Abstract
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. Examination of a number of site-directed mutants of E. coli CcmE by resonance Raman spectroscopy has identified ligands of the heme iron and provided insight into the initial steps of heme binding by CcmE before it binds the heme covalently. The heme binding histidine (His-130) appears to ligate the heme iron in the ferric oxidation state, but two other residues ligate the iron in the ferrous form, thereby freeing His-130 to undergo covalent attachment to a heme vinyl group. It appears that the heme ligation in the non-covalent form is different from that in the holo-form, suggesting that a change in ligation could act as a trigger for the formation of the covalent bond and showing the dynamic and oxidation state-sensitive ligation properties of CcmE.
Highlights
C-type cytochromes are proteins that contain covalently attached heme cofactors and are essential for the life of virtually all organisms
In this work we have presented data identifying protein ligands to the heme iron in the absence of the covalent bond using resonance Raman spectroscopy and a variety of site-directed mutants of the soluble domain of E. coli CcmE that furthers our understanding of the molecular function of this novel heme chaperone
Coordination Structure of Heme in b-type CcmEЈ—resonance Raman (RR) spectra showed that ferric b-type CcmEЈ has a 5c-high spin (HS) heme, which converts to a 6c-low spin (LS) heme upon reduction of the heme
Summary
C-type cytochromes are proteins that contain covalently attached heme cofactors and are essential for the life of virtually all organisms. The heme attachment reaction appears to occur by very different pathways in different types of organisms; in humans, for example, a single protein called heme lyase is involved, whereas in E. coli at least ten proteins are essential for the process [2, 3] The latter system is known as the cytochrome c maturation (Ccm) system and comprises the proteins. In this work we have presented data identifying protein ligands to the heme iron in the absence of the covalent bond using resonance Raman spectroscopy and a variety of site-directed mutants of the soluble domain of E. coli CcmE (with its single helical membrane anchor removed) that furthers our understanding of the molecular function of this novel heme chaperone
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