalent attachment of heme to protein through two thioether bonds to a Cys-Xaa-Xaa-Cys-His peptide motif. Here we show, contrary to opinion of 30 years standing, that a c-type cytochrome can form from heme and apoprotein in vitro under mild conditions and in the absence of any biosynthesis apparatus. This reaction occurs provided formation of a disulfide bond within the Cys-Xaa-Xaa-Cys-His motif is avoided.